ABB PEB_PEBR_Ux.0.1-xxx_PH Instructions

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ABB PEB_PEBR_Ux.0.1-xxx_PH Instructions | Manualzz

9AKK107046A2227 │

20.11.2020

KNX Technical Reference Manual

ABB i-bus

®

KNX PEONIA

PEB/U2.0.1-xxx 2 / 4 gang

PEB/U3.0.1-xxx 3 / 6 gang

PEB/U5.0.1-xxx 5 /10 gang

PEBR/U2.0.1-xxx 2 / 4 gang with RTC

PEBR/U3.0.1-xxx 3 / 6 gang With RTC

PEBR/U5.0.1-xxx 5 /10 gang with RTC

KNX Technical Reference Manual

ABB i-Bus ® KNX PEONIA

1 Information on the manual ........................................................................................ 3

1.1

General information ........................................................................................ 3

1.2

Structure of the manual ................................................................................... 3

1.3

Symbol of the manual ..................................................................................... 4

2 Safety ........................................................................................................................ 5

2.1

Intended use ................................................................................................... 5

2.2

Improper use ................................................................................................... 5

2.3

Target groups and qualifications ..................................................................... 5

2.4

Liability and warranty ...................................................................................... 5

3 Environment .............................................................................................................. 6

4 Setup and Function ................................................................................................... 7

4.1

Features of function and equipment ................................................................ 7

4.2

Overview of devices ........................................................................................ 8

5 Technical data ......................................................................................................... 12

6 Circuit diagrams and dimensional drawings ............................................................ 14

6.1

Circuit diagram .............................................................................................. 14

6.2

Dimensional drawing ..................................................................................... 14

7 Installation and electrical connection ...................................................................... 16

7.1

Requirements for the electricians.................................................................. 16

7.2

Mounting ....................................................................................................... 17

7.3

Replacement of rocker button ....................................................................... 22

7.4

Electrical connection ..................................................................................... 23

7.5

Maximum number of PEONIA devices per TP line ....................................... 24

8 Commissioning ....................................................................................................... 25

8.1

Software ........................................................................................................ 25

8.2

Preparatory steps.......................................................................................... 25

8.3

Assigning a physical address ........................................................................ 25

8.4

Assigning the group address(es) .................................................................. 26

8.5

Selecting the application program ................................................................. 26

8.6

Differentiating the application program ......................................................... 26

9 Operation ................................................................................................................ 27

9.1

Control buttons.............................................................................................. 27

9.2

LED concept ................................................................................................. 28

9.3

Proximity sensor operation ........................................................................... 28

9.4

RTC function operation ................................................................................. 29

10 Cleaning .............................................................................................................. 33

11 Maintenance ........................................................................................................ 33

12 Description of applications / Objects ................................................................... 34

12.1

Overview of applications ............................................................................ 34

12.2

Application “General” ................................................................................. 35

12.3

Application “Temperature sensor – Non RTC version” .............................. 37

12.4

Application “Proximity sensor function” ...................................................... 38

12.5

Application “Energy saving mode” ............................................................. 44

12.6

Application “Top Ambient LED” ................................................................. 46

12.7

Application “Bottom Ambient LED” ............................................................ 47

12.8

Application “LCD display backlight” ........................................................... 49

12.9

Application “LCD display subdisplay”......................................................... 51

12.10

Application “1-button switching” ................................................................. 52

12.11

Application “1-button dimming” .................................................................. 53

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12.12

Application “1-button blind” ........................................................................ 54

12.13

Application “1-button short-long operation” ................................................ 57

12.14

Application “1-button value transmitter” ..................................................... 61

12.15

Application “1-button value transmitter, 2 objects” ..................................... 64

12.16

Application “1-button light scene extension unit with memory function” ..... 72

12.17

Application “1-button step switch” .............................................................. 74

12.18

Application “1-button multiple operation” ................................................... 76

12.19

Application “1-button operating mode, “Adjust thermostat settings” .......... 81

12.20

Application “2-button switching” ................................................................. 84

12.21

Application “2-button dimming” .................................................................. 85

12.22

Application “2-button blind” ........................................................................ 86

12.23

Application “2-button value transmitter” ..................................................... 88

12.24

Application “2-button value dimming sensor” ............................................. 90

12.25

Application “2-button step switch” .............................................................. 92

12.26

Application “Status / Orientation LED ” ...................................................... 93

12.27

Application “Symbol LED function” ............................................................ 97

12.28

Application “Dynamic display – Dimming”.................................................. 98

12.29

Application “Dynamic display – Blind” ........................................................ 99

12.30

Application “Dynamic display – Scene”.................................................... 100

12.31

Application “Telegram cyclic” ................................................................... 100

12.32

Application “Priority”................................................................................. 104

12.33

Application “Logic gate” ........................................................................... 104

12.34

Application “Gate” .................................................................................... 108

12.35

Application “Staircase lighting” ................................................................ 112

12.36

Application “Light scene actuator” ........................................................... 115

12.37

Application “Delay” .................................................................................. 117

12.38

Application “Min/max value transducer” ................................................... 120

12.39

Application “Threshold value hysteresis” ................................................. 122

12.40

Application “RTC” .................................................................................... 126

12.41

Communication object for RTC ................................................................ 185

13 Information about planning and application ....................................................... 211

13.1

Auxiliary power supply capacity ............................................................... 211

13.2

KNX room climate control ........................................................................ 212

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1 Information on the manual

1.1

General information

Please read this manual through carefully and adhere to the information listed. This will ensure reliable operation and long service life of your product.

For reasons of clarification, this manual does not contain all the detailed information on all the models of the product, nor can it taken into consideration all conceivable circumstances related to installation, operation and maintenance.

If additional information is required or problems arise that are not dealt with in this manual, the necessary information can be requested from the manufacturer.

The product has been manufacture according to the latest valid regulations governing technology and is operationally reliable. It has been tested and left the factory in a technically safe and reliable state.

To maintain this state for the period of its operation, the specifications of this manual must be observed and adhered to.

Modifications and repairs to the product must only be undertaken if the manual expressly permits this.

It is only the adherence to the safety instructions and all safety and warning symbols in this manual that will ensure the optimum protection of the user and the environment as well as the safe and trouble-free operation of the product .

1.2

Structure of the manual

This manual provides you with the detailed technical information on the device, its installation and programming. The use of the device is explain by means of examples.

• The chapters "Information on the manual", "Safety" and "Environment" contain general specifications and basic information as well as a description of functions.

• Chapters "Setup and function", "Technical data" and "Circuit diagrams and dimensional drawings" explain the device instrumentation.

• Chapter "Installation and electrical connection" describes the installation, mounting and the electrical connections.

• Chapters "Commissioning" and "Operation" contain instructions on commissioning and how to operate the device.

• One or several chapters "Application ..." contain general information on the individual applications of the device, the setting options of all device parameters and a list of all objects.

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1.3

Symbol of the manual

Danger-danger to life

This symbol in connection with the signal word “Danger” indicates dangerous situations which could lead to immediate death or to serious injury.

Warning-danger to life

This symbol in connection with the signal word “Warning” indicates dangerous situations which could lead to immediate death or to serious injury.

Caution-risk to injury

This symbol in connection with the signal word “Caution” indicates a possibly dangerous situations which could lead to slight or moderately serious injury.

Attention-damage to property

This symbol indicates a possibly harmful situation. Non-observance of the safety instructions can lead to damage or destruction of the product.

NOTE

This symbol indicates information or references to addition useful topics. This is not a signal word for a dangerous situation.

This symbol refers to integrated video with addition information on the respective chapter. An Acrobat Reader from Version 9.0 is required to view the videos.

This symbol indicates information on the protection of the environment.

Examples on application, installation and programming are displayed with a grey background.

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2 Safety

2.1

Intended use

The device must only be operate within the specified technical data!

Extensive functions are available for the control elements. The scope of applications is contained in chapter "Application ... " (only in languages of the countries EN and CN).

The integrated bus coupler makes possible the connection to a KNX bus line.

Note: They may only be install in dry interior rooms in flush-mounted sockets according to BS 4662:2006+A1:2009.

2.2

Improper use

The device represents a danger if it is improperly used. Each non-intended use is deem improper use. The manufacturer is not liable for damages resulting from such improper use. The associated risk is borne by the user/operator.

The device must never be use outdoors or in bathroom areas. Do not push objects through the openings in the device. The device has an integrated bus coupler. The use of an additional bus coupler is therefore not admissible.

2.3

Target groups and qualifications

Installation, commissioning and maintenance of the product must only be carried out by trained and properly qualified electrical installers. The electrical installers must have read and understood the manual and follow the instructions provided. The operator must adhere to the valid national regulations in his country governing the installation, functional test, repair and maintenance of electrical products.

2.4

Liability and warranty

Improper use, non-observance of this manual, the use of inadequately qualified personnel, as well as unauthorized modification excludes the liability of the manufacturer for the damages caused. It voids the warranty of the manufacturer.

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3 Environment

Consider the protection of the environment!

Used electric and electronic devices must not be disposed of with domestic waste.

– The device contains valuable raw materials which can be recycled.

Therefore, dispose of the device at the appropriate collecting depot

All packaging materials and devices bear the markings and test seals for proper disposal. Always dispose of the packaging material and electric devices and their components via the authorized collecting depots and disposal companies.

The products meet the legal requirements, in particular the laws governing electronic and electrical devices and the REACH ordinance.

(EU Directive 2002/96/EC WEEE and 2002/95/EC RoHS)

(EU REACH ordinance and law for the implementation of the ordinance (EC)

No.1907/2006)

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4 Setup and Function

4.1

Features of function and equipment

The 2/4gang, 3/6gang, 5/10gang and 2/4gang with RTC, 3/6gang with RTC, 5/10gang with RTC control elements are part of the ABB i-bus® KNX sensor PEONIA KNX sensor range. They are monoblock application modules, which are suitable for installation in flush-mounted boxes according to BS 4662:2006+A1:2009. The devices are equipped with an integrated bus coupler.

The control elements can send switching, dimming or blind control commands to KNX actuators. They can also be used for storing and/or sending light scenes.

The following table lists the options for use:

Special features

• Status illumination

• Orientation illumination

• Freely programmable

• LED colour concept

• Day / night switchover of the LEDs

• Replaceable rocker for symbol button

• General functions

• Comprehensive application program

• Proximity sensor function

• Energy saving mode

Function

• Switching

• Dimming

• Blind

• Value sender

• Light scene extension unit

• Multiple operation

• Step switch

• Short/long operation

• Logic functions

(separate logic and value objects)

• among others

General functions

• Light scene actuator

• Logic

• Delay

• Staircase lighting

• Preset

• Cyclic telegram

• Flashing

• Gate

• Min/max value transducer

• Threshold value / hysteresis

• Priority

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4.2

Overview of devices

4.2.1 Front – Picture of product

Ambient LED

Contact button

Push button(5x)

Ambient LED

Push button(5x)

LED(10x)

LED(10x)

Proximity sensor

Ambient LED

Proximity sensor

Ambient LED

Product with RTC Product without RTC

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4.2.2 Rear – Picture of product

Security clip Security clip

Optional – to be purchase separately

KNX connection pin

Aux power supply connection pin

Claw Claw

Product with RTC Product without RTC

Optional – to be purchase separately

KNX connection pin

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4.2.3 Bottom – Picture of product, location of programming button and temperature sensor

Temperature sensor

Product with RTC

Ambient LED

Programming button

Temperature sensor Ambient LED

Product without RTC

Programming button

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4.2.4 Front without rocker cover plate – Picture of product

Push button(10x)

Rocker

Product with RTC

LED(15x)

Push button(10x)

LED(15x)

Rocker

Product without RTC

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5 Technical data

Control element

Supply KNX bus voltage

Current consumption via bus

Power consumption via bus

Supply auxiliary bus voltage

Current consumption via auxiliary power supply

21…31 V DC

< 12 mA

Maximum 250 mW

21…31 V DC

< 120 mA

Power consumption via auxiliary power supply

Electrical endurance: IEC 60669-2-5

Connections KNX

Operating and display

Maximum 1.5W

Via bus connection terminals,

0.8 mm Ø, solid

Programming button/LED For assignment of the physical address elements

Degree of protection

Protection class

IP 20

III

To EN 60529

To EN 61140

Overvoltage category III To EN 60664-1 Isolation category

Pollution degree

2 To EN 60664-1

KNX safety extra low voltage

Temperature Operation range Storage

Transport

Ambient conditions

Maximum air humidity

Maximum air pressure

Type

Dimensions

Width W in mm

Mounting depth in mm

SELV 24 V DC

- 5 °C…+45 °C

-25 °C…+55 °C

-25 °C…+70 °C

95 %, no condensation allowed

Equivalent to 2000 m altitude

2.6.2.1 /4.6.2.1 /8.6.2.1 /12.6.2.1

90 x W x 64.5 mm (H x W x D)

36 /72 /144 /216

64.5

Weight in kg

Mounting position

Housing/color

Approvals

CE mark

KNX acc. to EN 50090-1, -2

0.15

Vertical

Plastic housing, gray

Certification

In accordance with the EMC guideline and low voltage guideline

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LCD display screen

ITEM

LCD type

Color requirement

TFT

Negative display,

Module size

Active area

(from ID view) resolution

50(W)x69.2(H)

57.6x35.4

320x196

Backlight Light 4 White LED units mm mm dots

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6 Circuit diagrams and dimensional drawings

6.1

Circuit diagram

B= bus (KNX)

A= auxiliary supply

6.2

Dimensional drawing

Front / side / top dimension:

Product with RTC

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Product without RTC

Rocker

No Product description

1 2/4 Gang with RTC

2 3/6 Gang with RTC

3 5/10 Gang with RTC

4 2/4 Gang

5 3/6 Gang

6 5/10 Gang

7 Rocker 2/4 Gang with

RTC

8 Rocker 3/6 Gang with

RTC

9 Rocker 5/10 Gang with

RTC

10 Rocker 2/4 Gang

11 Rocker 3/6 Gang

12 Rocker 5/10 Gang

X(mm)

86

104.3

140.7

86

86

143.55

18

18

18

42.85

28.47

28.47

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7 Installation and electrical connection

Warning

Electric voltage!

Risk of death due to electrical voltage of 230 V during shortcircuit in the low-voltage line.

– Low-voltage and 230 V lines must not be installed together in a flush-mounted socket!

7.1

Requirements for the electricians

Warning

Electric voltage!

Install the device only if you have the necessary electrical engineering knowledge and experience.

• Incorrect installation endangers your life and that of the user of the electrical system.

• Incorrect installation can cause serious damage to property, e.g. due to fire.

The minimum necessary expert knowledge and requirements for the installation are as follows:

• Apply the "five safety rules" (DIN VDE 0105, EN 50110):

1. Disconnect from power;

2. Secure against being re-connected;

3. Ensure there is no voltage;

4. Connect to earth and short-circuit;

5. Cover or barricade adjacent live parts.

• Use suitable personal protective clothing.

• Use only suitable tools and measuring devices.

• Check the supply network type (TN system, IT system, TT system) to secure the following power supply conditions

(classic connection to ground, protective earthing, necessary additional measures, etc.).

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7.2

Mounting

7.2.1 Installation consideration

The 2-4gang, 3-6gang, 5-10gang and 2-4gang with RTC, 3-6gang with RTC, 5-10gang with RTC control elements are surface mounted device (AP) with an integrated bus coupler. The device with RTC function operates with additional supply voltage. It can be install on flush-mounted sockets (UP) (VDE, China, and BS).

Selection of a suitable installation location for the controller and suitable parameter settings are essential for good temperature and proximity detection.

- The room temperature controller should be installed approximately

150 cm above the floor and 50 cm from the door frame.

- The room temperature controller should be installed on a wall opposite the radiator.

- The radiator and the room temperature controller must not be separated by corners in the room.

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- The room temperature controller should not be installed near a radiator or behind curtains.

- The room temperature controller should also not be installed on an exterior wall - low outside temperatures will influence the temperature regulation.

- The room temperature controller must not be exposed to direct contact with liquids.

- Temperature regulation will also be affected by exposure to heat from electrical appliances and direct sunlight on the ambient temperature controller.

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7.2.2 Installation of the device

1. Install the supporting metal plate onto the flush-mounted box (“TOP” toward the top) and screw it on to secure.

2. Install KNX and auxilary (RTC version) connectors onto the pins at the back of the device. Insert the device aiming at the rectangular hole of the supporting metal plate and push at the front of the device in until it flush with the surface of the wall. The metal clip (1) and security clip (2) secure and limit the movement of the device in all direction.

1

2

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3. Optional – security clip can be purchase separately and clip at the side of the device

4. To remove the device, use finger to pull the device out from side (RTC button or metal strip) and create an opening between the device and the wall. Hold onto the three sides near the upper area of the device and pull outward until it was remove out from the supporting metal plate.

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5. To remove device install with security clip, a removal tools (come together with the security clip) will be required. Use finger to pull the device out from side (RTC button or metal strip) and create an opening between the device and the wall. Hold onto the three sides near the upper area of the device and pull outward until it stop to display the security clip. Insert the removal tools into the side of the device as per diagram.

Once removal tools is in place, device would be able to be remove out from the supporting metal plate.

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7.3

Replacement of rocker button

1. Press down onto the identified area (circle) on the rocker that need to be replace.

While pressing down on the rocker, at the same time push the rocker parallel toward the left of the device to slide and remove the rocker from the device.

2. Place the new rocker on the placement as per picture and ensure that the rocker surface is flush with existing rocker of the device. Press down on the identified area

(circle) on the rocker and push the left side of the rocker toward the right until the rocker is install in place.

Error!

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7.4

Electrical connection

B= bus (KNX)

A= auxiliary supply

System topology illustration

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7.5

Maximum number of PEONIA devices per TP line

*Estimated under 5-gang without RTC & 5-gang with RTC

The system capacity calculation is based on the worst-case scenario as per describe in the table below:

System

Capacity per line

Prerequisite

Maximum capacity of 5gang RTC

Total Cable length (Max)

Distance in between two device

Lowest working Voltage of Auxiliary power supply

Total number of operating devices synchronously

Cable wire diameter

16

350

20

10

3

0.6

pcs m m

V pcs mm

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8 Commissioning

8.1

Software

Note

The devices are products of the KNX system and meet KNX guidelines. Detailed expert knowledge by means of KNX training sessions for a better understanding is assume.

To start the device a physical address must be assign first. The physical address is assign and the parameters are set with the Engineering Tool Software ETS (from version ETS 4.2 – Build 3884, ETS 5).

8.2

Preparatory steps

1. Connect a PC via the KNX interface, e.g. the commissioning interface / adapter

IP/S 3.1.1, to the KNX bus line. The Engineering Tool Software ETS (from version ETS 4.2 – Build 3884, ETS 5) must have been install on the PC.

2. Switch on the bus voltage.

8.3

Assigning a physical address

Use a tool to press the programming button at the bottom of the device (right side, specified hole). The diameter of the tool should be less than 2mm.

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8.4

Assigning the group address(es)

The group addresses are assigne in connection with the ETS.

8.5

Selecting the application program

Please contact our Internet support unit (www.abb.com/KNX). The application is loaded into the device via the ETS.

8.6

Differentiating the application program

Various functions can be implement via the software application (ETS) (detailed descriptions of parameters are contained as Help text in chapter "Application ..." (only in languages of the countries EN and CN).

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9 Operation

9.1

Control buttons

The rocker (in rectangular area marked) need to be press with strength for operation to carry out. Device with RTC function will have capacitive button on the right side of the device. Operation is by touching the elliptical region with fingers

Product with RTC Product with RTC

Product without RTC Product with RTC

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9.2

LED concept

The KNX function are supported by an innovation LED colour concept

Rocker / Symbol LED

Colour

Red

Green

Yellow

Blue

Red-Orange

Violet

White

Meaning

“On” Status

“Off” Status

Lighting

Blind control

Room temperature control (RTC)

Scene

Neutral / no assignment of function

Ambient LED

Colour

Red

Green

Yellow

Blue

Red-Orange

Violet

White

Meaning

Neutral / no assignment of function

Neutral / no assignment of function

Neutral / no assignment of function

Neutral / no assignment of function

Neutral / no assignment of function

Neutral / no assignment of function

Neutral / no assignment of function

9.3

Proximity sensor operation

Proximity sensor type

Trigger method

Sensing distance

Detect speed

Trigger objects

Operating condition

Recommend install requirement

Infrared Ray

To be activate with a flat hand in parallel to the device. Triggering hand must be in front of the device.

10mm ~ 50mm from surface

Approx. 0.2m/s

Object equal or bigger than teenager hand shape, no black colour and IR light absorption object

Less than 3000Lux , no direct sunlight , no direct spotlight , no direct IR light.

If saturation happen, upon it relieve, IR sensor revert back to operation in 1 second

No object in 25cm

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9.4

Switching between operation

Up button

Down button

Fan button

Menu, On/Off button,

Switching between operation

The function of switching between operation would only be available when multiple pages function is activated for display in the "Page Setting" parameter. The operation page that is not selected from the "Page Setting" will not be displayed when switching between operation is trigger. When the desired operation page is selected and remain for more than 3 sec, the display operation page is automatic confirms and will remain on the selected operation page until the next operation page selection is activated. For example, after the user has selected to adjust the temperature on the VRV operation page, the operation page will remain on the VRV operation page until the next operation page selection is activated.

Operation logic of the display page

RTC operation page Display page operating sequences RTC RTC operation state selection

RTC mode selection

VRV

Up/down button

Adjustment of temperature

Fan button Fan speed adjustment

(auto, 1, 2, 3, 4,

5)

Menu button short press

Enter into operation state

(heating/cooling) selection, blinking of icon

Menu button long press

On or off RTC function

Heating / cooling selection

Comfort /

ECO mode selection

Confirm selection, blinking stop

Enter into mode selection, blinking of icon

On or off RTC function

Confirm selection, blinking stop

Enter into

VRV operation page

On or off

RTC function

VRV operation page

Adjustment of VRV temperature

Fan speed adjustment

(auto, 1, 2, 3, 4, 5)

VRV operation state selection

Adjustment of VRV operation state

(Fan/heating/cooling/Auto/

Dehumidification)

Confirm selection, blinking stop

Enter into operation state

(heating/cooling/fan) selection, blink of icon

On or off VRV function

Enter into Fresh air operation page

On or off VRV function

Fresh air operation page

Fresh air

Not applicable

Fan speed adjustment (off,

1, 2, 3, 4, 5)

Enter into RTC operation page

On or off Fresh air function

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9.5

RTC function operation

Up button

Down button

Fan button

Menu, On/Off button,

Switching between operation

9.5.1 Setting of the setpoint temperature

A single press on the up or down button will adjust the setpoint temperature by 0.5 °C.

Continues press on the up or down button will accelerate the adjustment of the set temperature at a speed of about 2°C per second

9.5.2 Setting of Fan speed

Function will be only be available if heating / cooling control is select as fan coil control.

A single press on the fan button will adjust the fan speed. Continues press on the fan button will have no reaction. Fan speed adjustment will be in looping sequence.

9.5.3 Selection of operating state

Function will only be available if “Combine heating and cooling mode” with “on-site/via extension unit and via object” is select. A single press on the menu button will enter into operation mode selection (blinking of symbol). Press on up or down button will adjust the operating mode (heating / cooling). Upon selection, symbol will stop blinking after 3 sec. Once blinking stop, operating mode is confirm.

9.5.4 Selection of mode

If “Combine heating and cooling mode” and “on-site/via extension unit and via object” is

Selected. ‘Menu’ button need to be press twice to enter into mode selection else press once will enter into mode selection. Press on up or down button will adjust the operating mode (comfort / ECO). Upon selection, symbol will stop blinking after 3 sec. Once blinking stop, mode is confirm.

9.5.5 Switching between operation

When other operation page is activated via "Page Setting" parameter, need to press the menu button 3 times in order to switch to other operation page.

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9.5.6 On/Off RTC function

To turn on or off RTC controller, press and hold on menu button for 3 sec.

9.6

VRV function operation

Up button

Down button

Fan button

Menu, On/Off button,

Switching between operation

9.6.1 Setting of the setpoint temperature

A single press on the up or down button will adjust the setpoint temperature by 0.5 °C.

Continues press on the up or down button will accelerate the adjustment of the set temperature at a speed of about 2°C per second.

9.6.2 Setting of Fan speed

A single press on the fan button will adjust the fan speed. Continues press on the fan button will have no reaction. Fan speed adjustment will be in looping sequence.

9.6.3 Selection of VRV operating state

A single press on the menu button will enter into VRV operation mode selection

(blinking of symbol). Press on up or down button will adjust the operating mode (Fan / heating / cooling / Auto / Dehumidification). Upon selection, symbol will stop blinking after 3 sec. Once blinking stop, operating state is confirm.

9.6.4 Switching between operation

When other operation page is activated via "Page Setting" parameter, need to press the menu button 2 times in order to switch to other operation page.

9.6.5 On/Off VRV function

To turn on or off VRV controller, press and hold on menu button for 3 sec.

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9.7

Fresh air function operation

Up button

Down button

Fan button

Menu, On/Off button,

Switching between operation

9.7.1 Setting of Fan speed

A single press on the fan button will adjust the fan speed. Continues press on the fan button will have no reaction. Fan speed adjustment will be in looping sequence

9.7.2 Switching between operation

When other operation page is activated via "Page Setting" parameter, need to press the menu button 1 times in order to switch to other operation page.

9.7.3 On/Off Fresh air function

To turn on or off Fresh air controller, press and hold on menu button for 3 sec 。

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10 Cleaning

Caution! - Risk of damaging the device!

When spraying on cleaning agents, these can enter the device through crevices.

– Do not spray cleaning agents directly onto the device.

■ Aggressive cleaning agents can damage the surface of the device.

– Never use caustic agents, abrasive agents or solvents

- Clean dirty devices with a soft dry cloth.

- If this is insufficient, the cloth can be moisten slightly with a soap solution.

11 Maintenance

The unit is maintenance-free. In case of damage (e.g., during transport or storage), do not perform repairs. Once the unit is open, the warranty is void!

Access to the device must be guarantee for operation, testing, inspection, maintenance and repairs (according to DIN VDE 0100-520).

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12 Description of applications / Objects

12.1

Overview of applications

The application program for the control element contains the applications listed:

General setting

Temperature sensor – Non RTC version

Proximity sensor function

Energy saving function

Top Ambient LED

Bottom Ambient LED

LCD display backlight

LCD display subdisplay

1-button switching

1-button dimming

1-button blind

1-button short-long operation

1-button value transmitter

1-button value transmitter, 2 objects

1-button light scene extension unit with memory function

1-button step switch

1-button multiple operation

1-button operating mode, Adjust thermostat settings

2-button switching

2-button dimming

2-button blind

2-button value transmitter

2-button value dimming sensor

2-button step switch

Status / Orientation illumination LED

Symbol LED function

Dynamic display – Dimming

Dynamic display – Blind

Dynamic display – Scene

Cyclic telegram

Priority

Logic gate

Gate

Staircase lighting

Light scene actuator

Delay

Min/max value transducer

Threshold value hysteresis

Room Temperature Controller (RTC)

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12.2

Application “General”

General setting of device rocker configuration, Left/Right individual – 1 button or

Left/Right pair – 2 button and master status / symbol LED brightness activate/deactivate by group object

12.2.1 General – Send cyclic "In operation" object

Options Send value “0” cyclically

Send value “1” cyclically

– The "In operation" communication object serves to inform that the controller still operates. Value "1" is sent cyclic. This parameter is use to set the cycle for sending. If the cyclic telegram fails, the function of the device is faulty and the air-conditioning of the room can be maintain with a forced operation. However, for this the system and/or actuator must have "Forced operation" function.

12.2.2 General – Send cyclic "In operation" time (min)

Options Time input from 5 min to 3000 min

– Interval time of sending cyclic

12.2.3 Common parameter – Rocker 1 - 5

Options Inactive

Left/Right individual – 1 button

Left/Right pair – 2 button

Left/Right individual – 1 button: Rocker will be split into 1 st (left) and 2 nd (right) button.

Individual button will have its own assign application that make a set of parameters and communication objects. When the 1 st (left) or 2 nd (right) button is actuate or release, a telegram is sent out.

Left/Right pair – 2 button: Rocker will function as “rocker total”, Both left and right button will have the same assign application that make a set of parameters and communication objects. When either left or right button is actuate or release, a telegram is send out. It does not differentiates here between whether the rocker is operate on the left or right button.

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12.2.4 Common parameter – Master - status/symbol LED brightness activate/deactivate by group object

Options Inactive

1 = LED on / 0 = LED off

1 = LED off / 0 = LED on

This 1 bit communication object is use as master control of the Master - status/symbol

LED brightness. Example application can be for turning off the status / symbol LED illumination during the night. When the application is apply combine with proximity sensor function and/or energy saving mode. The operation is a follow:

Note: Status/symbol LED illumination to be deactivated by group object setting must be in “1 = LED on / 0 = LED off”

Either proximity sensor function and/or energy saving mode is activate.

1 = LED: Status/Symbol illumination operator as per standard operation

0 = LED: Status/Symbol Illumination will turn off

- Proximity sensor trigger = Status/Symbol LED illuminate up and upon “Time before status change from active to efficiency mode in second” in Energy saving mode expire, Status/Symbol LED illumination will be off (not minimum), energy saving mode must be activate to compliment Proximity sensor function.

- Energy saving mode = Status/Symbol LED illuminate up and upon “Time before status change from active to efficiency mode in second” expire, Status/Symbol

LED illumination will be off (not minimum)

If proximity sensor function and energy saving mode is not activate.

1 = LED: Status/Symbol illumination operator as per standard operation

0 = LED: Status/Symbol illumination will turn off and remain off until 1 bit communication object status is revert back to 1.

12.2.5 Objects no

No

2

Object name

LED illumination controller

Data type

1 Bit DPT 1.001

Flags

C, W

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12.3

Application “Temperature sensor – Non RTC version”

The device can be activate as temperature sensor. As such it serves as slave device/temperature sensor for a room temperature controller which functions as master device. Slave devices are to be link to the master device with the appropriately labelled communication objects. The slave device handles the room temperature control functions of the master device.

12.3.1 Common parameter – Send measured values

Options Only cyclical

Cyclic and during change

The "Send measured values" parameter specifies whether the actual temperature is to be sent out only cyclically if the actual temperature has also changed. However, it can also be specified whether the actual temperature is always sent out in the interval in which the "Cycle time for the sending of the actual temperature" parameter is set.

12.3.2 Common parameter – Send cyclic "Measure temperature" (hh:mm:ss)

Options Input from 00:00:25 to 01:30:00

The actual temperature is sent on the bus cyclically. The "Cycle time for sending the actual temperature" parameter determines the interval after which a new sending out of the actual temperature occurs.

12.3.3 Common parameter – Temperature difference for sending within the cycle time (x

0.1 K)

Options Input from 1 to 255

Note: This parameter is only visible if the "Send measured values" parameter is set on "Cyclic and during change of value".

The actual temperature is sent on the bus cyclically. The "Cycle time for sending the actual temperature" parameter determines the interval after which a new sending out of the actual temperature occurs.

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12.3.4 Common parameter – Temperature difference for sending within the cycle time (x

0.1 K)

Options Input from -127 to 127

If the measured temperature is distort by external influences or the device is mount at a location, where it is always constantly being measured too much or too little, a compensation value for the temperature measurement can be set. The compensation value is specify via the "Offset of the temperature sensor" parameter. The mounting location of the controller and the suitable selection of the parameter settings are decisive for a good temperature reading.

12.3.5 Objects no

No

4

Object name

TS output

Data type

2 byte DPT 9.001

Flags

C, T

12.4

Application “Proximity sensor function”

The device have proximity sensor integrate at the rocker position. It will activate the status/symbol LED illumination and LCD display (RTC controller) when object are place/move close to the surface of the device. It will have the option to send out an assign telegram when proximity sensor is trigger; there will also be an option to send off telegram automatically (like presence detector).

Note: The duration of resetting proximity sensor trigger is following the “Time before status change from active to efficiency mode (sec)”, energy saving mode must be activate to compliment Proximity sensor function.

12.4.1 Common parameter – Proximity sensor function activate / deactivate by group object

Options Inactive

1 = Deactivated / 0 = Activated

1 = Activated / 0 = Deactivated

This parameter is use to define whether the proximity sensor function can be activate or deactivate by a 1 bit communication object via the bus line

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12.4.2 Common parameter – Reinstate proximity sensor function group object last status after bus voltage recovery

Options Deactivated

Activated

Note: This parameter is only visible if “Proximity sensor function activate / deactivate by group object” is activate.

The " Reinstate proximity sensor function group object last status after bus voltage recovery" parameter is use to specify whether the device status for “Proximity sensor function activate/deactivate by group object” is to be reinstate after a bus voltage failure and subsequent return of bus voltage.

Deactivate: After a bus voltage failure and subsequent return of bus voltage “Proximity sensor function activate/deactivate by group object” status have to be updated via bus line.

Activate: After a bus voltage failure and subsequent return of bus voltage “Proximity sensor function activate/deactivate by group object” status will be reinstate back as per before a bus voltage failure.

12.4.3 Common parameter – Send telegram when proximity sensor is trigger – primary function

Options Inactive

Value 1

Value 2

Alternating value1/value2

This parameter is use to specify whether the trigger of proximity sensor will sends out

"Value 1" or "Value 2". With the behavior "Alternating Value1/Value2", switching is always between Value 1 and Value 2. That means, for example, if value 1 was last sent out, a renewed trigger of the proximity sensor will send out value 2. When the proximity sensor is trigger again, value 1 is again sent out, etc. The proximity sensor trigger thus always remembers the last state and then switches over to the other value.

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12.4.4 Common parameter – Interval time for proximity sensor to resend telegram (sec)

Options Input from 1 to 1800

Note: This parameter is only visible if “Send telegram when proximity sensor is trigger – primary function” is activate.

This parameter is use to specify the duration that proximity sensor will not send out telegram upon trigger. It will only resend out telegram after the duration is expire before retrigger of proximity sensor will send out a telegram.

12.4.5 Common parameter – Send "off" telegram automatic after interval time expire

Options Deactivate

Activate

Note: This parameter is only visible if “Send telegram when proximity sensor is trigger – primary function” is activate.

This parameter is use to specify whether to send an off value when “Interval time for proximity sensor to resend telegram” expire. It will remember the last value (value 1 or

2) send and then 0 value.

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12.4.6 Common parameter – Telegram object type

Options 1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

Number of light scene 1..64

Note: This parameter is only visible if “Send telegram when proximity sensor is trigger – primary function” is activate.

The bit size of the communication object to be send out by proximity sensor via the

"Send telegram when proximity sensor is trigger – primary function" parameter.

For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via "Group object type for telegram". For every multiple operation function, a different object size and thus a different function can be select.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

– 1 byte : arbitrary values from 1 to 64

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12.4.7 Common parameter – Value 1

Options On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

1..64

Note: This parameter is only visible if “Send telegram when proximity sensor is trigger – primary function” is activate.

Value 1 options are dependent on the setting of the "Object type" parameter.

1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.4.8 Common parameter – Value 2

Options On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

1..64

Note: This parameter is only visible if “Send telegram when proximity sensor is trigger – primary function” is activate.

Value 2 options are dependent on the setting of the "Object type" parameter.

1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.4.9 Object no

No

0

1

Object name

Proximity sensor state – 1 bit 1 bit DPT 1.001

Send value when proximity trigger - 1 bit

Data type

1 bit DPT 1.001

1

1

Send value when proximity trigger - 1 byte 0..100%

Send value when proximity trigger - 1 byte 0..255

1 byte DPT 5.001

1 byte DPT 5.010

1 2 byte DPT 9.xxx

1

1

1

1

1

1

2

Send value when proximity trigger - 2 byte float

Send value when proximity trigger - 2 byte signed

Send value when proximity trigger - 2 byte unsigned

Send value when proximity trigger - 4 byte float

Send value when proximity trigger - 4 byte signed

Send value when proximity trigger - 4 Byte unsigned

Send value when proximity trigger – 1 byte

Deactivate/activate proximity sensor - 1 bit

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 byte DPT 18.001

1 bit DPT 1.001

12.5

Application “Energy saving mode”

The device have the features of energy saving. After non-actuation of the control element, the brightness of the all LED and LCD display screen will switchover to minimum/off brightness.

12.5.1 Common parameter – Interval time for switchover, active to energy saving (sec)

Options Input from 1 to 30

Flags

C, R, T

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W, U

This parameter is use to specify the duration for control element to switchover to energy saving mode after non-actuation of the control element.

12.5.2 Common parameter – LED status/symbol brightness

Options Inactive

Off

Minimum

Dark

This parameter is use to specify the brightness of status/Symbol LED illumination when control element is switchover to energy saving mode after non-actuation of the control element.

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12.5.3 Common parameter – Ambient LED brightness

Options Inactive

Off

Minimum

Dark

This parameter is use to specify the brightness of ambient LED illumination when control element is switchover to energy saving mode after non-actuation of the control element.

12.5.4 Common parameter – Energy saving function activate/deactivate by group object

Options Inactive

1 for activate – 0 for deactivate

1 for deactivate – 0 for activate

Energy saving mode can be activate / deactivate by a 1 bit communication object via bus line. This parameter is use to specify energy saving mode operating status upon receiving the 1 bit communication object.

12.5.5 Common parameter – Reactivate energy saving mode object after bus voltage recovery

Options Inactive

1 for activate – 0 for deactivate

1 for deactivate – 0 for activate

Note: This parameter is only visible if “Energy saving function activate/deactivate by group object” is activate.

The "Reactivate energy saving mode object after bus voltage recovery" parameter is use to specify whether the device status for “Energy saving mode activate by group object” is to be reinstate after a bus voltage failure and subsequent return of bus voltage.

Deactivate: After a bus voltage failure and subsequent return of bus voltage “Energy saving mode activate by group object” status have to be updated via bus line.

Activate: After a bus voltage failure and subsequent return of bus voltage “Energy saving mode activate by group object” status will be reinstate back as per before a bus voltage failure.

12.5.6 Object no

No

0

1

Object name

Energy saving state – 1 bit

Energy saving mode activate by group object - 1 bit

Data type

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, R, T

C, W, U

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12.6

Application “Top Ambient LED”

The device have ambient LED build in at the top. Ambient LED can be used as orientation illumination or for mood setting.

12.6.1 Common parameter – Ambient LED activate/deactivate by group object

Options Inactive

1 = LED on / 0 = LED off

1 = LED off / 0 = LED on

This parameter is use to define whether the top ambient LED can be activate or deactivate by a 1 bit communication object via the bus line

12.6.2 Common parameter – Colour of ambient LED

Options Yellow

Red/orange

Red

Violet

Blue

Green

White

When ambient LED is activate, it can light up in different colors. Alternatively, the LED can also be deactivate by a communication object.

12.6.3 Common parameter – Day/night mode

Options Deactivate

Activate

Ambient LED can light up with two different brightness levels. When an ON telegram is receive, the LED lights up "bright"; when an OFF telegram is receive, the LED lights up

"dark".

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12.6.4 Common parameter – Master / Proximity / Energy saving function

Options Deactivated

Activated

This 1-bit communication object can be associated with the following function:

1. Proximity sensor state (Proximity sensor function, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Proximity sensor state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

2. Energy saving state (Energy saving mode, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Energy saving state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

12.6.5 Common parameter – Brightness of the LED illumination

Options Dark

Bright

Note: This parameter is only visible if “– Day/night mode” is not activate

Ambient LED can light up with two different brightness levels. The brightness can be set to "dark" or "bright" via the "Brightness of the LED illumination" parameter.

12.6.6 Object no

No Object name

0

1

Deactivate/activate ambient

LED – 1 bit

Proximity/Energy function - 1 bit

Data type

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, R, T

C, W, U

12.7

Application “Bottom Ambient LED”

The device have ambient LED build in at the bottom. Ambient LED can be used as orientation illumination or for mood setting.

12.7.1 Common parameter – Ambient LED activate/deactivate by group object

Options Inactive

1 = LED on / 0 = LED off

1 = LED off / 0 = LED on

This parameter is use to define whether the top ambient LED can be activate or deactivate by a 1 bit communication object via the bus line

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12.7.2 Common parameter – Colour of ambient LED

Options Yellow

Red/orange

Red

Violet

Blue

Green

White

When ambient LED is activate, it can light up in different colors. Alternatively, the LED can also be deactivate by a communication object.

12.7.3 Common parameter – Day/night mode

Options Deactivate

Activate

Ambient LED can light up with two different brightness levels. When an ON telegram is receive, the LED lights up "bright"; when an OFF telegram is receive, the LED lights up

"dark".

12.7.4 Common parameter – Master / Proximity / Energy saving function

Options Deactivated

Activated

This 1-bit communication object can be associated with the following two types of communication object:

1. Proximity sensor state (Proximity sensor function, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Proximity sensor state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

2. Energy saving state (Energy saving mode, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Energy saving state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

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12.7.5 Common parameter – Brightness of the LED illumination

Options Dark

Bright

Note: This parameter is only visible if “– Day/night mode” is not activate

Ambient LED can light up with two different brightness levels. The brightness can be set to "dark" or "bright" via the "Brightness of the LED illumination" parameter.

12.7.6 Object no

No Object name

0

1

Deactivate/activate ambient

LED – 1 bit

Proximity/Energy function - 1 bit

Data type

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, R, T

C, W, U

12.7.7 Bottom ambient LED programming status

When assigning physical address. Pressing of the programming button at the bottom right of the device will send the bottom ambient LED colour to be RED.

12.8

Application “LCD display backlight”

The device have an LCD display that indicated the current operating status and values.

The use of simple symbol on the display of the room temperature controller is meant for easy and intuitively operation.

12.8.1 Common parameter – Master – LCD backlight to be activate/deactivate by group object

Options Inactive

1 = LCD backlight on / 0 = LCD Backlight off

1 = LCD Backlight off / 0 = LCD Backlight on

This parameter is use to define whether the LCD backlight can be activate or deactivate by a 1 bit communication object via the bus line

12.8.2 Common parameter – Day/night mode

Options Deactivate

Activate

LCD backlight can light up with two different brightness levels. When an ON telegram is receive, the LCD backlight lights up "bright"; when an OFF telegram is receive, the LCD backlight lights up "dark".

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12.8.3 Common parameter – Master / Proximity / Energy saving function

Options Deactivated

Activated

This 1-bit communication object can be associated with the following two types of communication object:

1. Proximity sensor state (Proximity sensor function, common parameter). If an ON telegram was receive, LCD display will be in bright illumination, if an OFF telegram was receive, LCD display will be in dark illumination.

Proximity sensor state with “Deactivate/activate LCD display” (1= LCD backlight on / 0 = LCD Backlight off) activate. If an ON telegram was receive, LCD display will be in bright illumination, if an OFF telegram was receive, LCD display will be off.

2. Energy saving state (Energy saving mode, common parameter). If an ON telegram was receive, LCD display will be in bright illumination, if an OFF telegram was receive, LCD display will be in dark illumination.

Energy saving state with “Deactivate/activate LCD display” (1= LCD backlight on

/ 0 = LCD Backlight off) activate. If an ON telegram was receive, LCD display will be in bright illumination, if an OFF telegram was receive, LCD display will be off.

12.8.4 Common parameter – LCD backlight brightness in Master / Proximity / Energy saving function

Options Off

Minimum

Dark

This parameter is use to specify the brightness of LCD display when control element have proximity / energy saving mode activate after non-actuation of the control element.

12.8.5 Common parameter – LCD backlight brightness in active

Options Dark

Bright

Note: This parameter is only visible if “– Day/night mode” is not activate

LCD display can light up with two different brightness levels. The brightness can be set to "dark" or "bright" via the "LCD backlight brightness" parameter.

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12.8.6 Object no

No

0

1

1

Object name

Deactivate/activate LCD display – 1 bit

Activate day/night mode - 1 bit

Activate proximity/energy saving function - 1 bit

Data type

1 bit DPT 1.001

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, W, U

C, W, U

C, W, U

12.9

Application “LCD display subdisplay”

The device have an LCD display that indicated the current operating status and values.

It can also display six other values receive from the bus line.

12.9.1 Common parameter – Subdisplay selection

Options Inactive

Actual temperature

Humility

Pm2.5

VOC

CO2

Time

This parameter is use to define what value is to be display at the subdisplay located at the bottom of the LCD display. Value have to be transmitted by an external device and receive by the control element via the bus line.

12.9.2 Common parameter – Time format

Options 24 hr

12 hr

“Time”

Note: This parameter is only visible if “– Subdisplay” is activate and selection is

This parameter is use to specify the time format in the subdiaplay.

0

0

0

0

12.9.3 Object no

No

0

0

Object name Data type

Value for subdisplay – 2 byte 2 byte DPT 9.001

Value for subdisplay – 1 byte 1 byte DPT 5.001

Value for subdisplay – 2 byte 2 byte DPT 7.001

Value for subdisplay – 2 byte 2 byte DPT 7.001

Value for subdisplay – 2 byte 2 byte DPT 9.009

Value for subdisplay – 3 byte 3 byte DPT 10.001

Flags

C, W, T, U

C, W, T, U

C, W, T, U

C, W, T, U

C, W, T, U

C, W, T, U

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12.10

Application “1-button switching”

When the 1st or 2nd button is actuated or released, a switching telegram is sent out. In each case, the application makes a separate set of parameters and communication objects available for the 1st and the 2nd button. The other side of the button can be assigned a further "button-oriented" function.

12.10.1

Options

Common parameter – Reaction on rising edge

On

Off

Alternating on/off

Deactivated

The application can differentiate between the operation and the releasing of the button.

An operation is designate as "Rising edge" and the releasing is designate as "Falling edge". The application "1-button switching" makes two separate "Switching" communication objects available for the left or right side of the button. The value 1 is always sent out on the first object (Value 1) and the value 2 is always sent out on the second object (Value 2). The "Reaction to rising edge" parameter specifies whether the

"Value 1 for rising edge" or the "Value 2 for rising edge" is sent out for rising edge.

Alternatively, Value1/Value2 can also be alternatingly set for a rising edge, i.e. after

Value 1 was sent (or received), a renewed operation will send out Value 2. After it is operate again, Value 1 is again sent out. The values 1 and 2 are specify via the parameters "Value 1 for rising edge" and "Value 2".

The "Deactivated" setting causes no telegram to be sent out for an operation of the button.

12.10.2

Options

Common parameter – Reaction on falling edge

On

Off

Alternating on/off

Deactivated

The application can differentiate between the operation and the releasing of the button.

An operation is designate as "Rising edge" and the releasing is designate as "Falling edge". The application "1-button switching" makes two separate "Switching" communication objects available for the left or right side of the button. The value 1 is always sent out on the first object (Value 1) and the value 2 is always sent out on the second object (Value 2). The "Reaction to falling edge" parameter specifies whether the

"Value 1 for falling edge" or the "Value 2 for falling edge" is sent out for falling edge.

Alternatively, Value1/Value2 can also be alternatingly set for a rising edge, i.e. after

Value 1 was sent (or received), a renewed operation will send out Value 2. After it is operate again, Value 1 is again sent out. The values 1 and 2 are specify via the parameters "Value 1 for rising edge" and "Value 2".

The "Deactivated" setting causes no telegram to be sent out for an operation of the button.

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12.10.3

No

0

Objects no

Object name

Switching

Data type

1 Bit DPT 1.001

Flags

C, W ,T ,U

12.11

Application “1-button dimming”

The push-buttons have communication objects for switching and dimming. A distinction is made between a short (switching) and long (dimming) press of the button. In each case, the application makes a separate set of parameters and communication objects available for the 1st and the 2nd button. The application allows a lamp to be dim with the one button and the other button to be assign with other "button-oriented" functions.

12.11.1

Options

Common Parameter – Duration of long operation (ss:ms)

Time input from 0.3 to 3.0 seconds

A differentiation can be made between a short or long operation of the button. With a short operation of the button, the next level forward is switch to in each case. With a long operation, the first level is activate. Thus with a long button press a jump back from every position to the first level is possible, without having to run through the remaining levels.

Via the "Duration of long operation", the time is specified from which a long button press is recognized and the object values are reset. The first level must be set again with a press of the button. Any time from 0.3 to 3 seconds can be set. A typical value after which a jump-back to level 1 is set at 0.4 s.

12.11.2

Options

Common parameter – Working mode of the buttons for switching

On

Off

Alternating on/off

Deactivated

The "Working mode of the buttons for switching" is use to specified whether an operation of the left or right side of the button will send out an ON or an OFF telegram. Alternatively, for the selection "Alternating on/off", you can switch between switching on and switching off for every operation that triggers a switching telegram. This means that after a switchon telegram has been sent out (or received), a switch-off telegram will be sent out for a renewed operation. After it is operate again, a switch-on telegram is sent out.

If a switching telegram is trigger by operation of the button, this will sent out on the 1-bit communication object "Switching".

12.11.3

Options

Common parameter – Working mode of the buttons for dimming

Darker

Brighter

Alternating brighter/darker

For a long operation of the button, a "Relative dimming" dimming telegram is sent out on the 4-bit communication object. The "Working mode of the buttons for dimming" is use to specify whether a long operation sends out a dim brighter or a dim darker

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This means that after a dim brighter telegram has been sent out (or received), a dim darker telegram will be sent out for a renewed operation. After it is operate again, a dim brighter telegram is sent out.

0

1

12.11.4

No

Objects no

Object name

Switching

Relative dimming

Data type

1 Bit DPT 1.001

4 bit DPT 3.007

Flags

C, W ,T ,U

C,T

12.12

Application “1-button blind”

The buttons differentiate between a short press (stop / slat adjustment) and a long press

(moving) for roller shutter operation (up/down) and between a short press (moving) and a long press (stop / slat adjustment) for blind operation (left/right). For control, the button that is assigned with the "1-button blind" application always remembers the last action performed.

Example:

If a blind was lowered and halted at half open via a long button press, then a renewed short button press will close the blind.

12.12.1

Options

Common parameter – Duration of long operation (ss:ms)

Time input from 0.3 to 3.0 seconds

A differentiation can be made between a short or long operation of the button. With a short operation of the button, the next level forward is switch to in each case. With a long operation, the first level is activate. Thus with a long button press a jump back from every position to the first level is possible, without having to run through the remaining levels.

Via the "Duration of long operation", the time is specified from which a long button press is recognized and the object values are reset. The first level must be set again with a press of the button. Any time from 0.3 to 3 seconds can be set. A typical value after which a jump-back to level 1 is set at 0.4 s.

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12.12.2

Options

Common parameter – Cyclic time of telegram repetition (ss:ms)

Time input from 0.1 to 5.0 seconds

Note: This parameter is only visible if the “Object type” parameter is set to 1 bit.

Telegrams are sent out on the "Adjust" object cyclically as long as the button is operate.

The intervals can be freely set from 0.1 s to 5.0 s. As standard, the telegrams are sent out cyclic at an interval of 1 second.

Via this function, it is possible to adjust accurately position of larger slats that require a longer time for a complete slat rotation. This means that the user holds the button pressed until the slats are set to the desired position and then releases the button.

12.12.3

Options

Common parameter – Object type

1 bit

1 byte 0..100%

Via the parameter object type, you can specified whether the blind control occurs via two 1-bit or two 1-byte communication objects "Move blinds / shutter up-down" and

"Slats adjustm / stop up-down".

If 1-byte was selected as object type, the communication objects can be connected with

1-byte position objects from blind actuators.

For example: One side of the button could lower the blind to 50% with slats closed 50%, while the other button side can lower the blind to 80% with slats closed 100%

12.12.4

Options

Extended parameter – Switchover of function roller shutter/blind

Roller shutter

Blind

The "Function switchover roller shutters/blind" specifies whether a roller shutter or blind is to be driven by a button operation. With the "blind" setting, the value for the slats adjustment does not apply.

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12.12.5

Options

Extended parameter – Value for position down (%)

0..100%

Note: This parameter is only visible if the “Function switchover roller shutter/blind” parameters is set on roller shutter

The position that a connected blind is to be lowered to is set via this parameter. The associated 1-byte "Move" communication object must hereby be connected with a 1byte position object of a blind actuator. Percentage values from 0% to 100% can be set in 1% steps. The value 0% means travel up completely; the value 100% means travel down completely.

12.12.6

Options

Extended parameter – Value for position up (%)

0..100%

Note: This parameter is only visible if the “Function switchover roller shutter/blind” parameters is set on roller shutter

The position that a connected blind is to be raised to is set via this parameter. The associated 1- byte "Move" communication object must hereby be connected with a 1byte position object of a blind actuator. Percentage values from 0% to 100% can be set in 1% steps. The value 0% means travel up completely; the value 100% means travel down completely.

12.12.7

Options

Extended parameter – Value for slat position down (%)

0..100%

Note: This parameter is only visible if the “Function switchover roller shutter/blind” parameters is set on roller shutter

The position that a connected blind slat is to be opened to is set via this parameter. The associated 1-byte "Adjust" communication object must hereby be connected with a 1byte slat position object of a blind actuator. Percentage values from 0% to 100% can be set in 1% steps. The value 0% means opened completely; the value 100% means closed completely.

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12.12.8

Options

Extended parameter – Value for slat position up (%)

0..100%

Note: This parameter is only visible if the “Function switchover roller shutter/blind” parameters is set on roller shutter

The position that a connected blind slat is to be close to is set via this parameter. The associated 1-byte "Adjust" communication object must hereby be connected with a 1byte slat position object of a blind actuator. Percentage values from 0% to 100% can be set in 1% steps. The value 0% means opened completely; the value 100% means closed completely.

1

1

12.12.9

No

Objects no for “Function switchover roller shutter

Object name Data type

0

0

Move blinds / shutter updown

Move blinds / shutter updown

Stop up-down

1 Bit DPT 1.008

1 byte DPT 5.001

1 Bit DPT 1.007

Slats adjustm / stop up-down 1 byte DPT 5.001

Flags

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

12.12.10

No

Objects no for “Function switchover blind

Object name Data type

0 1 Bit DPT 1.008

1

Move blinds / shutter updown

Stop up-down 1 Bit DPT 1.007

Flags

C, W ,T ,U

C, W ,T ,U

12.13

Application “1-button short-long operation”

The application makes two separate functions available on one side of the button which can be called up via a short or long button press, while the other side of the button can be assigned a further "button-oriented" function. In each case, the application makes a separate set of parameters and communication objects available for the 1st and the 2nd button.

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12.13.1

Options

Common parameter – Object type

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

The application "1-button short-long-operation" makes two communication objects available: "Reaction for short operation" and "Reaction for long operation". The bit size of both communication objects is specified together via the "Object type" parameter.

For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via "Object type".

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.13.2

Options

Common parameter – Reaction for short operation

No reaction

Value 1

Value 2

Alternating value1/value2

Here it is specify whether the "Value 1" or the "Value 2" is sent out for a short operation of the button. Alternatively, Value1/Value2 can also be alternatingly set for a short operation, i.e. after Value 1 was sent (or received), a renewed operation will send out a

Value 2. After it is operate again, Value 1 is again sent out. The "No reaction" setting causes no telegram to be sent out for a short operation of the button.

12.13.3

Options

Common parameter – Reaction for long operation

No reaction

Value 1

Value 2

Alternating value1/value2

Here it is specify whether the "Value 1" or "Value 2" is sent out for a long operation of the button. Alternatively, Value1/Value2 can also be alternating set for a long operation, i.e. after Value 1 was sent (or received), a renewed operation will send out a Value 2.

After it is operate again, Value 1 is again sent out. The "No reaction" setting causes no telegram to be sent out for a long operation of the button.

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12.13.4

Options

Extended parameter – Duration of long operation (ss:ms)

Time input from 0.3 to 3.0 seconds

A differentiation can be made between a short or long operation of the button. With a short operation of the button, the next level forward is switch to in each case. With a long operation, the first level is activate. Thus with a long button press a jump back from every position to the first level is possible, without having to run through the remaining levels.

Via the "Duration of long operation", the time is specified from which a long button press is recognized and the object values are reset. The first level must be set again with a press of the button. Any time from 0.3 to 3 seconds can be set. A typical value after which a jump-back to level 1 is set at 0.4 s.

12.13.5

Options

Extended parameter – Value 1 for short operation

Off

On

Note”: This parameter is only visible if the "Reaction at short operation" parameter is set on either "Value 1" or "Alternating Value1/Value2".

Value 1 is specified here which is sent out at a short operation of the button. This is dependent on the setting of the "Object type" parameter.

12.13.6

Options

Extended parameter – Value 2 for short operation

Off

On

Note”: This parameter is only visible if the "Reaction at short operation" parameter is set on either "Value 2" or "Alternating Value1/Value2".

Value 2 is specified here which is sent out at a short operation of the button. This is dependent on the setting of the "Object type" parameter.

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12.13.7

Options

Extended parameter – Value 1 for long operation

Off

On

Note”: This parameter is only visible if the "Reaction at long operation" parameter is set on either "Value 1" or "Alternating Value1/Value2".

Value 1 is specified here which is sent out at a long operation of the button. This is dependent on the setting of the "Object type" parameter.

12.13.8

Options

Extended parameter – Value 2 for long operation

Off

On

Note”: This parameter is only visible if the "Reaction at long operation" parameter is set on either "Value 2" or "Alternating Value1/Value2".

Value 2 is specified here which is sent out at a long operation of the button. This is dependent on the setting of the "Object type" parameter.

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12.13.9

No

0

0

0

0

0

Object no

Object name

Value switching for short operation - 1 bit

Value switching for short operation - 1 byte 0..100%

Value switching for short operation - 1 byte 0..255

Value switching for short operation - 2 byte float

Value switching for short operation - 2 byte signed

0

0

Value switching for short operation - 2 byte unsigned

Value switching for short operation - 4 byte float

0

0

1

1

1

1

1

1

1

1

1

Value switching for short operation - 4 byte signed

Value switching for short operation - 4 Byte unsigned

Value switching for long operation - 1 bit

Value switching for long operation - 1 byte 0..100%

Value switching for long operation - 1 byte 0..255

Value switching for long operation - 2 byte float

Value switching for long operation - 2 byte signed

Value switching for long operation - 2 byte unsigned

Value switching for long operation - 4 byte float

Value switching for long operation - 4 byte signed

Value switching for long operation - 4 Byte unsigned

Data type

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

12.14

Application “1-button value transmitter”

The application "1-button value transmitter" makes its own communication object available for the left or right side of the button. The bit size of the communication object is specify via the "Object type" parameter. For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via

"Object type".

Flags

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

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12.14.1

Options

Common parameter – Object type

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

The "1-button value transmitter" application makes its own "Value switching" communication object available for the button. The bit size of the communication object is specify via the "Object type" parameter.

For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via "Object type". For every multiple operation function, a different object size and thus a different function can be select.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.14.2

Options

Extended parameter – Reaction on rising edge

No reaction

Value 1

Value 2

Alternating value1/value2

The application can differentiate between the operation and the releasing of the button.

An operation is designate as "Rising edge" and the releasing is designate as "Falling edge". The application "1-button value transmitter" makes two separate "Switching" communication objects available for the left or right side of the button. The value 1 is always sent out on the first object (Value 1) and the value 2 is always sent out on the second object (Value 2)

The "Reaction to rising edge" parameter specifies whether the "Value 1 for rising edge" or the "Value 2 for rising edge" is sent out for rising edge. Alternatively, Value1/Value2 can also be alternatingly set for a rising edge, i.e. after Value 1 was sent (or received), a renewed operation will send out Value 2. After it is operate again, Value 1 is again sent out. The values 1 and 2 are specified via the parameters "Value 1" and "Value 2".

The "No reaction" setting causes no telegram to be sent out for an operation of the button.

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12.14.3

Options

Extended parameter – Reaction on failing edge

No reaction

Value 1

Value 2

Alternating value1/value2

The application can differentiate between the operation and the releasing of the button.

An operation is designate as "Rising edge" and the releasing is designate as "Falling edge". The application "1-button value transmitter" makes two separate "Switching" communication objects available for the left or right side of the button. The value 1 is always sent out on the first object (Value 1) and the value 2 is always sent out on the second object (Value 2)

The "Reaction to falling edge" parameter specifies whether the "Value 1 for falling edge" or the "Value 2 for falling edge" is sent out for falling edge. Alternatively, Value1/Value2 can also be alternatingly set for a rising edge, i.e. after Value 1 was sent (or received), a renewed operation will send out Value 2. After it is operate again, Value 1 is again sent out. The values 1 and 2 are specify via the parameters "Value 1" and "Value 2".

The "No reaction" setting causes no telegram to be sent out for an operation of the button.

12.14.4

Options

Extended parameter – Value 1

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Value 1 options are dependent on the setting of the "Object type" parameter.

1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.14.5

Options

Extended parameter – Value 2

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Value 2 options are dependent on the setting of the "Object type" parameter.

1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

0

0

0

0

0

0

12.14.6

No

Object no

Object name

0

Value switching - 1 bit

Value switching - 1 byte

0..100%

Value switching - 1 byte

Data type

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

0..255

Value switching - 2 byte float 2 byte DPT 9.xxx

0

Value switching - 2 byte signed

Value switching - 2 byte unsigned

2 byte DPT 8.001

2 byte DPT 7.001

Value switching - 4 byte float 4 byte DPT 14.xxx

4 byte DPT 13.001

0

Value switching - 4 byte signed

Value switching - 4 Byte unsigned

4 byte DPT 12.001

Flags

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

12.15

Application “1-button value transmitter, 2 objects”

With the "1-button value transmitter, 2 objects" application, two telegrams with predefined values from two different communication objects can be sent out for an operation and/or upon release of the button. In each case, the application "1-button value transmitter, 2 objects" makes a separate set of parameters and communication objects available in each case for the right and left side of the button. The application makes it possible, for example, to send out a switching function and a floating point value when actuating one side of the button and to assign an additional "buttonoriented" function to the other side of the button.

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12.15.1

Options

Common parameter – Object type for rising edge

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

The application "1-button value transmitter" makes two separate "Switching" communication objects available for the left or right side of the 1st and 2nd button. The bit size of the first communication object is specify via the "Object type for rising edge" parameter.

For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via "Object type for rising edge".

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.15.2

Options

Common parameter – Object type for failing edge

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

The application "1-button value transmitter" makes two separate "Switching" communication objects available for the left or right side of the 1st and 2nd button. The bit size of the first communication object is specify via the "Object type for failing edge" parameter.

For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via "Object type for failing edge".

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.15.3

Options

Extended parameter – Reaction on rising edge

No reaction

Value 1

Value 2

Alternating value1/value2

The application can differentiate between the operation and the releasing of the button.

An operation is designate as "Rising edge" and the releasing is designate as "Falling edge". The application "1-button value transmitter, 2 objects" makes two separate

"Switching" communication objects available for the left or right side of the button. The value 1 is always sent out on the first object (Value 1) and the value 2 is always sent out on the second object (Value 2).

The "Reaction to rising edge" parameter specifies whether the "Value 1 for rising edge" or the "Value 2 for rising edge" is sent out for rising edge. Alternatively, Value1/Value2 can also be alternatingly set for a rising edge, i.e. after Value 1 was sent (or received), a renewed operation will send out Value 2. After it is operate again, Value 1 is again sent out. The values 1 and 2 are specify via the parameters "Value 1" and "Value 2".

The "No reaction" setting causes no telegram to be sent out for a operation of the button.

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12.15.4

Options

Extended parameter – Reaction on failing edge

No reaction

Value 1

Value 2

Alternating value1/value2

The application can differentiate between the operation and the releasing of the button.

An operation is designated as "Rising edge" and the releasing is designate as "Falling edge". The application "1-button value transmitter, 2 objects" makes two separate

"Switching" communication objects available for the left or right side of the button. The value 1 is always sent out on the first object (Value 1) and the value 2 is always sent out on the second object (Value 2).

The "Reaction to falling edge" parameter specifies whether the "Value 1 for falling edge" or the "Value 2 for falling edge" is sent out for falling edge. Alternatively, Value1/Value2 can also be alternatingly set for a rising edge, i.e. after Value 1 was sent (or received), a renewed operation will send out Value 2. After it is operate again, Value 1 is again sent out. The values 1 and 2 are specify via the parameters "Value 1" and "Value 2".

The "No reaction" setting causes no telegram to be sent out for a operation of the button.

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12.15.5

Options

Extended parameter – Value 1 for rising edge

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Note”: This parameter is only visible if the "Reaction at rising edge" parameter is set on either "Value 1" or "Alternating Value1/Value2". The options are dependent on the setting of the "Object type for rising edge" parameter.

Value 1 options are dependent on the setting of the "Object type for rising edge" parameter.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.15.6

Options

Extended parameter – Value 2 for rising edge

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Note”: This parameter is only visible if the "Reaction at rising edge" parameter is set on either "Value 2" or "Alternating Value1/Value2". The options are dependent on the setting of the "Object type for rising edge" parameter.

Value 2 options are dependent on the setting of the "Object type for rising edge" parameter.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.15.7

Options

Extended parameter – Value 1 for failing edge

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Note”: This parameter is only visible if the "Reaction at failing edge" parameter is set on either "Value 1" or "Alternating Value1/Value2". The options are dependent on the setting of the "Object type for failing edge" parameter.

Value 1 options are dependent on the setting of the "Object type for failing edge" parameter.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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12.15.8

Options

Extended parameter – Value 2 for failing edge

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Note”: This parameter is only visible if the "Reaction at failing edge" parameter is set on either "Value 2" or "Alternating Value1/Value2". The options are dependent on the setting of the "Object type for failing edge" parameter.

Value 2 options are dependent on the setting of the "Object type for failing edge" parameter.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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1

12.15.9

No

0

0

Object no

Object name Data type

Switching (rising edge) - 1 bit 1 bit DPT 1.001

Switching (rising edge) - 1 byte 0..100%

1 byte DPT 5.001

0

0

Switching (rising edge) - 1 byte 0..255

Switching (rising edge) - 2 byte float

1 byte DPT 5.010

2 byte DPT 9.xxx

0

0

0

0

0

1

1

1

1

1

1

1

Switching (rising edge) - 2 byte signed

2 byte DPT 8.001

Switching (rising edge) - 2 byte unsigned

Switching (rising edge) - 4 byte float

2 byte DPT 7.001

4 byte DPT 14.xxx

Switching (rising edge) - 4 byte signed

Switching (rising edge) - 4

Byte unsigned

4 byte DPT 13.001

4 byte DPT 12.001

Switching (failing edge) - 1 bit 1 bit DPT 1.001

1 byte DPT 5.001

Switching (failing edge) - 1 byte 0..100%

Switching (failing edge) - 1 byte 0..255

Switching (failing edge) - 2 byte float

Switching (failing edge) - 2 byte signed

Switching (failing edge) - 2 byte unsigned

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

Switching (failing edge) - 4 byte float

Switching (failing edge) - 4 byte signed

Switching (failing edge) - 4

Byte unsigned

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

12.16

Application “1-button light scene extension unit with memory function”

When a button is activate, a predefined light scene number is call backlight up. In each case, the application makes a separate set of parameters and communication objects available for the 1 st and the 2nd button. The application makes it possible to call up a light scene via one button side while the other button side can be assign with a further

"button-oriented" function. The user has the option to trigger a light scene memory command via a long actuation of the button.

Flags

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

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12.16.1

Options

Common Parameter – Duration of long operation (ss:ms)

Time input from 0.3 to 10.0 seconds

A short and long operation can be differentiate between for the operation of the button.

For a short operation of the button, a preset light scene is call up on the 1-byte communication object "Light scene number". For a long operation, a command for storage of the preset light scene is sent out on the same communication object.

Via the "Duration of long operation (ss:ms)", the time is specified after which a long button press is recognized and a command for the light scene storage is sent out instead of the light scene number. Any time from 0.3 to 10.0 seconds can be set. A typical value, after which a button triggers a storage for a long press is 5 s.

12.16.2

Options

Common Parameter – Storage function light scene

Deactivate

Activate

Within the 1-byte value, a memory bit is set in addition to the light scene number. If a light scene module (e.g. Busch-ComfortTouch®) receives this 1-byte value, the module can identify the affected light scene and trigger a storage procedure. Read requests are sent to all connected actuators that in turn answer with their current communication object values. The answers are saved by the light scene module and are sent out again for every future receipt of the light scene number.

12.16.3

Options

Common Parameter – Number of light scene

1 to 64

In the parameter "Light scene number", an arbitrary light scene number from 1 to 64 can be specified which can be sent out via the 1-byte communication object "Light scene number" for operation of the button.

The button only serves as light scene extension unit, i.e. the button only calls up the light scene number. The individual values for the dimming actuators or blind actuators to be adjusted are stored either in the actuator itself or in connected light scene modules

(e.g. Busch-ComfortTouch®).

A light scene module will receive the light scene number and subsequently send the stored light scene values consecutively to the connected actuators.

12.16.4

No

Object no

Object name

0 Number of light scene

Data type

1 Byte DPT 18.001

Flags

C, T

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12.17

Application “1-button step switch”

Different switching processes are triggered with each new actuation of the 1st or 2nd button.

For example:

■ First actuation (2nd button) switches on lamp 1.

■ Second actuation (2nd button) switches lamp 1 off and lamp 2 on.

Third actuation (2nd button) switches lamp 2 off and lamp 3 on.

■ Fourth actuation (1st button) switches lamp 3 off and lamp 2 on.

■ Fifth actuation (1st button) switches lamp 2 off and lamp 1 on.

etc.

Up to five switching levels can be activate.

The application differentiates between whether the 1st or 2nd button was actuated.

Depending on the setting, one lower or one higher level can be switch to.

12.17.1

Options

Common parameter – Number of objects

1 to 5

The application can switch up to five levels. For every level, its own 1-bit communication object is available. The number of the levels is specify via the "Number of objects" parameter.

12.17.2

Options

Common parameter – Evaluation period (sec)

Time input from 2 to 5 seconds

The application can differentiate between a single, double, triple, quadruple or quintuple operation of the button. If the button is to recognize a multiple operation, then the button must be operate multiple times in a relatively short period of time. The period during which the button evaluates a multiple operation will start anew after each operation.

12.17.3

Options

Extended Parameter – Duration of long operation (ss:ms)

Time input from 0.3 to 2.5 seconds

A differentiation can be made between a short or long operation of the button. With a short operation of the button, the next level forward is switch to in each case. With a long operation, the first level is activate. Thus with a long button press a jump back from every position to the first level is possible, without having to run through the remaining levels.

Via the "Duration of long operation", the time is specified from which a long button press is recognized and the object values are reset. The first level must be set again with a press of the button. Any time from 0.3 to 2.5 seconds can be set. A typical value after which a jump-back to level 1 is set at 0.4 s.

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Options

Extended Parameter – Sending of objects

For change of value

For operation

The parameter "Sending of objects" specifies whether the object values for every button operation are sent out or only if the object values have changed since the last sending out.

12.17.5

Options

Extended Parameter –Object values

Normal

Inverse

The object values can be sent "normal" or "inverse" via their associated 1-bit communication objects. If the parameter "Object values" is set to "inverse" then all 1-bit communication objects of the individual levels, send out their values inverted.

12.17.6

Options

Extended Parameter – Bit pattern of object values x of n

1 of n

12.17.7

The levels can be switch in two different bit patterns: x of n (for 5 objects, object 0 to 4) 1 of n (for 5 objects, object 0 to 4)

00000

10000

11000

11100

11110

11111

00000

10000

11000

11100

11110

11111

2

3

4

0

1

12.17.8

No

Objects no

Object name

Switching stage 1

Switching stage 2

Switching stage 3

Switching stage 4

Switching stage 5

Data type

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.001

Flags

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

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12.18

Application “1-button multiple operation”

With the "1-button multiple actuation" application, a differentiation can be made between a single, double, triple, quadruple or quintuple actuation of the button. For each actuation, single, double, triple, quadruple, or quintuple, different values can be sent out. In each case, the application "1-button multiple operation" makes a separate set of parameters and communication objects available in each case for the right or left side of the button. This makes multiple operation possible via one button and assigning a further "button-oriented" function to the other button.

12.18.1

Options

Common parameter – Number of objects or operation

1 to 5

The application can differentiate between a single, double, triple, quadruple or quintuple operation of the button.

The "Number of objects or actuations" parameter specifies how many multiple operations are to be differentiate between.

– 1 object: single operation

– 2 objects: single and double operation

– 3 objects: single, double and triple operation

– 4 objects: single, double and triple and quadruple operation

– 5 objects: single, double and triple, quadruple quintuple operation

12.18.2

Options

Common parameter – Evaluation period (sec)

Time input from 1 to 5 seconds

The application can differentiate between a single, double, triple, quadruple or quintuple operation of the button. If the button is to recognize a multiple operation, then the button must be operate multiple times in a relatively short period of time. The period during which the button evaluates a multiple operation will start anew after each operation.

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12.18.3

Options

Extended parameter –Object type for object 0 to 4

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

The "1-button multiple operation" application makes a separate communication object,

"Switching multiple operation" for single, double, triple, quadruple and quintuple operation available in each case. The bit size of the communication objects is specify together via the "Object type for object 0 to 4" parameter. For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to

"4-byte unsigned" via "Object type for object 0 to 4". For every multiple operation function, a different object size and thus a different function can be select.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.18.4

Options

Extended parameter –Function for object type 1-bit for object 0-4

Transmit value

Alternative on/off

Note: This parameter is only visible if the "Object type for object 0-4" parameter is set to 1 bit.

If the "Object type for object 0-4" parameter was specified with "1 bit", an ON or an OFF telegram can be sent out using the setting "Send value". Whether an ON or an OFF telegram is sent is specify by the "Function for object type 1-bit for object 0-4" parameter.

The "Alternating on/off" setting means that switching always takes place between ON and OFF. This means that after a switch-on telegram has been sent out (or received), a switch-off telegram will be sent out for a renewed operation. After it is operate again, a switch-on telegram is sent out.

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12.18.5

Options

Extended parameter –Value for object 0-4

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

Note: The options are dependent on the setting of the "Object type for object 0-

4" parameter.

Value 0-4 is specified here which is sent out at a multiple operation (1-5) of the button.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

0

0

12.18.6

No

Objects no

Object name

0

Switching 1 actuator - 1 bit

Switching 1 actuator - 1 byte

0..100%

Switching 1 actuator - 1 byte

0..255

0

0

Switching 1 actuator - 2 byte float

Switching 1 actuator - 2 byte signed

0

0

0

0

1

Data type

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

Switching 1 actuator - 2 byte unsigned

Switching 1 actuator - 4 byte float

Switching 1 actuator - 4 byte signed

Switching 1 actuator - 4 Byte unsigned

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

Switching 2 actuator - 1 bit 1 bit DPT 1.001

Flags

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

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2

2

3

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1

1

1

1

1

1

2

2

2

2

2

2

2

3

3

3

3

3

3

Switching 2 actuator - 1 byte

0..100%

Switching 2 actuator - 1 byte

0..255

Switching 2 actuator - 2 byte float

Switching 2 actuator - 2 byte signed

Switching 2 actuator - 2 byte unsigned

Switching 2 actuator - 4 byte float

Switching 2 actuator - 4 byte signed

Switching 2 actuator - 4 Byte unsigned

Switching 3 actuator - 1 bit

Switching 3 actuator - 1 byte

0..100%

Switching 3 actuator - 1 byte

0..255

Switching 3 actuator - 2 byte float

Switching 3 actuator - 2 byte signed

Switching 3 actuator - 2 byte unsigned

Switching 3 actuator - 4 byte float

Switching 3 actuator - 4 byte signed

Switching 3 actuator - 4 Byte unsigned

Switching 4 actuator - 1 bit

Switching 4 actuator - 1 byte

0..100%

Switching 4 actuator - 1 byte

0..255

Switching 4 actuator - 2 byte float

Switching 4 actuator - 2 byte signed

Switching 4 actuator - 2 byte unsigned

Switching 4 actuator - 4 byte float

Switching 4 actuator - 4 byte signed

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

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4

4

4

4

4

4

4

Switching 4 actuator - 4 Byte unsigned

4 byte DPT 12.001

Switching 5 actuator - 1 bit 1 bit DPT 1.001

Switching 5 actuator - 1 byte 1 byte DPT 5.001

0..100%

1 byte DPT 5.010

Switching 5 actuator - 1 byte

0..255

Switching 5 actuator - 2 byte float

2 byte DPT 9.xxx

2 byte DPT 8.001

Switching 5 actuator - 2 byte signed

Switching 5 actuator - 2 byte unsigned

Switching 5 actuator - 4 byte float

Switching 5 actuator - 4 byte signed

Switching 5 actuator - 4 Byte unsigned

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

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12.19

Application “1-button operating mode, “Adjust thermostat settings”

With the "1-button operating mode" "Adjust room temperature controller"" application, an operating mode switchover for connected room temperature controllers can be carried out with an operation of one button side.

Depending on the setting of the "Object type for output" parameter, the application offers either 1-bit communication objects "Comfort operating mode", "Standby operating mode", "ECO operating mode" and Frost protection, heat protection operating mode" or

1-byte communication objects "Auto operating mode", "Comfort operating mode",

"Standby operating mode", "ECO operating mode" and "Frost protection, heat protection operating mode".

The selection "1-bit" is use for activating room temperature controllers that have 1-bit communication objects for operating mode switchover. The "1-byte" selection is use for activating room temperature controllers that have a 1-byte communication object for operating mode switchover to KNX. In this case, the values mean:

– 0 = Auto

– 1 = Comfort

– 2 = Standby

– 3 = Eco

– 4 = Frost- / heat protection

The function can be temporarily block via a 1-bit "Enable" communication object.

12.19.1

Options

Common parameter – Object type for output

1 bit

1 byte

The "Object type for output" parameter is use to specified the size of the output communication object. You can select between "1-bit" and "1-byte". The selection "1-bit" is use for activating room temperature controllers that have 1-bit communication objects for operating mode switchover. The "1-byte" selection is use for activating room temperature controllers that have a 1-byte communication object for operating mode switchover to KNX. In this case, the values mean:

– 0 = Auto

– 1 = Comfort

– 2 = Standby

– 3 = Night

– 4 = Frost- / heat protection

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12.19.2

Options

Common parameter – Operating mode

Auto (1 byte only)

Comfort

Standby

Eco

Frost protection, heat protection

Note: The options are dependent on the setting of the "Object type for output" parameter.

The "Operating mode" parameter specifies the operating mode that is sent out on the 1byte communication object for the KNX operating mode switchover when a button is operated. The possible selections are:

– Auto (1 byte only)

– Comfort

– Standby

– Eco

– Frost protection, heat protection

With selection "Auto" the value "0" is sent out on the1-byte object. For a connected room temperature controller, this means that for every new operation, the individual operating modes "Comfort", "Standby" and "Night" will be switch between. When forced guidance is activate, selection "Auto" is use to switch over to the standard operating mode object.

With the selection of "Comfort", a "1" is sent out on the 1-byte object and a connected room temperature controller switches to the comfort operating mode.

With the selection of "Standby", a "2" is sent out on the 1-byte object and a connected room temperature controller switches to the standby operating mode.

With the selection of "ECO", a "3" is sent out on the 1-byte object and a connected room temperature controller switches to the night time temperature reduction operating mode.

With the selection of "Frost protection, heat protection", a "4" is sent out on the 1-byte object and a connected room temperature controller switches to the frost/heat protection operating mode.

12.19.3

Options

Extended parameter – Application activate/deactivate by group object

Deactivate

Activate

If the "Enable object" parameter is set to "activated", the function can temporarily be block via the 1-bit communication object "Enable". The function is active if an ON telegram is receive on the 1-bit communication object "Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable". This means that no telegram is sent out on the "Output" communication object.

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12.19.4

Options

Extended parameter – Group object value

Normal

Inverse

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The enable function normally functions as follows:

The function is active if an ON telegram is receive on the 1-bit communication object

"Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable".

Via the parameter "Logic of the enable function", the above-described behavior can be reversed, i.e. if an ON telegram is received on the 1-bit communication object "Enable", the function is blocked. The function is active if an OFF telegram is receive on the 1-bit communication object "Enable".

12.19.5

Options

Extended parameter – Enable group object after return of voltage

Blocked

Enable

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The parameter "Enable after return of voltage" exists to permit a defined behavior at the

"Enable" communication object after a return of bus voltage. A determination is made here about whether a "1" ("enable") or a "0" ("blocked") is present on the enable object after the return of bus voltage.

Note: If the logic of the enable function is set to "inverse", the behavior is also inverted after the return of bus voltage, i.e. if the parameter "enable after return of bus voltage" is set to "enable", and at the same time the "logic of the enable function" is parameterized to "inverse", then the function will initially not be active after return of bus voltage. This must first be activate via the receipt of an OFF telegram on the enable object.

12.19.6

Options

Extended parameter –Send comfort object

Deactivate

Activate

Only available when parameter "Object type for output" is set on "1 bit", and for operating modes "Comfort", "Standby" and "ECO".

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12.19.7

Options

Extended parameter –Send ECO object

Deactivate

Activate

Only available when parameter "Object type for output" is set on "1 bit" and for operating modes "Standby", and "ECO".

12.19.8

Options

Extended parameter – Send frost object

Deactivate

Activate

Only available when parameter "Object type for output" is set on "1 bit", and for operating modes "Comfort", "Standby" and "ECO".

0

0

0

0

0

12.19.9

No

Objects no

Object name

Operating mode

Enable

Comfort operating mode

ECO operating mode

Frost protection / Heating protection mode

Data type

1 byte DPT 20.102

1 bit DPT 1.001

1 bit DPT 1.001

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C,T

C, W ,U

C, T

C, T

C, T

12.20

Application “2-button switching”

With the application "2-button switching”, a switching telegram is sent when the button is actuated and/or released. Here it does not differentiate between whether the button is operate on the left or right side. In each case, the application makes a separate set of parameters and communication objects available for the right and left side of the button.

It also makes a switching function possible via one side of the button and assigning a further "button-oriented" function to the other side of the button.

12.20.1

Options

Common parameter – Reaction on rising edge

1 st button off / 2 nd button on

1 st button on / 2 nd button off

Alternating on/off

The "Working mode of the button for switching" is use to specified whether an operation of the left or right side of the button will send out an ON or an OFF telegram.

Alternatively, for the selection "Alternating on/off", you can switch between switching on and switching off for every operation that triggers a switching telegram. This means that after a switch-on telegram is sent out (or received), a switch-off telegram is sent out for a renewed operation. After it is operate again, a switch-on telegram is sent out.

If a switching telegram is trigger by operation of the button, this will be sent out on the 1bit communication object "Switching".

12.20.2

No

Objects no

Object name

0 Switching

Data type

1 Bit DPT 1.001

Flags

C, W ,T ,U

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12.21

Application “2-button dimming”

The push-buttons have two communication objects for switching and dimming. A distinction is made between a short (switching) and long (dimming) press of the button.

A differentiation is made between whether the 1st or 2nd button is actuated. The parameter "Working mode of the buttons for switching and dimming" is used to set whether the 1st button or 2nd button switches on or off or whether it is dimmed brighter or darker.

12.21.1

Options

Common parameter - Duration of long operation (ss:ms)

Time input from 0.3 to 3.0 seconds

A differentiation can be made between a short or long operation of the button. With a short operation of the button, the next level forward is switch to in each case. With a long operation, the first level is activate. Thus with a long button press a jump back from every position to the first level is possible, without having to run through the remaining levels.

Via the "Duration of long operation", the time is specified from which a long button press is recognized and the object values are reset. The first level must be set again with a press of the button. Any time from 0.3 to 3 seconds can be set. A typical value after which a jump-back to level 1 is set at 0.4 s.

12.21.2

Options

Common parameter – Method of dimming

Start-stop dimming

Step-wise dimming

You can switch between the two dimming versions "Start-Stop dimming" and "Step-wise dimming" via this parameter.

"Start-Stop dimming" means that exactly two 4-bit telegrams for dimming are always sent out. For triggering of a dimming command, a telegram with the information "Dim by

100% brighter" or "Dim by 100% darker". When the button is release, the second telegram is sent out with the "Dimming stop" information. Hence, a connected dimming actuator can be halt at any time during the dimming phase.

The second dimming procedure is the step-wise dimming ("Dim stop is not sent" setting). For step-wise dimming, a defined value, e.g. "Dim brighter by 6.25%" is always sent out for triggering of a dimming command. This dimming procedure can be utilized if dimming sensor and actuator are install in different lines. In this case, telegram delays can occur through a coupler and thus varying brightness values if multiple dimming actuators are to be activate in different lines.

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12.21.3

Options

Extended parameter – Working mode of the buttons for switching

1st button off / 2nd button on

1st button on / 2nd button off

Alternating on/off

The "Working mode of the button for switching" application determines whether switching on or switching off occurs via the right or the left side of the button. Using the behavior "Alternating on/off" always switches between ON and OFF. That means, for example, if an ON telegram was last sent out, then a renewed operation of the rocker switch will trigger an OFF telegram. If the button is operate again, an ON telegram will be sent again, etc. The button thus always remembers the last state and then switches over to the other value.

This also applies for values that are received via the associated 1-bit communication object. This means that if an ON telegram was sent out for the last button operation, thereafter an OFF telegram was received via the communication object, the next operation of the button will send out an ON telegram. It must be observe here that the

S-flag (writing) of the communication object is activate.

12.21.4

Options

Extended parameter – Working mode of the buttons for dimming

1st button brighter / 2nd button darker

1st button darker / 2nd button brighter

The "Working mode of the button for dimming" determines whether operation of the left or right side of the button will send out a dim brighter or a dim darker telegram.

If a dimming telegram is trigger by operation of the button, a dimming telegram will be sent out on the 4-bit communication object "Relative dimming".

12.21.5

No

0

1

Objects no

Object name

Switching

Relative dimming

Data type

1 Bit DPT 1.001

4 bit DPT 3.007

Flags

C, W ,T ,U

C,T

12.22

Application “2-button blind”

Via the application "2-button blind", blind movement and/or slats adjustment commands can be sent to connected blind actuators with a short or long actuation of the button. A short button press always triggers a travel command and a long button press always triggers a slats adjustment or stop command. In each case, the "2-button blind" application makes a separate set of parameters and communication objects available for the right or left side of the button.

This thus facilitates controlling a blind using one side of the button and assigning a

"button orientated" function to the other side of the button. The control always remembers the last action performed on the side of the button that is assigned with the

"2-button blind" application.

For example: If a blind was lowered and halted at half height via a long press of the button, then a renewed short press of the button will raise the blind.

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12.22.1

Options

Common parameter - Duration of long operation (ss:ms)

Time input from 0.3 to 3.0 seconds

A differentiation can be made between a short or long operation of the button. With a short operation of the button, the next level forward is switch to in each case. With a long operation, the first level is activate. Thus with a long button press a jump back from every position to the first level is possible, without having to run through the remaining levels.

Via the "Duration of long operation", the time is specified from which a long button press is recognized and the object values are reset. The first level must be set again with a press of the button. Any time from 0.3 to 3 seconds can be set. A typical value after which a jump-back to level 1 is set at 0.4 s.

12.22.2

Options

Common parameter – Object type

1 bit

1 byte 0..100%

Via the parameter object type, you can specified whether the blind control occurs via two 1-bit or two 1-byte communication objects " Move blinds / shutter up-down " and "

Slats adjustm / stop up-down ".

If 1-byte was selected as object type, the communication objects can be connected with

1-byte position objects from blind actuators.

For example: One side of the button could lower the blind to 50% with slats closed 50%, while the other button side can lower the blind to 80% with slats closed 100%

12.22.3

Options

Extended parameter – Working mode of the buttons

1st button up / 2nd button down

1st button down / 2nd button up

The "Working mode of the buttons" is use to specified whether an operation of the left or right side of the button will send out a travel up or travel down telegram.

1

1

12.22.4

No

Objects no

Object name

0 Move blinds / shutter updown

0

Data type

1 Bit DPT 1.008

Move blinds / shutter updown

Stop up-down

1 byte DPT 5.001

1 Bit DPT 1.007

Slats adjustm / stop up-down 1 byte DPT 5.001

Flags

C, T

C, T

C, T

C, T

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12.23

Application “2-button value transmitter”

With an actuation of the 1st or 2nd button a telegram with a predefined value is sent out.

The application differentiates here between whether the 1st or 2nd button is actuated.

12.23.1

Options

Common Parameter – Object type

1 bit

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

4-byte float

4-byte signed

4-byte unsigned

The "2-button value transmitter" application makes its own "Value switching" communication object available for the buttons. The bit size of the communication object is specify via the "Object type" parameter.

For the most diverse applications, the bit size of the communication objects can be adapted from "1-bit" up to "4-byte unsigned" via "Object type". For every multiple operation function, a different object size and thus a different function can be selected.

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.23.2

Options

Extended parameter – Working mode of the buttons

1st button value 1 / 2nd button value 2

1st button value 2 / 2nd button value 1

Alternative value 1 / value 2

The parameter "Working mode of the buttons" is used to specify whether the 1st button or 2 nd button sends out "Value 1" or "Value 2". With the behavior "Alternating

Value1/Value2", switching is always between Value 1 and Value 2. That means, for example, if value 1 was last sent out, then a renewed operation of the button will send out value 2. When the button is operate again, value 1 is again sent out, etc. The button thus always remembers the last state and then switches over to the other value.

This also applies for values that are receive via the associated communication object, i.e. if value 1 was sent out for the last button operation, thereafter value 2 was received via the communication object, the next operation of the button will send out value 1 again. It must be observe here that the S-flag (writing) of the communication object is activate.

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12.23.3

Options

Common parameter – Value 1

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Value 1 options are dependent on the setting of the "Object type" parameter.

1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.23.4

Options

Common parameter – Value 2

On/off

0..100%

0..255

-671088.6..+670760.9

-32768..+32767

0..65535

-4000000..+4000000

2147483648..2147483647

0..4294967295

Value 2 options are dependent on the setting of the "Object type" parameter.

1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

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0

0

0

0

12.23.5

No

0

0

Object no

Object name

Value switching - 1 bit

Value switching - 1 byte

0..100%

0

0

Data type

1 bit DPT 1.001

1 byte DPT 5.001

Value switching - 1 byte

0..255

1 byte DPT 5.010

Value switching - 2 byte float 2 byte DPT 9.xxx

Value switching - 2 byte 2 byte DPT 8.001

signed

Value switching - 2 byte unsigned

2 byte DPT 7.001

0

Value switching - 4 byte float 4 byte DPT 14.xxx

Value switching - 4 byte 4 byte DPT 13.001

signed

Value switching - 4 Byte unsigned

4 byte DPT 12.001

Flags

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

C, W ,T ,U

12.24

Application “2-button value dimming sensor”

With the "2-button value dimming sensor" application, it is possible to send 1-byte value telegrams via an operation of the rocker. Each operation of the left or right side of the rocker will increase or reduce a 1-byte value (percent or value from 0 to 255). The 1byte value can be connected with 1-byte brightness value objects of dimming actuators.

This allows a dimming actuator to be dimmed brighter or darker with the rocker via value telegrams.

12.24.1

Options

Common parameter – Object type

1 byte 0 - 100%

1 byte (0 - 255)

The 1-byte communication object "Value" is set via the "Object type" parameter. With the setting "1 byte 0..100%", the momentary value is increased or reduced by a percentage amount for every operation. With the setting "1 byte 0..255", the momentary value is increased or reduced by an absolute value for every operation. How large the percentage value or the absolute value will be is specified via the "Step size" parameter.

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12.24.2

Options

Common parameter – Step size

1 … 50 %

1 … 128

Note: The options are dependent on the setting of the "Object type" parameter

1 byte 0 - 100% : The size by which the momentary value is to be increase or reduce for an operation is set via the "Step size" parameter. A percentage value can be specified.

Example: The current value on the 1-byte communication object "Value" amounts to

40%. For a step size of "10%", the current value is increase from 40% to 50% for an operation (for an increase).

1 byte 0 - 255: The size by which the momentary value is to be increase or reduce for an operation is set via the "Step size" parameter. An absolute value from 1 to 128 can be specified. Example: The current value on the 1-byte communication object "Value" amounts to 100. For a step size of "20", the current value is increase from 100 to 120 for an operation (for an increase).

12.24.3

Options

Common parameter – Working mode of the rocker as value dimming sensor

1 st button brighter, 2 nd button darker

1 st button darker, 2 nd button brighter

If the rocker left 1 st button or right 2 nd button is operate, the value that is sent out from the 1- byte communication object "Value" is increased (brighter) or lowered (darker).

Whether the operation of the button increases or lowers the value depends on the setting of the "Working mode of the rocker as value dimming sensor" parameter.

0

0

12.24.4

No

Object no

Object name

Value - 1 byte 0..100%

Value - 1 byte 0..255

Data type

1 byte DPT 5.001

1 byte DPT 5.010

Flags

C, W ,T ,U

C, W ,T ,U

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12.25

Application “2-button step switch”

The application "2-button step-type switch" facilitates step-type switching. This means that the user can trigger different switching processes with each new actuation of the button.

For example:

■ First operation switches lamp 1 on.

Second operation switches lamp 1 off and lamp 2 on.

■ The third actuation switches lamp 2 off and lamp 3 on.

■ The fourth actuation switches lamp 3 off and lamp 1 on.

etc.

Up to five switching levels can be activate. In each case, the "2-button step switch" application makes a separate set of parameters and communication objects available for the right or left side of the button. The application enables realizing switching functions via one button side while the other button side can be assign with an additional "button-orientated" function.

12.25.1

Options

Common parameter – Number of objects

1 to 5

The application can switch up to five levels. For every level, its own 1-bit communication object is available. The number of the levels is specify via the "Number of objects" parameter.

12.25.2

Options

Common parameter – Evaluation period (sec)

Time input from 1 to 5 seconds

The application can differentiate between a single, double, triple, quadruple or quintuple operation of the button. If the button is to recognize a multiple operation, then the button must be operated multiple times in a relatively short period of time. The period during which the button evaluates a multiple operation is start anew after each operation.

12.25.3

Options

Extended parameter –Working mode of the buttons

1st button down , 2nd button up

1st button up , 2nd button down

The "Working mode of the buttons" is use to specified whether an operation of the left or right side of the button will send out a travel up or travel down telegram.

12.25.4

Options

Extended Parameter – Sending of objects

For change of value

For operation

The parameter "Sending of objects" specifies whether the object values for every button operation are sent out or only if the object values have changed since the last sending out.

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12.25.5

Options

Extended Parameter –Object values

Normal

Inverse

The object values can be sent "normal" or "inverse" via their associated 1-bit communication objects. If the parameter "Object values" is set to "inverse" then all 1-bit communication objects of the individual levels, send out their values inverted.

12.25.6

Options

Extended Parameter – Bit pattern of object values x of n

1 of n

12.25.7

The levels can be switch in two different bit patterns: x of n (for 5 objects, object 0 to 4)

00000

10000

11000

11100

11110

11111

1 of n (for 5 objects, object 0 to 4)

00000

10000

01000

00100

00010

00001

2

3

4

12.25.8

No

0

1

Objects no

Object name

Switching stage 1

Switching stage 2

Switching stage 3

Switching stage 4

Switching stage 5

Data type

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.001

Flags

C, W ,T

C, W ,T

C, W ,T

C, W ,T

C, W ,T

12.26

Application “Status / Orientation LED ”

With the application "LED functionality", the LED of the button can be used for orientation illumination, for status display or for function display. The LED can light up in different colors. The LED can also flash for alarm display and/or scene storage display.

12.26.1

Options

Common parameter – Operating mode

Status illumination

Orientation illumination

The LED can serve either as a status display ("Status illumination") or orientation

("Orientation illumination"). If the operating mode "Status illumination" is selected, the

LED has its own communication object "Status". This can either be a 1-bit or a 1-byte object (setting parameter "Object type for status object"). When a telegram is receive on the status object, the LED changes colour. Which colour the LED takes on depends on the parameter settings "Colour for Off/On".

If the operating mode "Orientation illumination" is select, the colour of the LED does not support the button function. The colour is specify via the "Colour of the orientation illumination" parameter.

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12.26.2

Options

Common parameter – Status feedback object type

1 bit

1 Byte 0 - 100%

The status object can either be set to the size "1 bit" or "1 byte 0 - 100%".

1 bit: With the setting "1-bit", the communication object "Status" has the size "1-bit". If an ON telegram is, receive on the object, the LED takes on the colour that is stored in the "Colour for

“1”" parameter. If an OFF telegram is receive, the LED takes on the colour that is stored in the "Colour for “0”" parameter.

1 byte: With the setting "1-byte 0 - 100%", the communication object "Status" has the size "1- byte". When a value telegram is receive on the object, the LED can change colour. Whether the colour and to which colour will be switched to depend on the parameter settings "Colour for value …".

The five adjustable zones have the following behavior:

Colour for 0%

Colour for value between 1% to value A-1%

■ Colour for value between value A to value B-1%

■ Colour for value between value B to 99%

■ Colour for value 100%

The two threshold values Value A and Value B are specified via the parameters

"Threshold between value 1% to value A-1% and A to value B-1% and "Threshold between B-1% to value B and value B% to 99%.

12.26.3

Options

Common parameter – Brightness of the LED illumination

Dark

Bright

The LED can light up with two different brightness levels. The brightness can be set to

"dark" or "bright" via the "Brightness of the LED illumination" parameter.

12.26.4

Options

Common parameter – Colour of orientation illumination

Off

Yellow (light)

Red/orange (HVAC)

Red

Violet (scene)

Blue (blind)

Green

White (neutral)

When the LED is use for orientation, i.e. the button or rockers are easier to see, it can light up in different colors. Alternatively, the LED can also be deactivate, such as when the device is in a sleeping area.

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12.26.5

Options

Extended parameter – Day/night mode

Deactivated

Activated

The LED can light up with two different brightness levels. When an ON telegram is receive, the LED lights up "bright"; when an OFF telegram is receive, the LED lights up

"dark".

NOTE

If the operating mode of the LED is set to status illumination, the Day/Night mode object can also be used for the status display.

Example: The button was assigned with the application "1-button switching" and connected with a switching actuator that switches a lamp group. The LED of the button is parameterized to "Status illumination" and the colour set to "yellow" so that the user is signal LED that the button triggers a light function. If the Day/Night mode object is connected with the status response object of the switching actuator via a group address/action, the LED lights up bright when the light is switch on. The LED lights up dark if the light is switch off.

12.26.6

Options

Extended parameter – Master / Proximity / Energy saving function

Deactivated

Activated

This 1-bit communication object can be associated with the following three types of communication object:

3. LED illumination controller (General setting, common parameter): Depending on the parameter setting, upon receiving a telegram, status/Symbol LED illumination will be turn on/off (override). To revert back to normal operation, there must be a change on the status on the telegram receive.

4. Proximity sensor state (Proximity sensor function, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Proximity sensor state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

5. Energy saving state (Energy saving mode, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Energy saving state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

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12.26.7

Options

Extended parameter – Storage function light scenes

Deactivated

Activated

NOTE: If the LED is currently serving as an orientation light, it will not blink.

This also applies if orientation illumination is switch to during the flashing.

If a scene storage telegram is received on the 1-byte communication object "Scene storage", the LED will blink for 3 s and then stop blinking automatically. The LED always flashes in the same colour and brightness that is specify via the status function or function display.

12.26.8

Options

Extended parameter – Alarm function

Deactivated

Activated

NOTE: If the LED is currently serving as an orientation light, it will not blink.

This also applies if during the flashing it is switch to orientation lighting, i.e. the LED stops flashing immediately.

The LED will flash if an ON telegram is receive on the 1-bit communication object

"Alarm". If the object receives an OFF telegram, the LED will no longer flash.

The LED always flashes in the same colour and brightness that was specified via the status function or function display.

The alarm function could be used to display a wind alarm to the user, for example, so that the user knows that no blind operation is possible at that time. An additional application would be the signaling of an open door when user would like to lower a roller blind.

3

4

1

2

0

0

12.26.9

No

Objects no

Object name

LED status

LED status

Day/night mode

Master/proximity/energy saving

Alarm

Scene storage

Data type

1 Bit DPT 1.001

1 byte DPT 5.001

1 Bit DPT 1.001

1 Bit DPT 1.001

1 Bit DPT 1.005

1 Byte DPT 18.001

Flags

C, W ,U

C, W ,U

C, W ,U

C, W ,U

C, W ,U

C, W ,U

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12.27

Application “Symbol LED function”

With the application "LED functionality", LED of rocker symbol will be illuminated. The

LED can light up in different colors.

12.27.1

Options

Common parameter – Brightness of the LED illumination

Dark

Bright

The LED can light up with two different brightness levels. The brightness can be set to

"dark" or "bright" via the "Brightness of the colors" parameter.

12.27.2

Options

Common parameter – Colour of symbol illumination

Off

Yellow (light)

Red/orange (HVAC)

Red

Violet (scene)

Blue (blind)

Green

White (neutral)

When the LED is illuminate, it will illuminate the rocker symbol. It can light up in different colors.

12.27.3

Options

Extended parameter – Day/night mode

Deactivated

Activated

The LED can light up with two different brightness levels. When an ON telegram is receive, the LED lights up "bright"; when an OFF telegram is receive, the LED lights up

"dark".

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12.27.4

Options

Extended parameter – Master / Proximity / Energy saving function

Deactivated

Activated

This 1-bit communication object can be associated with the following three types of communication object:

1. LED illumination controller (General setting, common parameter): Depending on the parameter setting, upon receiving a telegram, status/Symbol LED illumination will be turn on/off (override). To revert back to normal operation, there must be a change on the status on the telegram receive.

2. Proximity sensor state (Proximity sensor function, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Proximity sensor state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

3. Energy saving state (Energy saving mode, common parameter). If an ON telegram was receive, LED will be in bright illumination, if an OFF telegram was receive, LED will be in dark illumination.

Energy saving state with LED illumination controller (1=LED on / 0=LED off) activate. If an ON telegram was receive, LED will be in bright illumination, if an

OFF telegram was receive, LED will be off.

12.27.5

No

0

1

Objects no

Object name

Day/night mode

Master/proximity/energy saving

Data type

1 Bit DPT 1.001

1 Bit DPT 1.001

Flags

C, W ,U

C, W ,U

12.28

Application “Dynamic display – Dimming”

To have dimming up or down graphic animation when triggering on dimming control button. Animation will be display on LCD display screen.

12.28.1

Options

Common parameter – Dynamic display animation format

Inactive

Display of graphic and percentage

Display of graphic

Dynamic display have the following display options:

- Inactive (No display of dynamic graphic and percentage)

- Display of graphic and percentage: During the adjusting, there will be display of graphic and percentage. Once completed adjustment, percentage display will get the feedback and display with the feedback from actuator

- Display of graphic:

- With feedback: During the adjusting, there will only be display of graphic

(synchronize) and percentage will be in "-". Once completed adjustment, percentage will be display with the feedback from actuator

- Without feedback: During the adjusting, there will only be display of graphic, graphic display will be looping and stop upon release of button.

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12.28.2

Options

Common parameter – Relative dimming speed from 0..100% in second

Input from 0 to 65535

Time taken for dimming up from 0% to 100% vice versa for 100% to 0%. Must be the same “value” as per actuator configure for dimming in order to synchronize the dynamic graphic with physical dimming speed.

12.29

Application “Dynamic display – Blind”

To have roller shutter / blind up / open or down / close graphic animation when triggering on roller shutter / blind control button. Animation will be display on LCD display screen.

12.29.1

Options

Common parameter – Animation display

Shutter

Roller blind

Dynamic display graphic have the following display options:

- Shutter: blind display will be up for open and down for close format

- Roller blind: blind display will from left to right for open and right to left for close format

12.29.2

Options

Common parameter – Dynamic display animation format

Inactive

Display of graphic and percentage

Display of graphic

Dynamic display have the following display options:

- Inactive (No display of dynamic graphic and percentage)

- Display of graphic and percentage: During the adjusting, there will be display of graphic and percentage. Once completed adjustment, percentage display will get the feedback and display with the feedback from actuator

- Display of graphic:

- With feedback: During the adjusting, there will only be display of graphic

(synchronize) and percentage will be in "-". Once completed adjustment, percentage will be display with the feedback from actuator

- Without feedback: During the adjusting, there will only be display of graphic, graphic display will be looping and stop upon release of button.

12.29.3

Options

Common parameter – Time travel up (sec)

Input from 0 to 5400

Time taken for roller shutter / blind to move up / open. Must be the same “value” as per actuator configure for time travel in order to synchronize the dynamic graphic with physical travel speed.

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12.29.4

Options

Common parameter – Time travel down (sec)

Input from 0 to 5400

Time taken for roller shutter / blind to move down / close. Must be the same “value” as per actuator configure for time travel in order to synchronize the dynamic graphic with physical travel speed.

12.30

Application “Dynamic display – Scene”

To configure scene name graphic display when triggering on 1 button light scene extension with memory control button. Scene name graphic will be display on LCD display screen.

12.30.1

Options

Common parameter – Scene dynamic display graphic

No display

Scene 1

Scene 2

Scene 3

Scene 4

Scene 5

Movie

Party

Master on

Master off

Speech

Leisure

Welcome

Reading

Meeting

Banquet

Night

Away

Scene dynamic display graphic have the following selection. Graphic are preload in device

12.31

Application “Telegram cyclic”

Via the "Telegram cyclic" application and after receipt of a telegram on the "Input" object, a telegram with the same volume is cyclically sent out on the "Cyclic output" object. The object types for "Input" and "Output" can be collectively parameterized for the different applications. The times for cyclic sending on the "Output" object are adjustable. Via an additional "Enable" object, there is the option of temporarily blocking the function.

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12.31.1

Options

Channel – Object type

1 bit switching

1 bit alarm

1 byte 0 - 100%

1 byte (0 - 255)

2-byte float

2-byte signed

2-byte unsigned

2-byte temperature

4-byte float

4-byte signed

4-byte unsigned

The object types for "Input" and "Output" can be collectively parameterized for the different application cases. The following sizes can be selected:

– 1 bit : switching functions (e.g. On/Off, enable/blocked, true/untrue)

– 1 bit : alarm (e.g. alarm status)

– 1 byte 0 - 100%: percentage values (0 = 0%, 255 = 100%)

– 1 byte 0 - 255 : arbitrary values from 0 to 255

– 2-byte float : floating point value (physical values such as temperature or brightness)

– 2-byte signed : arbitrary values from -32768 to +32767

– 2-byte unsigned : arbitrary values from 0 to 65,535

– 2-byte temperature: Temperature value

– 4-byte float : floating point value (physical values)

– 4-byte signed: arbitrary values from -2147483648 to 2147483647

– 4-byte unsigned : arbitrary values from 0 to 4294967295

12.31.2

Options

Channel – Cycle time (hh:mm:ss)

Time input from 00:00:55 to 01:30:00

Via the "Cycle time" parameter, the interval is specify with which telegrams are sent on the "Output" object. The default time of 00:10:00 can be changed against a time of

00:00:55 to 01:30:00 in 1 s steps.

12.31.3

Options

Extended parameter – Application activate/deactivate by group object

Deactivate

Activate

If the "Enable object" parameter is set to "activated", the function can temporarily be block via the 1-bit communication object "Enable". The function is active if an ON telegram is receive on the 1-bit communication object "Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable". This means that no telegram is sent out on the "Output" communication object.

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12.31.4

Options

Extended parameter – Group object value

Normal

Inverse

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The enable function normally functions as follows:

The function is active if an ON telegram is receive on the 1-bit communication object

"Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable".

Via the parameter "Logic of the enable function", the above-described behavior can be reversed, i.e. if an ON telegram is received on the 1-bit communication object "Enable", the function is blocked. The function is active if an OFF telegram is receive on the 1-bit communication object "Enable".

12.31.5

Options

Extended parameter – Enable group object after return of voltage

No

Yes

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The parameter "Enable after return of voltage" exists to permit a defined behavior at the

"Enable" communication object after a return of bus voltage. A determination is made here about whether a "1" ("enable") or a "0" ("blocked") is present on the enable object after the return of bus voltage.

Note: If the logic of the enable function is set to "inverse", the behavior is also inverted after the return of bus voltage, i.e. if the parameter "enable after return of bus voltage" is set to "enable", and at the same time the "logic of the enable function" is parameterized to "inverse", then the function will initially not be active after return of bus voltage. This must first be activate via the receipt of an OFF telegram on the enable object.

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12.31.6

Options

Extended parameter – Cyclical sending

Always activated

Activate for specified value

Activate except for specified value

The "Cyclical sending" parameter specifies whether the telegrams that are received on the "Input" object are always directly forwarded to the "Output" object and permanently sent out cyclically there ("Activated" setting). Or it is specified with the "Activated for specified value" setting that the "Output" object sends out this value cyclically only upon receipt of a specifically set value. If a different value is receive on the "Input" object, no telegram is sent out on the "Output" object.

12.31.7

Options

Extended parameter – Value for cyclical sending

Off

On

Note: This object is only adjustable if the "Cyclical sending" parameter is set to

“Activate for specified value” or “Activate except for specified value”.

The parameter "Value for cyclical sending" specifies which value must be receive on the "Input" object so that the same value is cyclically sent out on the output. The set value is an ON or an OFF telegram.

1

1

1

0

1

0

0

0

0

1

1

1

1

1

2

0

0

0

12.31.8

No

Object no

Object name

0 Input - 1 bit

Input - 1 byte 0..100%

Input - 1 byte 0..255

Input - 2 byte float

Input - 2 byte signed

Input - 2 byte unsigned

Input - 4 byte float

Input - 4 byte signed

Input - 4 Byte unsigned

Output- 1 bit

Output- 1 byte 0..100%

Output- 1 byte 0..255

Output- 2 byte float

Output- 2 byte signed

Output- 2 byte unsigned

Output- 4 byte float

Output- 4 byte signed

Output- 4 Byte unsigned

Enable – 1 bit

Data type

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

Flags

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, W

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12.32

Application “Priority”

The "Priority" application has 3 communication objects, a 1-bit object "Switch input", a 2bit object "Input priority" and a 1-bit object "Output". The telegrams received on the

"Switch input" are transferred to the "Output" depending on the state of the

"Input priority" object.

The 2-bit object "Input priority" can receive and differentiate between four different values (0, 1, 2 and 3). Here, the "Output" object is positively driven. Three different states are differentiate: - "Input priority" has value "3": the value that is present on

"Switch input" has no meaning. The "Output" is switch to positively driven and has the value "1".

– "Input priority" has the value "2". The value that is present on "Switch input" has no meaning. The "Output" is switch off positively driven and has the value "0".

– "Input priority" has the value "1" or "0". The "Output" is not positively driven. The

"Switch input" is linked to the status bit of the priority object OR and transferred to the

"Output".

During a positive drive, changes of the "Switch input" object are save, even if the current state on the "Output" object does not immediately change through this. If the positive drive is terminate, a telegram transmission on the "Output" occurs according to the current value of the "Switch input" object.

0

0

12.32.1

No

0

Object no

Object name

Switch input - 1 bit

Priority input - 1 bit

Output - 1 bit

Data type

1 bit DPT 1.001

1 bit DPT 2.001

1 bit DPT 1.001

Flags

C, W

C, W

C, T

12.33

Application “Logic gate”

12.33.1

Options

Channel – Logic function

AND

OR

XOR (exclusive OR)

XNOR (exclusive NOR)

NAND

NOR

The "Logical function" parameter specifies the function that shall be execute between the input objects and the output object. The default setting is always an AND element.

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12.33.2

Options

Channel – Number of input objects

1 to 10

Up to ten input objects can act on every logical function. The input objects are enable with the "Number of input objects" parameter.

Note: If the parameter is set to "1", the logical function works as NOT element.

12.33.3

Options

Parameter input 1 – Object type input 1

1 bit

1 byte

The communication object "Input 1" can be set to the size "1 bit" or "1 byte". The default setting is "1-bit". If the size "1-byte" is selected, the receipt of a telegram with a value greater than "0" always means that a logical "1" is placed on the input.

12.33.4

Options

Parameter input 1 – Initial value input 1

Initialized with 0

Initialized with 1

The "Initial value input 1" parameter specifies which input value shall be pending on the input after the initial startup and after return of voltage. You can select between the logical values "0" and "1". Thus, no undefined states can arise.

12.33.5

Options

Parameter input 1 – Logic input 1

Normal

Inverse

The input signal can be inverted via the "Logic input 1" setting.

Note: For a 1-byte size input object, the "inverse" setting means that only upon receipt of the value "0" will a logical "1" be present on the input. All other values (1 to 255) cause a logical "0" on the input.

12.33.6

Options

Parameter input 1 – Object type input 2

1 bit

1 byte

The communication object "Input 1" can be set to the size "1 bit" or "1 byte". The default setting is "1-bit". If the size "1-byte" is selected, the receipt of a telegram with a value greater than "0" always means that a logical "1" is placed on the input.

12.33.7

Options

Parameter input 1 – Initial value input 2

Initialized with 0

Initialized with 1

The "Initial value input 1" parameter specifies which input value shall be pending on the input after the initial startup and after return of voltage. You can select between the logical values "0" and "1". Thus, no undefined states can arise.

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12.33.8

Options

Parameter input 1 – Logic input 2

Normal

Inverse

The input signal can be inverted via the "Logic input 1" setting.

Note: For a 1-byte size input object, the "inverse" setting means that only upon receipt of the value "0" will a logical "1" be present on the input. All other values (1 to 255) cause a logical "0" on the input.

12.33.9

Options

Parameter output – Object type output

1 bit

1 byte

The "Output" communication object can be set to the size "1 bit" or "1 byte". The default setting is "1-bit". In both cases you can set which value is sent out if the function is fulfill

("true") or not fulfill ("untrue").

12.33.10

Options

Parameter output – Send output object

With each input telegram

With a change of the output object

The "Send output object" specifies whether a telegram is trigger on the "Output" communication object "For a change of an input object" or only "For a change of the output object".

The first setting ("For change of an input object") means that as soon as a telegram is receive on an input communication object, the value of the output communication object is immediately sent out. This also happens if the output value has not changed at all.

Example OR function with 2 inputs. An input already had received an ON telegram so that an ON telegram was also trigger on the output. If the second output now receives an ON or OFF telegram, the output value does not change thereby. Nonetheless, an additional telegram is sent out on the output communication object.

The second setting ("For change of the output object") means that only one telegram is sent out on the output communication object when the value has also really changed.

Example AND function with 2 inputs. An input already had received an ON telegram that has, however, still not trigger an ON telegram on the output. If the second output now receives an ON telegram, the output value changes. Only now is a telegram sent out the output communication object.

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12.33.11

Options

Parameter output – Value of the output object for logic true

Output is set to 1

Defined via output default value true

The "Value of the output object for logic true" is set to "1" by default. I.e. as soon as the function is fulfill, a logical "1" is present on the output. The value that is present on the output for fulfill logic can be set via the setting "Defined via output default value true".

Note: The output value is also set to "1" with the output object size of 1-byte for the standard setting (output object is set to 1) and a fulfill function.

12.33.12

Options

Parameter output – Value of the output object for logic untrue

Output is set to 0

Defined via output default value untrue

The "Value of the output object for logic untrue" is set to "0" by default. I.e. as soon as the function is not fulfill, a logical "0" is present on the output. The value that is present on the output for unfulfilled logic can be set via the setting "Defined via output default value untrue".

Note: The output value is also set to "0" with the output object size of 1-byte for the standard setting (output object is set to 0) and an unfulfilled function.

4

4

5

3

3

6

7

5

6

8

9

9

7

8

10

10

2

2

1

1

12.33.13

No

0

0

Object no

Object name

Output - 1 bit

Output - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Input - 1 bit

Input - 1 byte

Data type

1 bit DPT 1.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

1 bit DPT 2.001

1 bit DPT 5.010

Flags

C, R, T

C, R, T

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

C, W, U

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12.34

Application “Gate”

The "Gate" application allows specific signals to be filter and the signal flow to be temporarily blocked. The function has three communication objects: "Control input",

"Input" and "Output".

The input or output object can assume different sizes. The bit size can be freely assign with the "Not assigned" setting. This means that the first internal or external group address/action that is assigned and already connected to some other communication object will specified the size.

The control can occur from "Input to output" or also from "Output to input", provided the control input allows this. Enabling via the control input can occur via an ON or an OFF telegram.

If, for example, the "Control input" setting is set to "ON telegram", only telegrams from the input are transmitted to the output, if prior to this the control input has received an

ON telegram.

It is also possible to block signals via the "Filter function" setting. Either "nothing is filter out" or the signal "ON is filter out" or the signal "OFF is filter out". This function is always necessary, for example, when only the ON telegram is interesting for a sensor and the sensor does not offer any filter function in its application program.

12.34.1

Options

Channel – Object type

1 bit switching

1 bit move blinds / shutter up-down

1 bit stop up-down

2 bit priority

4 bit relative dimming

1 byte 0..100%

1 byte 0..255

2 byte float

2 byte signed

2 byte unsigned

3 byte time of day

3 byte date

4 byte float

4 byte signed

4 byte unsigned

Not assigned

The input or output object can assume different sizes. The bit size can be freely assigned with the "Not assigned" setting. That means the first internal or external group address/action that is assigned and already connected to some other communication object will specified the size. The set selection specifies the size for the input and output object together.

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12.34.2

Options

Extended parameter – Data flow direction

Input towards the output

Output towards the input

In both direction

The parameter defines in which direction the signal transfer shall occur. This can occur either from the "Input towards the output", from the "Output towards the input" or "In both directions".

12.34.3

Options

Extended parameter – Application activate/deactivate by group object

Deactivate

Activate

If the "Enable object" parameter is set to "activated", the function can temporarily be block via the 1-bit communication object "Enable". The function is active if an ON telegram is receive on the 1-bit communication object "Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable". This means that no telegram is sent out on the "Output" communication object.

12.34.4

Options

Extended parameter – Group object value

Normal

Inverse

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The enable function normally functions as follows:

The function is active if an ON telegram is receive on the 1-bit communication object

"Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable".

Via the parameter "Logic of the enable function", the above-described behavior can be reversed, i.e. if an ON telegram is received on the 1-bit communication object "Enable", the function is blocked. The function is active if an OFF telegram is receive on the 1-bit communication object "Enable".

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12.34.5

Options

Extended parameter – Enable group object after return of voltage

No

Yes

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The parameter "Enable after return of voltage" exists to permit a defined behavior at the

"Enable" communication object after a return of bus voltage. A determination is made here about whether a "1" ("enable") or a "0" ("blocked") is present on the enable object after the return of bus voltage.

Note: If the logic of the enable function is set to "inverse", the behavior is also inverted after the return of bus voltage, i.e. if the parameter "enable after return of bus voltage" is set to "enable", and at the same time the "logic of the enable function" is parameterized to "inverse", then the function will initially not be active after return of bus voltage. This must first be activate via the receipt of an OFF telegram on the enable object.

12.34.6

Options

Extended parameter – Save input signal

Deactivate

Activate

Via the "Save input signal", you can set whether the signals are saved or not for 1-bit input and output objects "During the blocking phase".

Example: Data flow direction: Input towards the output. If the setting "Activate" is select, the output sends out its value if a telegram has been receive on the input during the blocking phase.

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1

1

1

1

1

1

2

1

1

1

1

1

0

0

0

0

0

1

1

0

0

0

0

0

0

12.34.7

No

0

0

Object no

Object name

Input - 1 bit

Input – 2 bit

Input – 4 bit

Input - 1 byte 0..100%

Input - 1 byte 0..255

Input - 2 byte float

Input - 2 byte signed

Input - 2 byte unsigned

Input – 3 byte

Input – 3 byte

Input - 4 byte float

Input - 4 byte signed

Input - 4 Byte unsigned

Input - 1 bit

Input – 2 bit

Input – 4 bit

Input - 1 byte 0..100%

Input - 1 byte 0..255

Input - 2 byte float

Input - 2 byte signed

Input - 2 byte unsigned

Input – 3 byte

Input – 3 byte

Input - 4 byte float

Input - 4 byte signed

Input - 4 Byte unsigned

Control input – 1 bit

Data type

1 bit DPT 1.001

2 bit DPT 2.001

4 bit DPT 3.007

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

3 byte DPT 10.001

3 byte DPT 11.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

2 bit DPT 2.001

4 bit DPT 3.007

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

3 byte DPT 10.001

3 byte DPT 11.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, T

C, T

Flags

C, W

C, W

C, W

C, W

C, W

C, W

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, W

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12.35

Application “Staircase lighting”

With the "Staircase lighting" application, switching telegrams or value telegrams can be provided with a light-on time. Depending on the parameterization, the application shows different communication objects:

- a 1-bit object for input and output If an ON telegram is received via the "Input/Output" object, the light-on time is started immediately. This can be a light-on time of 00:10 min to 88:45 min, which is adjustable in 0.1 s steps. After expiration of the light-on time, the

"Input/Output" object sends an OFF telegram.

- two 1-bit objects for input and output

- and two 1-byte objects for input and output

If a telegram is receive via the "Input" object, the light-on time is start immediately and a telegram with the same value of the telegram received on the input is sent out on the

"Output" object. This can be a light-on time of 00:10 min to 88:45 min, which is adjustable in 0.1 s steps. After expiration of the light-on time, the "Output" object sends out an OFF telegram (1-bit) or a telegram with the value "0" (1-byte).

Via two additional communication objects, it is possible to specify the light-on time and the switch-off prewarning time. The 2-byte values received are written to the memory of the device and are retained even after a bus power failure and subsequent return of voltage.

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12.35.1

Options

Channel – Object type / number

A 1 bit object for input and output

Two 1 bit objects for input and output

Two 1 byte objects for input and output

The "Object type/number" parameter sets the size and number of communication objects:

- a 1-bit object for input and output

If an ON telegram is receive via the "Input/Output" object, the light-on time is started immediately. This can be a light-on time of 1.0 s to 20 s, which is adjustable in 0.1 s steps. After expiration of the light-on time, an OFF telegram is sent out on the

"Input/Output" object.

- two 1-bit objects for input and output

If a switching telegram is receive via the "Input" object, the light-on time is started immediately and a telegram with the same value of the telegram received (ON or OFF) on the input is sent out on the "Output" object. This can be a light-on time of 1.0 s to 20 s, which is adjustable in 0.1 s steps. After expiration of the light-on time, an OFF telegram is sent out on the "Output" object.

- two 1-byte objects for input and output

If a value telegram is receive via the "Input" object, the light-on time start immediately and a telegram with the same value of the telegram received on the input is sent out on the "Output" object. This can be a light-on time of 1.0 s to 20 s, which is adjustable in

0.1 s steps. After expiration of the light-on time, the "Output" object sends out a telegram with the value "0".

12.35.2

Options

Channel – Follow-up time (hh:mm:ss)

Time input from 00:00:10 to 01:30:00

For the behavior of the light-on time, depending on the set "Object type/number":

1-bit object for input and output:

If an ON telegram is receive via the "Input/Output" object, the light-on time start immediately. This can be a light-on time of 1.0 s to 20 s, which is adjustable in 0.1 s steps. After expiration of the light-on time, an OFF telegram is sent out on the

"Input/Output" object.

two 1-bit/1-byte objects for input and output:

If a telegram is receive via the "Input" object, the light-on time start immediately and a telegram with the same value of the telegram received on the input is sent out on the

"Output" object. This can be a light-on time of 1.0 s to 20 s, which is adjustable in 0.1 s steps. After expiration of the light-on time, the "Output" object sends out an OFF telegram (1-bit) or a telegram with the value "0" (1-byte).

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12.35.3

Options

Extended parameter – Retriggering

Deactivate

Activate

The "Retriggering possible" parameter specifies whether the light-on time is restart for arrival of an additional telegram on the input. This behavior is call retriggering.

For example, a retriggering makes sense for a light-on time of motion detectors. This ensures that the delay time continues to be reset as long as there is motion detected.

If 1-byte telegrams with different values are receive during the retriggering phase, the values are immediately transfer to the output and the light-on time is restart. With the

"no" setting, the set light-on time always proceeds to the end so that a telegram is always sent out on the "Output" object after the light-on time.

12.35.4

Options

Extended parameter – Switch-off prewarning

Deactivate

Activate

Via the "Switch-off prewarning" parameter, you can activate whether an additional value is sent out on the output object shortly before expiration of the light-on time. This signals to the user that the staircase lighting time has almost expired and that the light will be switching off shortly.

12.35.5

Extended parameter – Overwrite light on and switch off prewarning time for download

Options Deactivate

Activate

Telegrams with new times can be receive via the 2-byte communication objects "Lighton time" and "Switch-off prewarning time". The received 2-byte values are written to the memory of the device and are retained even after a bus power failure and subsequent return of voltage.

The "Overwrite light-on and switch-off prewarning time for download" parameter specifies whether the received storage values are to be retained for a reprogramming of the device or whether the storage values are to be replaced by the values specified in the parameterizing software.

0

0

0

0

0

0

0

12.35.6

No

Object no

Object name

Input - 1 bit

Input – 1 byte

Input / output – 1 bit

Light on time – 2 byte

Switch off prewarning – 2 byte

Output – 1 bit

Output – 1 byte

Data type

1 bit DPT 1.001

1 byte DPT 5.010

1 bit DPT 1.001

2 byte DPT 7.001

2 byte DPT 7.001

1 bit DPT 1.001

1 byte DPT 5.010

Flags

C, W

C, W

C, W, T

C, R, W

C, R, W

C, T

C, T

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12.36

Application “Light scene actuator”

Via the application "Light scene extension unit with memory function", a predefined light scene number is call up when the rocker is actuated.

The application "Light scene extension unit with memory function" makes a separate set of parameters and communication objects available in each case for the right or left side of the rocker.

The application facilitates calling up a light scene via a rocker side while the other rocker side can be assign an additional "button orientated" function. The user has the option to trigger a light scene memory command with a long button contact.

12.36.1

Options

Channel – Number of scene

1 to 8

Up to eight different scenes can be call up via the device. The "Number of scenes" parameter defines this. Any arbitrary number from 1 to 8 seconds can be entered. The values that are sent out over the different actuator objects for the scene call-up are adjustable but they can also be save in the device by the user.

12.36.2

Options

Channel – Number of actuator

1 to 8

For the call-up of a scene, consecutive telegrams are sent out on the actuator groups communication objects. The "Number of actuator groups" parameter defines this. An arbitrary number from 1 to 8 actuator groups can be entered. That means if a blind and an absolute temperature value are to be sent out during call-up of a scene of four lamp groups, the parameter is to be set to "6" actuator groups.

The size of the actuator groups communication objects can be adjust under the "Type actuator group" parameter. The following object sizes are available:

- 1-bit switching

- 1-bit blind

- 1-byte 0..100%

- 1-byte light scene number

- 2-byte temperature values absolute (-33.5°C to +93.5°C)

12.36.3

Options

Channel – Time for telegram delay

Time input from 0.1 to 10.0 seconds

For the call-up of a scene, consecutive telegrams are sent out on the actuator groups communication objects. The sequence is strictly specified. First the telegram of the actuator group A is sent out, then the telegram of the actuator group B and then the telegram of the actuator group C etc. The time between the telegrams can be adjust.

An arbitrary time between 0.1 and 60 seconds (in 0.1 s intervals) can be set.

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12.36.4

Options

Channel – Overwrite scene for download

Deactivate

Activate

The user has the option of triggering a scene storage via the receipt of a corresponding scene storage command. The actuator groups communication objects in this case send read requests to the connected actuators. Provided that the L-flag is set for the communication objects of the connected actuators, these will send their current values to the device via an answer telegram. The values are stored in the memory and overwrite the previous values.

When reprogramming the device, the values stored by the user can be overwritten by the preset values in the parameterizing software. To do this, the "Overwrite scenes for download" must be set to "activated". The values stored by the user remain in the device with the "deactivated" setting.

12.36.5

Options

Extended parameter – Object type actuator group A..H

Number of light scene

1 bit switching

1 bit blind

1 byte 0..100%

Temperature

This parameter is only adjustable if the "Number of actuator groups" is set to at least

"2". The size of the actuator group communication object can be adjusted for different application cases under the "Type actuator group A..H" parameter. The following object sizes are available:

- 1-bit switching, for the activation of switching functions or actuators

- 1-bit blind, for the activation of blind actuators

- 1-byte 0..100 %, for the activation of dimming actuators or blind positions (default setting)

- 1-byte light scene number for the calling up of additional actuator groups

- 2-byte temperature values absolute (-33.5°C to +93.5°C) for specifying a new default value in room thermostats

12.36.6

Options

Extended parameter – Scene number

1 to 64

The "Scene number" parameter specifies with which value the Scene 1 or a scene storage can be call up that is received on the 1-byte "Scene call-up" communication object. An arbitrary scene number from 1 to 64 can be set.

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12.36.7

Options

Extended parameter – Scene can be saved

Deactivate

Activate

The scene values that are stored in the device and which are sent out via the actuator objects can be overwritten by the user. If the "Overwrite scene for download" parameter is activated, the user has the option of carrying out a scene storage. In this case, read requests are sent to the connected actuators on the actuator objects for receipt of a scene storage command. The values of the reply telegrams are stored in the memory of the device and overwrite the previously current values. These are also not lost in the event of a possible power failure.

12.36.8

Options

Extended parameter – Object type actuator group A..H

Deactivate

Activate

Via the "Actuator group A" parameter, you can specified whether the actuator group A is sent out or not for a call of the scene 1. Select the "activated" setting if the actuator group A is to trigger a telegram for call of the scene 1.

12.37

Application “Delay”

Telegrams can be receive via the "Input" object using the "Delay" application. The telegrams received are sent out on the "Output" object with a set delay time.

The object types for "Input" and "Output" can be collectively parameterized for different applications.

12.37.1

Options

Channel – Object type

1 bit switching

1 bit move blinds / shutter up-down

1 bit stop up-down

1 byte 0..100%

1 byte 0..255

2 byte float

2 byte signed

2 byte unsigned

4 byte float

4 byte signed

4 byte unsigned

The object types for "Input" and "Output" can be collectively parameterized for the different application cases. The following sizes can be selected.

12.37.2

Options

Channel – Delay time (hh:mm:ss:ms)

Time input from 00:00:01:00 to 01:00:00:00

The telegrams received via the "Input" object are sent out on the "Output" object after the time set under "Delay time". This can be a delay time of 1 s to 1 hour, which is adjustable in 0.01 s steps.

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12.37.3

Options

Extended parameter – Retriggering

Deactivate

Activate

The "Retriggering possible" parameter specifies whether the delay time is restarted for arrival of an additional telegram on the input. This behavior is call retriggering.

For example, a retriggering makes sense for a light-on time of motion detectors. This ensures that the delay time continues to be reset as long as there is motion detected. If telegrams with different values are receive during the retriggering phase, only the last received value on the "Output" object is sent out after expiration of the delay time. With the "no" setting, the set delay time always proceeds to the end so that a telegram is always sent out on the "Output" object after the delay time.

12.37.4

Options

Extended parameter – Filter active

Deactivate

Activate

If the "Filter active" parameter is set to "yes", the delayed transferring of the input values to the output can be influence. A filter value can be specified appropriate to the set object type for this.

Through the "Filter function" parameter, you can specified whether

- only the filter value is sent with delay and all other values are sent directly.

- only the filter value is sent with delay and all other values are blocked.

- only the filter value is sent directly and all other values are sent with delay.

- only the filter value is blocked and all other values are sent with delay.

12.37.5

Options

Extended parameter – Overwrite delay time by group object

Deactivate

Activate

A telegram with a new delay time can be received via the 2-byte communication object

"Delay time". The received 2-byte value is written to the memory of the device and is retain even after a bus power failure and subsequent return of voltage.

The "Overwrite for download" parameter specifies whether the received storage value is to be retain for a reprogramming of the device or whether the storage value is to be replaced by the value specified in the parameterizing software.

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1

1

1

2

1

1

1

1

1

0

0

0

0

0

0

0

1

1

0

0

12.37.6

No

0

0

Object no

Object name

Input - 1 bit

Move blinds / shutter updown – 1 bit

Stop up-down – 1 bit

Input- 1 byte 0..100%

Input- 1 byte 0..255

Input- 2 byte float

Input- 2 byte signed

Input- 2 byte unsigned

Input- 4 byte float

Input- 4 byte signed

Input- 4 Byte unsigned

Output - 1 bit

Move blinds / shutter updown – 1 bit

Stop up-down – 1 bit

Output - 1 byte 0..100%

Output - 1 byte 0..255

Output - 2 byte float

Output - 2 byte signed

Output - 2 byte unsigned

Output - 4 byte float

Output - 4 byte signed

Output - 4 Byte unsigned

Delay time – 2 byte

Data type

1 bit DPT 1.001

1 Bit DPT 1.008

1 Bit DPT 1.007

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

1 Bit DPT 1.008

1 Bit DPT 1.007

1 byte DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

2 byte DPT 7.001

Flags

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, T

C, R, W

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12.38

Application “Min/max value transducer”

Up to eight input values can be compare with each other using the "Min/max value transducer" application. The application can output the highest input value, the smallest input value or the average of all input values on the output.

The size of the input objects, and with it also the size of the output object can be adapted for the most diverse applications. You can select from the following object types:

- 1-byte 0..100 %, for comparison of percent values

- 1-byte 0..255, for the comparison of decimal values between 0 and 255

- 2-byte float, for the comparison of 2-byte floating point values (physical values such as temperature, brightness value etc.)

- 2-byte signed, for the comparison of decimal values between -32,768 and +32,767

- 2-byte unsigned, for the comparison of decimal values between 0 and 65,535

- 4-byte float, for the comparison of 4-byte floating point values (physical values such as acceleration, electrical current, work etc.)

- 4-byte signed, for the comparison of decimal values between -2,147,483,648 and

2,147,483,647

- 4-byte unsigned, for the comparison of decimal values between 0 and 4,294,967,295

Hint: With whole numbers the average value is rounded.

12.38.1

Options

Channel – Object type

1 byte 0..100%

1 byte 0..255

2 byte float

2 byte signed

2 byte unsigned

4 byte float

4 byte signed

4 byte unsigned

The size of the input objects and thus also the size of the output object can be adapted for the most diverse applications. You can select from the following object types:

- 1-byte 0..100 %, for comparison of percent values

- 1-byte 0..255, for the comparison of decimal values between 0 and 255

2-byte float, for the comparison of 2-byte floating point values (physical values such as temperature, brightness value etc.)

- 2-byte signed, for the comparison of decimal values between -32,768 and +32,767

- 2-byte unsigned, for the comparison of decimal values between 0 and 65,535

4-byte float, for the comparison of 4-byte floating point values (physical values such as acceleration, electrical current, work etc.)

- 4-byte signed, for the comparison of decimal values between -2.147.483.648 and

2.147.483.647

- 4-byte unsigned, for the comparison of decimal values between 0 and 4,294,967,295

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12.38.2

Options

Channel – Number of input objects

1 to 8

The number of available input objects is adjustable. A maximum of eight input objects can be enable. All input objects assume the size that is specify under the "Object type" parameter.

12.38.3

Options

Channel – Output sends

For every assignment of the input

With a change of the output object

The "Min/max value transducer" application compares the values that are present on the input objects Depending on the setting of the "Output object" parameter, it will send out the largest, the smallest or the average value on the output object.

The "Output sends" parameter allows you to set whether the output value is sent out

"for every assignment of the inputs" or only "with a change of the output object".

The "for every assignment of the inputs" setting means that the output communication object always sends out its value immediately if a telegram is receive on an input communication object. It does not matter whether the value of the output has changed by the receipt of the input telegram or not.

The "with a change of the output object" setting means that only one telegram is always sent out on the output communication object if its value has changed.

12.38.4

Options

Channel – Output object

Adopts the largest value of the inputs

Adopts the smallest value of the inputs

Adopts the average value of the inputs

The "Min/max value transducer" application compares the values that are present on the input objects

Depending on the setting of the "Output object" parameter,

- the largest value ("adopts the largest value of the inputs"),

- the smallest value ("adopts the smallest value of the inputs"),

- or the average value ("adopts the average value of the inputs"), of the inputs is sent out on the output object.

Provided the average value is sent out, the application always calculates the arithmetic mean of the inputs. Decimal places are rounded.

Example 2-byte signed, 2 inputs:

Input 1 = 4

Input 2 = 5

Arithmetic mean = (input 1 + input 2): 2 = 4.5

Average value = 5

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0

0

0

0

12.38.5

No

0

0

Object no

Object name

Output - 1 bit

Output - 1 byte 0..255

Output - 2 byte float

Output - 2 byte signed

Output - 2 byte unsigned

Output - 4 byte float

Data type

1 bit DPT 1.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

0

0

Output - 4 byte signed

Output - 4 Byte unsigned

4 byte DPT 13.001

4 byte DPT 12.001

1..10

Input - 1..10 1 byte 0..100% 1 byte DPT 5.001

1..10 Input - 1..10 1 byte 0..255

1 byte DPT 5.010

1..10

Input - 1..10 2 byte float 2 byte DPT 9.xxx

1..10

Input - 1..10 2 byte signed 2 byte DPT 8.001

1..10 Input - 1..10 2 byte unsigned 2 byte DPT 7.001

1..10

Input - 1..10 4 byte float

1..10 Input - 1..10 4 byte signed

4 byte DPT 14.xxx

4 byte DPT 13.001

1..10

Input - 1..10 4 Byte unsigned 4 byte DPT 12.001

C, T

C, T

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

Flags

C, T

C, T

C, T

C, T

C, T

C, T

12.39

Application “Threshold value hysteresis”

With the "Threshold value / Hysteresis" application, value telegrams can be received on an input communication object and compared with threshold values specified in the device.

Predefined values are sent out on the communication "Output" communication object if the upper or lower thresholds are exceeded. The size of the object can be adjust for different applications. The function can be temporarily block via an enable object. If the value of the lower threshold lies above the value for the upper threshold, the function is not execute.

12.39.1

Options

Channel – Object type input

1 byte 0..100%

1 byte 0..255

2 byte float

2 byte signed

2 byte unsigned

4 byte float

The size of the input object can be adapted for different applications. You can select from the following object types:

- 1-byte 0..100 %, for comparison of percent values

- 1-byte 0..255, for the comparison of decimal values between 0 and 255

2-byte float, for the comparison of 2-byte floating point values (physical values such as temperature, brightness value etc.)

- 2-byte signed, for the comparison of decimal values between -32.768 and +32.767

- 2-byte unsigned, for the comparison of decimal values between 0 and 65,535

4-byte float, for the comparison of 4-byte floating point values (physical values such as acceleration, electrical current, work etc.)

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12.39.2

Options

Channel – Object type output

1 bit switching

1 byte 0..100%

1 byte 0..255

Predefined values are sent out on the communication "Output" communication object if the upper or lower thresholds are exceeded. The size of the object can be adjusted for different applications.

12.39.3

Options

Extended parameter – Application activate/deactivate by group object

Deactivate

Activate

If the "Enable object" parameter is set to "activated", the function can temporarily be block via the 1-bit communication object "Enable". The function is active if an ON telegram is receive on the 1-bit communication object "Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable". This means that no telegram is sent out on the "Output" communication object.

12.39.4

Options

Extended parameter – Group object value

Normal

Inverse

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The enable function normally functions as follows:

The function is active if an ON telegram is receive on the 1-bit communication object

"Enable". The function is block if an OFF telegram is receive on the 1-bit communication object "Enable".

Via the parameter "Logic of the enable function", the above-described behavior can be reversed, i.e. if an ON telegram is received on the 1-bit communication object "Enable", the function is blocked. The function is active if an OFF telegram is receive on the 1-bit communication object "Enable".

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12.39.5

Options

Extended parameter – Enable group object after return of voltage

No

Yes

Note: This object is only adjustable if the "Enable object" parameter is set to

"activated".

The parameter "Enable after return of voltage" exists to permit a defined behavior at the

"Enable" communication object after a return of bus voltage. A determination is made here about whether a "1" ("enable") or a "0" ("blocked") is present on the enable object after the return of bus voltage.

Note: If the logic of the enable function is set to "inverse", the behavior is also inverted after the return of bus voltage, i.e. if the parameter "enable after return of bus voltage" is set to "enable", and at the same time the "logic of the enable function" is parameterized to "inverse", then the function will initially not be active after return of bus voltage. This must first be activate via the receipt of an OFF telegram on the enable object.

12.39.6

Options

Extended parameter – Input monitoring

Deactivate

Activate

Should there the upper or lower threshold value be exceeded (i.e. above the upper limit or below the lower limit) during the blocking, the relevant output telegrams are sent out after the cancellation of the blocking. The "Deactivated" setting causes that no input value to be evaluate after cancellation of the blocking.

12.39.7

Options

Extended parameter – Behavior output after return of voltage

Deactivate

Output value upper threshold

Output value lower threshold

The parameter "Behavior output after return of voltage" exists to permit a defined behavior at the "Output" communication object after a return of voltage. A determination is made here about whether the "Output value upper threshold" or the "Output value lower threshold" is sent out on the output object. The "Deactivated" setting causes no telegram to be sent out after return of voltage.

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12.39.8

Options

Extended parameter – Send behavior

For every object receipt

Only with a change of the output object

The parameter “Send behavior” sets weather an outgoing signal should only be sent if the ingoing value changed or not.

12.39.9

Options

Extended parameter – Upper threshold (%)

0 to 100

The "Upper threshold (%)" parameter specifies the upper threshold. i.e. if the value on the "Input" object is higher than the set value, the "Output value for exceeding the upper threshold" telegram is sent out on the "Output" communication object. Values from 0 to 100 % can be set in 2.55 % steps.

12.39.10

Options

Extended parameter – Output value for exceeding the upper threshold

Off

On

The parameter "Output value for exceeding the upper threshold" specifies the value that is sent out on the 1-bit communication object "Output" if the set upper threshold is exceeded. The values ON and OFF can be set.

12.39.11

Options

Extended parameter – Lower threshold (%)

0 to 100

The "Lower threshold (%)" parameter specifies the lower threshold. i.e. if the value on the "Input" object is lower than the set value, the "Output value for falling below the lower threshold" telegram is sent out on the "Output" communication object. Percent values from 0 to 100 % can be set in 2.55 % steps.

12.39.12

Options

Extended parameter – Output value for failing below the lower threshold

Off

On

The parameter "Output value for falling below the lower threshold" specifies the value that is sent out on the 1-bit communication object "Output" if the set upper threshold is fallen below. The values ON and OFF can be set.

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1

1

0

0

2

0

0

0

0

12.39.13

No

0

0

Object no

Object name

Input - 1 byte 0..100%

Input - 1 byte 0..255

Input - 2 byte float

Input - 2 byte signed

Input - 2 byte unsigned

Input - 4 byte float

Input - 4 byte signed

Input - 4 Byte unsigned

Output - 1 bit

Output - 1 byte 0..100%

Output - 1 byte 0..255

Enable

12.40

Page setting - display

Data type

1 bit DPT 5.001

1 byte DPT 5.010

2 byte DPT 9.xxx

2 byte DPT 8.001

2 byte DPT 7.001

4 byte DPT 14.xxx

4 byte DPT 13.001

4 byte DPT 12.001

1 bit DPT 1.001

1 byte DPT 5.001

1 byte DPT 5.010

1 bit DPT 1.001

12.40.1

Options

Page setting - Page Combine

RTC

VRV

Fresh Air

RTC + VRV

RTC + Fresh Air

VRV + Fresh Air

RTC + VRV + Fresh Air

Select of the combination of operation page to be displayed on the screen, and switching of different operation pages by triggering of the menu button.

12.40.2

Options

Page setting - RTC Page Title

Deactivated

Floor Heating

Wall Heating

Cool Ceiling

Capillary

Flags

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, W

C, T

C, T

C, T

C, W

Note: This parameter can only be used when the "RTC" page is activated in

"Page_Combine". If RTC page title is "Deactivated", the RTC page will not display the

RTC page title and it will display the default "Fan speed", "operation state" and "Scene" function icons. If any of the RTC page title is selected, the "fan speed" icon will not be displayed, but will be replaced by the icon of the selected RTC page title.

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12.40.3

Options

Page setting - VRV Page Title

Deactivated

Air Condition

Central Air Condition

VRV

Note: This parameter can only be used when the "VRV" page is activated in

"Page_combine". If VRV page title is "Deactivated", the VRV page will not display the

VRV page title and it will display the default "Fan speed" and "operation state". If any of the VRV page title is selected, It will display the VRV page title, "Fan speed" and

"operation state".

12.40.4

Options

Page setting - Fresh Air Page Title

Deactivated

Fresh Air

Note: This parameter can only be used when the "Fresh Air" page is activated in "Page_combine". If Fresh air page title is "Deactivated", the Fresh air page will not display the Fresh air page title and it will display the default "Fan speed" and "operation state". If any of the Fresh air page title is selected, It will display the Fresh air page title,

"Fan speed" and "operation state".

12.41

Application “RTC”

12.41.1

Options

General – Display language

English

Chinese

Configuration of display language on RTC LCD display screen.

12.41.2

Options

General – Main Temperature display

Setpoint

Actual

If the actual temperature is to be shown on the display, the parameter must be set on

“Actual”. The device will then primarily display the actual temperature. When actuating the control element the display changes to the setpoint adjustment. After non-actuation of the control element, the current actual temperature again appears in the display after the set waiting period.

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Options

General – Interval time for switchover to RTC page (sec)

Time input from 3 sec to 30 sec

After non-actuation of the control element the temperature again appears in the display after the set waiting period.

12.41.4

Options

General – RTC button feedback (vibrate)

Deactivate

Activate

Configuration of vibration feedback upon pressing of RTC control button. Up, Down,

Fan, Menu button.

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Options

General – Device function

Single device

Master device

Slave device

– Single device : The device is use singly in a room as room temperature controller.

– Master device : At least two room temperature controllers are located in one room.

One device is to be set up as a master device, while the others are to be program as slave devices / temperature sensors. The master device is to be link to the slave devices using the appropriately labelled communication objects. The master device regulates the temperature.

– Slave device /temperature sensor: At least two room temperature controllers are located in one room. One device is to be set up as a master device, while the others are to be program as slave devices / temperature sensors. The slave devices are to be link to the master device with the appropriately labelled communication objects. The slave device serves the room temperature control functions of the master.

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Options

General – Control function

Heating

Heating with additional stage

Cooling

Cooling with additional stage

Heating and cooling

Heating and cooling with additional stage

Note: This parameter is only available if the "Device function" parameter is set on "Single device" or "Master device".

– Heating : For operating a heat-based automatic single-room control. The temperature is regulated to the setpoint value defined in the parameter. The "Controller type" and

"Heating type" can be program for optimal control.

– Heating with additional stage : In addition to the control function described under heating, the additional stage enables the activation of an additional heating circuit. This type of additional stage is use, for example, to heat up a bathroom quickly with floor heating via a heated towel rack.

– Cooling : For operating a cooling-based automatic single-room control. The temperature is regulated to the setpoint value defined in the parameter. The "Controller type" and "Cooling type" can be program for optimal control.

– Cooling with additional stage : In addition to the control function described under cooling, the additional stage enables the activation of an additional cooling device. This type of additional stage is use, for example, to cool a room quickly via an added cooling device.

– Heating and cooling : For operating a two-wire or four-wire system used to heat or cool a room. Switching between heating and cooling takes place using a central switch (twowire system) or is carry out manually and / or automatically via the single room temperature controller (four-wire system).

– Heating and cooling with an additional stage: In addition to the heating and cooling functions, one additional stage each with an autonomous controller type can be program.

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Options

General – Operating mode after reset

Comfort

Standby

Eco mode

Frost/heat protection

Note: This parameter is only available if the "Device function" parameter is set on "Single device" or "Master device".

After a reset the device will run in the operating mode after a restart until a new operating mode is set as the result of device operation or by communication objects, as the case may be. This operating mode should be define during the planning phase. An improperly defined operating mode can result in a loss of comfort or increased energy consumption.

– Comfort : If the room temperature is not automatically lower and the room is therefore controlled independent of its use.

– Standby : If the room is controlled automatically, e.g. by a presence detector, as a function of its use.

– Eco mode : If the room is controlled automatically or manually as a function of it use.

– Frost/heat protection : If only the building protection function is necessary in the room after a reset.

12.41.8

Options

General – Send cyclic “In operation” (min)

Time input from 5 min to 3000 min

– The "In operation" communication object serves to inform that the controller still operates. Value "1" is sent cyclic. This parameter is use to set the cycle for sending. If the cyclic telegram fails, the function of the device is faulty and the air-conditioning of the room can be maintain with a forced operation. However, for this the system and/or actuator must have "Forced operation" function.

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Options

General – Additional functions / objects

No

Yes

– This parameter enables additional functions and communication objects.

Single / master / Slave:

- RTC controller On/Off

- Send fault actual temperature

- Window contact

- Presence detector

- Controller status RHCC

- Controller status HVAC

- Units switchover Celsius (°C) or Fahrenheit (°F)

Single / Master:

- Set basic setpoint by group object

Slave:

- RTC condensate water alarm

12.41.10

Options

General – Delay time for read telegrams after reset (s)

Time input from 1 sec to 255 sec

A delay in reading additional functions / objects after the reset of device

12.41.11

Options

Operating functions – Temperature unit

°C

°F

This is where the temperature unit is select to be display on the device. The parameter is use to choose between Celsius (°C) and Fahrenheit (°F).

12.41.12

Options

Operating functions – Hide temperature unit

No

Yes

To select whether to display or not to display the temperature unit on the RTC LCD main display

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Options

Operating functions – Switchover heating / cooling

No

Yes

Note: This parameter is only available if the "Device function" parameter is set on "slave device".

To switchover between heating and cooling on the room temperature controller via the 1 bit communication object

12.41.14

Options

Operating functions – Fan coil control during heating mode

No

Yes

Note: This parameter is only available if the "Device function" parameter is set on "slave device".

To set the fan coil actuator to be in manual fan mode or in automatic fan mode via the 1 bit communication object when in heating mode.

12.41.15

Options

Operating functions – Fan coil control during cooling mode

No

Yes

Note: This parameter is only available if the "Device function" parameter is set on "slave device".

To set the fan coil actuator to be in manual fan mode or in automatic fan mode via the 1 bit communication object when in cooling mode.

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Options

Control heating – Control value type

2-point 1 bit, Off/On

2-point 1 byte, (0/100%)

PI continuous, 0-100%

PI PWM, On/Off

Fan coil

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating", "Heating with additional stage", "Heating and cooling" or "Heating and cooling with additional stages".

The actuation of the control valve is determine by the selection of the controller type.

– 2-Point 1 Bit, Off/On : The 2-point control is the simplest type of control. The controller switches on when the room temperature drops below a certain level (setpoint temperature value minus hysteresis) and switches off when a particular value (setpoint temperature value plus hysteresis) is exceeded. The switch-on and switch-off commands are transmitted as 1-bit commands.

– 2-Point 1 Byte, 0/100% : This is another two-point control as described above. In this case, however, the switch-on and switch-off commands are transmit as 1-byte values

(0% / 100%).

– PI continuous, 0-100% : The PI controller adjusts its output value between 0% and

100% to match the difference between the actual value and the setpoint value and enables a precise regulation of the room temperature to the setpoint value. It sends the control value to the bus as a 1-byte value (0% - 100%). To reduce the bus load, the control value is only transmitted if it has changed by a predefined percentage in relation to the previous sent value. The control value can also be transmit cyclically.

– PI PWM, On/Off : This also is a PI controller. Here, the output is a 1-bit command. For this to occur, the calculated control value is convert into a pulse-interval signal.

– Fan coil : The fan coil controller operates like the PI continuous controller. In addition, it allows the separate activation of the fan in the fan coil unit (e.g. fan speed levels 1 –

3/5).

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Control heating – Heating type

Options

PI continuous, 0 – 100% and PI

PWM, On/Off:

Options

Fan coil:

Area (e.g. floor heating) 4°C 200 min

Convector (e.g. heater) 1.5°C 100 min

Free configuration

Fan coil 4°C 90 min

Free configuration

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

Multiple heating types (panel heating, convector heating or fan coil) with preset parameters are available to the user. If the required heating type is not available, individual parameters can be specified in free configuration.

12.41.18

Options

Control heating – P-component (x 0.1 °C)

Input from 10 to 100

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil". In addition, the

"Heating type" parameter must be set on "Free configuration".

The P-component refers to the proportional band of a control. It fluctuates around the setpoint value and can be used to influence control speed with a PI controller. The smaller the setpoint, the faster it reacts to the control. However, to avoid the risk of an overshoot, this value should not be set too low. A P-component from 0.1 to 25.5 K can be set.

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Options

Control heating – I-component (min)

Input from 0 to 255

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil". In addition, the

"Heating type" parameter must be set on "Free configuration".

The I-component refers to the reset time of a control. The integral component has the effect of moving the room temperature slowly toward, and ultimately reaching, the setpoint value. Depending on the type of system used, the reset time has to have different values. In general, the more inactive the overall system, the greater the reset time.

12.41.20

Options

Control heating – Extended setting

No

Yes

This parameter enables additional functions and communication objects, e.g. "Basic stage heating".

12.41.21

Options

Basic stage heating – Status object heating

No

Yes

Note: Only available when the "Extended settings" parameter under "Heating control" is set on "Yes".

This parameter enables the “Status heating” communication object.

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Options

Basic stage heating – Control direction of control valve

Normal

Inverse

Note: Only available when the "Extended settings" parameter under "Heating control" is set on "Yes".

The mode of the control value can be used to adapt the control value to de-energized opened (normal) or de-energized closed (inverse) valves.

– N ormal : Value 0 means "Valve closed".

– Inverse : Value 0 means "Valve open".

12.41.23

Options

Basic stage heating – Hysteresis (x 0.1 °C)

Input from 3 to 255

Note: This parameter is only available when the "Control value type" parameter is set either on "2-point 1 Bit, Off/On" or "2-point 1 Byte, 0/100%".

The hysteresis of the two-point controller specifies the fluctuation range of the controller around the setpoint value. The lower switching point is located at "Setpoint value minus hysteresis" and the upper point is at "Setpoint value plus hysteresis".

12.41.24

Basic stage heating – Control value difference for sending of heating control value

Options 2 %

5 %

10 %

Send cyclic only

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%" or "Fan coil".

The control values of the 0 - 100% PI continuous controller are not transmitted after every calculation. Instead, they are transmit when the calculation results in a value that is different enough to the previous sent value to make a transmission meaningful. This value difference can be enter here.

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Options

Basic stage heating – Cyclic sending of the control value (min)

Input from 1 to 60

Note : This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

The current control value used by the device can be cyclically transmit to the bus.

12.41.26

Options

Basic stage heating – PWM cycle heating (min)

Input from 1 to 60

Note : This parameter is only available when the "Control value type" parameter is set on "PI PWM, On/Off“.

In PI PWM, On/off the control value percentage values are convert into a pulse-interval signal. This means that a selected PWM cycle will be divided into an on-phase and an off-phase based on the control value. Accordingly, a control value output of 33% in a

PWM cycle of 15 min. results in an "On-phase" of five minutes and an "Off-phase" of 10 min. The time for a PWM cycle can be specified here.

12.41.27

Options

Basic stage heating – Maximum control value

Input from 0 to 255

Note : This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

The maximum control value of the PI controller defines the maximum value outputted by the controller. If a maximum value under 255 is chosen, the value will not be exceeded, even if the controller calculates a higher control value.

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Options

Basic stage heating – Minimum control value for basic load

Input from 0 to 255

Note : This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

The minimum control value of the PI controller defines the minimum value output by the controller. If a minimum value greater than zero is chosen, the controller will not output a lower value, even if it calculates a value that is lower. This parameter can be used to set a basic load, e.g. for operating floor heating. Even if the controller calculates the control value zero, a heating medium will flow through the floor heating system to prevent the floor from cooling down. Under "Settings of basic load", it is also possible to define whether this basic load will be permanently active or whether it will be switched by the "Basic load" object.

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Options

Control of heating additional stage – Control value type

2-point 1 bit, Off/On

2-point 1 byte, (0/100%)

PI continuous, 0-100%

PI PWM, On/Off

Fan coil

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages".

The actuation of the control valve is determine by the selection of the controller type.

– 2-Point 1 Bit, Off/On : The 2-point control is the simplest type of control. The controller switches on when the room temperature drops below a certain level (setpoint temperature value minus hysteresis) and switches off when a particular value (setpoint temperature value plus hysteresis) is exceeded. The switch-on and switch-off commands are transmitted as 1-bit commands.

– 2-Point 1 Byte, 0/100% : This is another two-point control as described above. In this case, however, the switch-on and switch-off commands are transmit as 1-byte values

(0% / 100%).

– PI continuous, 0-100% : The PI controller adjusts its output value between 0% and

100% to match the difference between the actual value and the setpoint value and enables a precise regulation of the room temperature to the setpoint value. It sends the control value to the bus as a 1-byte value (0% - 100%). To reduce the bus load, the control value is only transmitted if it has changed by a predefined percentage in relation to the previous sent value. The control value can also be transmit cyclically.

– PI PWM, On/Off : This also is a PI controller. Here, the output is a 1-bit command. For this to occur, the calculated control value is convert into a pulse-interval signal.

– Fan coil : The fan coil controller operates like the PI continuous controller. In addition, it allows the separate activation of the fan in the fan coil unit (e.g. fan speed levels 1 –

3/5).

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Control of heating additional stage – Additional heating type

Options

PI continuous, 0 – 100% and PI

PWM, On/Off:

Options

Fan coil:

Area (e.g. floor heating) 4°C 200 min

Convector (e.g. heater) 1.5°C 100 min

Free configuration

Fan coil 4°C 90 min

Free configuration

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages" ,only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

Multiple heating types (panel heating, convector heating or fan coil) with preset parameters are available to the user. If the required heating type is not available, individual parameters can be specified in free configuration.

12.41.31

Options

Control of heating additional stage – P-component (x 0.1 °C)

Input from 10 to 100

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil". In addition, the "Heating type" parameter must be set on "Free configuration".

The P-component refers to the proportional band of a control. It fluctuates around the setpoint value and can be used to influence control speed with a PI controller. The smaller the setpoint, the faster it reacts to the control. However, to avoid the risk of an overshoot, this value should not be set too low. A P-component from 0.1 to 25.5 K can be set.

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Options

Control of heating additional stage – I-component (min)

Input from 0 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages" only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil". In addition, the "Heating type" parameter must be set on "Free configuration".

The I-component refers to the reset time of a control. The integral component has the effect of moving the room temperature slowly toward, and ultimately reaching, the setpoint value. Depending on the type of system used, the reset time has to have different values. In general, the more inactive the overall system, the greater the reset time.

12.41.33

Control of heating additional stage – Temperature difference to basic stage (x 0.1 °C)

Options Input from 0 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages"

The setpoint temperature of the additional stage is define as a function of the current setpoint temperature of the base stage and is express as a difference. The value represents the setpoint value starting at which the additional stage will operate.

12.41.34

Options

Control of heating additional stage – Extended setting

No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages"

This parameter enables additional functions and communication objects, e.g. "additional heating stage".

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Options

Additional heating stage – Control direction of control valve

Normal

Inverse

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when the "Extended settings" parameter under "Control of heating additional stage" is set on "Yes".

The mode of the control value can be used to adapt the control value to de-energized opened (normal) or de-energized closed (inverse) valves.

– N ormal : Value 0 means "Valve closed".

– Inverse : Value 0 means "Valve open".

12.41.36

Options

Additional heating stage– Hysteresis (x 0.1 °C)

Input from 3 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when the "Control value type" parameter is set either on "2-point 1 Bit, Off/On" or "2-point 1 Byte, 0/100%".

The hysteresis of the two-point controller specifies the fluctuation range of the controller around the setpoint value. The lower switching point is located at "Setpoint value minus hysteresis" and the upper point is at "Setpoint value plus hysteresis".

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12.41.37

Additional heating stage – Control value difference for sending of heating control value

Options 2 %

5 %

10 %

Send cyclic only

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%" or "Fan coil".

The control values of the 0 - 100% PI continuous controller are not transmitted after every calculation. Instead, they are transmit when the calculation results in a value that is different enough to the previous sent value to make a transmission meaningful. This value difference can be enter here.

12.41.38

Options

Additional heating stage – Cyclic sending of the control value (min)

Input from 1 to 60

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

The current control value used by the device can be cyclically transmit to the bus.

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Options

Additional heating stage – PWM cycle heating (min)

Input from 1 to 60

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when the "Control value type" parameter is set on "PI PWM, On/Off“.

In PI PWM, On/off the control value percentage values are convert into a pulse-interval signal. This means that a selected PWM cycle will be divided into an on-phase and an off-phase based on the control value. Accordingly, a control value output of 33% in a

PWM cycle of 15 min. results in an "On-phase" of five minutes and an "Off-phase" of 10 min. The time for a PWM cycle can be specified here.

12.41.40

Options

Additional heating stage – Maximum control value

Input from 0 to 255

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

The maximum control value of the PI controller defines the maximum value outputted by the controller. If a maximum value under 255 is chosen, the value will not be exceeded, even if the controller calculates a higher control value.

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Options

Additional heating stage – Minimum control value for basic load

Input from 0 to 255

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

The minimum control value of the PI controller defines the minimum value output by the controller. If a minimum value greater than zero is chosen, the controller will not output a lower value, even if it calculates a value that is lower. This parameter can be used to set a basic load, e.g. for operating floor heating. Even if the controller calculates the control value zero, a heating medium will flow through the floor heating system to prevent the floor from cooling down. Under "Settings of basic load", it is also possible to define whether this basic load will be permanently active or whether it will be switched by the "Basic load" object.

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Options

Control cooling – Control value type

2-point 1 bit, Off/On

2-point 1 byte, (0/100%)

PI continuous, 0-100%

PI PWM, On/Off

Fan coil

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling", "Cooling with additional stage", "Heating and cooling" or "Heating and cooling with additional stages".

The actuation of the control valve is determine by the selection of the controller type.

– 2-Point 1 Bit, Off/On : The 2-point control is the simplest type of control. The controller switches on when the room temperature drops below a certain level (setpoint temperature value minus hysteresis) and switches off when a particular value (setpoint temperature value plus hysteresis) is exceeded. The switch-on and switch-off commands are transmitted as 1-bit commands.

– 2-Point 1 Byte, 0/100% : This is another two-point control as described above. In this case, however, the switch-on and switch-off commands are transmit as 1-byte values

(0% / 100%).

– PI continuous, 0-100% : The PI controller adjusts its output value between 0% and

100% to match the difference between the actual value and the setpoint value and enables a precise regulation of the room temperature to the setpoint value. It sends the control value to the bus as a 1-byte value (0% - 100%). To reduce the bus load, the control value is only transmitted if it has changed by a predefined percentage in relation to the previous sent value. The control value can also be transmit cyclically.

– PI PWM, On/Off : This also is a PI controller. Here, the output is a 1-bit command. For this to occur, the calculated control value is convert into a pulse-interval signal.

– Fan coil : The fan coil controller operates like the PI continuous controller. In addition, it allows the separate activation of the fan in the fan coil unit (e.g. fan speed levels 1 –

3/5).

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Options

Control cooling – Cooling type

PI continuous, 0 – 100% and PI

PWM, On/Off:

Options

Fan coil:

Area (e.g. cooling ceiling) 5°C 200 min

Free configuration

Fan coil 4°C 90 min

Free configuration

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

Two cooling types (area or fan coil) with preset parameters are available to the user.

If the required cooling type is not available, individual parameters can be specified in free configuration.

12.41.44

Options

Control cooling – P-component (x 0.1 °C)

Input from 10 to 100

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil". In addition, the

"Cooling type" parameter must be set on "Free configuration".

The P-component refers to the proportional band of a control. It fluctuates around the setpoint value and can be used to influence control speed with a PI controller. The smaller the setpoint, the faster it reacts to the control. However, to avoid the risk of an overshoot, this value should not be set too low. A P-component from 0.1 to 25.5 K can be set.

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Options

Control cooling – I-component (min)

Input from 0 to 255

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil". In addition, the

"Cooling type" parameter must be set on "Free configuration".

The I-component refers to the reset time of a control. The integral component has the effect of moving the room temperature slowly toward, and ultimately reaching, the setpoint value. Depending on the type of system used, the reset time has to have different values. In general, the more inactive the overall system, the greater the reset time.

12.41.46

Options

Control cooling – Extended setting

No

Yes

This parameter enables additional functions and communication objects, e.g. "Basic stage cooling".

12.41.47

Options

Basic stage cooling – Cooling status object

No

Yes

Note: Only available when the "Extended settings" parameter under "Cooling control" is set on "Yes".

This parameter enables the “Status cooling” communication objects.

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12.41.48

Options

Basic stage cooling – Control direction of control valve

Normal

Inverse

Note: Only available when the "Extended settings" parameter under "Cooling control" is set on "Yes".

The mode of the control value can be used to adapt the control value to de-energized opened (normal) or de-energized closed (inverse) valves.

– N ormal : Value 0 means "Valve closed".

– Inverse : Value 0 means "Valve open".

12.41.49

Options

Basic stage cooling – Hysteresis (x 0.1 °C)

Input from 3 to 255

Note: This parameter is only available when the "Control value type" parameter is set either on "2-point 1 Bit, Off/On" or "2-point 1 Byte, 0/100%".

The hysteresis of the two-point controller specifies the fluctuation range of the controller around the setpoint value. The lower switching point is located at "Setpoint value minus hysteresis" and the upper point is at "Setpoint value plus hysteresis".

12.41.50

Basic stage cooling – Control value difference for sending of cooling control value

Options 2 %

5 %

10 %

Send cyclic only

Note: This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%" or "Fan coil".

The control values of the 0 - 100% PI continuous controller are not transmitted after every calculation. Instead, they are transmit when the calculation results in a value that is different enough to the previous sent value to make a transmission meaningful. This value difference can be enter here.

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12.41.51

Options

Basic stage cooling – Cyclic sending of the control value (min)

Input from 1 to 60

Note : This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

The current control value used by the device can be cyclically transmit to the bus.

12.41.52

Options

Basic stage cooling – PWM cycle cooling (min)

Input from 1 to 60

Note : This parameter is only available when the "Control value type" parameter is set on "PI PWM, On/Off“.

In PI PWM, On/off the control value percentage values are convert into a pulse-interval signal. This means that a selected PWM cycle will be divided into an on-phase and an off-phase based on the control value. Accordingly, a control value output of 33% in a

PWM cycle of 15 min. results in an "On-phase" of five minutes and an "Off-phase" of 10 min. The time for a PWM cycle can be specified here.

12.41.53

Options

Basic stage cooling – Maximum control value

Input from 0 to 255

Note : This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

The maximum control value of the PI controller defines the maximum value outputted by the controller. If a maximum value under 255 is chosen, the value will not be exceeded, even if the controller calculates a higher control value.

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12.41.54

Options

Basic stage cooling – Minimum control value for basic load

Input from 0 to 255

Note : This parameter is only available when "Control value type" parameter is set either on "PI continuous, 0 – 100%", "PI PWM, On/Off“ or "Fan coil".

The minimum control value of the PI controller defines the minimum value output by the controller. If a minimum value greater than zero is chosen, the controller will not output a lower value, even if it calculates a value that is lower. This parameter can be used to set a basic load, e.g. for operating floor cooling. Even if the controller calculates the control value zero, a cooling medium will flow through the floor cooling system to prevent the floor from cooling down. Under "Settings of basic load", it is also possible to define whether this basic load will be permanently active or whether it will be switched by the "Basic load" object.

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12.41.55

Options

Control of cooling additional stage – Control value type

2-point 1 bit, Off/On

2-point 1 byte, (0/100%)

PI continuous, 0-100%

PI PWM, On/Off

Fan coil

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Cooling and cooling with additional stages".

The actuation of the control valve is determine by the selection of the controller type.

– 2-Point 1 Bit, Off/On : The 2-point control is the simplest type of control. The controller switches on when the room temperature drops below a certain level (setpoint temperature value minus hysteresis) and switches off when a particular value (setpoint temperature value plus hysteresis) is exceeded. The switch-on and switch-off commands are transmitted as 1-bit commands.

– 2-Point 1 Byte, 0/100% : This is another two-point control as described above. In this case, however, the switch-on and switch-off commands are transmit as 1-byte values

(0% / 100%).

– PI continuous, 0-100% : The PI controller adjusts its output value between 0% and

100% to match the difference between the actual value and the setpoint value and enables a precise regulation of the room temperature to the setpoint value. It sends the control value to the bus as a 1-byte value (0% - 100%). To reduce the bus load, the control value is only transmitted if it has changed by a predefined percentage in relation to the previous sent value. The control value can also be transmit cyclically.

– PI PWM, On/Off : This also is a PI controller. Here, the output is a 1-bit command. For this to occur, the calculated control value is convert into a pulse-interval signal.

– Fan coil : The fan coil controller operates like the PI continuous controller. In addition, it allows the separate activation of the fan in the fan coil unit (e.g. fan speed levels 1 –

3/5).

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12.41.56

Options

Control of cooling additional stage – Additional cooling type

PI continuous, 0 – 100% and PI

PWM, On/Off:

Options

Fan coil:

Area (e.g. floor cooling) 5°C 200 min

Free configuration

Fan coil 4°C 90 min

Free configuration

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages" ,only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

Two cooling types (area or fan coil) with preset parameters are available to the user.

If the required cooling type is not available, individual parameters can be specified in free configuration.

12.41.57

Options

Control of cooling additional stage – P-component (x 0.1 °C)

Input from 10 to 100

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil". In addition, the "Cooling type" parameter must be set on "Free configuration".

The P-component refers to the proportional band of a control. It fluctuates around the setpoint value and can be used to influence control speed with a PI controller. The smaller the setpoint, the faster it reacts to the control. However, to avoid the risk of an overshoot, this value should not be set too low. A P-component from 0.1 to 25.5 K can be set.

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12.41.58

Options

Control of cooling additional stage – I-component (min)

Input from 0 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages" only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil". In addition, the "Cooling type" parameter must be set on "Free configuration".

The I-component refers to the reset time of a control. The integral component has the effect of moving the room temperature slowly toward, and ultimately reaching, the setpoint value. Depending on the type of system used, the reset time has to have different values. In general, the more inactive the overall system, the greater the reset time.

12.41.59

Control of cooling additional stage – Temperature difference to basic stage (x 0.1 °C)

Options Input from 0 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages"

The setpoint temperature of the additional stage is define as a function of the current setpoint temperature of the base stage and is expressed as a difference. The value represents the setpoint value starting at which the additional stage will operate.

12.41.60

Options

Control of cooling additional stage – Extended setting

No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages"

This parameter enables additional functions and communication objects, e.g. "additional cooling stage".

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12.41.61

Options

Additional cooling stage – Control direction of control valve

Normal

Inverse

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when the "Extended settings" parameter under "Control of cooling additional stage" is set on "Yes".

The mode of the control value can be used to adapt the control value to de-energized opened (normal) or de-energized closed (inverse) valves.

– N ormal : Value 0 means "Valve closed".

– Inverse : Value 0 means "Valve open".

12.41.62

Options

Additional cooling stage– Hysteresis (x 0.1 °C)

Input from 3 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when the "Control value type" parameter is set either on "2-point 1 Bit, Off/On" or "2-point 1 Byte, 0/100%".

The hysteresis of the two-point controller specifies the fluctuation range of the controller around the setpoint value. The lower switching point is located at "Setpoint value minus hysteresis" and the upper point is at "Setpoint value plus hysteresis".

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12.41.63

Additional cooling stage – Control value difference for sending of cooling control value

Options 2 %

5 %

10 %

Send cyclic only

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%" or "Fan coil".

The control values of the 0 - 100% PI continuous controller are not transmitted after every calculation. Instead, they are transmit when the calculation results in a value that is different enough to the previous sent value to make a transmission meaningful. This value difference can be enter here.

12.41.64

Options

Additional cooling stage – Cyclic sending of the control value (min)

Input from 1 to 60

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

The current control value used by the device can be cyclically transmit to the bus.

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12.41.65

Options

Additional cooling stage – PWM cycle cooling (min)

Input from 1 to 60

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when the "Control value type" parameter is set on "PI PWM, On/Off“.

In PI PWM, On/off the control value percentage values are convert into a pulse-interval signal. This means that a selected PWM cycle will be divided into an on-phase and an off-phase based on the control value. Accordingly, a control value output of 33% in a

PWM cycle of 15 min. results in an "On-phase" of five minutes and an "Off-phase" of 10 min. The time for a PWM cycle can be specified here.

12.41.66

Options

Additional cooling stage – Maximum control value

Input from 0 to 255

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

The maximum control value of the PI controller defines the maximum value outputted by the controller. If a maximum value under 255 is chosen, the value will not be exceeded, even if the controller calculates a higher control value.

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12.41.67

Options

Additional cooling stage – Minimum control value for basic load

Input from 0 to 255

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Cooling with additional stage" or "Heating and cooling with additional stages", only available when "Control value type" parameter is set either on "PI continuous, 0 –

100%", "PI PWM, On/Off“ or "Fan coil".

The minimum control value of the PI controller defines the minimum value output by the controller. If a minimum value greater than zero is chosen, the controller will not output a lower value, even if it calculates a value that is lower. This parameter can be used to set a basic load, e.g. for operating floor cooling. Even if the controller calculates the control value zero, a cooling medium will flow through the floor cooling system to prevent the floor from cooling down. Under "Settings of basic load", it is also possible to define whether this basic load will be permanently active or whether it will be switched by the "Basic load" object.

12.41.68

Options

Setting of basic load – Minimum control value for basic load > 0

Always active

Activate via object

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage", "Cooling with additional stage", "Heating and cooling" or

"Heating and cooling with additional stages".

The function finds application when in the desired area, e.g. with floor heating, the floor is to have a basic warmth. The size of the minimum control value specifies the volume of heating medium that flows through the controlled area, even when the calculation of the control value of the controller would indicate a lower value.

– Always active : Here it is possible to define whether this basic load will be permanently active or whether it will be switch via the "Basic load" object.

– Activate via object : When this parameter is select, the basic load function, which means the minimum control value with a value higher than zero, can be activated (1) or deactivated (2). If it is activate, then the heating medium will always be fed through the system with at least the minimum control value. If it is deactivate, the control value can be reduce to zero with the controller.

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12.41.69

Options

Setting of basic load – Basic load active when controller is off

No

Yes

Note : Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating with additional stage", "Cooling with additional stage", "Heating and cooling" or

"Heating and cooling with additional stages".

When room temperature controller is off, it will operate at the min basic load.

12.41.70

Options

Combine heating and cooling mode – Switchover heating / cooling

Automatic

Only via object

On-site/via extension unit and via object

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating and cooling" or "Heating and cooling with additional stages".

This function makes it possible to switch between the heating and cooling mode of the device.

– Automatic : E.g. for four-conductor systems which allow the switchover between heating and cooling at all times. The device switches automatically between heating and cooling and to the associated setpoint. "Switchover heating/cooling" is a transmitting object.

– Only via object : E.g. for two-conductor systems which are operated in heating mode in the winter and cooling mode in the summer. The switchover between heating and cooling and to the associated setpoint is carry out via the corresponding communication object. This function is use when a central switchover of the single room controllers is required. "Switchover heating/cooling" is a receiving object.

– Local/ via extension unit and via object : E.g. for four-conductor systems which allow the switchover between heating and cooling at all times. The switchover between heating and cooling and to the associated setpoint is carry out manually on the device by the user of the room or via the "Switchover heating/cooling" object via the bus.

"Switchover heating/cooling" is a transmitting and receiving object.

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12.41.71

Options

Combine heating and cooling mode – Operating state after reset

Cooling

Heating

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating and cooling" or "Heating and cooling with additional stages".

After a bus voltage failure, a system reset, or the attachment of a device to the bus coupler, the device starts in the parameterized "Operating state after reset". The operating state can be change when the system is running using the options set under

"Switchover heating/cooling".

12.41.72

cooling

Combine heating and cooling mode – Output control value heating and

Options Via 1 object

Via 2 objects

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on either

"Heating and cooling" or "Heating and cooling with additional stages".

This parameter is use to define whether the control value is transmitted to the climate control actuator using one or two objects. If the climate control actuator has separate control value inputs for heating and cooling, or if separate actuators are used, then the option "Via 2 objects" must be selected. Select the option "Via 1 object" if a single actuator only has one object that receives both the heating and the cooling control values.

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12.41.73

Combine heating and cooling mode – Output control value additional stage heating and cooling

Options Via 1 object

Via 2 objects

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the control function parameter is set on "Heating and cooling with additional stages".

This parameter is use to define whether the control value is transmitted to the climate control actuator using one or two objects. If the climate control actuator has separate control value inputs for heating and cooling, or if separate actuators are used, then the option "Via 2 objects" must be selected. Select the option "Via 1 object" if a single actuator only has one object that receives both the heating and the cooling control values.

12.41.74

Setpoint setting – Setpoint for heating comfort = setpoint for cooling comfort

Options No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on "Heating and cooling" or "Heating and cooling with additional stages".

This parameter is use to configure the manner in which the setpoint adjustment functions.

– Yes : The device has the same setpoint for heating and cooling in the comfort mode.

The system switches to heating when the temperature drops below the setpoint minus hysteresis. It switches to cooling when the temperature exceeds the setpoint plus hysteresis. The hysteresis can be parameterize.

– No : The function has two separate setpoints for heating and cooling in the comfort mode. The device will display the currently active setpoint value. Switching between heating and cooling occurs via the "Switchover heating/cooling" parameter setting.

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12.41.75

Options

Setpoint setting – Hysteresis for switchover heating/cooling (x 0.1°C)

Input from 5 to 100

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on "Heating and cooling" or "Heating and cooling with additional stages", only available when the

“switchover heating / cooling” is set to automatic and "Setpoint heating comfort =

Setpoint cooling comfort" parameter is set on "Yes".

This parameter specifies the one-sided hysteresis for switching between heating and cooling when "Setpoint heating comfort = Setpoint cooling comfort" is active. If the room temperature exceeds the setpoint temperature value plus hysteresis, the system switches to cooling. If the room temperature falls below the setpoint temperature value minus hysteresis, the system switches to heating.

12.41.76

(°C)

Options

Setpoint setting – Setpoint temperature for heating and cooling comfort

Input from 10 to 40

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on "Heating and cooling" or "Heating and cooling with additional stages", only available when

"Setpoint heating comfort = Setpoint cooling comfort" parameter is set on "Yes".

Specifies the comfort temperature for heating and cooling when people are present.

12.41.77

Options

Setpoint setting – Setpoint temperature for heating comfort (°C)

Input from 10 to 40

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Heating”, “Heating with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages", only available when "Setpoint heating comfort = Setpoint cooling comfort" parameter is set on "No".

Specifies the comfort temperature for heating when people are present.

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12.41.78

Options

Setpoint setting – Reduction for standby heating (°C)

Input from 0 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Heating”, “Heating with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

Specifies the temperature in heating mode when nobody is present. On devices with a display, this mode is indicated by the standby symbol.

12.41.79

Options

Setpoint setting – Reduction for ECO heating (°C)

Input from 0 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Heating”, “Heating with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

Specifies the temperature in heating mode when nobody is present. On devices with a display, this mode is indicated by the ECO symbol.

12.41.80

Options

Setpoint setting – Setpoint temperature for frost protection (°C)

Input from 5 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Heating”, “Heating with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

Function for protecting the building against the cold. On devices with a display, this mode is indicated by the frost protection symbol. Manual operation is lock.

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12.41.81

Options

Setpoint setting – Setpoint temperature for cooling comfort (°C)

Input from 10 to 40

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Cooling”, “Cooling with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages", only available when "Setpoint heating comfort = Setpoint cooling comfort" parameter is set on "No".

Specifies the comfort temperature for cooling when people are present.

12.41.82

Options

Setpoint setting – Increase for standby cooling (°C)

Input from 0 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Cooling”, “Cooling with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

Specifies the temperature in cooling mode when nobody is present. On devices with a display, this mode is indicated by the standby symbol.

12.41.83

Options

Setpoint setting – Increase for ECO cooling (°C)

Input from 0 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Cooling”, “Cooling with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

Specifies the temperature in cooling mode when nobody is present. On devices with a display, this mode is indicated by the ECO symbol.

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12.41.84

Options

Setpoint setting – Setpoint temperature for heat protection (°C)

Input from 5 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the Control function parameter is set on

“Cooling”, “Cooling with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

Function for protecting the building against the heat. On devices with a display, this mode is indicated by the heat protection symbol. Manual operation is lock.

12.41.85

Options

Setpoint setting – Display indicates

Actual setpoint

Relative setpoint

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

The display can indicate either the absolute or relative setpoint value.

– Current setpoint : On devices with a display, the setpoint is shown as an absolute temperature, e.g. 21.0°C.

– Relative setpoint : On devices with display, the setpoint is indicated as a relative value, e.g. -5°C .. + 5°C.

12.41.86

Options

Setpoint setting – Send current setpoint

Cyclic and during change

Only for change

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

The current setpoint value can be sent to the bus either cyclically and after a change, or only after a change.

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12.41.87

Options

Setpoint setting – Cyclic sending of the current setpoint temperature (min)

Time input from 5 to 240

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and only available when the "Send current setpoint" is set on "Cyclic and during change".

This parameter is use to specified the amount of time that will elapse before the current setpoint value is automatically transmitted onto the bus line.

12.41.88

Options

Setpoint setting – Basic setpoint is

Setpoint for cooling comfort

Setpoint for heating comfort

Mean value between heating comfort and cooling comfort

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device"

This parameter is use to specified the reference for basic setpoint.

12.41.89

(°C)

Options

Changing set value – Maximum manual increase during heating mode

Input from 0 to 9

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device", and the Control function parameter is set on

“Heating”, “Heating with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

This preset is use to limit the manual increase during heating mode.

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12.41.90

(°C)

Options

Changing set value – Maximum manual reduction during heating mode

Input from 0 to 9

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device", and the Control function parameter is set on

“Heating”, “Heating with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

This preset is use to limit the manual reduction during heating mode.

12.41.91

Options

Changing set value – Maximum manual increase during cooling mode (°C)

Input from 0 to 9

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device", and the Control function parameter is set on

“Cooling”, “Cooling with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

This preset is use to limit the manual increase during cooling mode.

12.41.92

(°C)

Options

Changing set value – Maximum manual reduction during cooling mode

Input from 0 to 9

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device", and the Control function parameter is set on

“Cooling”, “Cooling with additional stage”, "Heating and cooling" or "Heating and cooling with additional stages".

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This preset is use to limit the manual reduction during cooling mode.

12.41.93

Changing set value – Resetting of the manual adjustment for receipt of a basic setpoint

Options No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

Activating this parameter will cause the manual adjustment to be deleted and the new setpoint value to be provided when a new value is received via the "Basic setpoint" object. If the parameter is deactivate, the manual adjustment is add to the new base setpoint value.

Example: Previous base setpoint value of 21°C + manual adjustment of 1.5°C = 22.5°C.

The object receives a new basic setpoint of 18°C plus the previous manual adjustment of 1.5°C for a total of 19.5°C.

12.41.94

Changing set value – Resetting of the manual adjustment for change of operating mode

Options No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

If the device switches to a new operating mode, the manual adjustment is delete and the parameterized setpoint temperature for the operating mode plus any change by the base setpoint value object will be applied if this parameter is activate. Example: Comfort temperature of 21°C plus manual adjustment of 1.5°C = 22.5°C. Change to Eco with programmed temperature 17°C. The device regulates the temperature to 17°C, since the manual adjustment is delete.

If the parameter is deactivate, the manual setpoint adjustment will be added to the temperature in the new operating mode.

Example: Comfort temperature of 21°C plus manual adjustment of 1.5°C = 22.5°C. If the system switches to Eco with a parameterized temperature of 17°C, the device regulates the temperature to 18.5°C, since the manual adjustment is add.

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12.41.95

Options

Changing set value – Resetting the manual adjustment via object

No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

If this parameter is activate, a separate object can be used to delete the manual adjustment at any time. Example of application: Resetting the manual adjustment on all devices located in a building using a system clock.

12.41.96

Options

Changing set value – Permanent storage of onsite operation

No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

If this parameter is activated, the manual settings for setpoint and, where applicable, fan speed level, as well as the value of the "Basic load" object, will be stored in the device and re-activated after a reset. If the device is re-programmed, the stored setpoint values will also be deleted.

12.41.97

Options

Temperature reading – Input of temperature reading

Internal measurement

External measurement

Weighted measurement

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

The room temperature can be measure at the device or fed to the device by an object via the bus. In addition, weighted measuring is also available, in which the weighted average of up to three temperature values (1 x internal, 2 x external) is calculated and used as an input value for control.

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12.41.98

Options

Temperature reading – Input of weighted temperature reading

Internal and external measurement

2 x external measurement

Internal and 2x external measurement

Note: This parameter is only available when the "Device function" parameter is set on either "Single device" or "Master device" and the "Inputs of temperature reading" parameter is set on "Weighted measurement".

Specifies the temperature reading inputs for the weighted measurement, in which the calculated weighted average of the inputs is used as an input value for control

12.41.99

Options

Temperature reading – Weighting of internal measurement (%)

Input from 0 to 100

Note: This parameter is only available when the "Device function" parameter is set on either "Single device" or "Master device" and the "Inputs of weighted temperature reading" parameter is set on "Internal and external measurement" or "Internal and 2x external measurement".

Specifies the weighting of the internal measurement at a level between 0% and 100%.

12.41.100 Temperature reading – Weighting of external measurement (%)

Options Input from 0 to 100

Note: This parameter is only available when the "Device function" parameter is set on either "Single device" or "Master device" and the "Inputs of weighted temperature reading" parameter is set on "Internal and external measurement" or "Internal and 2x external measurement".

Specifies the weighting of the external measurement at a level between 0% and 100%.

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12.41.101 Temperature reading – Weighting of external measurement 2 (%)

Options Input from 0 to 100

Note: This parameter is only available when the "Device function" parameter is set on either "Single device" or "Master device" and the "Inputs of weighted temperature reading" parameter is set on "2 x external measurement" or "Internal and 2x external measurement".

Specifies the weighting of the external measurement 2 at a level between 0% and

100%. When added together with the (0%...100%) weighting of the external measurement, the result must be 100%.

12.41.102 Temperature reading – Cyclic sending of the actual temperature (min)

Options Input from 5 to 240

Note: This parameter is only available when the "Inputs of temperature reading" parameter is set on "Internal measurement" or "Weighted measurement".

The current actual temperature used by the device can be cyclically transmit onto the bus line.

12.41.103 Temperature reading – Difference of value for sending the actual temperature (x 0.1 °C)

Options Input from 1 to 100

Note: This parameter is only available when the "Inputs of temperature reading" parameter is set on "Internal measurement" or "Weighted measurement".

If the change in temperature exceeds the parameterized difference between the measured actual temperature and the previous actual temperature that was sent, the changed value will be transmitted.

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12.41.104 Temperature reading – Difference value for internal temperature measurement (x 0.1 °C)

Options Input from -127 to 127

Note: This parameter is only available when the "Inputs of temperature reading" parameter is set on "Internal measurement" or "Weighted measurement". The calibration measurement should not be carry out immediately after the device has been installed. The device should first adjust to the ambient temperature before calibration is carry out. The calibration measurement should be repeated shortly before or after the room is occupy.

Every installation location has different physical conditions (interior or exterior wall, lightweight or solid wall, etc.). In order to use the actual temperature at the installation location as a measured value for the device, a temperature measurement must be performed by an external equalized and / or calibrated thermometer at the installation location.

The difference between the actual temperature displayed on the device and the actual temperature determined by the external measurement device must be entered in the parameter field as an "Adjustment value".

12.41.105 Temperature reading – Monitoring time for temperature reading (0=no monitoring) (min)

Options Input from 0 to 120

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

If no temperature is read within the parameterized time period, the device switches to error mode. It transmits a telegram to the bus via the "Actual temperature error" object and applies the operating state and control value for error (0 - 255) settings.

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12.41.106 Temperature reading – Operating state for fault

Options Cooling

Heating

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and only available when the "Control function" parameter is set on "Heating and cooling" or "heating and cooling with additional stages".

In the event of a failure of the actual temperature measurement, the device will no longer be able to independently specify the heating/cooling operating type. As a result, the operating type best suited to protecting the building will be selected.

12.41.107 Temperature reading – Control value for fault

Options Input from 0 to 255

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device"

In the event of a failure of the actual temperature measurement, the device will no longer be able to independently determine the control value. Therefore, a control value which is suitable for protecting the building will be selected.

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12.41.108 Alarm function – Condensate water alarm

Options No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and only available when the "Control function" parameter is set either on "Cooling", "Cooling with additional stage", "Heating and cooling" or "Heating and cooling with additional stages".

If a fan coil is used, condensation may form during operation as a result of excessive cooling and/or humidity. The associated condensate is typically collected in a container.

To protect the container against overflowing, and thus prevent potential damage to devices and/or the building, the container alerts the "Condensation alarm" object

(receiving only) that the maximum fill level has been exceeded.

This causes the controller to switch to a protective mode. This status is indicated by the corresponding symbol on devices that have a display. Local operation is blocked.

Operation is only possible again after the alarm has been deactivated.

12.41.109 Alarm function – Dew point alarm

Options No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and only available when the "Control function" parameter is set either on "Cooling", "Cooling with additional stage", "Heating and cooling" or "Heating and cooling with additional stages".

When refrigerating machines are used, dew may appear on the refrigerant supply lines during operation as a result of excessive cooling and/or humidity. The dew indicator reports the dew formation via the "Dew point alarm" object (receiving only).

This causes the controller to switch to a protective mode. This status is indicated by the corresponding symbol on devices that have a display. Local operation is blocked.

Operation is only possible again after the alarm has been deactivated.

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12.41.110 Alarm function – Frost alarm temperature for HVAC and RHCC status (°C)

Options Input from 0 to 15

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

The RHCC status and HVAC objects have a frost alarm bit. It the input temperature of the controller drops below the temperature set in this parameter, the frost alarm bit is set in the status objects. It is reset when the temperature is exceed.

12.41.111 Alarm function – Heat alarm temperature for RHCC status (°C)

Options Input from 25 to 70

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device".

The RHCC status object has a heat alarm bit. If the input temperature of the controller exceeds the temperature set in this parameter, then the heat alarm bit is set in the status object. It is reset when the temperature falls below the set temperature.

12.41.112 Fan coil settings - Fan speed levels – Number of fan stages

Options 3 levels

5 levels

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

This parameter is use to specified the number of fan speed levels the actuator will use to control the fan of the fan coil.

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12.41.113 Fan coil settings - Fan speed levels – Format of the stage output

Options 0..5

0..255

1 bit m off n

1 bit m 1 off n

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

– 0 to 5 : The level values (0..3 or 0..5) are output in the 1-byte format as the counter values 0..3 or 0..5.

– 0 to 255 : The level values (0..3 or 0..5) are output as percentage values. Example 5stage fan: The level value 1 is output as 20%, and 5 is output as 100%.

– 1 Bit m from n : The level values (0..3 or 0..5) are output using 1-bit objects. The number of objects available is the same as the number of fan speed levels. For level 2, for example, the 1-bit fan speed level objects 1 and 2 are output as the value 1, while the other fan speed level objects use the value 0.

– 1 Bit 1 from n : The level values (0..3 or 0..5) are output using 1-bit objects. The number of objects available is the same as the number of fan speed levels. For the level

2, for example, only the 1-bit fan speed level object 2 is output as the value 1. The other fan speed level objects use the value 0.

12.41.114 Fan coil settings - Fan speed levels – Position output

Options For manual operation and automatic

Only for manual operation

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

This parameter is use to specify when the output of the fan speed level values will occur: either only when the fan speed levels are manually adjusted or also in automatic mode. This setting depends on the options for the fan coil actuator. If the actuator itself controls the fan speed levels in automatic mode based on a derivative of the control value, than the "Only for manual operation" option must be selected. Otherwise, the other option should be selected.

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12.41.115 Fan coil settings - Fan speed levels – Lowest manually adjustable fan speed level

Options Stage 0

Stage 1

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

This parameter is use to preselect the lowest fan speed level that can be set by an operation performed at the device. When level 0 is selected, the heating/cooling system will not be in operation (fan speed level and valve control 0) as long as the current operating state and operation type are maintained. To avoid damage to the building, level 0 is deactivate after 18 hours and the device is return to automatic state.

12.41.116 Fan coil settings - Fan speed levels – Evaluation stage status

Options No

Yes

Note: Only available when the "Device function" parameter is set on either

"Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

The controller obtains the current fan speed level for controlling a fan coil actuator either by calculating it from the table of level values under "Fan coil settings for heating" or

"Fan coil settings for cooling", or by receiving feedback from the fan coil actuator. If the

"Yes" option is select, the "Fan coil step status" object is activate for receiving the fan speed level from the fan coil actuator.

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12.41.117 Fan coil settings - Fan coil settings heating – Fan speed level 1 to 5 up to control value heating (0..255)

Options Input from 0 to 255

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil", and the "Control function" parameter must be set on either "Heating",

"Heating with additional stage", "Heating and cooling" or "Heating and cooling with additional stages".

- These level settings should be adjusted to match the settings in the fan coil actuator.

- Setting the "Control value type" to "Fan coil" in the control parameters is only useful for one of either the basic stage or the additional stage. Setting the basic and additional stage parameters to fan coil is not useful, since the control of only one fan coil actuator each for heating and cooling is support.

- The "Fan speed level 4 - 5 up to control value (0 - 255) heating“ parameters are available only when the "Number of fan speed levels" is set on "5 levels".

In this parameter, the control values of the controller are assign to fan speed levels.

This assignment is use if the fan speed levels are transmit together with the control values.

12.41.118 Fan coil settings - Fan coil settings heating – Fan stage limit heating for

ECO mode

Options No

Yes

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

This parameter limits the fan speed level when the system is switch to ECO mode.

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12.41.119 Fan coil settings - Fan coil settings heating – Max. fan stage heating for

ECO mode

Options Input from 0 to 5

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil", and the “Fan stage limit heating for ECO mode” parameter is set to

“Yes”

Specifies the maximum possible fan speed level when the system is switch to ECO mode.

12.41.120 Fan coil settings - Fan coil settings cooling – Fan speed level 1 to 5 up to control value cooling (0..255)

Options Input from 0 to 255

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil", and the "Control function" parameter must be set on either "Cooling",

"Cooling with additional stage", "Heating and cooling" or "Heating and cooling with additional stages".

- These level settings should be adjusted to match the settings in the fan coil actuator.

- Setting the "Control value type" to "Fan coil" in the control parameters is only useful for one of either the basic stage or the additional stage. Setting the basic and additional stage parameters to fan coil is not useful, since the control of only one fan coil actuator each for heating and cooling is support.

- The "Fan speed level 4 - 5 up to control value (0 - 255) heating“ parameters are available only when the "Number of fan speed levels" is set on "5 levels".

In this parameter, the control values of the controller are assign to fan speed levels.

This assignment is use if the fan speed levels are transmit together with the control values.

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12.41.121 Fan coil settings - Fan coil settings cooling – Fan stage limit cooling for

ECO mode

Options No

Yes

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil".

This parameter limits the fan speed level when the system is switch to ECO mode.

12.41.122 Fan coil settings - Fan coil settings cooling – Max. fan stage cooling for

ECO mode

Options Input from 0 to 5

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the "Control value type" parameter is set on "Fan coil", and the “Fan stage limit cooling for ECO mode” parameter is set to

“Yes”

Specifies the maximum possible fan speed level when the system is switch to ECO mode.

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12.41.123 Summer compensation – Summer compensation

Options No

Yes

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device".

In order to save energy, and to ensure that the temperature difference occurring during entry and exit of a climate-controlled building stays within comfortable limits, the excessive reduction of room temperature should be prevented during high temperatures in the summer ( Summer compensation according to DIN 1946). The room temperature is increase by adjusting the setpoint temperature for cooling.

Raising the room temperature does not, however, mean that you heat up the room.

Rather, the adjustment is intend to allow the room temperature to increase to a certain setpoint without cooling. This, for example, prevents the air-conditioning system from further reducing the room temperature to 24°C with an external temperature of 35°C.

However, activation of the summer compensation requires an outside temperature sensor that transmits its measured value to the bus and can be evaluated by the room temperature controller.

The following parameters are available for summer compensation:

- "Lower outside temperature value for summer compensation",

- "Upper outside temperature value for summer compensation",

- “Lower setpoint offset for summer compensation",

- “Upper setpoint offset for summer compensation"

Above the "Upper outside temperature value", the minimum setpoint temperature for cooling is the outside temperature minus the "Upper setpoint offset". The outside temperature has no effect on the minimum setpoint temperature for cooling below the

"Lower outside temperature value". Between the "Lower" and "Upper outside temperature value", the minimum setpoint temperature for cooling undergoes floating adjustment by the parameterized setpoint temperature equal to the outside temperature minus the "Lower offset" to a value equal to the outside temperature minus the "Upper setpoint offset" as a function of the outside temperature.

Typical values for summer compensation are:

- 21°C: Lower outside temperature value

- 32°C: Upper outside temperature value

0 K: Lower setpoint offset

- 6 K: Upper setpoint offset

This means that a continuous increase of the minimum setpoint value for cooling occurs to a value equal to the outside temperature minus a setpoint offset of 0 to 6 K if the outside temperature increases to 32°C from 21°C.

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For example:

For an increasing outside temperature, the minimum setpoint value for cooling will be increase starting at an outside temperature of 21°C. The minimum setpoint temperature for cooling is 25.1°C at an outside temperature of 30°C; 25.5°C at an outside temperature of 31°C; 26°C at an outside temperature of 32°C; and 27°C at an outside temperature of 33°C.

12.41.124 Summer compensation – (Lower) Starting temperature for summer compensation (°C)

Options Input from -127 to 127

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the “Summer compensation” parameter is set to “Yes”

The parameter defines the lower outside temperature value up to which temperature value the setpoint correction (summer compensation) is perform based on too high an outside temperature.

12.41.125 Summer compensation – Offset of the setpoint temperature for the entry in the summer compensation (x 0.1 °C)

Options Input from -127 to 127

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the “Summer compensation” parameter is set to “Yes”

The parameter is use to define how many degrees Kelvin the setpoint value will be increased by during summer compensation when the lower temperature value is reached.

Typical values for summer compensation are:

- 20°C: Lower outside temperature value

- 32°C: Upper outside temperature value

- 0 K: Lower setpoint offset

- 4 K: Upper setpoint offset

That means that a flowing setpoint increase of 0 to 4 K occurs if the outside temperature increases from 20°C to 32°C.

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12.41.126 Summer compensation – (Upper) Escape temperature for summer compensation (°C)

Options Input from -127 to 127

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the “Summer compensation” parameter is set to “Yes”

The parameter defines the upper outside temperature value up to which temperature value the setpoint correction (summer compensation) is perform based on too high an outside temperature.

12.41.127 Summer compensation – Offset of the setpoint temperature for the exit in the summer compensation (x 0.1 °C)

Options Input from -127 to 127

Note: This parameter is only available if the "Device function" parameter is set on either "Single device" or "Master device" and the “Summer compensation” parameter is set to “Yes”

The parameter is use to define how many degrees Kelvin the setpoint value will be increased by during summer compensation when the upper temperature value is reached.

Typical values for summer compensation are:

■ 20°C: Lower outside temperature value

■ 32°C: Upper outside temperature value

0 K: Lower setpoint offset

■ 4 K: Upper setpoint offset

That means that a flowing setpoint increase of 0 to 4 K occurs if the outside temperature increases from 20°C to 32°C.

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12.42

Communication object for RTC

12.42.1

General – Operating mode - Object no

No Object name Data type

202 1. Operating mode – 1 byte 1 byte DPT 20.102

1 byte DPT 20.102

202 2. Operating mode – 1 byte

(master)

202 3. Operating mode – 1 byte

(slave)

1 byte DPT 20.102

Flags

C, W, T, U

C, W, T, U

C, T

Item 2: If the master/slave mode is the active operating mode, the Operating mode

(slave) object must be connected to this object.

Item 3: If the master/slave mode is the active operating mode, the operating mode

(master) object must be connected to this object.

The "Operating mode" object receives, as a 1-byte value, the operating mode that is to be set. Here value 1 means "Comfort", value 2 "Standby", value 3 "Economy" and value

4 "Frost/heat protection". In addition to manual setpoint adjustment and the adjustment of the basic setpoint value, the setpoint temperature of the controller can also be defined by objects "Superimposed operating mode", "Condensate ware alarm", "Dew alarm", "Window contact", "Control On/Off", "Presence detector" and "Operating mode

(listed in decreasing order of priority).

12.42.2

No

203

General – Superimposed operating mode - Object no

Object name

1. Superimposed operating mode – 1 byte

203 2. Superimposed operating mode – 1 byte (master / slave)

Data type

1 byte DPT 20.102

1 byte DPT 20.102

Flags

C, W, T, U

C, W, T, U

Item 2: If the master/slave mode is active, the "Superimposed operating mode" object of the master and the slave must be connected to the group address of the transmitter.

The "Superimposed operating mode" object receives the operating mode that is to be set as 1- byte value. Here value 0 means "Superimposition inactive", value 1 "Comfort", value 2 "Standby", value 3 "Economy" and value 4 "Frost/heat protection". In addition to manual setpoint adjustment and the adjustment of the basic setpoint value, the setpoint temperature of the controller can also be defined by objects "Superimposed operating

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ABB i-Bus ® KNX PEONIA mode", "Condensate ware alarm", "Dew alarm", "Window contact", "Control On/Off",

"Presence detector" and "Operating mode (listed in decreasing order of priority).

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12.42.3

No

General – In operation - Object no

Object name

237 Send in operation – 1 bit

Data type

1 bit DPT 1.001

Flags

C, T

The controller uses this 1-bit communication object to send a cyclical "sign of life". This signal can be used to monitor the device, e.g. by means of a visualization.

12.42.4

General – Additional functions/objects – Control on/off - Object no

No Object name

195 1. Control on/off – 1 bit

Data type

1 bit DPT 1.001

Flags

C, W, T, U

195 2. Control on/off – 1 bit

(master)

195 3. Control on/off – 1 bit

(slave)

1 bit DPT 1.001

1 bit DPT 1.001

C, R, W, T, U

C, W, T, U

Item 2: During active ON/OFF controller function in master/slave mode the ON/OFF

(master) control object is to be link with this object.

Item 3: During active ON/OFF controller function in master/slave mode the ON/OFF

(slave) control object is to be link with this object.

If a 0 telegram is receive, the controller switches to OFF mode and regulates the temperature to the setpoint value for frost/heat protection. When the controller is switch on again, the remaining operating mode objects are require in order determining the new operating mode.

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12.42.5

no

No

General – Additional functions/objects – Fault actual temperature - Object

Object name Data type Flags

1 bit DPT 1.001

C, T 199 1. Fault actual temperature

– 1 bit

199 2. Fault actual temperature

– 1 bit (master)

1 bit DPT 1.001

C, R, T

199 3. Fault actual temperature

– 1 bit (slave)

1 bit DPT 1.001

C, W, T, U

Item 2: This object must be connected to the "Fault, actual temperature (slave)" object in order to indicate the error mode.

Item 3: This object must be connected to the "Fault, actual temperature (slave)" object in order to indicate the error mode.

If one of the parameterized input temperatures is unavailable to the controller for a period longer than the monitoring time, the controller enters the error mode. The error mode is sent to the bus as the value 1.

12.42.6

No

General – Additional functions/objects – Window contact - Object no

Object name Data type Flags

204 Window contact – 1 bit 1 bit DPT 1.001

C, W, T, U

Item 2: If the master/slave mode is active, the "Window contact (master/slave)" object of the master and the slave must be connected to the group address of the transmitter.

The object uses the value 1 to signal an open window to the controller. If no other object with a higher priority is present, then the "Window contact" message causes the controller to be set to the setpoint value for frost/heat protection. In addition to manual setpoint adjustment and the adjustment of the basic setpoint value, the setpoint temperature of the controller can also be defined by objects "Superimposed operating mode", "Condensate water alarm", "Dew alarm", "Window contact", "Control On/Off",

"Presence detector" and "Operating mode (listed in decreasing order of priority).

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12.42.7

General – Additional functions/objects – Presence detector - Object no

No Object name

205 Presence detector – 1 bit

Data type

1 bit DPT 1.001

Flags

C, W, T, U

Item 2: If the master/slave mode is active, the "Presence detector (master/slave)" object of the master and the slave must be connected to the group address of the transmitter.

This object transmits the value 1 to the controller to signal that there are people in the room. If not other object with a higher priority is present, then the "Presence detector" causes the controller to be set to the comfort setpoint value. In addition to manual setpoint adjustment and the adjustment of the basic setpoint value, the setpoint temperature of the controller can also be defined by objects "Superimposed operating mode", "Condensate water alarm", "Dew alarm", "Window contact", "Control On/Off",

"Presence detector" and "Operating mode (listed in decreasing order of priority).

12.42.8

No

General – Additional functions/objects – Basic setpoint - Object no

Object name Data type Flags

218 Basic setpoint – 2 byte 2 byte DPT 9.001

C, W, T, U

This 2-byte communication object can be used to change/adjust the parameterized basic setpoint value via the KNX bus. Parameters can be used to define whether the value received by this object is interpreted as "Setpoint heating comfort", "Setpoint cooling comfort" or an average between heating and cooling comfort.

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12.42.9

General – Additional functions/objects – Units switchover - Object no

No Object name Data type

225 1. Units switchover – 1 bit 1 bit DPT 1.001

225 2. Units switchover – 1 bit

(master)

1 bit DPT 1.001

225 3. Units switchover – 1 bit

(slave)

1 bit DPT 1.001

Flags

C, W, T, U

C, W, T, U

C, W, T, U

Item 2: If the Fahrenheit object is active in the master/slave mode, the Fahrenheit

(slave) object must be connected to this object.

Item 3: If the Fahrenheit object is active in the master/slave mode, the Fahrenheit

(master) object must be connected to this object.

The temperature indication on the display can be changed from Celsius (°C) to

Fahrenheit (°F). The conversion from Celsius to Fahrenheit always takes place in the display unit, since only Celsius values are sent over the KNX bus. The value (0) results in a temperature indication in Celsius, while the value (1) results in Fahrenheit.

12.42.10

no

No

General – Additional functions/objects – Controller status RHCC - Object

Object name Data type Flags

235 Controller status RHCC – 2 byte

2 byte DPT 9.001

C, T

This communication object outputs the heating/cooling operation type, active/inactive operation, the frost and heat alarm, and the error (actual temperature reading failure) in accordance with the specification for the RHCC (Room Heating Cooling Controller) status.

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no

No

General – Additional functions/objects – Controller status HVAC - Object

Object name Data type Flags

1 byte DPT 5.001

C, T 236 1. Controller status HVAC –

1 byte

236 2. Controller status HVAC –

1 byte (master)

1 byte DPT 5.001

C, T

236 3. Controller status HVAC –

1 byte (slave)

1 byte DPT 5.001

C, R, T

Item 2: If the master/slave mode is active, the HVAC status (slave) object must be connected to this object.

Item 3: If the master/slave mode is active, the HVAC status (master) object must be connected to this object.

This communication object outputs the current operating mode, the heating/cooling state, active/inactive mode, the frost alarm and the dew point alarm in accordance with the specification for the HVAC (Heating Ventilation Air Conditioning) status.

12.42.12

No

Control heating - Object no

Object name Data type

191 Heating control value – 1 bit 1 bit DPT 1.001

191 Heating control value - 1 1 byte DPT 5.001

byte 0..100%

Flags

C, T

C, T

- 1 bit: This object is use to operate a switching actuating drive, e.g. a thermoelectric positioner that is controlled by a switching/heating actuator.

- 1 byte This object is use to control an actuating drive with a continuous input value (0%..100%), e.g. an electromotive actuating drive.

12.42.13

No

206

Control heating – Basic stage heating – Object no

Object name

Status heating – 1 bit

Data type

1 bit DPT 1.001

Flags

C, T

The room temperature controller sends an ON telegram via the "Heating status" object as soon as it is active in the heating mode. If the controller is in the inactive zone between heating and cooling or is in cooling mode, the room temperature controller transmits an OFF telegram on the "Heating status" object.

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12.42.14

No

192

Control of heating additional stage - Object no

Object name

Additional heating stage – 1 bit

192 Additional hating stage - 1 byte 0..100%

Data type

1 bit DPT 1.001

1 byte DPT 5.001

Flags

C, T

C, T

- 1 bit: This object is use to operate a switching actuating drive, e.g. a thermoelectric positioner that is controlled by a switching/heating actuator.

- 1 byte This object is use to control an actuating drive with a continuous input value (0%..100%), e.g. an electromotive actuating drive.

12.42.15

Control cooling - Object no

No Object name Data type

193 Cooling control value – 1 bit 1 bit DPT 1.001

193 Cooling control value - 1 byte

0..100%

1 byte DPT 5.001

Flags

C, T

C, T

- 1 bit: This object is use to operate a switching actuating drive, e.g. a thermoelectric positioner that is controlled by a switching/heating actuator.

- 1 byte This object is use to control an actuating drive with a continuous input value (0%..100%), e.g. an electromotive actuating drive.

12.42.16

No

207

Control cooling – Basic stage cooling – Object no

Object name

Status cooling – 1 bit

Data type

1 bit DPT 1.001

Flags

C, T

The room temperature controller sends an ON telegram via the "Cooling status" object as soon as it is active in the cooling mode. If the controller is in the inactive zone between heating and cooling or is in heating mode, the room temperature controller transmits an OFF telegram on the "Cooling status" object.

12.42.17

No

Control of cooling additional stage - Object no

Object name Data type

1 bit DPT 1.001

194 Additional cooling stage – 1 bit

194 Additional cooling stage - 1 byte 0..100%

1 byte DPT 5.001

Flags

C, T

C, T

- 1 bit: This object is use to operate a switching actuating drive, e.g. a thermoelectric positioner that is controlled by a switching/heating actuator.

- 1 byte This object is use to control an actuating drive with a continuous input value (0%..100%), e.g. an electromotive actuating drive.

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12.42.18

No

Setting of basic load – Object no

Object name

208 Basic load – 1 bit

Data type

1 bit DPT 1.001

Flags

C, W, T, U

This object uses the value 1 to activate a parameterized base load, i.e. a minimum control value greater than zero. The value 0 deactivates the base load. When the base load is deactivate, the control value can be lowered all the way to zero if necessary when the setpoint temperature is reach, despite the minimum value set in the parameter. Deactivating the basic load for a floor heating system is always useful in the summer, since it saves heating energy.

12.42.19

No Object name

209 Switchover heating / cooling

– 1 bit

Setting of basic load – Combined heating and cooling mode - Object no

Data type

1 bit DPT 1.001

Flags

C, T

1. Automatic: If the switchover between heating and cooling is performed automatically by the room temperature controller, then this object is used to provide information on the current heating (0) or cooling (1) status to the KNX bus. It is a transmitting object.

2. Only via object: The switchover between heating and cooling on the room temperature controller occurs solely via this 1-bit communication object. The value (0) activates the heating mode, and the value (1) activates the cooling mode. This is a receiving object.

3. Manual or via object: The switchover between heating and cooling on the room temperature controller occurs by user interaction or via the 1-bit communication object.

The information on the respective heating (0) or cooling (1) status is available to the

KNX bus. This is a receiving and sending object.

12.42.20

No Object name

201 Actual setpoint – 2 byte float value

Setpoint Setting – Object no

Data type

2 byte DPT 9.001

Flags

C, T

The object outputs the current setpoint temperature resulting from the following: the parameterized setpoint temperature of the current operation type and operating mode, the manual setpoint temperature adjustment, a change in the base setpoint temperature via the base setpoint value object. This is purely a transmitting object.

12.42.21

No Object name

209 Resetting manual setpoints –

1 bit

Changing set values – Object no

Data type

1 bit DPT 1.001

Flags

C, W, U

This 1-bit communication object is use to reset the manual setpoint adjustment that was set on the device.

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No

196

Temperature reading – Actual temperature - Object no

Object name

1. Actual temperature – 2 byte float value

196 2. Actual temperature weighted – 2 byte float value

Data type

2 byte DPT 9.001

2 byte DPT 9.001

Flags

C, T

C, T

Item1: The object outputs the measured (room) temperature, adjusted by the calibration value.

Item 2: The object outputs the temperature value, which is calculate from the recording and weighting of internal and up to two external temperatures.

An external temperature measurement for room control may be practical for larger rooms and/or floor heating.

12.42.23

No

197

Temperature reading - External actual temperature – Object no

Object name

External actual temperature

– 2 byte float value

Data type

2 byte DPT 9.001

Flags

C, W, T, U

2-byte communication object for reading an external temperature value provided via the

KNX bus.

12.42.24

No

Temperature reading - External actual temperature 2 – Object no

Object name Data type Flags

198 External actual temperature

2 – 2 byte float value

2 byte DPT 9.001

C, W, T, U

2-byte communication object for reading an additional external temperature value provided via the KNX bus.

12.42.25

No

Alarm function – Dew point alarm - Object no

Object name Data type

220 Dew point alarm – 1 bit 1 bit DPT 1.001

Flags

C, W, T, U

This protective mechanism is only active in the cooling mode. It remains in place until it is cancel by the value (0). When an alarm is active, manual operation of the controller is block. This information is indicate by a corresponding symbol on the control unit.

This 1-bit communication object is use to place the controller in the dew point alarm mode. This causes the current setpoint value to be set to the heat protection setpoint value in order to keep the structure from being damage by dew.

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12.42.26

No

221

Alarm function – Condensate water alarm - Object no

Object name

1. Condensate water alarm

– 1 bit

221 2. Condensate water alarm

– 1 bit (master / slave)

Data type

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, W, T, U

C, W, T, U

Item 1: This protective mechanism is only active in the cooling mode. It remains in place until it is cancel by the value (0). When an alarm is active, manual operation of the controller is block. This information is indicate by a corresponding symbol on the device.

Item 2: This protective mechanism is only active in the cooling mode. It remains in place until it is cancel by the value (0). When an alarm is active, manual operation of the controller is block. This information is indicated by a corresponding symbol on the device. When the master/slave mode is active, the condensate water alarm

(master/slave) objects must be connected to the alarm transmitter.

This 1-bit communication object is use to place the controller in the condensation alarm mode.

This causes the current setpoint value to be set to the heat protection setpoint value in order to keep the structure from being damage by an overflowing condensation container.

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12.42.27

No

210

210

Fan coil setting - Object no

Object name

1. Fan coil manual – 1 bit

2. Fan coil manual – 1 bit

(Master)

Data type

1 bit DPT 1.001

1 bit DPT 1.001

210 3. Fan coil manual – 1 bit

(Slave)

1 bit DPT 1.001

Flags

C, T

C, R, T

C, W, T, U

Item 2: If fan coil manual is active in the master/slave mode, the fan coil manual (slave) object must be connected to this object.

Item 3: If fan coil manual is active in the master/slave mode, the fan coil manual

(master) object must be connected to this object.

Using this 1-bit communication object, a fan coil actuator can be place in manual fan mode or returned to automatic fan mode. In the automatic fan mode of the fan coil actuator, the fan's rotational speed is define in the fan coil actuator using the control value. In manual fan operation, the user of the room temperature controller can set the fan's rotational speed as needed. This setting will remain active until it is reset. The fan speed level 0 is an exception: to avoid damage to the building, automatic mode is activate again 18 hours after fan speed level 0 is select.

12.42.28

Fan coil setting – Fan speed level – Fan coil step - Object no

No Object name

211 1. Fan coil step – 1 byte

211 2. Fan coil step – 1 byte

(Master)

Data type

1 byte DPT 5.001

1 byte DPT 5.001

Flags

C, T

C, T

Item 2: If fan coil step is active in the master/slave mode, the fan coil step (slave) object must be connected to this object.

The fan speed level in the fan coil actuator is select via the 1-byte communication object. Whether the fan speed level information is transmit in manual or also in automatic fan speed level mode can be set. The formats that can be selected for the 1byte communication object are the fan speed level (0..5) or a percentage value

(0..100%) which is calculated back to a fan speed level in the fan coil actuator.

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12.42.29

Fan coil setting – Fan speed level – Fan coil step status - Object no

No Object name Data type

212 Fan coil step status – 1 byte 1 byte DPT 5.001

Flags

C, W, T, U

Using the "Fan coil step status" object, the room temperature controller receives the current fan speed level of the fan coil actuator.

12.42.30

Summer compensation – Outside temperature for summer compensation -

Object no

No Object name Data type Flags

222 Outside temperature for summer compensation – 2 byte

2 byte DPT 9.001

C, W, T, U

In order to save energy, and to ensure that the temperature difference occurring during entry and exit of a climate-controlled building stays within comfortable limits, the reduction of room temperature by cooling devices should be limited as a function of the outside temperature (summer compensation). This, for example, prevents the airconditioning system from further reducing the room temperature to 24°C with an outside temperature of 35°C. This function can only be used with an outside temperature sensor. This 2-byte communication object must then be used to provide the controller with the current outside temperature.

12.42.31

No

Summer compensation –Summer compensation active - Object no

Object name Data type Flags

223 Summer compensation active – 1 bit

1 bit DPT 1.001

C, T

This 1-bit communication object is use to indicate via the bus whether the summer compensation is active (1) or inactive (0). If it is active, the setpoint value configured for the cooling mode is increase by the summer compensation function. A decrease of the cooling mode setpoint temperature below the value calculated by the parameterized summer compensation function is not possible. An increase of the setpoint temperature for the cooling mode is always possible.

12.42.32

Slave – General – on/off request - Object no

No Object name

227 On/Off request – 1 bit

Data type

1 bit DPT 1.001

(master)

227 On/Off request – 1 bit (slave) 1 bit DPT 1.001

Flags

C, W, U

C, T

This 1-bit communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

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No

228

Slave – General – Setpoint display - Object no

Object name

Setpoint display – 2 byte

(master)

228 Setpoint display – 2 byte

(slave)

Data type

2 byte DPT 9.001

2 byte DPT 9.001

Flags

C, R, T

C, W, T, U

This 2-byte communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

12.42.34

No

Slave – General – Request setpoint - Object no

Object name Data type

229 Request setpoint – 1 byte

(master)

1 byte DPT 5.001

229 Request setpoint – 1 byte

(slave)

1 byte DPT 5.001

Flags

C, W, U

C, T

This 1-byte communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

12.42.35

No

230

Slave – General – Confirm setpoint - Object no

Object name

Confirm setpoint – 1 byte

(master)

230 Confirm setpoint – 1 byte

(slave)

Data type

1 byte DPT 5.001

1 byte DPT 5.001

Flags

C, R, T

C, W, T, U

This 1-byte communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

12.42.36

No

231

Slave – General – Heating / Cooling request - Object no

Object name

Heating / cooling request – 1 bit (master)

231 Heating / cooling request – 1 bit (slave)

Data type

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, W, U

C, T

This 1-bit communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

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No

232

Slave – General – Request fan speed level manual - Object no

Object name

Request fan speed level manual – 1 bit (master)

232 Request fan speed level manual – 1 bit (slave)

Data type

1 bit DPT 1.001

1 bit DPT 1.001

Flags

C, W, U

C, T

This 1-bit communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

12.42.38

No

Slave – General – Request fan speed level - Object no

Object name Data type

233 Request fan speed level - 1 byte (master)

1 byte DPT 5.001

233 Request fan speed level – 1 byte (slave)

1 byte DPT 5.001

Flags

C, W, U

C, T

This 1-byte communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

12.42.39

No

234

Slave – General – Confirm fan speed level - Object no

Object name

Confirm fan speed level - 1 byte (master)

234 Confirm fan speed level – 1 byte (slave)

Data type

1 byte DPT 5.001

1 byte DPT 5.001

Flags

C, R, T

C, W, T, U

This 1-byte communication object must be connected to the respective slave communication object in order to synchronize the devices in the master/slave configuration.

12.42.40

No

269

RTC function - set temperature (main) - object no

Object name

Setpoint command (master)

Data type

2 byte DPT 9.001

Flags

C, W, T, U

This 2-byte communication object can be used to change/adjust the set temperature of the RTC via the KNX bus. The parameter can be used to determine whether the received value of the object is interpreted as the "heating comfort setting value",

"cooling comfort setting value" or the average value between heating and cooling comfort.

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12.43 Application “VRV”

Note: The following parameters can only be used when the "VRV" page is activated in "Page_combine" parameter.

12.43.1

Options

Operating mode – The code number of the heating mode

Input from 0 - 255

This parameter is used to specify the 1Byte value corresponding to the heating mode.

Due to the different brands of the VRV air-conditioning-KNX protocol gateway connected, the 1Byte value corresponding to the heating mode used will also be different. Please refer to the actual VRV air-conditioning gateway used. The agreement requires to set the corresponding value.

If the heating mode value specified by this parameter does not match the heating mode value corresponding to the actual VRV air conditioner gateway protocol, the VRV interface cannot control the heating mode of the VRV air conditioner

12.43.2

Options

Operating mode – The code number of the cooling mode

Input from 0 - 255

This parameter is used to specify the 1Byte value corresponding to the cooling mode.

Due to the different brands of the VRV air-conditioning-KNX protocol gateway to be connected, the 1Byte value corresponding to the cooling mode used will be different.

Please refer to the actual VRV air-conditioning gateway protocol used Request to set the corresponding value.

If the cooling mode value specified by this parameter does not match the cooling mode value corresponding to the actual VRV air conditioner gateway protocol, the VRV interface cannot control the cooling mode of the VRV air conditioner.

12.43.3

Options

Operating mode – Activate fan only mode

Activate

Deactivate

This parameter is used to select whether to turn on the fan mode for controlling the VRV air conditioner. Please select this parameter according to whether the actual VRV air conditioning system allows the fan mode to be turned on or not.

If you enable this parameter and the actual VRV air conditioning system does not allow the fan mode to be turned on, the VRV interface cannot control the fan mode of the

VRV air conditioning

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12.43.4

Options

Operating mode – The code number of fan only mode

Input from 0 - 255

Note: The following parameters will only be available when the "Fan only mode" is activated. This parameter is used to specify the 1Byte value corresponding to the fan only mode. Due to the different brands of the VRV air-conditioning-KNX protocol gateway connected, the 1Byte value corresponding to the fan only mode used will be different. Please refer to the actual VRV air-conditioning gateway protocol used.

Request to set the corresponding value.

If the fan only mode value specified by this parameter does not match the fan only mode value corresponding to the actual VRV air conditioning gateway protocol, the VRV interface cannot control the fan only mode of the VRV air conditioning.

12.43.5

Options

Operating mode – Activate dehumidification mode

Activate

Deactivate

This parameter is used to select whether to turn on the dehumidification mode for controlling the VRV air conditioner. Please select this parameter according to whether the actual VRV air conditioner system allows the dehumidification mode to be turned on or not.

If you enable this parameter and the actual VRV air conditioning system does not allow the dehumidification mode to be turned on, the VRV interface cannot control the dehumidification mode of the VRV air conditioning.

12.43.6

Options

Operating mode – The code number of dehumidification mode

Input from 0 - 255

Note: The following parameters will only be available when the

"Dehumidification mode" is activated. This parameter is used to specify the 1Byte value corresponding to the dehumidification mode. Due to the different brands of the VRV air conditioner-KNX protocol gateway that is connected, the 1Byte value corresponding to the dehumidification mode used will also be different. Please refer to the actual VRV air conditioner gateway protocol used Request to set the corresponding value.

If the dehumidification mode value specified by this parameter does not match the dehumidification mode value corresponding to the actual VRV air conditioner gateway protocol, the VRV interface cannot control the dehumidification mode of the VRV air conditioner

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12.43.7

Options

Operating mode – Activate Auto mode

Activate

Deactivate

This parameter is used to select whether to turn on the automatic mode of controlling the VRV air conditioner. Please select this parameter according to whether the actual

VRV air conditioner system allows to turn on the automatic mode.

If you enable this parameter and the actual VRV air conditioning system does not allow the automatic mode to be turned on, the VRV interface cannot control the automatic mode of the VRV air conditioning.

12.43.8

Options

Operating mode – The code number of Auto mode

Input from 0 - 255

Note: The following parameters will only be available when the "Auto mode" is activated. This parameter is used to specify the 1Byte value corresponding to the auto mode. Due to the different brands of the connected VRV air conditioner-KNX protocol gateway, the 1Byte value corresponding to the auto mode will be different. Please refer to the actual VRV air conditioner gateway protocol used. Request to set the corresponding value.

If the auto mode value specified by this parameter does not match the auto mode value corresponding to the actual VRV air conditioning gateway protocol, the VRV interface cannot control the automatic mode of the VRV air conditioning.

Note: Air conditioning mode switching logic: There is a difference between the master control panel and the slave panel in the VRV system. The master control panel can switch between cooling and heating modes. The slave panel can only switch between dehumidification, air supply, auto mode and either one “cooling or heating" mode. For example, if the main panel have selected cooling mode, the slave panel can only switch between the following four modes: cooling, dehumidification, fan only mode and auto mode. In addition, dehumidification is not supported in heating mode. The mode switching logic of the Peonia panel is the same as the slave panel in the VRV system.

Note: The code number of various operating mode cannot be the same.

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12.43.9

Options

Fan – Fan speed levels

1

2

3

4

5

This parameter is used to define the level of fan speeds that can be controlled in the

VRV mode. The level of fan speeds have to be the same as what is being define by the

VRV air conditioner system.

If the level of fan speeds specified by this parameter does not match the level of fan speeds define by the VRV air conditioner system, this would result in not being able to have full control of the VRV air conditioner system fan speeds.

12.43.10

Options

Fan – The code number of the Fan Speed 1

Input from 0-255

This parameter is used to specify the 1Byte value corresponding to the first level fan speeds. As there are many different types and brands of VRV air conditioner system

KNX protocol interface gateway in the market, the 1Byte value corresponding to the first level of fan speeds could also be different. Therefore , please refer to the VRV air conditioning system KNX protocol interface gateway manual to obtain the correct corresponding 1Byte value of the first level fan speed. If the 1Byte value of the first level fan speed define by this parameter does not match the value of the VRV air conditioning system KNX protocol interface gateway, device would not be able to control the first level fan speed.

12.43.11

Options

Fan – The code number of the Fan Speed 2

Input from 0-255

This parameter is used to specify the 1Byte value corresponding to the second level fan speeds. As there are many different types and brands of VRV air conditioner system

KNX protocol interface gateway in the market, the 1Byte value corresponding to the second level of fan speeds could also be different. Therefore , please refer to the VRV air conditioning system KNX protocol interface gateway manual to obtain the correct corresponding 1Byte value of the second level fan speed. If the 1Byte value of the second level fan speed define by this parameter does not match the value of the VRV air conditioning system KNX protocol interface gateway, device would not be able to control the second level fan speed.

12.43.12

Options

Fan – The code number of the Fan Speed 3

Input from 0-255

This parameter is used to specify the 1Byte value corresponding to the third level fan speeds. As there are many different types and brands of VRV air conditioner system

KNX protocol interface gateway in the market, the 1Byte value corresponding to the third level of fan speeds could also be different. Therefore , please refer to the VRV air conditioning system KNX protocol interface gateway manual to obtain the correct

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12.43.13

Options

Fan – The code number of the Fan Speed 4

Input from 0-255

This parameter is used to specify the 1Byte value corresponding to the fourth level fan speeds. As there are many different types and brands of VRV air conditioner system

KNX protocol interface gateway in the market, the 1Byte value corresponding to the fourth level of fan speeds could also be different. Therefore , please refer to the VRV air conditioning system KNX protocol interface gateway manual to obtain the correct corresponding 1Byte value of the fourth level fan speed. If the 1Byte value of the fourth level fan speed define by this parameter does not match the value of the VRV air conditioning system KNX protocol interface gateway, device would not be able to control the fourth level fan speed.

12.43.14

Options

Fan – The code number of the Fan Speed 5

Input from 0-255

This parameter is used to specify the 1Byte value corresponding to the fifth level fan speeds. As there are many different types and brands of VRV air conditioner system

KNX protocol interface gateway in the market, the 1Byte value corresponding to the fifth level of fan speeds could also be different. Therefore , please refer to the VRV air conditioning system KNX protocol interface gateway manual to obtain the correct corresponding 1Byte value of the fifth level fan speed. If the 1Byte value of the fifth level fan speed define by this parameter does not match the value of the VRV air conditioning system KNX protocol interface gateway, device would not be able to control the fifth level fan speed.

12.43.15

Options

Fan – Activate Auto Fan Speed

Activate

Deactivate

This parameter is used to define whether the automatic fan speed of the VRV air conditioner would be active or not active. Please refer to the VRV air conditioning system manual to check whether does the VRV air conditioner system allow the control of automatic fan speed. If this parameter is activated and VRV air conditioner system itself does not allow the control of automatic fan speed, device would not be able to control the automatic fan speed of the VRV air conditioner system

12.43.16

Options

Fan – The code number of Auto Fan Speed

Input from 0-255

This parameter is used to specify the 1Byte value corresponding to the automatic level fan speeds. As there are many different types and brands of VRV air conditioner system

KNX protocol interface gateway in the market, the 1Byte value corresponding to the automatic level of fan speeds could also be different. Therefore , please refer to the

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VRV air conditioning system KNX protocol interface gateway manual to obtain the correct corresponding 1Byte value of the automatic level fan speed. If the 1Byte value of the automatic level fan speed define by this parameter does not match the value of the

VRV air conditioning system KNX protocol interface gateway, device would not be able to control the automatic level fan speed.

Note: The values corresponding to various wind speeds cannot be the same

12.43.17

Options

Changing set values – Max. setpoint ( °C)

Input from 0-40

This parameter is used to define the maximum temperature adjustment of the VRV mode. Please refer to the VRV air conditioning system manual to obtain the highest temperature that can be set by the VRV air conditioner system. If the maximum temperature define by this parameter does not match the maximum temperature that can be set by the VRV air conditioner system, device would not be able to have full control of the temperature setpoint of the VRV air conditioner system.

12.43.18

Options

Changing set values – Min. setpoint ( °C)

Input from 0-40

This parameter is used to define the minimum temperature adjustment of the VRV mode. Please refer to the VRV air conditioning system manual to obtain the lowest temperature that can be set by the VRV air conditioner system. If the minimum temperature define by this parameter does not match the minimum temperature that can be set by the VRV air conditioner system, device would not be able to have full control of the temperature setpoint of the VRV air conditioner system.

12.43.19

Options

Fault display – Activate VRV Temperature sensor Fault Display 1 bit

Activate

Deactivate

This parameter will define whether can the device receive a 1bit fault alarm datapoint. If it is activated and device receive a 1bit fault alarm datapoint. VRV mode will display the alarm message of "temperature sensor failure". From the moment onward, all VRV mode control will be locked and only page turning operations are supported until the fault alarm is resolve. When the fault alarm is removed, device will return back to normal operations.

12.43.20

Options

Fault display – Activate VRV Fault Display 1 Byte

Activate

Deactivate

This parameter will define whether can the device receive a 1Btye fault alarm datapoint.

If it is activated and device receive a 1btye fault alarm datapoint. VRV mode will display

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ABB i-Bus ® KNX PEONIA the alarm message of " air conditioning equipment failure". From the moment onward, all VRV mode control will be locked and only page turning operations are supported until the fault alarm is resolve. When the fault alarm is removed, device will return back to normal operations.

12.43.21

Options

Fault display – The code number to release alarm

Input from 0-255

This parameter will define the value (such as 0) to clear the alarm corresponding to the

"air conditioning equipment failure". As there are many different types and brands of

VRV air conditioner system KNX protocol interface gateway in the market, the 1Byte value corresponding to clear the alarm could also be different. Therefore , please refer to the VRV air conditioning system KNX protocol interface gateway manual to obtain the correct corresponding 1Byte value for clearing the alarm. Once the "air-conditioning equipment failure" group object receives the value corresponding to the code number to release alarm, the “air-conditioning equipment failure” state will be removed.

Note: This parameters would only be available when Fault display – Activate

VRV Fault Display 1 Byte is activated.

12.44

Communication object for VRV

12.44.1

No

VRV mode - Control on/off - Object no

Object name Data type

1 bit DPT 1.001

270 VRV: Control on/off request-

1 bit

274 VRV: Control on/off confirmation-1 bit

1 bit DPT 1,001

Flags

C, R, T,

C, W, T, U

This communication object is used to control the on/off of the corresponding indoor unit in the VRV system, and to obtain feedback of the current switch state of the VRV indoor unit. The VRV page belongs to the subordinate thermostat, so the request is the output object, and the confirmation is the input object.

12.44.2

No

271

VRV mode - Fan - Object no

Object name

VRV: fan speed request-1 byte

275 VRV: fan speed confirmation-1 byte

Data type

1 byte DPT 5.001

1 byte DPT 5,001

Flags

C, R, T,

C, W, T, U

This communication object is used to control the fan speed of the corresponding indoor unit in the VRV system and obtain feedback on the current fan speed state of the VRV indoor unit. Each fan speed, including the value corresponding to the automatic fan speed, can be set in the "VRV Function-Fan" parameter page. The VRV page belongs

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ABB i-Bus ® KNX PEONIA to the subordinate thermostat, so the request is the output object, and the confirmation is the input object.

12.44.3

No

VRV mode - Control mode - Object no

Object name Data type

1 byte DPT 5.001

272 VRV: control mode request-1 byte

276 VRV: control mode confirmation-1 byte

1 byte DPT 5,001

Flags

C, R, T,

C, W, T, U

This communication object is used to control the operation mode of the corresponding indoor unit in the VRV system, and obtain status feedback of the current operation mode of the VRV indoor unit. The values corresponding to each operating mode, including ventilation, heating, cooling, automatic, and dehumidification, can be set in the

"VRV function-operating mode" parameter page. The VRV page belongs to the subordinate thermostat, so the request is the output object, and the confirmation is the input object.

12.44.4

No

273

VRV mode - Set temperature request - Object no

Object name

VRV: Set temperature request-2 bytes

Data type

2 byte DPT 9.001

277 VRV: Set temperature confirmation-2 bytes

2 byte DPT 9,001

Flags

C, R, T,

C, W, T, U

This communication object is used to control the set temperature of the corresponding indoor unit in the VRV system, and to obtain the current set temperature status feedback of the VRV indoor unit. The temperature adjustment range of the set temperature can be set in the parameter page of "VRV Function-Change Set Value".

The VRV page belongs to the subordinate thermostat, so the request is the output object, and the confirmation is the input object.

12.44.5

No

278

VRV mode - Indoor temperature display- Object no

Object name

VRV: Indoor temperature display (for VRV page display)-2 bytes

Data type

2 byte DPT 9.001

Flags

C, W, T, U

This communication object is used for the room temperature displayed on the VRV page. If the group of objects does not receive the temperature value, there is no room temperature display on the VRV page.

12.44.6

No

VRV mode - Error alarm - Object no

Object name Data type

279 VRV: fault alarm-1 byte 1 byte DPT 9.001

280 VRV: Temperature sensor failure-1 bit

1 bit DPT 9,001

Flags

C, W, T, U

C, W, T, U

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This communication object is used to receive the alarm signal of "air conditioning equipment failure" 1Byte and "temperature sensor failure" 1bit. When the thermostat receives a 1Byte failure alarm, the VRV page will display the alarm information of "air conditioning equipment failure", when the thermostat receives a 1bit failure alarm, the

VRV page will display the alarm information of "temperature sensor failure". When an alarm is triggered, all VRV control operations will be locked, and only page turning operations are supported. When the fault alarm is removed, device will return back to normal operations.

The value (such as 0) corresponding to the removal of "air conditioning equipment failure" can be set in the parameter page of "VRV function-change set value", as long as the 1Byte group object of "air conditioning equipment failure" receives the value corresponding to the failure removal, it will be released the alarm state of "air conditioning equipment failure".

When the "temperature sensor failure" group object receives the value "0", the alarm state of "temperature sensor failure" is released. When the fault alarm is removed, device will return back to normal operations.

12.45

Fresh Air functions

Note: The following parameters can only be used when the "Fresh Air" page is activated in "Page_combine" parameter.

12.45.1

Options

Common parameter – Fan speed levels

1

2

3

4

5

This parameter is used to define the level of fan speeds that can be controlled in the

Fresh Air mode. The level of fan speeds have to be the same as what is being define by the Fresh Air system.

If the level of fan speeds specified by this parameter does not match the level of fan speeds define by the Fresh Air system, this would result in not being able to have full control of the Fresh Air system fan speeds.

12.45.2

Options

Common parameter – Enable communication object “Fan Speed” 1Byte

Activate

Deactivate

This parameter will define whether can the fresh air mode fan speed can be activated with a 1 byte datapoint. Please select the datapoint according to the datapoint type

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ABB i-Bus ® KNX PEONIA define by the fresh air system. If this parameter is activated and the fresh air system does not support 1 byte datapoint, this will result in the device being unable to control the fan speed of the fresh air system.

12.45.3

Options

Common parameter – Enable communication object “Fan Speed” 1bit

Activate

Deactivate

This parameter will define whether can the fresh air mode fan speed can be activated with a 1 bit datapoint. Please select the datapoint according to the datapoint type define by the fresh air system. If this parameter is activated and the fresh air system does not support 1 bit datapoint, this will result in the device being unable to control the fan speed of the fresh air system.

12.45.4

Common parameter – Fan speed after reset (depend on the selection of

“Fan speed levels”)

Options Off

1

4

5

2

3

No Telegram

This parameter is to define the fan speed of the fresh air system after a power restart.

The fan speed selected must reference to the fresh air system. For example, if the fresh air system maximum fan speed is level 3, the fan speed after power restart must be with

3 of lower, else fresh air system will not function normally.

If this parameter selected "Off", device will transmit an off command when the power restart.

If this parameter selected “No Telegram", device will not transmit any command when the power restart.

12.46

Communication object for Fresh Air

12.46.1

No

Fresh Air mode – Fan speed - Object no

Object name Data type

281 FAF : Fan speed-1 byte

282 FAF : Fan speed 1-1 bit

1 byte DPT 5.001

1 bit DPT 1.001

283 FAF : Fan speed 2-1 bit

284 FAF : Fan speed 3-1 bit

285 FAF : Fan speed 4-1 bit

286 FAF : Fan speed 5-1 bit 位

287 FAF : Fan speed -1 byte

1 bit DPT 1.001

1 bit DPT 1.001

1 bit DPT 1.001

1 bit DPT 1.001

1 byte DPT 5.001

Flags

C

C

C

C

C

C

C

R

R

R

R

R

R

W

T

T

T

T

T

T

T , U

This group of communication objects is to control the fan speed level of the fresh air system and receiving of command for the fresh air fan speed.

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Group object 281 “FAF : Fan speed-1 byte” will enable the direct control of the fan speed level depending on the fan speed level that was define in “common parameter –

Fan speed levels”. 0 means off, 1, 2, 3, 4, 5 means the fan speed level of the fresh air system.

Group object 282 - 286 "FAF: Fan speed X-1 bit", each 1 bit group object represents different level of fan speed, depending on the fan speed level that was define in

“common parameter – Fan speed levels”, these 1 bit group objects are interlock with each other (at any other time, only one 1 bit group object can be trigger at the same time), when all group objects are 0, it means that the fresh air system is Off.

Group object 287 is used to receive the fan speed control commands, , depending on the fan speed level that was define in “common parameter – Fan speed levels”, 0 means off, 1, 2, 3, 4, 5 means the fan speed level of the fresh air system.

12.46.2

No

Fresh Air mode – Room Temperature Display - Object no

Object name

288 FAF : Room Temperature

Data type

2 byte DPT 9.001

Flags

C , W , T, U

Display (display in Fresh air page) - 2 byte

This communication object is used for the room temperature displayed on the fresh air page. If the group of objects does not receive the temperature value, there is no room temperature display on the fresh air page.

12.46.3

Fresh Air mode – Control On/Off - Object no

No Object name

289 FAF : Control on/off confirm

Data type

1 bit DPT 1.001

- 1 bit

290 FAF : Control on/off request

- 1 bit

1 bit DPT 1.001

Flags

C

C

W

R

T

T

, U

This communication object is used to control the on/off of the fresh air system and obtain feedback on the current states of the fresh air system. The fresh air page is a slave device; therefore, the request is the output object, and the confirmation is the input object.

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13 Information about planning and application

13.1

Auxiliary power supply capacity

Power consumption for PEONIA with RTC is below:

Supply KNX bus voltage 21…31 V DC

Current consumption via bus

Power consumption via bus

< 12 mA

Maximum 300 mW

Supply auxiliary bus voltage

Current consumption via auxiliary power supply

Power consumption via auxiliary power supply

21…31 V DC

< 120 mA

Maximum 1.5W

KNX power supply

Each individual PEONIA device requires standard KNX power supply. Recommend power supplies is as per list below.

CAUTION: A KNX certified power supply module shall be use for the KNX bus, otherwise it may cause KNX communication failure and damage to the connected devices.

Auxiliary power supply

Each individual PEONIA device with RTC requires an auxiliary, additional, external power supply. Recommend auxiliary power supply is as per list below.

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13.2

KNX room climate control

If a room climate control system is in place, it is possible to record and control the factors affecting whether the room air is of good quality. In this case, the KNX bus is provide with data relating to air quality and room temperature control. If the CO2 concentration level in the room is too high, for example, it is possible to have ventilators switched on or windows opened automatically. The air quality in the room is constantly recorded and monitored. There is no need to intervene in the process – everything happens automatically.

A room climate control system is often used in rooms where the number of people varies within a small space, such as supermarkets, shopping centers, hotels, cinemas, hospitals and schools.

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Service

ABB LV Installation Materials Co.,

Ltd.Beijing

北京 ABB 低压电器有限公司

No 17 Kangding Street, BDA, Beijing http://www.abb.com.cn,

Tel: +86 400-820-9696

Notice

We reserve the right to make technical changes at all times as well as changes to the contents of this document without prior notice.

The detailed specifications agreed upon apply for orders. ABB accepts no responsibility for possible errors or incompleteness in this document.

We reserve all rights to this document and the topics and illustrations contained therein. The document and its contents, or extracts thereof, must not be reproduced, transmitted or reused by third parties without prior written consent by ABB

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