Legrand Lighting Integrator Native BACnet Panel (LIB8, LIB24, LIB48) Installation Instruction

Lighting Integrator

Native BACnet

Models: LIB8, LIB24, LIB48

SPECIFICATIONS

Supply Voltages ...........................................................................................per selected power supply

P115/277 Power Supply ............................................................................................. 120 or 277VAC

P240 Power Supply ................................................................................................................240VAC

P115/347 Power Supply ............................................................................................. 120 or 347VAC

Accessory Power Output ..............................................................................800mA@24VDC/VAC/ACR

Relay Load Ratings .................................................. @120VAC

Ballast ................................................................... N/A

Tungsten ................................................................ 20 Amp

Resistive ................................................................ N/A

Motor ..................................................................... 1 1 /

2

HP

@277VAC @347VAC

20 Amp

N/A

20 Amp

N/A

20 Amp

N/A

20 Amp

N/A

Duplex Receptacle................................................ 20 Amp N/A N/A

Environmental

Maximum Ambient Temperature .............................................................................................. 60°C

Maximum Humidity ....................................................................... 5% to 90% RH, non-condensing

UL & CUL Listed

Santa Clara, CA 95050

©2012 WattStopper

CONTENTS

SPECIFICATIONS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

INTRODUCTION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

COMPONENT LOCATION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4

I. INSTALATION AND SETUP. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

A. Mount the LI Enclosure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

B. Install the LI Interior. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

C. Connect the AC Power SUpply to Power Source. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

D. Connect Load and Line Voltage to Relays. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6

E. Low Voltage (Class 2) Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

F. Optional Group Switching and Smartwire Procedure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

II. LI BACnet QUICK SETUP REFERENCE. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

III. NATIVE BACnet OPTION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10

IV. TESTING AND TROUBLESHOOTING. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Basic power-up testing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Troubleshooting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

WARRANTY INFORMATION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20

LIST OF FIGURES

Figure 1: Interiors and enclosures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Figure 2: Component locations inside the LI panel enclosure . . . . . . . . . . . . . . . . . . . . . . . 4

Figure 3: Enclosure dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Figure 4: P115/277 wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

Figure 5: P115/347 wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

Figure 6: P240 wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

Figure 7: Relay Schedule form . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

Figure 8: Relay Control Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6

Figure 9: Manual relay channel setup for the Group Switching Card . . . . . . . . . . . . . . . . . .8

Figure 10: Group Switching card connections and components . . . . . . . . . . . . . . . . . . . . . 8

Page 2 Call 800.879.8585 for Technical Support

INTRODUCTION

As a minimum, each panel will require an interior assembly and an enclosure. These components may have shipped separately.

The panel interior assembly provides isolation between the line- and low-voltage sections of the panel, as well as the mounting frame for relays, the power supply and the circuit board assemblies.

Inside the low voltage area are LEDs for visual indication of relay status, plus manual push-buttons to turn individual relays on or off, and to perform smartwiring.

Smartwiring is a WattStopper innovation that enables easy push-button relay grouping for convenient group control.

Smartwiring offers flexible grouping of lighting loads for control of individual relays, groups of relays, or channels.

After installation and set up, a secure outer cover, when closed, offers protection from the high voltage area.

The following page shows a photograph of a fully assembled 24 relay Lighting Integrator panel that shows installed components for reference. The illustrations show component locations for 8 relay and 48 relay LI panels. Note that not all of the components shown may be fitted in every

Lighting Integrator panel depending on the application.

INTERIORS ENCLOSURES

Figure 1: Interiors and enclosures

CAUTION

RISK OF ELECTRIC SHOCK

Important Installation Notices

• All power must be turned off prior to wiring, installation or service.

• More than one disconnect may be required to deenergize power to the LI.

• External circuit protection to the LI is required (e.g., circuit breaker).

• Installation shall be in accordance with all

applicable regulations, wiring practices, and codes.

• Care should be taken to separate high voltage power from low voltage (Class 2) control wiring.

• Do not energize wiring until the unit is fully

assembled and connected circuits have been

tested and found to be free of electrical shorts.

Before installing the LI, read the instructions completely. If you have any questions, call our

Technical Support team at: 800.879.8585.

WARNING

IMPROPER INSTALLATION OR

CONNECTION OF THIS PANEL MAY

RESULT IN SERIOUS PERSONAL INJURY

AND/OR DAMAGE TO THE PANEL AND

OTHER DEVICES.

www.wattstopper.com

Page 3

COMPONENT LOCATIONS

The illustration below shows a Lighting Integrator panel installed inside an enclosure with the cover removed.

Relays

Note the location of components when the panel is fully assembled.

LI24 Interior assembly

Low voltage area for switch and sensor connections

Blue Flashing diagnostic LEDs in several locations

RELAY

NUMBER

1

2

Group Switching

Card

Mechanical Relay

Override Switches -

Use screwdriver tip to activate

Diagnostic LEDs

High voltage area

AC power transformer assembly (HPSM)

Low voltage power supply for 24VAC/

VDC accessories

(occupancy sensors, photocells, etc.)

Optional DIN rail and contactors

(capacity: 6 contactors)

High Voltage Area

Relay Driver cards (each card supports 4 relays)

NB card may be installed in either of these locations

Accessory module

DIN rail mounting plate

Relays

Relay Driver cards

AC power transformer assembly

Enclosure mounting holes (4x)

LI8

Group Switching

Card

Low voltage power supply

Relays

Relay Driver cards

AC power transformer assembly

Low voltage power supply

LI48

Group Switching

Card #1

Group Switching

Card #2

Figure 2: Component locations inside the LI panel enclosure


I. INSTALLATION AND SETUP

A. Mount the LI Enclosure

1. Attach the enclosure to the wall. The enclosure should be level, plumb and rigidly installed. Refer to the instructions provided with the enclosure for flush or surface mounting procedures.

2. Determine the appropriate wire entry locations. Make sure that all line and low voltage wiring entry locations are confined to the appropriate compartments as shown in the figure below.

Do not run low voltage wiring with line voltage or power wiring.

3. Drill or knock out openings to bring wiring conduit into the enclosure.

CAUTION

OBSERVE LINE AND LOW VOLTAGE

SEPARATION WHEN ROUTING

CONDUIT AND WIRE

B. Install the LI Interior

Do not install the interior assembly until after the LI enclosure has been securely mounted to the wall and the conduit/wiring holes have been drilled or knocked out.

Note: If this enclosure includes the optional DMP-1 Din

Rail Mounting Plate, place DMP Plate over lower studs before installing the interior.

1. Place the interior in the enclosure and align the interior with the studs provided in the enclosure.

2. Attach the interior assembly to the back of the enclosure using the four sets of nuts and washers provided.

3. After all wiring is completed, attach the cover according to the instructions provided with the enclosure.

15.08"

4.82"

LENC8S

LENC8F

11.68"

Low voltage section 13.58"

14.5"

23.34"

4.94"

LENC24S

LENC24F

14" 4.94"

Low voltage section

26"

35.8"

4.94"

LENC48S

LENC48F

14" 4.94"

Low voltage section

40.5"

8.08"

4.94"

16"

LENC24-48S

LENC24-48F

14" 4.94"

8.08"

15.08"

26"

11.3”

LENC8-24S

LENC8-24F

12.2" 11.68"

Low voltage section

16"

23.34" Low voltage section

40.5"

16"

21.26"

16"

Figure 3: Enclosure dimensions www.wattstopper.com

Page 5

C. Connect the AC Power Supply to

Power Source

The LI has several power supply options that allow it to operate with 115VAC, 240VAC, 277VAC or 347VAC line voltage. These power supplies function with either 50 or

60 Hz. They have internal overcurrent protection. The transformer automatically turns off when overloaded and resets when the fault is removed. The power supply contains MOVs to protect all downstream electronics from transient powerline voltage surges.

CAUTION

VERIFY WHETHER YOUR SUPPLY LINE

VOLTAGE IS 115VAC, 240VAC, 277VAC, OR

347VAC AND THAT THE POWER SUPPLY

IN THIS PANEL MATCHES THAT LINE

VOLTAGE. WIRING TO THE INCORRECT

VOLTAGE TERMINAL MAY RESULT IN

DAMAGE TO THE POWER SUPPLY

AND/OR THE PANEL, AND WILL VOID

THE PRODUCT WARRANTY.

1. Read and remove the CAUTION label covering the terminals.

2. Note that there are different terminals for supply voltage input.

Wire to ONLY ONE of these terminals. Match your input voltage to the correct terminal.

115VAC Supply 277VAC Supply

Page 6

D. Connect Load and Line Voltage to

Relays

Before making any connections to the relays, make sure that none of the load circuits are shorted. Route conductors from the circuit breaker through each relay’s SPST output terminals, and from there to the loads. Confirm that each circuit is wired to the relay specified in the electrical construction drawings and relay schedule forms provided with the panel.

Figure 4: P115/277 wiring

115VAC Supply 347VAC Supply

Figure 5: P115/347 wiring

Figure 7: Relay Schedule form

Power Up and Test Relays

1. Apply power to the LI power supply ONLY.

Do NOT apply power to the controlled circuit loads.

2. As shown in the illustration below, locate the relay control buttons on the Relay Driver card next to each relay’s 5-wire plug-in termination. Press the relay control button to toggle it ON/OFF. The relay clicks, the relay’s mechanical override switch moves and the LED status indicator changes.

3. Confirm the operation by measuring the continuity at the line voltage terminations of each relay.

4. Apply power to the relays.

5. Being careful not to touch any line voltage wiring, toggle each relay ON/OFF again and confirm that each relay controls the appropriate load.

LED

TO RELAY

240VAC Supply

RELAY

CONTROL

BUTTON

Figure 6: P240 wiring Figure 8: Relay Control Button

Call 800.879.8585 for Technical Support

E. Low Voltage (Class 2) Wiring

The low voltage (Class 2) section of the panel provides terminal connections for a variety of optional switches and other devices. See Figure 3 for location of the low voltage section. All wire entering this section must be Class 2 only.

Do not allow line voltage conductors to pass through the

Class 2 section for any reason.

An individual relay can be controlled from a switch or sensor by hardwiring it to the corresponding connector on the Relay Driver card (see Figure 2 for locations).

Alternatively, several relays can be grouped together so that they can be controlled from a single switch or sensor that is hardwired to the Group Switching card (see Optional Group

Switching Card and Smartwire Procedure section). A group of relays is assigned to a group channel via smartwiring. Up to 8 groups labeled A through H are available with a single

Group Switching card (refer to Figure 10). A 48 relay panel can support two Group Switching cards, for up to 16 group channels.

Hardwire Low Voltage Switch Wiring

Two-wire momentary — Operates as push ON/push OFF in an alternate action. This type of control is recommended for applications where the user can clearly see the lighting being controlled. This switch can not be hardwired to multiple inputs. If multiple relays need to be controlled by this type of switch, use a Group Switch card input.

B -to- W JUMPER

BLACK

RED

2-WIRE MOMENTARY

PUSH BUTTON

R B Y W

Two-wire maintained — Operates as a standard ON/

OFF toggle switch. This type of control should not be used where the lighting is being controlled by scheduled or other automatic means. If the lighting is turned off by automatic means, the switch will need to be moved through the OFF position before it will once again synchronize with the status of the lighting.

R -to- B JUMPER

BLACK

WHITE

2-WIRE MAINTAINED

ISOLATED CONTACT

R B Y W

Three-wire momentary — Operates in a dual momentary action mode with an independent contact for the ON and

OFF signals. This operation can be provided by a SPDT momentary toggle switch or a variety of WattStopper low voltage switch options. This is the most common type of direct wired switch option used with LI relay panels.

Occupancy Sensor — LI switch inputs are designed to automatically sense the connection of a WattStopper occupancy sensor. The operation of the input will configure for proper operation as soon as the sensor activates the input for the first time. Operation of the relay will be determined by motion detection in the space and the scheduled occupancy state of the relay or channel its is controlling. During scheduled occupied periods the sensor will turn lighting ON when motion is detected but will not turn the lighting OFF. During unoccupied periods, the sensor will turn the lighting ON and OFF based only on motion being detected.

COMMON

CONTROL

24VDC

BLACK

BLUE

RED

OCCUPANCY SENSOR

Red Blue

Black

R B Y W

Manual ON/OFF with Occupancy Sensor — Allows a twowire momentary switch to have manual ON/OFF control of the lighting in conjunction with occupancy sensor control.

Unlike the occupancy sensor this switch will turn the lighting ON or OFF regardless of the status of the sensor or scheduled occupancy status relay or channel it is controlling.

WHITE

BLACK

White

Black

COMMON

CONTROL

24VDC

BLACK

BLUE

RED

COMBINATION OF

2-WIRE MOMENTARY

PUSH BUTTON

WITH OCCUPANCY SENSOR

Red

Black

Blue

R B Y W

Switches with Pilot Lights

The “Y” (yellow) terminal on the Switch Input Terminal

Blocks supplies 24V rectified for use with pilot light switches.

To power a pilot light from the “Y” (yellow) terminal of a Group Switching (GS) card, install a jumper wire from

24VR to Yelcom on the GS card.

Voltage is present when the associated relay is ON.

Contact the Factory for configuring the panel for use with switch pilots requiring other voltages.

BLACK

WHITE

RED

STANDARD 3-WIRE

MOMENTARY

R B Y W www.wattstopper.com

Page 7

F. Optional group switching and

smartwire procedure

A Group Switching card (Figure 10) provides eight channels that may be smartwired to relays within the panel. Channels are used to group relays for common control

If automation is to be provided by an interface to another system, or by using manual switches only, the channels may be used simply for grouping relays. See instructions 1, 2 and 3.

1. On the Group Switching card, press and hold the Group channel push button for several seconds. Release the button when the red channel LED and the LEDs for relays currently controlled by that input begin to flash.

2. On each Relay card, select the relays to be controlled.

If a relay was previously “smartwired” to the channel input selected, the LED will be flashing, otherwise the

LED will be off. Press the associated Relay Control

Button to add/delete that relay to/from the group.

The LED for each relay included in the group will be flashing.

3. On the Group Switching card, press the Group Channel

Push-button again for several seconds. Release the button when all LEDs stop flashing. The input switch will now control the relays selected.

Step 1. GROUP SWITCHING CARD

TO SWITCH

(2) LED starts flashing

(1) Press and Hold Group

Channel Push-button

Step 2. RELAY DRIVER CARD

(2) LED starts flashing

LED

TO RELAY

(1) Press Relay

Control Button

on each relay

to be controlled

Figure 9: Manual relay channel setup for the Group Switching Card

Step 3. GROUP SWITCHING CARD

TO SWITCH

(2) LED stops flashing

(1) Press Group Channel

Push-button again

Power connectors

(power to accessories or sensors)

Pattern LED

Pattern push-button

Group channel connectors (8x)

(connect to switch or sensor contacts, or analog photocells)

Group channel LEDs (8x)

Group channel push-buttons (8x)

A B C D E F G H

GROUP CHANNEL

LEDs:

Green = assigned relays in mixed state (some OFF, some ON)

Red = all assigned relays are ON

Off = all assigned relays are OFF

Figure 10: Group Switching card connections and components

Test Smartwired Relay Group Channels

1. Press the Group channel Push-button ON/OFF/ON to toggle the group ON/OFF/ON.

2. The Group channel LED tracks the last action. With all relays in the group ON the Group channel LED is

Red.

3. Turn OFF each relay in the group using the individual

Relay Control Buttons. The Group channel LED turns

Green to indicate that the relays assigned to that channel are in mixed states – some are OFF, some are ON.

4. When the last relay is turned OFF, the Group

Channel LED should also go OFF.


II. LI BACnet QUICK SETUP REFERENCE

DEVICE INSTANCE (DEVICE ID)

Set the Device Instance (Device ID) for the panel using the three rotary switches SWT1, SWT2, and SWT3. Valid settings are 000

- 999. An alternate range of settings are available at 86000 -

86999. See SWT5 on page 2 of the installation instructions. The example shows an ID of 123.

MS/TP MAC ADDRESS

Set the MS/TP MAC address for the panel in the range of 0 - 127 using the dip switches SWT4. This setting must be unique on this network segment.

Add 1 to MAC

Add 2 to MAC

Add 4 to MAC

Add 8 to MAC

Add 16 to MAC

Add 32 to MAC

Add 64 to MAC

BAUD RATE

Set the baud rate for the MS/TP using the dip switches SWT5.

This setting must match the setting used for other devices on this network segment.

Switch 3 Switch 4

Right Right

Left Right

Right Left

Left Left

Baud Rate

9600

38400

76800

19200

Note: The panel must be power cycled before the above settings take affect.


SWT4

SWT5

Page 9

III. NATIVE BACnet OPTION

(e) SWT1, SWT2, SWT3

BACnet Device ID

(c) SWT4 MS/TP MAC address

(d) SWT5 MS/TP baud rate

(a) MS/TP connector

(f) LED indicators

(g) Reference jumper

(b) J3 EOL resistor jumper

The Native BACnet Option enables native level integration of lighting control between a Lighting Integrator (LI) Panel and any building automation system that supports the ANSI/

ASHRAE BACnet communication protocol.

The LI BACnet Option allows the BAS to schedule, monitor status, and override lighting freely without the need to support lighting-specific functions (i.e., blink warning, local override switches, and delay timers).

FEATURES

• Integral automation enables BAS to easily provide code compliant lighting control

• Distributed processing ensures operation of primary lighting control functions

• Compatible with WattStopper Occupancy Sensors

• Supports Auto ON, or energy saving manual ON function for lighting in areas scheduled as occupied

• Optional Photocell choices for exterior and interior lighting

SPECIFICATIONS

• MS/TP communications port with onboard termination jumper

• 9600/19200/38400/76800 baud rates, selectable

• MS/TP MAC address selectable, 0-127

• Device ID selectable, 0-999

• Compatible with direct wired low voltage switches for relay override; not compatible with dataline switches

• Description property writable for all objects

OPERATION

With the LI Native BACnet option, panel relays and channels are automatically exposed to the BAS (Building Automation

System) as standard BACnet objects. Relays can be individually commanded and monitored as a group. This permits a building to be conveniently divided into lighting control zones, greatly reducing the number of individual objects a BAS must administer. LI panels perform all typical lighting control sequence of operations without continuous supervision by the BAS.

APPLICATIONS

In most applications, a BAS sets lighting zones to occupied/ unoccupied status through a schedule or a workstation command.

The LI panel then coordinates local switch overrides, time delays and blink warnings based on this status.

LIGHTING CONTROL SPECIFIC FUNCTIONS

The LI Native BACnet option provides integral automation capabilities that enable lighting control that is compliant with state energy codes based on ASHRAE 90.1 and IECC. Its distributed processing also ensures operation of primary lighting control functions, such as wall switch overrides, blink warnings, and afterhours time out of overrides.

Before proceeding, read the instructions on the following pages.

For an overview of the entire system and the documentation forms, refer to the other sections of the Lighting Integrator Installation and Operation Manual.

If you have any questions, call Technical Support at: 800-879-8585.


HARDWARE SETUP

The Lighting Integrator native BACnet option is provided via a factory installed option card. Designated NB, this card is installed into one of the two option card positions of the mother board within the panel interior assembly. The NB card may be installed in either card position. However, it is not designed to operate with any other option card and therefore should be the only card installed in these two positions. The LI BACnet option is designed for use with a BACnet compliant BAS and requires the use of a BACnet enabled workstation for set-up and commissioning of the lighting control and automation features. Prior to BACnet commissioning, the relays may be controlled via the on board override pushbuttons or by switches connected to the inputs on the relay driver cards.

Group control of relays is also possible via the group switching card and Smartwired pushbutton programming as described in the

Lighting Integrator Installation Instructions.

Note: All notations to items (a) through (g) mentioned below should be referenced visually on the Physical Location Reference diagram on the following page

Connect the MS/TP bus to the NB card using the removable quick connector at the lower right hand corner of the card (a). Observe the polarity for the twisted pair as silk screened on the face of the NB card. The NB provides a jumper for insertion of a 108

Ohm resistor across the pair for end of line termination. This is the bottom most pair of header pins on J3 (b) which is located to the left of the network connector. WARNING: the end of line termination jumper should be installed only if this panel is the last device at the end of the MS/TP bus.

Note: Some MS/TP implementations use a three-wire connection where the third wire is a reference. In this case, the reference wire should be connected to the “S” terminal on the network connector. IMPORTANT: Install a jumper across pins 7 and 8 which are the fourth pair down from the top (g) on connector J3

(g). This will provide the proper reference connection for the MS/

TP bus.

Set the MS/TP MAC address for the panel using the dip switches

SWT4 (c). Note that the least significant digit is at the top and the set position for the switches is to the left such that all switches set to the right is MAC 0 and all switches set to the left is MAC 127.

Each panel connected to the MS/TP segment must have a unique

MAC address.

Set the baud rate for the MS/TP network using switches 3 and 4 on

SWT5 (d) which is located just above the network connector. SWT5

Switch 3 Switch 4 Baud Rate

Right Right 9600

Left Right 38400

Right

Left

Left

Left

76800

19200

Note that switches 1 and 2 are always set to the left. Switches

5–7 are for future use. Switch 8 is discussed in the following paragraph.

The BACnet Device ID for the panel is set using the three rotary switches SWT1, SWT2, and SWT3 (e) located at the upper right of the card. The most significant digit is set with SWT1 and the least significant digit is set with SWT3.

The Device ID for each panel must be unique among all devices throughout the entire network, not just this segment. An alternate range of device IDs may be selected using switch 8 on SWT5. With switch 8 set to the right,

86,000 will be added to the ID set with the three rotary switches allowing a range of 86,000 – 86,999.

The device object’s “description” property is writable and may be used to provide a meaningful name for the panel.

The device object’s “name” property is not writeable and will automatically provide a unique identification of the panel based on the Device ID set for the panel. A panel with Device ID set to #86 will display as “WS00086”. See

Hardware Setup above for setting the Device ID of the panel.

Note: The panel must be power cycled before changes to either the Device ID or MS/TP MAC address will take affect. With power on and the MS/TP network connected to a communicating device such as a router or controller, bi-color LED indicator DS1 marked MS/TP (f) should be randomly flashing green . The lighting control panel can now be discovered using the BACnet workstation.

THEORY OF OPERATION

The lighting control panel has the ability to perform a number of typical lighting control automation features on it’s own without full time supervision from the BAS. These include occupant initiated overrides, after hour time out of overrides, blink warn for an impending OFF and selection of Auto ON or Manual ON for lighting in occupied zones.

The above automation features of the panel are selectively set for each of the eight channels (A – H). Relays assigned to follow these channels will assume the features selected for the respective channel. The channels can assume either of two possible states, occupied or unoccupied.

The behavior of the relays assigned to the channel will be determined by a combination of the feature set for the channel and the occupied/unoccupied status of the channel. It is highly recommended that the channels (BV

1 - BV 8) be the primary means of controlling the relays.

This will take full advantage of the features provided in the panel. A description of each feature behavior follows this section.

IMPORTANT: while the panel supports BACnet priority arrays, it must be noted that by design, the panel assigns ultimate priority for controlling the lighting to the human operator or occupant of the controlled space. Wall switches and override push buttons within the panel will take precedence over the DDC and will always control the lighting (relays) regardless of the priority arrays. In order to reconcile this functionality with the DDC, operation of a wall switch or override push button will first NULL the entire priority array of the affected relays (BO) and then command the relay(s) at priority level 16.

IMPORTANT: WattStopper highly recommends that relays be controlled in groups through association with the 8 automation channels (BV1 - BV8). Using the panel in this fashion will allow you to take full advantage of the special lighting control features of the panel. www.wattstopper.com

Page 11

ASSIGNING RELAYS TO CHANNELS

Relays can be assigned to follow channels in either of two ways.

This can be done manually at the panel using the Smartwired pushbutton programming feature of the group switch card.

Refer to the section F above for information on Smartwiring.

Alternately, relays can be assigned to follow channels using workstation commands. The AV objects 1 – 48 are used for this purpose. These correspond to each of 48 possible relay positions within the panel. Commanding present value equal to the number of the channel (1 – 8 = A – H) for an AV will assign the corresponding relay to that channel. Commanding 0 will remove the relay from all channels. For example, writing an 8 to AV 24 will assign relay 24 to follow channel H. Note that when channels are configured using smartwiring, the appropriate value is automatically written to the AV object representing the channel.

COMMAND CHANNELS OCCUPIED/UNOCCUPIED

A key benefit of the panel is realized when the lighting is scheduled through the channels rather than scheduling individual relays. The panel has internal logic that will automatically adjust the behavior of the lighting based on the occupancy state of the channel. It is not necessary to repeat occupancy commands to the channels. Repeating occupancy commands periodically can produce undesirable results by distorting the operation of the internal lighting logic functions.

This is not recommended practice.

The occupied/unoccupied mode for channels is determined by the present value of the BV1 – BV8 objects. For example, commanding 1 to BV8 will put channel H into the occupied mode. Commanding 0 or NULL will put the channel into the unoccupied mode. These actions will turn the associated relays on and off if the channel is set to the Auto ON mode (this is the factory default). See Auto ON - Manual ON below. Note that the present value of the BV object will reflect the net result of the commanded values in the BV priority array such that the highest

(lowest priority level number) wins. The relinquish default for the

BV priority arrays is unoccupied.

A common use for the channels will be scheduling the lighting to follow the BAS. In order to allow flexible override of individual relays, the panel applies the following rule to channel control of relays: Commanding a BV on (occupied) will turn on the member relays (assuming the channel is set to Auto On). The BO objects for the member relays will be commanded on by the channel at priority level16 and the remainder of the BO priority array will be set to NULL. This is similar to the functionality of panel overrides described for switch overrides. It should be noted that the present value of the BV objects represents the occupied/ unoccupied status of the channel and not necessarily the status of the relays controlled by the channel. A series of Multi-State

Value objects are provided for channel relay status. See Channel

Relay Status below. The “description” property of the BV and

MV objects is writable and may be used to provide a meaningful name for the channels.

Channel Relay Status

The actual on/off status of relays assigned to channels can be monitored using the Present Value property of the Multi-State

Value objects (MV1 – MV8) provided for this purpose. A group of relays that is assigned to a channel can have four possible states:

All ON (all relays are on), Blink (the relays have blinked and are currently running the blink warn timer before going off) , Mixed

(some relays are on and some are off) , and All Off (all relays are off). The actual state of individual relays can also be monitored via the BI objects. See Relay Control .

Auto ON - Manual ON

This feature can be used to maximize the energy savings by not turning on the lighting until the first person arrives in the area. To use the Manual ON setting requires that a wall switch or occupancy sensor be installed in the area to provide the arrival signal to the panel. The wall switch can be connected to an individual relay input for localized control or connected to the group switch card input as a channel master override. This feature is set for channels A – H via the BV101 – BV108 objects.

Command 0 to set the channel to Auto ON (factory default).

Command 1 to set the channel to Manual ON.

Blink Warn

The blink warn feature provides a means to warn occupants that their lights are going to be turned off. When enabled for a channel, the relays associated with the channel will blink off and on when the channel transitions from occupied to unoccupied.

The lighting will then turn off after five minutes unless an occupant signals the panel by pressing a wall switch. This action will cancel the impending off for the relay that is controlled by the switch and will start the time delay count down for this relay.

Blink warn is set for channels A - H via the AV101 — AV108 objects. Command 5 to set the blink warn interval to five minutes.

Command 0 to set the channel to no blink warn. Note that the current firmware version only supports a five minute interval.


The time delay feature insures that relays that are overridden on by a wall switch will not remain on indefinitely during unoccupied periods. When an occupant uses a wall switch to turn lighting on, the time delay counter starts counting down. At the end of the time delay period, the lights will either turn off (blink warn is not set) or will blink warn. Pressing the wall switch during the warn period will cancel the off and again start the time delay count down. Note that the time delay feature is automatically disabled during occupied periods.

The time delay feature has the added benefit of allowing the BAS to provide just a one time unoccupied signal to an area rather than “sweeping” the area off at intervals as would be required to meet state energy codes. The time delay is set in the range of 0

– 240 minutes for channels A – H via the AV201 - AV 208 objects.

For example, writing the value 120 to AV208 will set a time delay of two hours for channel H. Setting 0 for the time delay disables the feature for this channel. The time delay is also used to set the

“sweep” interval when also using the Automatic Wall Switch (see below).

Relay Control

Relays may be controlled and monitored individually and independently from the channels. However, this behavior should be limited to individual override of relays when required. It is recommended that simultaneous control of multiple relays be performed using the channel feature of the panel. Each relay is represented as a binary output object (BO). The present value property of the BO is used to control the relay and read the status of the relay. The present value will reflect the net result of the values written in the priority array such that the highest (lowest priority level number) wins. The relinquish default for the priority array is NULL or off. The “description” property of the BO objects is writable and may be used to provide a meaningful name for the relays. Note that a description written to a BO will automatically be assigned to the corresponding BI object. The description property of the BI is not writable.

Support for Automatic Wall Switch device

The panel is provided with integral support for the WattStopper

AS-100/AS-110 Automatic Wall Switch. This device can be installed in place of a standard line voltage wall switch and enable the BAS to provide automatic shut off of the lighting while maintaining the ability for occupants of individual offices to override their lighting on. This is done without the requirement for low voltage control wiring.

This feature can be activated for each channel by assigning a value of 250 to the Blink Warn property of the channel (AV101

– AV108). When set to this value, the channel will automatically turn the relays off for a period of one second then back on when the channel is commanded unoccupied. This brief power interruption, signals the Automatic Wall Switch to start its 5 minute grace period timer. At the end of the grace period, the lights will turn off unless the user cancels the off by activitating the integral override switch on the AS-100. This process will automatically repeat after the time interval is set in the “time delay” (AV201 - AV208). See Time Delay above for additional information. See the documentation for the AS-100 or AS-110 for more information on the use of these switches.

COMPLETE LIST OF OBJECTS

Object Instance # Object Name

(read only)

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BO

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BO

BO

BO

BO

BO

BO

BO

BO

BO

BI

35

36

37

38

39

30

31

32

33

34

25

26

27

28

29

20

21

22

23

24

15

16

17

18

19

10

11

12

13

14

5

6

7

8

9

3

4

1

2

10

11

12

7

8

9

2

3

4

5

6

45

46

47

48

1

40

41

42

43

44

RELAY 30

RELAY 31

RELAY 32

RELAY 33

RELAY 34

RELAY 35

RELAY 36

RELAY 37

RELAY 38

RELAY 39

RELAY 20

RELAY 21

RELAY 22

RELAY 23

RELAY 24

RELAY 25

RELAY 26

RELAY 27

RELAY 28

RELAY 29

RELAY 01

RELAY 02

RELAY 03

RELAY 04

RELAY 05

RELAY 06

RELAY 07

RELAY 08

RELAY 09

RELAY 10

RELAY 11

RELAY 12

RELAY 13

RELAY 14

RELAY 15

RELAY 16

RELAY 17

RELAY 18

RELAY 19

RELAY 40

RELAY 41

RELAY 42

RELAY 43

RELAY 44

RELAY 45

RELAY 46

RELAY 47

RELAY 48

RELAY 01 STATUS

RELAY 02 STATUS

RELAY 03 STATUS

RELAY 04 STATUS

RELAY 05 STATUS

RELAY 06 STATUS

RELAY 07 STATUS

RELAY 08 STATUS

RELAY 09 STATUS

RELAY 10 STATUS

RELAY 11 STATUS

RELAY 12 STATUS www.wattstopper.com

Present Value

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

Page 13

2

3

4

5

6

45

46

47

48

1

40

41

42

43

44

35

36

37

38

39

30

31

32

33

34

25

26

27

28

29

20

21

22

23

24

13

14

15

16

17

18

19

7

8

9

RELAY CHANNEL 07

RELAY CHANNEL 08

RELAY CHANNEL 09

10 RELAY CHANNEL 10

11 RELAY CHANNEL 11

12 RELAY CHANNEL 12

13 RELAY CHANNEL 13

14 RELAY CHANNEL 14

15 RELAY CHANNEL 15

16 RELAY CHANNEL 16

17 RELAY CHANNEL 17

18 RELAY CHANNEL 18

19 RELAY CHANNEL 19

20 RELAY CHANNEL 20

21 RELAY CHANNEL 21

22 RELAY CHANNEL 22

23 RELAY CHANNEL 23

24 RELAY CHANNEL 24

25 RELAY CHANNEL 25

26 RELAY CHANNEL 26

RELAY 35 STATUS

RELAY 36 STATUS

RELAY 37 STATUS

RELAY 38 STATUS

RELAY 39 STATUS

RELAY 40 STATUS

RELAY 41 STATUS

RELAY 42 STATUS

RELAY 43 STATUS

RELAY 44 STATUS

RELAY 45 STATUS

RELAY 46 STATUS

RELAY 47 STATUS

RELAY 48 STATUS

RELAY CHANNEL 01

RELAY CHANNEL 02

RELAY CHANNEL 03

RELAY CHANNEL 04

RELAY CHANNEL 05

RELAY CHANNEL 06

RELAY 13 STATUS

RELAY 14 STATUS

RELAY 15 STATUS

RELAY 16 STATUS

RELAY 17 STATUS

RELAY 18 STATUS

RELAY 19 STATUS

RELAY 20 STATUS

RELAY 21 STATUS

RELAY 22 STATUS

RELAY 23 STATUS

RELAY 24 STATUS

RELAY 25 STATUS

RELAY 26 STATUS

RELAY 27 STATUS

RELAY 28 STATUS

RELAY 29 STATUS

RELAY 30 STATUS

RELAY 31 STATUS

RELAY 32 STATUS

RELAY 33 STATUS

RELAY 34 STATUS

BI

BI

BI

BI

AV

AV

AV

AV

AV

AV

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

BI

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

Page 14

Object Instance # Object Name Present Value

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF

1 = ON, 0 = OFF assign relay 1 to channel # (1-8) assign relay 2 to channel # (1-8) assign relay 3 to channel # (1-8) assign relay 4 to channel # (1-8) assign relay 5 to channel # (1-8) assign relay 6 to channel # (1-8) assign relay 7 to channel # (1-8) assign relay 8 to channel # (1-8) assign relay 9 to channel # (1-8) assign relay 10 to channel # (1-8) assign relay 11 to channel # (1-8) assign relay 12 to channel # (1-8) assign relay 13 to channel # (1-8) assign relay 14 to channel # (1-8) assign relay 15 to channel # (1-8) assign relay 16 to channel # (1-8) assign relay 17 to channel # (1-8) assign relay 18 to channel # (1-8) assign relay 19 to channel # (1-8) assign relay 20 to channel # (1-8) assign relay 21 to channel # (1-8) assign relay 22 to channel # (1-8) assign relay 23 to channel # (1-8) assign relay 24 to channel # (1-8) assign relay 25 to channel # (1-8) assign relay 26 to channel # (1-8)

Call 800.879.8585 for Technical Support

MV

MV

MV

MV

MV

BV

BV

BV

BV

BV

BV

BV

BV

BV

BV

BV

BV

MV

MV

MV

AV

AV

AV

AV

AV

AV

AV

AV

AV

BV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

AV

BV

BV

BV

AV

AV

AV

AV

AV

AV

AV

108

201

202

203

204

205

206

207

208

103

104

105

106

107

106

107

108

101

102

27 RELAY CHANNEL 27

28 RELAY CHANNEL 28

29 RELAY CHANNEL 29

30 RELAY CHANNEL 30

31 RELAY CHANNEL 31

32 RELAY CHANNEL 32

33 RELAY CHANNEL 33

34 RELAY CHANNEL 34

35 RELAY CHANNEL 35

36 RELAY CHANNEL 36

37 RELAY CHANNEL 37

38 RELAY CHANNEL 38

39 RELAY CHANNEL 39

40 RELAY CHANNEL 40

41 RELAY CHANNEL 41

42 RELAY CHANNEL 42

43 RELAY CHANNEL 43

44 RELAY CHANNEL 44

45 RELAY CHANNEL 45

46 RELAY CHANNEL 46

47 RELAY CHANNEL 47

48 RELAY CHANNEL 48

1 CHANNEL A

2

3

4

5

6

CHANNEL B

CHANNEL C

CHANNEL D

CHANNEL E

CHANNEL F

7 CHANNEL G

8 CHANNEL H

1 CHANNEL A STATUS

2 CHANNEL B STATUS

3 CHANNEL C STATUS

101

102

103

104

105

4 CHANNEL D STATUS

5 CHANNEL E STATUS

6 CHANNEL F STATUS

7 CHANNEL G STATUS

8 CHANNEL H STATUS

MANUAL/AUTO 1

MANUAL/AUTO 2

MANUAL/AUTO 3

MANUAL/AUTO 4

MANUAL/AUTO 5

MANUAL/AUTO 6

MANUAL/AUTO 7

MANUAL/AUTO 8

BLINK WARN 1

BLINK WARN 2

BLINK WARN 3

BLINK WARN 4

BLINK WARN 5

BLINK WARN 6

BLINK WARN 7

BLINK WARN 8

TIME DELAY 1

TIME DELAY 2

TIME DELAY 3

TIME DELAY 4

TIME DELAY 5

TIME DELAY 6

TIME DELAY 7

TIME DELAY 8

Object Instance # Object Name Present Value assign relay 27 to channel # (1-8) assign relay 28 to channel # (1-8) assign relay 29 to channel # (1-8) assign relay 30 to channel # (1-8) assign relay 31 to channel # (1-8) assign relay 32 to channel # (1-8) assign relay 33 to channel # (1-8) assign relay 34 to channel # (1-8) assign relay 35 to channel # (1-8) assign relay 36 to channel # (1-8) assign relay 37 to channel # (1-8) assign relay 38 to channel # (1-8) assign relay 39 to channel # (1-8) assign relay 40 to channel # (1-8) assign relay 41 to channel # (1-8) assign relay 42 to channel # (1-8) assign relay 43 to channel # (1-8) assign relay 44 to channel # (1-8) assign relay 45 to channel # (1-8) assign relay 46 to channel # (1-8) assign relay 47 to channel # (1-8) assign relay 48 to channel # (1-8)

1 = Occupied, 0 = Unoccupied.

1 = Occupied, 0 = Unoccupied







ON (4), Mixed (3), OFF (1), Blink (2)








0 = Auto ON, 1 = Manual ON








5 = Five Min., 0 = No Blink







5 = Five Min. 0 = No Blink

1 - 240 Min., 0 = No Time Delay




1 - 240 Min. 0 = No Time Delay




Notes to the System Integrator

1. The WattStopper Native BACnet panel will handle the tasks unique to lighting control - Multiple Off sweeps, After hours Time

Delays, etc. It is highly recommended that you take advantage of these features rather than implementing logic on the control side.

2. Each BACnet Panel supports 8 channels (functional groups). Decide which relays will go into each channel (relays can only be assigned to one channel). Control these 8 channels, not the individual relays, by the schedules. You can either “smartwire” the relays to the channels, or use AV # object to assign relays to channels at the workstation.

When the Channel is set to “Occupied”

3. Some spaces should have lights go ON automatically in the morning, but in others people should manually turn on the lights - use

BV-10# object to define which scenario should happen when you turn the channel to “occupied”. In either case, time delays will be disabled.

When the Channel is set to “Unoccupied”

4. Most people appreciate a warning before lights go off, but there are ome lights and hardware that should not be “blinked” - HID lights for example. Set the AV-10# object to “5” and when the channel goes unoccupied the lightw will “blink” and 5 minutes later they will go off, unless an occupant overrides the sweep by pressing a local low voltage switchyy during the 5 minute grace period.

5. WattStopper’s AS-100 switches wire to the line voltage circuit and need to be pulsed Off for 2 seconds to go into their unoccupied mode. By setting a 250 value to the AV-10# object the panel will automatically take care of this pulsing behavior. Note that AS-100 swithces will not go ON automatically in the morning, and that since these relays are now basically Normally Closed contacts, their state will almost alwayus be ON regardless of whether their channel is an occupied or unoccupied state.

6. Most states have an energy code, and lighting overrides should last no more than 2 or 4 hours. Instead of sending out multiple OFF sweeps, use the AV-20# object to set a channel time delay. Note that this delay will only occur during the unoccupied times, and is disabled automatically when the channel is occupied.

7. Direct wired low voltge switchs always control the relay. Wheterh the relay stays on based on its channel’s time delay or until the occupancy state is changed will be handled by the panel automatically.

Sample Time of Day Schedule

Day

M-F, S,S

M-F, S,S

M-F, S,S

M-F, S,S

M-F, S,S

M-F, S,S

Time

7:00

17:00

17:00

19:00

7:00

7:00

Object-

Instance

BV-1

BV-2

BV-3

BV-1

BV-2

BV-3

Channel

A

B

C

A

B

C

Channel Type Write Present

Value

Interior AS-100

Exterior B

Exterior C

Interior AS-100

Exterior B

Exterior C

1

0

0

1

1

0

Channel Status

Occupied

Occupied

Occupied

Unoccupied

Unoccupied

Unoccupied

NOTE: Afterhour OFF sweeps and blink warnings will be handled by the panel based on the BV-10#, AV-10#, and AV-20# settings

Helpful Hints

1. Make sure communication speed is set properly via SWT-5, using dip switches 3 and 4

2. Use schedlued events that control relay panel channels via BV-1 through BV-8

3. Send one “Occupied” command and one “Unoccupied” command per channel as required by schedules. Reinforcement of the channel state by repeated writes is not necessary.

4. Dip switch settings are only read during initial panel startup - if they need to be changed, make sure power to the panel is cycled so the new settings are read.

5. Direct wired Low Voltage switches WILL ALWAYS cnotrol relays ON or OFF regardless of the priority array. Array values will then all be set to null except for 16, which will be set to 1 for ON or 0 for OFF.

6. AS-100s are unique line voltage switches made by WattStopper. For more info see: http://www.wattstopper.com.


Page 15

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- AS-1 sk-11: rior rior

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Watt Stopper MS/TP BACnet Native Panel Documentation Form

Lighting Control Relay Panel Schedule

Group Descriptions

Site Name:

LCP Description:

BACnet Device ID (1 - 999):

Device Name:

Location:

Flush or Surface Cover:

Panel Power Circuit:

27

28

29

30

31

32

33

34

16

17

18

19

12

13

14

15

10

11

8

9

6

7

4

5

* Relay

Relay Object-Instance

2

3

#

1

(1=On, 0=Off)

BO-1

BO-2

BO-3

BO-4

BO-5

BO-6

BO-7

BO-8

20

21

BO-9

BO-10

BO-11

BO-12

BO-13

BO-14

BO-15

BO-16

BO-17

BO-18

BO-19

BO-20

BO-21

22

23

24

BO-22

BO-23

BO-24

25

26

BO-25

BO-26

BO-27

BO-28

BO-29

BO-30

BO-31

BO-32

BO-33

BO-34

Circuit Description

Channel

LV Switch Object-Instance or Sensor ( Values ==>)

AV-1

AV-2

AV-3

AV-4

AV-5

AV-6

AV-7

AV-8

AV-9

AV-10

AV-11

AV-12

AV-13

AV-14

AV-15

AV-16

AV-17

AV-18

AV-19

AV-20

AV-21

AV-22

AV-23

AV-24

AV-25

AV-26

AV-27

AV-28

AV-29

AV-30

AV-31

AV-32

AV-33

AV-34

A

1

B

AV-# Object Present Value

2

Automation Channel

35

36

37

38

39

BO-35

BO-36

BO-37

BO-38

BO-39

AV-35

AV-36

AV-37

AV-38

AV-39

44

45

46

47

40

41

42

43

BO-40

BO-41

BO-42

BO-43

BO-44

BO-45

BO-46

BO-47

AV-40

AV-41

AV-42

AV-43

AV-44

AV-45

AV-46

AV-47

48 BO-48 AV-48

* Proper operation REQUIRES scheduling using Channel Commands, not via individual BO-# Object Instances

C

3

D

4

E

5

F

6

G

7

H

8 www.wattstopper.com

Page 17

Watt Stopper MS/TP BACnet Native Panel Documentation Form

BACnet Card Setting Channel Setup

Device ID (Rotary Switches):

Firmware Version (Label):

Object-

Channel Instance

J3 EOL 120 Ohm Jumper:

NOTE: Only install J3 Jumper on extreme ends of local MS/TP network segment.

Installed-Removed

SWT 4 - MS/TP MAC

ADD

Off null

On

Feature Dip (Left) (Rt)

Add 1 to MAC 1 On

Off Add 2 to MAC

Add 4 to MAC

Add 8 to MAC

Add 16 to MAC

Add 32 to MAC

Add 64 to MAC na (always set Off)

Calculated MAC Address:

6

7

8

4

5

2

3

Off

Off

10

On

On

On

On

SWT 5 - Baud Rate

Off On

Feature Dip (Left) (Rt) na (always set Off) na (always set Off)

MS/TP baud rate

MS/TP baud rate na (always set Off) na (always set Off) na (always set Off)

1

2

3

4

5

6

7

Off

Off

Off

Off

Off

Off

On

On=Device ID+86000 8 Off

NOTE: Dip

Swt 5 Baud Values 3

9600 On

38400 Off

76800 On

19200 Off

Dip

4

On

On

Off

Off

A

B

C

D

E

F

G

H

Object-


A

B

BV-1

BV-2

E

F

C

D

G

H

BV-3

BV-4

BV-5

BV-6

BV-7

BV-8

Feature

BV-101 Auto or Manual On

AV-101 Blink / No Blink / AS-100

AV-201 Time Delay



AV-202 Time Delay



AV-203 Time Delay



AV-204 Time Delay



AV-205 Time Delay



AV-206 Time Delay



AV-207 Time Delay



AV-208 Time Delay

0=Auto (default), 1=Manual

0=No, 5=yes (5 min grace), 250=AS-100

0=None, 1-240 = Time Delay (minutes)






















Channel Occupancy Command Write/Read

Feature

Channel Occupancy

Channel Occupancy

Channel Occupancy

Channel Occupancy

Channel Occupancy

Channel Occupancy

Channel Occupancy

Channel Occupancy

Options

(Present Value)

Options

(Present Value)

0 or Null =Unoccupied, 1=Occupied








Channel Relay Status Read

Object-


A

B

MV-1

MV-2

E

F

C

D

G

H

MV-3

MV-4

MV-5

MV-6

MV-7

MV-8

Feature

Status

Status

Status

Status

Status

Status

Status

Status

Options

(Present Value)

1=Off, 2=Blink, 3=Mixed, 4=On








Panel

Setting


IV. TESTING AND TROUBLESHOOTING

Basic power-up testing

Test

Observe Blue LEDS on the C8 or C24 board

Observe Blue LEDs (at

DS6) on RD boards (and on GS card if installed)

Observe the Green Status

LEDs on the C8 or C24 board

Observe the two green

Power LEDs at DS1 &

DS2 on the PS board

Look for any lit Amber

LEDs on the RD (and GS if installed).

Response

Blue LED blinks at a regular tempo.

Go to next Test.

Blue LED off or continuously lit.

Blue LED flashes at regular intervals on both boards.

Blue LED off or continuously lit.

Reset panel power. Check LED again.

Go to next Test.

Reset panel power. Check LED again.

All 6 Green Status LEDs are continuously lit.

Any Green Status LED is off.

Both green Power LEDs are continuously lit.

Go to next Test.

Reset panel power. Check LEDs again.

Go to next Test.

Either Green Power LED is off.

No Amber LEDs observed.

An Amber LED is lit or blinking.

What next?

If the panel continues to fail a test, call Technical Support

Turn off power to panel and check red and black wire connections to the J2 terminal block on the PS board.

Reset panel power. Check LEDs again.

Go to next Test.

Reset panel power. Check for Amber LEDs again.

Relay Operation: Press each Relay control pushbutton

NB (BACnet card) verification: Press one of the relay control pushbuttons to toggle the relay state

Red LED for each relay lights and relay clicks. Press button again, relay clicks and Red LED goes off.

Red LED doesn’t light and/or relay doesn’t click.

Green LED labeled PANEL on the NB

(BACnet) card lights momentarily.

Green LED on NB card does not light momentarily.

Green LED labeled MS/TP should begin to blink in a random pattern.

Ok to wire low voltage devices to relay card terminals.

Make sure a jumper is installed on PS board between

YELCOM and 24VR terminals.

Go to next Test.

Replace the NB card

Test complete, BACnet interface is good.

MS/TP Communication:

Connect a known good

MS/TP segment to the

NB card

Green LED labeled MS/TP does not begin to blink.

Check that the baud rate is set correctly, check for duplicate MAC or Device ID address, check polarity of the network wire connection, make sure that switches

#1 and #2 on SWT5 are both set to the left (off), check for a jumper across the bottom two pins on J3

(termination jumper should be in place only if this is the last device on the network segment).


Page 19

Troubleshooting

Problem

1 The LV switch does not control the relay or group.

Test Steps

Are the wires routed and terminated correctly in the panel? See pages 5 & 7.

Is the 12VDC indicating LED on the C8 or

C24 motherboard solid Green?

Does the board mounted override pushbutton control the relay or group?

Disconnect input terminals.

Next

No – Correct terminations

Yes – Go to next step

No – Cycle power to panel; recheck


No – Call tech support


No – Call tech support

Yes - Verify the LV wiring is not shorted and that the switch is operating correctly

2 When I try to turn the relay off it goes off for a second then comes back on.

3 When I try to turn the relay on it comes on for a second then goes off again.

4 I need to remove a sensor from the system.

Does jumping the Red to White input terminals turn the relay on and does Black to White turn it off?

If using a Group switch, have the relays been assigned to the particular group using the GS card?

Remove any LV switching that is landed at the relay input and attempt to turn relay ON using the board override buttons.

Move LV relay connection to a different point on the RD board and attempt to override the relay on.

Remove any LV switching that is landed at the relay input and attempt to turn relay ON using the board override buttons.

Move LV relay connection to a different point on the RD board and attempt to override the relay on.

No – Make the necessary assignments (refer to page 8)


No change in status - Go to next step

Relay functions normally - Verify the LV wiring is not shorted and that the switch is operating correctly

No change in status - relay needs to be replaced - call tech support

Relay functions properly – circuit board needs to be replaced - call tech support

No change in status - Go to next step

Relay functions normally – Verify the LV wiring is not shorted and that the switch is operating correctly

No change in status - relay needs to be replaced - call tech support

Relay functions properly – circuit board needs to be replaced - call tech support

No – Call tech support Once a sensor has been connected to a relay driver or group switch card low voltage input, the input will remain in the sensor mode even if the sensor is removed.

To restore normal operation :

Yes – Normal operation is restored. The input is configured for standard low voltage switches.

1. Remove the sensor wiring from the panel input.

2. Turn the associated relay or group off using the red override button corresponding to the input where the sensor had been connected.

3. Momentarily jumper the white and red terminals.

4. Does the relay/group turn on?

WARRANTY INFORMATION

WattStopper warranties its products to be free of defects in materials and workmanship for a period of one (1) year. There are no obligations or liabilities on the part of WattStopper for consequential damages arising out of, or in connection with, the use or performance of this product or other indirect damages with respect to loss of property, revenue or profit, or cost of removal, installation or reinstallation.

Page 20

2800 De La Cruz Boulevard

Santa Clara, CA 95050

Call 800.879.8585 for Technical Support www.wattstopper.com

Please

Recycle

12343r1 10/2012

Legrand Lighting Integrator Native BACnet Panel (LIB8, LIB24, LIB48) Installation Instruction

Lighting Integrator

SPECIFICATIONS

CONTENTS

LIST OF FIGURES

INTRODUCTION

CAUTION

RISK OF ELECTRIC SHOCK

Important Installation Notices

WARNING

IMPROPER INSTALLATION OR

CONNECTION OF THIS PANEL MAY

RESULT IN SERIOUS PERSONAL INJURY

AND/OR DAMAGE TO THE PANEL AND

OTHER DEVICES.

COMPONENT LOCATIONS

I. INSTALLATION AND SETUP

A. Mount the LI Enclosure

CAUTION

OBSERVE LINE AND LOW VOLTAGE

SEPARATION WHEN ROUTING

CONDUIT AND WIRE

B. Install the LI Interior

C. Connect the AC Power Supply to

Power Source

CAUTION

VERIFY WHETHER YOUR SUPPLY LINE

VOLTAGE IS 115VAC, 240VAC, 277VAC, OR

347VAC AND THAT THE POWER SUPPLY

IN THIS PANEL MATCHES THAT LINE

VOLTAGE. WIRING TO THE INCORRECT

VOLTAGE TERMINAL MAY RESULT IN

DAMAGE TO THE POWER SUPPLY

AND/OR THE PANEL, AND WILL VOID

THE PRODUCT WARRANTY.

D. Connect Load and Line Voltage to

Relays

E. Low Voltage (Class 2) Wiring

Hardwire Low Voltage Switch Wiring

Switches with Pilot Lights

F. Optional group switching and

smartwire procedure

II. LI BACnet QUICK SETUP REFERENCE

DEVICE INSTANCE (DEVICE ID)

MS/TP MAC ADDRESS

BAUD RATE

SWT4

SWT5

III. NATIVE BACnet OPTION

FEATURES

SPECIFICATIONS

OPERATION

APPLICATIONS

LIGHTING CONTROL SPECIFIC FUNCTIONS

HARDWARE SETUP

THEORY OF OPERATION

ASSIGNING RELAYS TO CHANNELS

COMMAND CHANNELS OCCUPIED/UNOCCUPIED

Channel Relay Status

Auto ON - Manual ON

Blink Warn

Relay Control

Support for Automatic Wall Switch device

COMPLETE LIST OF OBJECTS

Notes to the System Integrator

Watt Stopper MS/TP BACnet Native Panel Documentation Form

Watt Stopper MS/TP BACnet Native Panel Documentation Form

IV. TESTING AND TROUBLESHOOTING

Basic power-up testing

Test

Response

What next?

Troubleshooting

WARRANTY INFORMATION

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