Endres+Hauser Deltabar S FMD77/78; PMD75 FOUNDATION Fieldbus (V 04.00.zz) Operating Instruction

BA00301P/00/EN/19.16

71336231 valid from Software version:

04.00.zz

Products Solutions

Operating Instructions

Deltabar S FMD77, FMD78,

PMD75

Differential pressure measurement

Services

2

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

1.

Order code:

Ser. no.:

Ext. ord. cd.:

XXXXX-XXXXXX

XXXXXXXXXXXX

XXX.XXXX.XX

Serial number

2.

www.endress.com/deviceviewer

Endress+Hauser

Operations App

3.

A0023555

Make sure the document is stored in a safe place such that it is always available when working on or with the device.

To avoid danger to individuals or the facility, read the "Basic safety instructions" section carefully, as well as all other safety instructions in the document that are specific to working procedures.

The manufacturer reserves the right to modify technical data without prior notice. Your

Endress+Hauser Sales Center will supply you with current information and updates to these

Instructions.

Endress+Hauser


Table of contents

1 Document information . . . . . . . . . . . . . . 4

1.1 Document function . . . . . . . . . . . . . . . . . . . . . . . . . . 4

1.2 Symbols used . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4

1.3 Registered trademarks . . . . . . . . . . . . . . . . . . . . . . . 5

1.4 Terms and abbreviations . . . . . . . . . . . . . . . . . . . . . 6

1.5 Turn down calculation . . . . . . . . . . . . . . . . . . . . . . . 7

2 Basic safety instructions . . . . . . . . . . . . . 8

2.1 Requirements concerning the staff . . . . . . . . . . . . . 8

2.2 Designated use . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

2.3 Workplace safety . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

2.4 Operational safety . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

2.5 Hazardous area . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

2.6 Product safety . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

3 Identification . . . . . . . . . . . . . . . . . . . . . 10

3.1 Product identification . . . . . . . . . . . . . . . . . . . . . . 10

3.2 Device designation . . . . . . . . . . . . . . . . . . . . . . . . 10

3.3 Scope of delivery . . . . . . . . . . . . . . . . . . . . . . . . . . 12

3.4 CE mark, Declaration of Conformity . . . . . . . . . . 12

3.5 Registered trademarks . . . . . . . . . . . . . . . . . . . . . 12

4 Installation . . . . . . . . . . . . . . . . . . . . . . . 13

4.1 Incoming acceptance and storage . . . . . . . . . . . . 13

4.2 Installation conditions . . . . . . . . . . . . . . . . . . . . . 13

4.3 Installation instructions . . . . . . . . . . . . . . . . . . . . 14

4.4 Post-installation check . . . . . . . . . . . . . . . . . . . . . 30

5 Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

5.1 Connecting the device . . . . . . . . . . . . . . . . . . . . . 31

5.2 Connecting the measuring unit . . . . . . . . . . . . . . 32

5.3 Overvoltage protection (optional) . . . . . . . . . . . . 33

5.4 Post-connection check . . . . . . . . . . . . . . . . . . . . . 33

6 Operation. . . . . . . . . . . . . . . . . . . . . . . . . 34

6.1 Onsite display (optional) . . . . . . . . . . . . . . . . . . . 34

6.2 Operating elements . . . . . . . . . . . . . . . . . . . . . . . 36

6.3 FOUNDATION Fieldbus interface . . . . . . . . . . . . 38

6.4 Local operation – onsite display connected . . . . 51

6.5 HistoROM®/M-DAT (optional) . . . . . . . . . . . . . . 54

6.6 FieldCare . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 operation

6.8 Simulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59

6.9 Factory setting (reset) . . . . . . . . . . . . . . . . . . . . . 59

7 Commissioning. . . . . . . . . . . . . . . . . . . . 62

7.1 Configuring messages . . . . . . . . . . . . . . . . . . . . . 62

7.2 Function check . . . . . . . . . . . . . . . . . . . . . . . . . . . 62

7.3 Commissioning via an FF configuration program . .

62

7.4 Selecting the language and measuring mode . . 64

7.5 Position adjustment . . . . . . . . . . . . . . . . . . . . . . . 65

Endress+Hauser

7.6 Flow measurement . . . . . . . . . . . . . . . . . . . . . . . . . 67

7.7 Level measurement . . . . . . . . . . . . . . . . . . . . . . . . 70

7.8 Differential pressure measurement . . . . . . . . . . . 77

7.9 Scaling the OUT parameter . . . . . . . . . . . . . . . . . . 79

7.10 Configuring event behavior in accordance with

FOUNDATION Fieldbus Specification FF912 Field

Diagnostic Profile . . . . . . . . . . . . . . . . . . . . . . . . . . 80

8 Maintenance . . . . . . . . . . . . . . . . . . . . . 91

8.1 Cleaning instructions . . . . . . . . . . . . . . . . . . . . . . . 91

8.2 Exterior cleaning . . . . . . . . . . . . . . . . . . . . . . . . . . 91

9 Diagnostics and troubleshooting . . . . 92

9.1 Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . 92

9.2 Diagnostic information on local display . . . . . . . . 93

9.3 Diagnostic event in the operating tool . . . . . . . . . 94

9.4 Diagnostic messages in the DIAGNOSTIC

Transducer Block (TRDDIAG) . . . . . . . . . . . . . . . . 95

9.5 Overview of diagnostic events . . . . . . . . . . . . . . . . 99

9.6 Response of outputs to errors . . . . . . . . . . . . . . 108

9.7 Confirming messages . . . . . . . . . . . . . . . . . . . . . 109

9.8 Repair . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109

9.9 Repair of Ex-certified devices . . . . . . . . . . . . . . 110

9.10 Spare Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

9.11 Return . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

9.12 Disposal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

9.13 Software history . . . . . . . . . . . . . . . . . . . . . . . . . 111

10 Technical data . . . . . . . . . . . . . . . . . . . 111

Index . . . . . . . . . . . . . . . . . . . . . . . . . . . 112

3

Document information Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

1 Document information

1.1

Document function

These Operating Instructions contain all the information that is required in various phases of the life cycle of the device: from product identification, incoming acceptance and storage, to mounting, connection, operation and commissioning through to troubleshooting, maintenance and disposal.

1.2

Symbols used

1.2.1

Safety symbols

Symbol

DANGER

A0011189-DE

Meaning

DANGER!

This symbol alerts you to a dangerous situation. Failure to avoid this situation will result in seriousor fatal injury.

WARNING

A0011190-DE

WARNING!

This symbol alerts you to a dangerous situation. Failure to avoid this situation can result in seriousor fatal injury.

CAUTION

A0011191-DE

CAUTION!

This symbol alerts you to a dangerous situation. Failure to avoid this situation can result in minoror medium injury.

NOTICE

A0011192-DE

NOTICE!

This symbol contains information on procedures and other facts which do not result in personalinjury.

1.2.2

Electrical symbols

Symbol Meaning

Direct current

Direct current and alternating current

Protective ground connection

A terminal which must be connected to ground prior to establishing any other connections.

Symbol Meaning

Alternating current

)

Ground connection

A grounded terminal which, as far as the operator is concerned, is grounded via a grounding system.

Equipotential connection

A connection that has to be connected to the plant grounding system: This may be a potential equalization line or a star grounding system depending on national or company codes of practice.

1.2.3

Tool symbols

Symbol

A0011221

Hexagon wrench

A0011222

Meaning

Allen key

4 Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Document information

1.2.4

Symbols for certain types of information

Symbol Meaning

Permitted

Indicates procedures, processes or actions that are permitted.

A0011182

A0011184

Forbidden

Indicates procedures, processes or actions that are forbidden.

Tip

Indicates additional information.

A0011193

Reference to documentation

A0015482

Reference to page

A0015484

Reference to graphic

,

A0015487

…

A0031595

Series of steps

Result of a sequence of actions

A0018343

Visual inspection

A0015502

1.2.5

Symbols in graphics

Symbol

1, 2, 3, 4, ...

Meaning

Item numbers

Series of steps

, …

A0031595

A , B , C , D , ...

Views

1.2.6

Symbols at the device

Symbol

A0019159

Meaning

Safety instructions

Observe the safety instructions contained in the associated Operating Instructions.

1.3

Registered trademarks

KALREZ, VITON, TEFLON

Registered trademarks of E.I. Du Pont de Nemours & Co., Wilmington, USA

TRI-CLAMP

Registered trademark of Ladish & Co., Inc., Kenosha, USA

FOUNDATION TM Fieldbus

Registered trademark of the FieldComm Group, Austin, USA

GORE-TEX ®

Registered trademarks of W.L. Gore & Associates, Inc., USA

Endress+Hauser 5

Document information

1.4


Terms and abbreviations

1

2

3

4 p

LRL

0

LRV URV URL MWP OPL

A0029505

-

p

-

-

-

3

4

Position Term/Abbreviation

1

2

OPL

MWP

Maximum sensor measuring range

Calibrated/Adjusted measuring span

-

LRL

URL

LRV

URV

TD

Explanation

The OPL (over pressure limit = sensor overload limit) for the sensors depends on the lowest-rated element, with regard to pressure, of the selected components, i.e. the process connection must be taken into consideration in addition to the measuring cell. Also observe pressuretemperature dependency. For the relevant standards and additional notes, see technical information.

The OPL may be applied for a limited time period.

The MWP (maximum working pressure) for the sensors depends on the lowest-rated element, with regard to pressure, of the selected components, i.e. the process connection has to be taken into consideration in addition to the measuring cell. Also observe pressure-temperature dependency. For the relevant standards and additional notes, see technical information.

The MWP may be applied for an unlimited time.

Range between LRL and URL

This span is the maximum calibratable/adjustable measuring span.

Range between LRV and URV

Factory setting: 0...URL

Other calibrated spans can be ordered with customised settings.

Pressure

Lower range limit

Upper range limit

Lower range value

Upper range value

Turn down

6 Endress+Hauser


1.5

Turn down calculation

Document information

LRL LRV

1 = 2

URV

3

URL

A0029545

Fig. 1:

1

2

3

Calibrated/Adjusted measuring span

Zero-based span

Upper range limit

Example

• Sensor: 10 bar (150 psi)

• Upper range limit (URL) = 10 bar (150 psi)

Turn down (TD):

TD =

|URV

URL

-

• Calibrated/Adjusted measuring span: 0...5 bar

(0...75 psi)

• Lower range value (LRV) = 0 bar

• Upper range value (URV) = 5 bar (75 psi)

LRV|

TD =

10 bar (150 psi)

|5 bar (75 psi) 0 bar (0 psi)|

= 2

In this example, the TD is thus 2:1.

This span is based on the zero point.

Endress+Hauser 7

Basic safety instructions

8


2 Basic safety instructions

2.1

Requirements concerning the staff

The personnel for installation, commissioning, diagnostics and maintenance must fulfill the following requirements:

• Trained, qualified specialists: must have a relevant qualification for this specific function and task

• Are authorized by the plant owner/operator

• Are familiar with federal/national regulations

• Before beginning work, the specialist staff must have read and understood the instructions in the Operating Instructions and supplementary documentation as well as in the certificates (depending on the application)

• Following instructions and basic conditions

The operating personnel must fulfill the following requirements:

• Being instructed and authorized according to the requirements of the task by the facility's owner-operator

• Following the instructions in these Operating Instructions

2.2

Designated use

The Deltabar S is a differential pressure transmitter for measuring differential pressure, flow and level.

2.2.1

Incorrect use

The manufacturer is not liable for damage caused by improper or non-designated use.

Verification for borderline cases:

For special fluids and fluids for cleaning, Endress+Hauser is glad to provide assistance in verifying the corrosion resistance of fluid-wetted materials, but does not accept any warranty or liability.

2.3

Workplace safety

For work on and with the device:

• Wear the required personal protective equipment according to federal/national regulations.

• Switch off the supply voltage before connecting the device.

2.4

Operational safety

Risk of injury!

‣

Operate the device in proper technical condition and fail-safe condition only.

The operator is responsible for interference-free operation of the device.

Conversions to the device

Unauthorized modifications to the device are not permitted and can lead to unforeseeable dangers:

‣

If, despite this, modifications are required, consult with Endress+Hauser.

Repair

To ensure continued operational safety and reliability,

‣

Carry out repairs on the device only if they are expressly permitted.

Observe federal/national regulations pertaining to repair of an electrical device.

‣

Use original spare parts and accessories from Endress+Hauser only.

Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Basic safety instructions

2.5

Hazardous area

To eliminate a danger for persons or for the facility when the device is used in the hazardous area (e.g. explosion protection, pressure vessel safety):

• Based on the nameplate, check whether the ordered device is permitted for the intended use in the hazardous area.

• Observe the specifications in the separate supplementary documentation that is an integral part of these Instructions.

2.6

Product safety

This measuring device is designed in accordance with good engineering practice to meet state-of-the- art safety requirements, has been tested, and left the factory in a condition in which they are safe to operate. It fulfills general safety requirements and legal requirements.

It also conforms to the EC directives listed in the device-specific EC declaration of conformity.

Endress+Hauser confirms this fact by applying the CE mark.

Endress+Hauser 9

Identification Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

3 Identification

3.1

Product identification

The following options are available for identification of the measuring device:

• Nameplate specifications

• Order code with breakdown of the device features on the delivery note

• Enter serial numbers from nameplates in W@M Device Viewer

(www.endress.com/deviceviewer): All information about the measuring device is displayed.

For an overview of the technical documentation provided, enter the serial number from the nameplates in the W@M Device Viewer (www.endress.com/deviceviewer).

3.2

Device designation

3.2.1

Nameplates

• The MWP (maximum working pressure) is specified on the nameplate. This value refers to a reference temperature of +20 °C (68°F) and may be applied to the device for an unlimited time. Observe temperature dependency of the MWP. The pressure values permitted at higher temperatures can be found in the standards EN 1092-1: 2001 Tab. 18

(With regard to their stability-temperature property, the materials 1.4435 and 1.4404 are grouped together under 13EO in EN 1092-1 Tab. 18. The chemical composition of the two materials can be identical.), ASME B 16.5a – 1998 Tab. 2-2.2 F316, ASME B 16.5a –

1998 Tab. 2.3.8 N10276, JIS B 2220.

• For PMD75, the MWP applies for the temperature ranges specified in the Technical

Information TI00382P in the "Ambient temperature range" and "Process temperature limits" sections.

• The test pressure corresponds to the over pressure limit (OPL) of the device = MWP x 1.5.

• The Pressure Equipment Directive (2014/68/EU) uses the abbreviation "PS".

The abbreviation "PS" corresponds to the MWP (maximum working pressure) of the measuring device.

Aluminium housing (T14/T15) and stainless steel housing (T14)

1

2

3

4

Order code:

Ext . order code:

Ser . no .

:

5

6

A0016056

Fig. 2: Nameplate

3

4

1

2

5

6

Device name

Order code (for re-orders)

Extended order code (complete)

Technical data

Serial number (for identification)

Address of manufacturer

10 Endress+Hauser


Devices for use in hazardous areas are fitted with an additional nameplate.

Identification

1

2

A0021222

1

2

Approval-specific information

Document number for safety instructions or drawing number

Devices suitable for oxygen applications or with PVDF process connection are fitted with an additional nameplate.

1

A0022683

1 Application limits

Hygenic stainless steel housing (T17)

1

2

3

4

5

6

Order code:

Ext . ord . cd .

:

Ser . no .

:

7

Endress+Hauser

Fig. 5: Nameplate

5

6

7

3

4

1

2

Device name

Address of manufacturer

Order code (for re-orders)

Extended order code (complete)

Serial number (for identification)

Technical data

Approval-specific information and document number for safety instructions or drawing number

3.2.2

Identifying the sensor type

See parameter "Sensor Meas.Type" in Operating Instruction BA00303P.

A0021552

11

Identification Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

3.3

Scope of delivery

The scope of delivery comprises:

• Deltabar S differential pressure transmitter

• For PMD75 with side flanges made of AISI 316L or C22.8: additionally 2 vent valves, AISI

316L

• PMD75 with side flanges made of AISI 316L or C22.8 and side vent: additionally 4 locking screws, AISI 316L

• For devices with the "HistoROM/M-DAT" option: CD-ROM with Endress+Hauser operating program

• Optional accessories

Documentation supplied:

• Operating Instructions BA00301P and BA00303P are available via the Internet.

 See: www.endress.com  Download.

• Brief Operating Instructions KA01024P

• Fold-out brochure KA00252P

• Final inspection report

• Additional Safety Instructions with ATEX, IECEx and NEPSI devices

• Optional: factory calibration form, test certificates

3.4

CE mark, Declaration of Conformity

The devices are designed to meet state-of-the-art safety requirements, have been tested and left the factory in a condition in which they are safe to operate. The devices comply with the applicable standards and regulations as listed in the EC Declaration of Conformity and thus comply with the statutory requirements of the EC Directives. Endress+Hauser confirms the conformity of the device by affixing to it the CE mark.

3.5

Registered trademarks

KALREZ, VITON, TEFLON

Registered trademarks of E.I. Du Pont de Nemours & Co., Wilmington, USA

TRI-CLAMP

Registered trademark of Ladish & Co., Inc., Kenosha, USA

FOUNDATION TM Fieldbus

Registered trademark of the Fieldbus Foundation Austin, Texas, USA

12 Endress+Hauser


4 Installation

NOTICE

Incorrect handling!

Damage of the device!

‣

Disassembly of the screws with item number (1) is not permissible under any circumstances and will result in loss of warranty.

Installation

Endress+Hauser

1

A0025336

4.1

Incoming acceptance and storage

4.1.1

Incoming acceptance

• Check the packaging and the contents for damage.

• Check the shipment, make sure nothing is missing and that the scope of supply matches your order.

4.1.2

Transport

!

WARNING

Incorrect transport

Housing and diaphragm may be damaged and and there is a risk of injury!

‣

Transport the measuring device to the measuring point in its original packaging or by the process connection (with secure transport protection for the diaphragm).

‣

Follow the safety instructions and transport conditions for devices of more than 18 kg

(39.69 lbs).

‣

Do not use capillaries as a carrying aid for the diaphragm seals.

4.1.3

Storage

The device must be stored in a dry, clean area and protected against impact (EN 837-2).

Storage temperature range:

• –40 to +90°C (–40 to +194 °F)

• Onsite display: –40 to +85°C (–40 to +185°F)

• Separate housing: –40 to +60°C (–40 to +140°F)

4.2

Installation conditions

4.2.1

Dimensions

 For dimensions, please refer to the Technical Information for Deltabar S TI00382P,

"Mechanical construction" section.

13

Installation Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

4.3

Installation instructions

• Due to the orientation of the Deltabar S, there may be a shift in the measured value, i.e. when the container is empty or partially full, the measured value does not display zero. You can correct this zero point shift using the "Zero" key on the electronic insert or externally on the device or via the onsite display.

 ä 36, Section 6.2.1 "Position of the operating elements",

 ä 37, Section 6.2.3 "Function of the operating elements – onsite display connected" and

 ä 65, Section 7.5 "Position adjustment"..

• For FMD77 and FMD78, please refer to Section 4.3.4 "Installation instructions for devices with diaphragm seals (FMD78)",  ä 21.

• General recommendations for routing the pressure piping can be found in DIN 19210

"Methods for measurement of fluid flow; differential piping for flow measurement devices" or the corresponding national or international standards.

• Using a three-way or five-way valve manifold allows for easy commissioning, installation and maintenance without interrupting the process.

• When routing the pressure piping outdoors, ensure that sufficient antifreeze protection is used, e.g. by using pipe heat tracing.

• Install the pressure piping with a monotonic gradient of at least 10%.

• To ensure optimal readability of the onsite display, it is possible to rotate the housing up

to 380°.  ä 29, Section 4.3.9 "Rotating the housing".

• Endress+Hauser offers a mounting bracket for installing on pipes or walls.

 ä 26, Section 4.3.7 "Wall and pipe-mounting (optional)".

4.3.1

Installation for flow measurement

Flow measurement in gases with PMD75

➀

➁

➂

+ –

➃

P01-PMD75xxx-11-xx-xx-xx-000

Fig. 6:

3

4

1

2

Measuring arrangement for flow measurement in gases with PMD75

Deltabar S, here PMD75

Three-way valve manifold

Shutoff valves

Orifice plate or Pitot tube

• Mount the Deltabar S above the measuring point so that the condensate can run off into the process piping.

14 Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Installation

Flow measurement in steam with PMD75

➀

➂

+

➁

➃

–

➂

➄

➅

➄

➅

➆

Fig. 7:

5

6

7

3

4

1

2

Measuring arrangement for flow measurement in steam with PMD75

Condensate traps


Shutoff valves


Separator

Drain valves



• Mount the Deltabar S below the measuring point.

• Mount the condensate traps at the same level as the tapping points and at the same distance to the Deltabar S.

• Prior to commissioning, fill the pressure piping to the level of the condensate traps.

Flow measurement in liquids with PMD75

➀

➁

➃

➄

+

➂

Fig. 8:

3

4

1

2

5

6

Measuring arrangement for flow measurement in liquids with PMD75


Shutoff valves


Separator

Drain valves


➁

–

➃

➄

➅


• Mount the Deltabar S below the measuring point so that the pressure piping is always filled with liquid and gas bubbles can run back into the process piping.

• When measuring in media with solid parts, such as dirty liquids, installing separators and drain valves is useful for capturing and removing sediment.

Endress+Hauser 15


4.3.2

Installation for level measurement

Level measurement in an open container with PMD75 p atm min.

➃

➄

+ p atm

➀

➁

➂


Fig. 9:

3

4

1

2

5

Measuring arrangement for level measurement in an open container with PMD75

The negative side is open to atmospheric pressure


Shutoff valve

Separator

Drain valve

• Mount the Deltabar S below the lower measuring connection so that the pressure piping is always filled with liquid.

• The negative side is open to atmospheric pressure.


Level measurement in an open container with FMD77 max.

p atm min.

2

– p atm

1

+

Fig. 10:

1

2

Measuring arrangement for level measurement in an open container with FMD77

Deltabar S, here FMD77

The negative side is open to atmospheric pressure

A0024164

• Mount the Deltabar S directly on the container.  ä 23, Section 4.3.5 "Seal for flange mounting".

• The negative side is open to atmospheric pressure.

16 Endress+Hauser


Level measurement in a closed container with PMD75

– ➀ max.

Endress+Hauser

Installation min.

+

➀

➁

➂

➃

➂

➃

➄

Fig. 11:

3

4

1

2

5

Measuring arrangement for level measurement in a closed container with PMD75

Shutoff valves

Deltabar S, PMD75

Separator

Drain valves




• Always connect the impulse piping of negative side above the maximum level.


Level measurement in a closed container with FMD77

–

1 max.

min.

4

+

Fig. 12:

3

4

1

2

Measuring arrangement for level measurement in a closed container with FMD77

Shutoff valve

Separator

Drain valve


3

2

A0024163




17

Installation

18


Level measurement in a closed container with FMD78

– max.

min.

+

➀

P01-FMD78xxx-11-xx-xx-xx-000

Fig. 13:

1

Measuring arrangement for level measurement in a closed container with FMD78


• Mount the Deltabar S below the lower diaphragm seal.

 ä 21, Section 4.3.4 "Installation instructions for devices with diaphragm seals (FMD78)".

• The ambient temperature should be the same for both capillaries.

Level measurement is only ensured between the upper edge of the lower diaphragm seal and the lower edge of the upper diaphragm seal.

Level measurement in a closed container with superimposed steam with PMD75 max.

–

➀

➁ min.

+

➁

➂

➃

➄

➃

➄

➅

Fig. 14:

3

4

1

2

5

6

Condensate trap

Shutoff valves


Separator

Drain valves



Measuring arrangement for level measurement in a container with superimposed steam with PMD75



• A condensate trap ensures constant pressure on the negative side.


Endress+Hauser


Level measurement in a closed container with superimposed steam with FMD77 max.

– 1

2

3 min.

4

5

+

Fig. 15:

3

4

1

2

5

Measuring arrangement for level measurement in a container with superimposed steam with FMD77

Condensate trap

Shutoff valve

Separator

Drain valve


A0024162



• A condensate trap ensures constant pressure on the negative side.


4.3.3

Installation for differential pressure measurement

Differential pressure measurement in gases and steam with PMD75

➀

➁

➂

+

➃

➂

Fig. 16:

3

4

1

2

Measuring arrangement for differential pressure measurement in gases and steam with PMD75



Shutoff valves e.g. filter


• Mount the Deltabar S above the measuring point so that the condensate can run off into the process piping.

Endress+Hauser 19


Differential pressure measurement in liquids with PMD75

➁

➃

➄

+

➀

➂

–

➁

➃

➄

➅

Fig. 17:

3

4

1

2

5

6

Measuring arrangement for differential pressure measurement in liquids with PMD75 e.g. filter

Shutoff valves


Separator

Drain valves



• Mount the Deltabar S below the measuring point so that the pressure piping is always filled with liquid and gas bubbles can run back into the process piping.


Differential pressure measurement in gases, steam and liquids with FMD78

➀

➁

+

➁

–

➂

➃

Fig. 18:

3

4

1

2

Diaphragm seal

Capillary e.g. filter



Measuring arrangement for differential pressure measurement in gases, steam and liquids with FMD78

• Mount the diaphragm seal with capillaries at the top or on the side on the piping.

• For vacuum applications: mount the Deltabar S below the measuring point.

 ä 22,

Section 4.3.4, "Vacuum application (FMD78)".

• The ambient temperature should be the same for both capillaries.

20 Endress+Hauser


4.3.4

Installation instructions for devices with diaphragm seals

(FMD78)

• Please note that the hydrostatic pressure of the liquid columns in the capillaries can cause zero point shift. The zero point shift can be corrected.

• Do not clean or touch the process isolating diaphragm of the diaphragm seal with hard or pointed objects.

• Do not remove process isolating diaphragm protection until shortly before installation.

NOTICE

Improper handling!

Damage to the device!

‣

A diaphragm seal and the pressure transmitter together form a closed, oil-filled calibrated system. The fill fluid hole is sealed and may not be opened.

‣

When using a mounting bracket, sufficient strain relief must be ensured for the capillaries in order to prevent the capillary bending down (bending radius  100

(3.94 in)).

‣

Please observe the application limits of the diaphragm seal filling oil as detailed in the

Technical Information for Deltabar S TI00382P, "Planning instructions for diaphragm seal systems" section.

NOTICE

In order to obtain more precise measurement results and to avoid a defect in the device, mount the capillaries as follows:

‣

Vibration-free (in order to avoid additional pressure fluctuations)

Not in the vicinity of heating or cooling lines

‣

Insulate if the ambient temperature is below or above the reference temperature

With a bending radius of  100 mm (3.94 in).

‣

Do not use the capillaries as a carrying aid for the diaphragm seals!

The ambient temperature and length of both capillaries should be the same when using two-sided diaphragm seal systems.

‣

Two diaphragm seals which are the same (e.g. with regard to diameter, material, etc.) should always be used for the negative and positive side (standard delivery).

–

≥

100 mm

+

+ –

Fig. 19:


Mounting Deltabar S, FMD78 with diaphragm seals and capillaries, recommended mounting for vacuum applications: mount pressure transmitter below the lowest diaphragm seal!

Endress+Hauser 21

Installation

22


Vacuum application (FMD78)

For applications under vacuum, Endress+Hauser recommends mounting the pressure transmitter below the diaphragm seal. This prevents vacuum loading of the diaphragm seal caused by the presence of fill fluid in the capillary.

When the pressure transmitter is mounted above the diaphragm seal, the maximum height difference H1 in accordance with the illustrations below must not be exceeded.

–

H1

+

A0023983

Fig. 20: Installation above the lower diaphragm seal

The maximum height difference depends on the density of the filling oil and the smallest ever pressure that is permitted to occur at the diaphragm seal (empty vessel), see illustration below:

[m]

12.0

10.0

1

2

8.0

A 6 .0

4.0

3

4

5

2.0

0.0

5 0 100 200 300 400 5 00 6 00 7 00 800 900 1000

B

3

4

5

1

2

A

B

Fig. 21:

A0023986-en

Diagram of maximum installation height above the lower diaphragm seal for vacuum applications depending on the pressure at the diaphragm seal on the positive side

Height difference H1

Pressure at diaphragm seal

Low temperature oil

Vegetable oil

Silicone oil

High-temperature oil

Inert oil

Endress+Hauser


4.3.5

Seal for flange mounting

NOTICE

Distorted measurement results.

The seal is not allowed to press on the process isolating diaphragm as this could affect the measurement result.

‣

Ensure that the seal is not touching the process isolating diaphragm.

1 2

A0017743

Fig. 22:

1

2

Process isolating diaphragm

Seal

Endress+Hauser 23

Installation

T

P


4.3.6

Heat insulation – FMD77

The FMD77 must only be insulated up to a certain height. The maximum permitted insulation height applies to an insulation material with a heat conductivity  0.04 W/

(m x K) and to the maximum permitted ambient and process temperature. The data were determined under the most critical application "quiescent air".

100 (3.94)

T a

A

T

P

B

T a

1

5 3 (2.09)

77 (3.03)

1

C D

1

30 (1.18)

1

[°F]

T p [°C]

+ 75 2 +400

A

57 2 300

B

T p

392 200

D C

T a

18 5 8 5

+32

−40

−94

0

−40

A, B C, D

− 7 0

− 40 − 3 5 − 30 0 4 5 5 0 55 6 0 +8 5

[°C]

[°F]

T a

− 40 − 31 − 22 +32 113 122 131 140

Fig. 23:

1

Maximum insulation height

Insulation material

Without insulation, the ambient temperature decreases by 5 K.

Position Design Temperature isolator

C

D

A

B

Transmitter horizontally

Transmitter vertical

Transmitter horizontally

Transmitter vertical long long short short

1) Product Configurator, order code for "Process connection"

+18 5

Option 1)

MA

MB

MC

MD

A0025889

24 Endress+Hauser


T

P

1

100 (3.94)

T

U

E

Installation

A0023984

1 Insulation material

Position Design

E U-bracket, Transmitter horizontally

(for devices which require a CRN approval)

F Compact version, Transmitter vertical

1) Product Configurator, order code for "Process connection"

2) In combination with CSA approval.

Ambient temperature T

U

 70 °C (158 °F)

-

Process temperature T

P max. 350 °C (662 °F) , depending on the diaphragm seal filling oil used

Option 1)

2)

5, 6, 7, 8

Endress+Hauser 25


4.3.7

Wall and pipe-mounting (optional)

Endress+Hauser offers the following mounting brackets for installing the device on pipes or walls:

Standard design Heavy duty design

26

A0031326 A0031327

The standard mounting bracket version is not suitable for use in an application subject to vibrations.

The vibration resistance of the reinforced version of the mounting bracket has been tested according to IEC 61298-3, see the "Vibration resistance" section in the technical documentation TI00382P.

When using a valve block, the block's dimensions must be taken into account.

Bracket for wall and pipe mounting including retaining bracket for pipe mounting and two nuts.

material of the screws used to secure the device depend on the order code.

Technical data (e.g. dimensions or order numbers for screws) see accessory document

SD01553P/00/EN.

Please note the following when mounting:

• To prevent the mounting screws from scoring, lubricate them with a multi-purpose grease prior to mounting.

• In the case of pipe mounting, the nuts on the bracket must be tightened uniformly with a torque of at least 30 Nm (22.13 lbf ft).

• For installation purposes, only use the screws with item number (2) (see the following diagram).

Endress+Hauser


NOTICE

Incorrect handling!

Damage of the device!

‣

Disassembly of the screws with item number (1) is not permissible under any circumstances and will result in loss of warranty.

2

1

1

2

A0025335

Endress+Hauser 27


4.3.8

Assembling and mounting the "separate housing" version

6

2

4

5

7

1 r

³

120 mm

P01-xMD7xxxx-11-xx-xx-xx-011

Fig. 25:

4

5

1

2

6

7

"Separate housing" version

In the "separate housing" version, the sensor is supplied with the process connection and cable ready-fitted.

Cable with connection jack

Plug

Locking screw

Housing fitted with housing adapter, included

Mounting bracket suitable for wall and pipe mounting, included

Assembly and mounting

1. Insert the 10-pin connector (item 4) into the corresponding connection jack of the cable

(item 2).

2. Plug the cable into the housing adapter (item 6).

3. Tighten the locking screw (item 6).

4. Mount the housing on a wall or pipe using the mounting bracket (item 7).

When mounting on a pipe, tighten the nuts on the bracket uniformly with a torque of at least 5 Nm (3.69 lbs ft).

Mount the cable with a bending radius (r)  120 mm (4.72 in).

28 Endress+Hauser


4.3.9

Rotating the housing

The housing can be rotated up to 380° by loosening the Allen screw.

T 14 T 15 T 17

Installation

2 3

A0019996

1. T14 housing: Loosen setscrew with a 2 mm (0.08 in) Allen key.

T15 andT17 housing: Loosen setscrew with a 3 mm (0.12 in) Allen key.

2. Rotate housing (max. up to 380 °).

3. Retighten setscrew with 1 Nm (0,74 lbf ft.

4.3.10 Closing the housing cover

NOTICE

Devices with EPDM cover seal - transmitter leakiness!

Mineral-based, animal-based or vegetable-based lubricants cause the EPDM cover seal to swell and the transmitter to become leaky.

‣

The thread is coated at the factory and therefore does not require any lubrication.

NOTICE

The housing cover can no longer be closed.

Damaged thread!

‣

When closing the housing cover, please ensure that the thread of the cover and housing are free from dirt, e.g. sand.If you feel any resistance when closing the cover, check the thread on both again to ensure that they are free from dirt.

Closing the covers on the hygienic stainless steel housing (T17)

Endress+Hauser

+ –


Fig. 26: Closing the covers

The covers for the terminal and electronics compartment are hooked into the housing and closed with a screw. These screws should be tightened handtight (2 Nm (1.48 lbf ft)) to the stop to ensure that the covers sit tightly.

29


4.4

Post-installation check

After installing the device, carry out the following checks:

• Are all screws firmly tightened?

• Are the housing covers screwed down tight?

• Are all locking screws and vent valves firmly tightened?

30 Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Wiring

5 Wiring

5.1

Connecting the device

!

WARNING

Risk of electric shock!

If the operating voltage is > 35 VDC: Dangerous contact voltage at terminals.

‣

In a wet environment, do not open the cover if voltage is present.

!

WARNING

Limitation of electrical safety due to incorrect connection!

• Risk of electric shock and/or explosion in hazardous areas! In a wet environment, do not open the cover if voltage is present.

• When using the measuring device in hazardous areas, installation must comply with the corresponding national standards and regulations and the Safety Instructions or

Installation or Control Drawings.

• Devices with integrated overvoltage protection must be grounded.

• Protective circuits against reverse polarity, HF influences and overvoltage peaks are installed.

• The supply voltage must match the power supply on the nameplate. (  ä 10,

Section 3.2.1 "Nameplates".)

• Switch off the supply voltage before connecting the device.

• Remove the housing cover of the terminal compartment.

• Guide the cable through the gland.  For cable specifications,

 ä 32, Section 5.2.4.

• Connect the device in accordance with the following diagram.

• Screw down the housing cover.

• Switch on the supply voltage.

➀

➃

FF FF

➁

FF

➂

3

4

1

2

5

Fig. 27: Electrical connection of FOUNDATION Fieldbus



Please refer also to Section 5.2.1 "Supply voltage",  ä 32.

Housing

Internal ground terminal

External ground terminal

Supply voltage, for version in non-hazardous area = 9 to 32 V DC

Devices with integrated overvoltage protection are labeled OVP (overvoltage protection) here.

FF

➄

P01-xMx7xxxx-04-xx-xx-xx-009

Endress+Hauser 31

Wiring Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

5.1.1

Connecting devices with 7/8" plug

PIN assignment for 7/8" connector

1

2

3

4

3

4

1

2

PIN

PIN

A0011176

Meaning

Meaning

Signal –

Signal +

Shield

Not assigned

5.2

Connecting the measuring unit

For further information on the network structure and grounding and for further bus system components such as bus cables, see the relevant documentation, e.g. Operating Instructions

BA00013S "FOUNDATION Fieldbus Overview" and the FOUNDATION Fieldbus Guideline.

5.2.1

Supply voltage

• Version for non-hazardous area: 9 to 32 V DC

!

WARNING

Supply voltage might be connected!

Risk of electric shock and/or explosion!

‣

When using the measuring device in hazardous areas, installation must comply with the corresponding national standards and regulations and the Safety Instructions or

Installation or Control Drawings.

‣

All explosion protection data are given in separate documentation which is available upon request. The Ex documentation is supplied as standard with all devices approved for use in explosion hazardous areas.

5.2.2

Current consumption

15.5 mA ±1 mA, switch-on current corresponds to IEC 61158-2, Clause 21.

5.2.3

Terminals

• Supply voltage and internal ground terminal: 0.5 to 2.5 mm 2

• External ground terminal: 0.5 to 4 mm 2 (20 to 12 AWG)

(20 to 14 AWG)

5.2.4

Cable specification

• Use a twisted, shielded two-wire cable, preferably cable type A.

• Outer cable diameter: 5 to 9 mm (0.2 to 0.35 in)

For further information on the cable specifications, see Operating Instructions BA00013S

"FOUNDATION Fieldbus Overview", FOUNDATION Fieldbus Guideline and IEC 61158-2

(MBP).

32 Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Wiring

5.2.5

Grounding and shielding

Deltabar S must be grounded, for example by means of the external ground terminal.

Different grounding and shielding installation methods are available for FOUNDATION

Fieldbus networks such as:

• Isolated installation (see also IEC 61158-2)

• Installation with multiple grounding

• Capacitive installation

5.3

Overvoltage protection (optional)

NOTICE

Device could be destroyed!

Devices with integrated overvoltage protection must be earthed.

Devices showing version "M" in feature 100 "Additional options 1" or feature 110 "Additional options 2" in the order code are equipped with overvoltage protection (  see also Technical

Information TI00382P "Ordering information").

• Overvoltage protection:

– Nominal functioning DC voltage: 600 V

– Nominal discharge current: 10 kA

• Surge current check î = 20 kA as per DIN EN 60079-14: 8/20  s satisfied

• Arrester AC current check I = 10 A satisfied

5.4

Post-connection check

Perform the following checks after completing electrical installation of the device:

• Does the supply voltage match the specifications on the nameplate?

• Is the device connected as per Section 5.1?

• Are all screws firmly tightened?

• Are the housing covers screwed down tight?

As soon as voltage is applied to the device, the green LED on the electronic insert lights up for a few seconds or the connected onsite display lights up.

Endress+Hauser 33

Operation Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

6 Operation

Feature 20 "Output; operation" in the order code provides you with information on the operating options available to you.

Versions in the order code

P FOUNDATION Fieldbus; external operation, LCD

Q FOUNDATION Fieldbus; internal operation, LCD

R FOUNDATION Fieldbus; internal operation

Operation

Via onsite display and 1 key on the exterior of the device

Via onsite display and 1 key on the inside of the device

Without onsite display, 1 key on the inside of the device

6.1

Onsite display (optional)

A 4-line liquid crystal display (LCD) is used for display and operation. The onsite display shows measured values, fault messages and notice messages. The display of the device can be turned in 90° steps. Depending on the orientation of the device, this makes it easy to operate the device and read the measured value.

Functions:

• 8-digit measured value display including sign and decimal point, unit display

• Bar graph as graphic display of the current pressure measured value in relation to the set pressure range in the Pressure Transducer Block. The pressure range is set by means of the

SCALE_IN parameter.

• Easy and complete menu guidance by dividing the parameters into several levels and groups

• Menu guidance

The onsite display is available in English. Needless to say, the device can also be operated in 6 languages (de, en, fr, es, jp, ch) via the DTM or EDD. The FieldCare program is an E+H

DTM operating tool and can be acquired from endress.com.

• Each parameter has a 3-digit ID to aid navigation

• Option of configuring the display according to individual requirements and preferences, such as alternating display, contrast setting, display of other measured values such as sensor temperature

• Comprehensive diagnostic functions (fault and warning message, maximum indicator, etc.)

• Rapid and safe commissioning using Quick Setup menus

34 Endress+Hauser


– + E

O p er a t i n g k e ys

Operation

Measured value display

Fu nct i on n am e Valu e

H e a der li ne

Mai n li ne

I n f or ma t i on li ne

S ymb o l

Editing modes

Ba r g r aph

Pa r am eter

I dent ifi c a t i on n umb er

U n i t

Se l ect i on o p t i on s

Valu e t ha t c a n b e ed i ted

Cu rrent m e asu red valu e

P01-xxxxxxxx-07-xx-xx-en-011

The following table illustrates the symbols that can appear on the onsite display. Four symbols can occur at one time.

Symbol Meaning

Alarm symbol

– Symbol flashing: warning, device continues measuring.

– Symbol permanently lit: error, device does not continue measuring.

Note: The alarm symbol may overlie the tendency symbol.

Lock symbol

The operation of the device is locked. Unlock device,  ä 57, Section 6.7 "Locking/ unlocking operation".

Communication symbol

Data transfer via communication

Square root symbol

Active measuring mode "Flow measurement"

Simulation symbol

Simulation mode is activated. DIP switch 2 for simulation is set to "On".



See also Section 6.2.1 "Position of the operating elements" and  ä 59,

Section 6.8 "Simulation".

Tendency symbol (increasing)

The primary value of the Pressure Transducer Block is increasing.

Tendency symbol (decreasing)

The primary value of the Pressure Transducer Block is decreasing.

Tendency symbol (constant)

The primary value of the Pressure Transducer Block has remained constant over the past few minutes.

Endress+Hauser 35

Operation

36


6.2

Operating elements

6.2.1

Position of the operating elements

On the aluminum housing (T14/T15), the operating key is located either under the protective flap on the exterior of the device or inside on the electronic insert. In the case of the hygienic stainless steel housing (T17), the operating key is always inside on the electronic insert. In addition, there are three operating keys on the optional onsite display.

➀

0%

Zero on

➄ ➅

➀ off

1 2

➁

0 %

Sensor

Z ero

D isp l ay

➂

➃

HW

1 2 on off

Fig. 28:

1


Operating key external, under the protective flap

Operating key for position adjustment (zero point correction) and total reset

P01-xxxxxxxx-19-xx-xx-xx-106

3

4

5

Fig. 29:

1

2

6

Operating keys, internal

Green LED to indicate value is accepted

Operating key for position adjustment (zero point correction) and total reset

Slot for optional display

Slot for optional HistoROM ® /M-DAT

DIP switch for locking/unlocking parameters relevant to the measured value

DIP switch for simulation mode

6.2.2

Function of operating elements

Key(s) Meaning

0%

Zero


– Position adjustment (zero point correction): press key for at least 3 seconds. The

LED on the electronic insert lights up briefly if the pressure applied has been accepted for position adjustment.

 See also the following section "Performing position adjustment on site".

– Total reset: press key for at least 12 seconds. The LED on the electronic insert lights up briefly if a reset is being carried out.

on

1 2 off


– DIP switch 1: for locking/unlocking parameters relevant to the measured value.

Factory setting: off (unlocked)

 ä 57, Section 6.7 "Locking/unlocking operation".

– DIP switch 2: for simulation mode

Factory setting: off (simulation mode off)

 ä 59, Section 6.8 "Simulation"

Performing position adjustment on site

• Operation must be unlocked.  ä 57, Section 6.7 "Locking/unlocking operation".

• The device is configured for the Pressure measuring mode as standard.

– Operation via FF configuration program: In the Pressure Transducer Block, change the measuring mode by means of the PRIMARY_VALUE_TYPE and LINEARIZATION parameters.

– Operation via digital communication: change the measuring mode by means of the

MEASURING MODE parameter.

– You can change the measuring mode by means of the MEASURING MODE parameter.

 ä 64, Section 7.4 "Selecting the language and measuring mode".

Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Operation

• The pressure applied must be within the nominal pressure limits of the sensor. See information on the nameplate.

Perform position adjustment:

1. Pressure is present at device.

2. Press key for at least 3 seconds.

3. If the LED on the electronic insert lights up briefly, the pressure applied has been accepted for position adjustment.

If the LED does not light up, the pressure applied was not accepted. Observe the input

limits. For error messages,  ä 93, Section 9.2 "Diagnostic information on local display".

6.2.3

Function of the operating elements – onsite display connected

Key(s)

O

S

F

O

and

F

Meaning

– Navigate upwards in the picklist

– Edit numerical values or characters within a function

– Navigate downwards in the picklist

– Edit numerical values or characters within a function

– Confirm entry

– Go to next item

Contrast setting of onsite display: increase

Contrast setting of onsite display: reduce

S

and

F

O and

S on

1 2 off


ESC functions:

– Exit the editing mode without saving the altered value

– You are in the menu within a function group: the first time you press the keys simultaneously, you go back one parameter in the function group. Every subsequent time you press the keys simultaneously, you go up one level in the menu.

– You are in the menu on a selection level: every time you press the keys simultaneously, you go up one level in the menu.

Note: For the terms function group, level, selection level,

 ä 51, Section 6.4.1

– DIP switch 1: for locking/unlocking parameters relevant to the measured value.

Factory setting: off (unlocked)

– DIP switch 2: for the simulation mode Factory setting: off (simulation mode off)

Endress+Hauser 37


6.3

FOUNDATION Fieldbus interface

6.3.1

System architecture

The following diagram shows two typical examples of a FOUNDATION Fieldbus network with the associated components.

38

Industrial Network

FF-HSE

BT

PS

LD

BT

PS

FF-H1 SB

BT

FF-H1

BT


Fig. 30: FOUNDATION Fieldbus system architecture with associated components

FF-HSE: High Speed Ethernet, FF-H1: FOUNDATION Fieldbus-H1, LD: Linking Device FF-HSE/FF-H1, PS: Bus Power Supply, SB: Safety

Barrier, BT: Bus Terminator

The system can be connected in the following ways:

– A linking device makes the connection to higher-order fieldbus levels (e.g. High Speed Ethernet (HSE)) possible.

– An FF-H1 connecting card is needed for direct connection to a process control system.

Further information on FOUNDATION Fieldbus can be found in Operating Instructions

BA00013S "FOUNDATION Fieldbus Overview, Installation and Commissioning Guidelines", the FOUNDATION Fieldbus Specification or on the Internet at "http://www. fieldbus.org".

Endress+Hauser


6.3.2

Number of devices

• Endress+Hauser Deltabar S devices meet the requirements specified by the FISCO model.

• Due to the low current consumption, the following can be operated at one bus segment when installation is performed according to FISCO:

Up to HW version 1.10:

– Up to 7 Deltabar S devices for Ex ia, CSA and FM IS applications

– Up to 25 Deltabar S devices in all other applications, e.g. in non-hazardous areas, Ex nA etc.

As of HW version 02.00:

– Up to 6 Deltabar S devices for Ex ia, CSA and FM IS applications

– Up to 24 Deltabar S devices in all other applications, e.g. in non-hazardous areas, Ex nA etc.

The maximum number of measuring devices at one bus segment is defined by their current consumption, the performance of the bus coupler, and the required bus length.

As of hardware version 1.10, you will find a label in the device on the electronic insert.

6.3.3

Operation

You can obtain special configuration and operating programs from various manufacturers for the configuration, such as the FieldCare operating program from Endress+Hauser

 ä 57, Section 6.6 "FieldCare". These configuration programs make it possible to configure

FF functions and all the device-specific parameters. The predefined function blocks allow uniform access to all the network and device data.

6.3.4

Network configuration

You require the following to configure a device and integrate it into an FF network:

• An FF configuration program

• The Cff file (Common File Format: *.cff, *.fhx)

• The device description (Device Description: *.sym, *.ffo, *.sy5, *.ff5)

Pre-defined standard DDs, which can be obtained from FOUNDATION Fieldbus, are available for the basic functions of measuring devices. You require the device-specific DD to be able to access all the functions.

The files for Deltabar S can be acquired as follows:

• Internet Endress+Hauser: http://www.de.endresss.com  Search for FOUNDATION

Fieldbus

• Internet FOUNDATION Fieldbus: http://www.fieldbus.org

• On CD-ROM from Endress+Hauser, order number: 56003896

The device is integrated into the FF network as follows:

• Start the FF configuration program.

• Download the Cff and device description files (ffo, *.sym, *.cff or *.fhx files) to the system.

• Configure the interface, see Note.

• Configure the device for the measuring task and for the FF system.

• For more in-depth information on integrating the device into the FF system, see the description for the configuration software used.

• When integrating the field devices into the FF system, make sure you are using the right files. You can read out the required version by means of the DEV_REV and DD_REV parameters in the Resource Block.

Endress+Hauser 39

Operation

40


6.3.5

Device identification and addressing

FOUNDATION Fieldbus identifies the device using its ID code and automatically assigns it a suitable field address. The identity code cannot be changed.

The device appears in the network display once you have started the FF configuration program and integrated the device into the network. The blocks available are displayed under the device name.

If the device description has not yet been loaded, the blocks report "Unknown" or "(UNK)".

Deltabar S reports as follows:

–

–

➀ ➁

E H_ D eltabarS-XXXXXXXXXXXXXXXX

R S _ XXXXXXXXXXX (R B2 )

TR D1 _ XXXXXXXXXXX ( PCD )

SE R V I CE _ XXXXXXXXXXX

DP _FL OW _ XXXXXXXXXXX

( SE R V I CE )

( DP FL OW )

D IAGN OS TI C _

D I SP LAY_

XXXXXXXXXXX

XXXXXXXXXXX

( D IAGN OS TI C )

( D I SP )

AI 1 _ XXXXXXXXXXX (AI)

AI 2 _ XXXXXXXXXXX

AI3_ XXXXXXXXXXX

(AI)

(AI)

D I_ XXXXXXXXXXX ( D I)

DO _ XXXXXXXXXXX

P I D _ XXXXXXXXXXX

( DO )

( P I D )

ARTH_ XXXXXXXXXXX (AR B )

C HAR_ XXXXXXXXXXX ( SCB )

I SE L_ XXXXXXXXXXX (I SB )

INTG_ XXXXXXXXXXX

AAL M _ XXXXXXXXXXX

(IT B )

(AAL B )

Fig. 31:

1

2

Typical Deltabar S display in a configuration program after the connection has been established

Device name

Serial number

P01-xMx7xxxx-05-xx-xx-xx-005

6.3.6

Deltabar S block model

With FOUNDATION Fieldbus, all the device parameters are categorized according to their functional properties and task and are generally assigned to three different blocks.

A FOUNDATION Fieldbus device has the following block types:

• A Resource Block (device block):

This block contains all the device-specific features of the device.

• One or more Transducer Blocks

A Transducer Block contains all the measuring and device-specific parameters of the device. The measuring principles, such as pressure or totalizers, are mapped in the

Transducer Blocks.

• One or more function blocks:

Function blocks contain the automation functions of the device. A distinction is made between different function blocks such as the Analog Input Block or Proportional Integral

Differential Block (PID). Each of these function blocks is used to execute different application functions.

The function blocks can be connected by means of an FF configuration program, depending on the automation task. The device thus takes on simple control functions, thereby relieving the workload on the higher-order process control system.

Deltabar S has the following blocks:

• Resource Block (device block)

Endress+Hauser


• 5 Transducer Blocks

– Pressure Transducer Block (TRD)

This Block supplies the output variables PRIMARY_VALUE and SECONDARY_VALUE. It contains all the parameters to configure the measuring device for the measuring task such as measuring mode selection, linearization function and unit selection.

– Service Transducer Block

This Block supplies the output variables COUNTER P_PMAX, PRESSURE_1_ MAX_

RESETABLE and PRESSURE_1_AFTER_DAMPING. It also includes all the counters for measuring range overshoot/undershoot for pressure and temperature, minimum and maximum measured values for pressure and temperature and the HistoROM function.

– DP Flow Block

This Block supplies the output variable TOTALIZER_1_VALUE/TOTALIZER 1. It contains all the parameters that are needed to configure this totalizer.

– Display Transducer Block

This Block does not return any output variables. It contains all the parameters for configuring the onsite display such as DISPLAY_CONTRAST.

– Diagnostic Transducer Block

This Block does not return any output variables. It contains

– the simulation function for the Pressure Transducer Block

– parameters to configure the alarm response

– parameters to set the user limits for pressure and temperature.

• 9 function blocks

– 3 Analog Input Blocks (AI)

– Discrete Output Block (DO)

– Discrete Input Block (DI)

– PID Block (PID)

– Arithmetic Block (ARB)

– Signal Characterizer Block (SCB)

– Input Selector Block (ISB)

– Analog Alarm Block (AALB)

– Integrator Block (IT)

In addition to the pre-instantiated blocks already mentioned, the following blocks can also be instantiated:

• 3 Analog Input Blocks (AI)

• 1 Discrete Output Block (DO)

• 1 PID Block (PID)

• 1 Arithmetic Block (ARB)

• 1 Signal Characterizer Block (SCB)

• 1 Input Selector Block (ISB)

• 1 Analog Alarm Block (AALB)

• Integrator Block (IT)

A total of 20 blocks can be instantiated in Deltabar S altogether, including the blocks already instantiated. For instantiating blocks, see the appropriate Operating Instructions of the configuration program used.

Endress+Hauser Guideline BA00062S.

The guideline provides an overview of the standard function blocks that are described in

FOUNDATION Fieldbus Specifications FF 890 - 894.

It is designed to help operators use the blocks implemented in the Endress+Hauser field devices.

Endress+Hauser 41


Block configuration when device is delivered

The block model shown below illustrates the block configuration when the device is delivered.

M e asu red va r iabl e

Se nso r

S ig n al e valua t i on

D ispl a y wi t h s c ali n g

Re sou r c e Block

P re ssu re

Tra nsduc er Block

P r ima r y valu e

S en s or Te mp er a t u re

Ser vic e


D P Flow


T O TAL I ZER 1

D ispl a y


D i a gnos t ic


Ar i t hm et ic Block

A

L

PI n

CH

_

D a

A log Inpu

TY

NN

P E

EL

=

Block

= 1

D i t Block 1 rect

A n a log Inpu t Block 2

CH A NN EL = 2

L _ TY P E = D i rect

A n a log Inpu t Block 3

CH A NN EL = 6

L _ TY P E = D i rect

Inpu t Se l e c t o r

Block

D isc rete Inpu t

Block

D isc rete O u t pu t

Block

S ign a l

C h ara c ter iz er

Block

A n a log A l ar m

Block

In te g rat o r

Block

P01-xMD7xxxx-02-xx-xx-en-004

Fig. 32: Block configuration when device is delivered

The Pressure Transducer Block supplies the Primary Value and the sensor temperature

(secondary value). In the DP Flow Transducer Block, the flow is totalized in the "Flow" measuring mode and output by means of the TOTALIZER_1_VALUE/TOTALIZER 1 parameter. The Primary Value, Secondary Value and TOTALIZER_1_VALUE are each transferred to one Analog Input Block by means of the CHANNEL parameter (  see also the following section).

The Discrete Output, PID, Arithmetic, Signal Characterizer, Input Selector and Analog Alarm

Block are not connected in the as-delivered state.

!

CAUTION

Note Dependencies when setting parameters!

‣

Please note that the links between the blocks are deleted and the FF parameters are reset to the default values following a reset by means of the RESTART parameter in the

Resource Block, "Default" option.

42 Endress+Hauser


6.3.7

Assignment of Transducer Blocks (CHANNEL)

Settings for the Analog Input Block

Process variable Transducer Block Parameter name

Primary Value, a pressure, level or flow value depending on the measuring mode 1)

Pressure Transducer

Block

Secondary Value

(sensor temperature) 2)

Totalizer ("Flow" measuring mode) 3)

Pressure after damping

Maximum measured pressure

Overshoot counter for maximum set user limit for pressure

DP Flow Block

PRIMARY_VALUE

MEASURED_TEMPERA

TURE/TEMP. SENSOR

TOTALIZER_1_VALUE/

TOTALIZER 1

Service Transducer Block PRESSURE_1_AFTER_D

AMPING/PRESSURE

PRESSURE_1_MAX_RE

STABLE/MAX. MEAS.

PRESS.

COUNTER: P > Pmax

CHANNEL parameter in the Analog Input Block

1

2

6

3

4

5

1) Factory setting for Analog Input Block 1



Settings for the Discrete Output Block

Process variable

Totalizer ("Flow" measuring mode)

Overshoot counter for maximum set user limit for pressure 1)

Transducer Block Parameter name

DP Flow Block TOTALIZER_1_VALUE/

TOTALIZER 1

Service Transducer Block COUNTER: P > Pmax 1

CHANNEL parameter in the Discrete Output

Block

2

Endress+Hauser 43


Discrete Input Block settings

Alarm conditions Transducer Block

General device error

Configuration error

Sensor overpressure

Sensor underpressure

Sensor overtemperature

Sensor undertemperature

Process isolating diaphragm broken

Electronic overtemperature

Electronic undertemperature

Temperature transmitter override

Pressure transmitter override

Pmin PROCESS underrun

Pmax PROCESS overrun

Tmin PROCESS underrun

Tmax PROCESS overrun

Diagnostic

Transducer Block

Parameter name

DIAGNOSTIC_CODE

11

12

13

14

15

7

8

9

10

5

6

3

4

1

2

Parameter CHANNEL,

Discrete Input Block

44 Endress+Hauser


6.3.8

Index tables of Endress+Hauser parameters

The following tables list the manufacturer-specific device parameters for the Resource Block, the Transducer Blocks and the Analog Input Blocks. For the FF parameters, see either the

FF Specification or Operating Instructions BA00303P "Description of Device Functions,

Cerabar S/ Deltabar S/Deltapilot S". These parameters are not displayed in the block view in

FieldCare (exception: Analog Input Blocks).

General explanatory remarks

Data type

• DS: data structure, contains data types such as Unsigned8, Octet String etc.

• Bit enumerated

• Float: IEEE 754 format

• Visible String: ASCII coded

• Unsigned:

– Unsigned8: value range = 0 to 255

– Unsigned16: value range = 0 to 65535

Storage Class

• D: dynamic parameter

• N: nonvolatile parameter

• S: static parameter

If this is a write parameter, the MODE_BLK column indicates the block mode in which the parameter can be written. Some parameters can only be written in the OOS block mode.

The "Reset codes" column indicates which reset codes reset the parameter.

Resource Block

Parameter name, option "Symbolic name"

Parameter name, option "Label"

ENP_VERSION

DEVICE_TAG

SERIAL_NUMBER

ORDER_CODE

FIRMWARE_VERSION

SW_LOCK

STATUS_LOCKING

HARDWARE_REVISION

FF_COMM_VERSION

BLOCK_ERR_DESC_1

DEVICE_DIALOG

ELECTRONIC_SERIAL_NUMBER

PROCESS_CONNECTION_TYPE

MAT_PROC_CONN_POS

MAT_PROC_CONN_NEG

SEAL_TYPE

SCI_OCTET_STRING

MS_RESOURCE_DIRECTORY

1) Can be written with service code

ENP version

Device tag

Serial number

Order code

Firmware version

Insert PIN no.

Status locking

Hardware rev.

FF comm. version

Block Error desc.

Device dialog

Electr. serial no.

Proc. conn. type

Mat. proc. conn. +

Mat. proc. conn. -

Seal type

SCI_OCTET_STR

RESOURCE DIRECTORY

81

82

83

84

76

77

78

50

74

75

79

80

44

45

46

47

48

49

Index Data type

Visible String

Visible String

Visible String

Visible String

Visible String

Unsigned16

Unsigned16

Visible String

Visible String

Bit enumerated 4

Unsigned8 1

Visible String 16

Unsigned16

Unsigned16

2

2

2

16

16

32

16

32

16

2

Size

(Byte

)

16

Unsigned16

Unsigned16

Visible String

Unsigned16

2

2

40

20x2

D

D

S

S

S

D

S

S

S

S

S

S

S

S

S

S

S

S

Storage

Class

Read Writ e x x x x x x 1) x



) x



) x x x x x x x x x x x x x x x x x x x

MODE_BLK Reset codes

AUTO, OOS

AUTO, OOS

AUTO, OOS

AUTO, OOS

AUTO, OOS

AUTO, OOS

AUTO, OOS

AUTO, OOS

AUTO, OOS

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

Endress+Hauser 45



MEASURED_TEMPERATURE

MEASURED_TEMPERATURE_UNIT

DEVICE_DIALOG

SW_LOCK

STATUS_LOCKING

LINEARIZATION

SCALE_IN

SCALE_OUT

DAMPING_VALUE

ZERO_POSITION_ADJUST

POSITION_INPUT_VALUE

CALIBRATION_OFFSET

CUSTOMER_UNIT_PRESSURE

CUSTOMER_FACTOR_UNIT_PRESS

LOW_TRIM_MEASURED

HIGH_TRIM_MEASURED

LEVEL_MODE

LINEAR_MEASURAND

LINEARIZED_MEASURAND

COMBINED_MEASURAND

DENSITY_UNIT

HEIGHT_UNIT

CUSTOMER_HEIGHT_UNIT

CUSTOMER_UNIT_FACTOR_HEIGHT

VOLUME_UNIT

CUSTOMER_UNIT_VOLUME

CUSTOMER_UNIT_FACTOR_VOLUME

MASS_UNIT

CUSTOMER_UNIT_MASS

CUSTOMER_UNIT_FACTOR_MASS

CALIBRATION_MODE

ADJUST_DENSITY

ZERO_POSITION

EMPTY_CALIBRATION

FULL_CALIBRATION

TANK_VOLUME

TANK_HEIGHT

HUNDRED_PERCENT_VALUE

LEVEL_MIN

LEVEL_MAX

PROCESS_DENSITY

LINEARIZATION_TABLE_SELECTION

LINEARIZATION_EDIT_MODE

LINEARIZATION_TABLE_PRE_EDIT

LINEARIZATION_TABLE_INDEX

LINEARIZATION_TABLE_X_VALUE

LINEARIZATION_TABLE_Y_VALUE

LINEARIZATION_TABLE_POST_EDIT

LINEARIZATION_TABLE_POST_VIEW

LEVEL_TANK_DESCRIPTION

SENSOR_PRESSURE

PRESSURE

LEVEL_BEFORE_LINEARISATION

Pressure Transducer Block


Temperature

Temp. eng. unit

Device dialog

Insert PIN no.

Status locking

Linearization

Scale In

Scale Out

Damping value

Pos. zero adjust

Pos. input value

Calib. offset

Customer unit P

Cust. unit. fact. P

Lo trim measured

Hi trim measured

Level mode

Lin. measurand

Lin. measurand

Comb. measurand

Density unit

Height unit

Customer unit H

Cust. unit. fact. H

Unit volume

Customer unit V

Cust. unit. fact. V

Unit mass

Customer unit M

Cust. unit. fact. M

Calibration mode

Adjust density

Zero position

Empty calib. level easy

Full calib. level easy

Tank volume

Tank height

100% point

Level Min.

Level Max.

Process density

Table selection

Edit table

Editor table

Line numb:

X-value:

Y-value:

Table editor

Measuring table

Tank description

Sensor pressure

Pressure

Level before lin

78

79

80

76

77

81

82

83

84

44

52

53

54

49

50

51

45

46

47

48

58

59

60

55

56

57

74

75

70

71

72

67

68

69

73

61

62

63

64

65

66

Visible String 8

Float

Float

Float

Unsigned8

Unsigned8

Unsigned8

Unsigned8

Unsigned16 2

Unsigned16 2

Visible String 8

1

1

1

4

4

4

1

Float 4

Unsigned16 2

Visible String 8

Float 4

Unsigned16 2

Visible String 8

Float

Unsigned8

Float

Float

Float

Float

Float

Float

Float

Float

Float

Float

Unsigned8

Unsigned8

Unsigned8

1

1

4

4

4

4

4

4

1

8

1

4

4

4

4

Unsigned8

Float

Float

Unsigned8

Unsigned8

Visible String 32

Float

Float

Float

4

4

4

4

1

1

1

4

36

37

38

39

40

41

42

43

33

34

35

Index Data type Size

(Byte)

32 DS-65 5

Unsigned16 2

Unsigned8 1

Unsigned16 2

S

D

S

Storage

Class

D x x x

Read Writ e x x x

MODE_BLK

OOS

AUTO, OOS,

MAN

Unsigned16 2

Unsigned8 2

DS-68

DS-68

Float

Unsigned8

Float

1

4

11

11

4

Float 4

S

S

S

D

S

D

S

S x x x x x x x x x x x x x x x

OOS

OOS

OOS

OOS

OOS

OOS

OOS x x x x x x x x x x x x x x x x x x x x x x x x x x x x x

AUTO, OOS,

MAN

OOS x OOS

OOS

OOS

OOS

OOS

OOS

AUTO, OOS,

MAN

OOS

OOS

AUTO, OOS,

MAN

OOS

OOS

AUTO, OOS,

MAN

OOS

OOS

OOS

OOS

OOS

OOS x x x x

OOS

OOS

OOS

OOS

OOS

OOS

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN x x

AUTO, OOS,

MAN

OOS

AUTO, OOS,

MAN

AUTO, OOS,

MAN

S

D

D

D

S

S

D

D

D

S

S

S

S

S

S

S

S

S

S

S

S

S

S

S

S

S

S

D

S

S

S

S

S

S

S

S

S

S

S

S

S x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x

Reset codes

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864

7864, 333

7864

7864

7864, 333

7864

7864

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864

7864, 333,

2509

7864, 333,

2509

7864

7864

2509

2509

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864

7864

7864

7864

46 Endress+Hauser



SENSOR_MEAS_TYPE

LEVEL_SELECTION

HEIGHT_UNIT_EASY

OUTPUT_UNIT_EASY

CALIBRATION_MODE_EASY

DENSITY_UNIT_EASY

ADJUST_DENSITY_EASY

EMPTY_HEIGHT_EASY

FULL_HEIGHT_EASY

PROCESS_DENSITY_EASY

MEASURED_LEVEL_EASY

FULL_CALIBRATION_EASY

EMPTY_CALIBRATION_EASY

FULL_PRESSURE_EASY

EMPTY_PRESSURE_EASY


Sensor meas. type

Level mode

Height unit

Output unit

Calibration mode level easy

Density unit level easy 90

Adjust density level easy 91

Full calib. level easy 92


86

87

88

89

Process density level easy 94

Meas. level easy 95


Full calib. level easy

Full pressure

Empty pressure

97

98

99


(Byte)

85 Unsigned16 2

Unsigned8 1

Unsigned16 2

Unsigned16 2

Unsigned8 1

Unsigned16 2

Float

Float

Float

4

4

4

Float

Float

Float

Float

Float

Float

4

4

4

4

4

4

S

S

S

D

D

S

S

S

S

S

S

S

S

S

Storage

Class

D x x x x

Read Writ e x x x x x x x x x x x x x x x x x x x x x x x x

MODE_BLK

OOS

OOS

OOS

OOS

OOS

OOS

OOS

OOS

OOS

OOS

OOS

OOS

OOS


DEVICE_DIALOG

SW_LOCK


Device dialog

Insert PIN no.

STATUS_LOCKING

CONFIGURATION_COUNTER

ELECTRONICS_TEMPERATURE

ELECTRONICS_TEMP_LOW_LIMIT

ELECTRONICS_TEMP_HIGH_LIMIT

PMAX_PROC_CONN

Status locking

Config recorder

Pcb temperature

Allowed min. temp

Allowed max temp

Pmax proc. conn.

SENSOR_MEAS_TYPE

SENSOR_MIN_ABSOLUTE_LIMIT

SENSOR_MAX_ABSOLUTE_LIMIT

SENSOR_TEMP_LOW_LIMIT

SENSOR_TEMP_HIGH_LIMIT

SENSOR_HARDWARE_REV

COUNTER P_MAX

MAX_MEASURED_PRESSURE

COUNTER_PMIN

MIN_MEASURED_PRESSURE

Sensor meas. type

Pmin sensor. damage

Pmax sensor. damage

Tmin sensor

Tmax sensor

Sens. H/ware rev.

Counter: P> Pmax

Max. meas. press.

Counter: P < Pmin

Min. meas. press.

COUNTER_TMAX

MAX_MEASURED_TEMP

COUNTER_TMIN

MIN_MEASURED_TEMP

ELECTRONIC_OVER_TEMP_COUNTER

ELECTRONIC_OVER_TEMPERATURE

Counter: T > Tmax

Max. meas. temp.

Counter: T < Tmin

Min. meas. temp.

Pcb count: T > Tmax

Pcb max. temp

ELECTRONIC_UNDER_TEMP_COUNTER Pcb count: T < Tmin

ELECTRONIC_UNDER_TEMPERATURE PCB min. temp.

RESET_PEAK_HOLD Reset peakhold

PRESSURE

CORRECTED_PRESSURE

MEASURED_VALUE_TREND

MAX_TURNDOWN

SENSOR_CHANGES

PRESSURE_PEAK_HOLD_STEP

TEMP_PEAK_HOLD_STEP

ACCELERATION_OF_GRAVITY

CREEP_FLOW_HYST

HISTOROM_SAVING_CYCLE_TIME

HISTOROM_AVAIBLE

DOWNLOAD_SELECTION

HISTOROM_CONTROL

PRESSURE_UNIT

TEMPERATURE_UNIT

Pressure

Corrected press.

Meas. val. trend

Max. turndown

Sensor changes

P. peakhold step

T. peakhold step

Acc. of gravity

Creep flow hyst.

Hist. saving cycl

Historom avail.

Download select.

Historom control

Cal. unit

Temp. eng. unit

Service Transducer Block

45

46

47

48

49

38

39

40

41

42

43

44

50

51

52

32

33

34

29

30

31

35

36

37

24

25

26

27

28

19

20

21

22

23

16

17

18

13

14

15


(Byte)

11

12

Unsigned8 1

Unsigned16 2

D

S

Storage

Class x x

Read Writ e x

MODE_BLK

AUTO, OOS,

MAN

Unsigned16 2

Unsigned16 2

Float 4

Float

Float

Float

4

4

4

S

S

S

D

S

D x x x x x x x AUTO, OOS,

MAN

Unsigned16 2

Float 4

Float

Float

Float

4

4

4

Unsigned8

DS-65

DS-65

Unsigned16 2

Float 4

1

5

5

Unsigned16 2

Float 4

Unsigned16 2

Float 4

Unsigned16 2

Float 4

Unsigned16 2

Float 4

Unsigned8 1

DS-65

Float

Unsigned8

Float

Unsigned16 2

1

4

Float

Float

5

4

4

4

Float

Float

Unsigned8

Unsigned8

Unsigned8

4

4

1

1

1

Unsigned8 1

Unsigned16 2

Unsigned16 2

S

S

S

S

D

D

S

S

D

D

S

S

D

S

S

D

D

D

D

D

D

D

D

D

S

D

D

D

D

S

S

S

S

S x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x 1) x



) x



) x



) x



) x



) x



)

AUTO, OOS,

MAN

OOS

OOS

AUTO, OOS,

MAN

Reset codes

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

7864, 333

Reset codes

7864, 333

Endress+Hauser 47



INPUT_PRESSURE_INVERSION

1) Can be written with service code


Inp.press invers


(Byte)

53 Unsigned8 1

Storage

Class

S

Read Writ e x x



)

MODE_BLK

OOS

Reset codes


DEVICE_DIALOG

DISPLAY_MAINLINE_CONTENT

DISPLAY_MAINLINE_FORMAT

DISPLAY_ALTERNATING_VALUES

DISPLAY_CONTRAST

DISPLAY_LANGUAGE

SIL_DIGITS_TEST_STRING

Display Transducer Block


Device dialog

Main line cont.

Main data format

Alternate data

Display contrast

Language

Digits set


(Byte)

10

11

Unsigned8

Unsigned8

1

1

D

S

Storage

Class x x

Read Writ e x

12

13

14

15

Unsigned8

Unsigned8

Unsigned8

Unsigned8

1

1

1

1

S

S

S

S x x x x x x x x

BLK_MODE

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

16 Visible String 16 D x


DEVICE_DIALOG

SW_LOCK


Device dialog

Insert PIN no.

STATUS_LOCKING

SIMULATION_MODE

SCALE_OUT_UNITS_INDEX

SIMULATED_VALUE

SIMULATION_ERROR_NUMBER

Status locking

Simulation mode

Units index

Simulated value

Sim. error no.

ALARM_STATUS

ALARM_STATUS_WITH_CATEGORY

LAST_DIAGNOSTIC_CODE

LAST_DIAGNOSTIC_CODE_WITH_CATE

GORY

ACKNOWLEDGE_ALARM_MODE

-

Alarm status info

-

Last diag. code info

Ack. alarm mode

ACKNOWLEDGE_ALARM

RESET_ALL_ALARMS

ERROR_NUMBER

SELECT_ALARM_TYPE

ALARM_DELAY

ALARM_DISPLAY_TIME

Ack. alarm

Reset all alarms

Error no.

Select alarm type

Alarm delay

Alarm displ. time

PRESSURE_UNIT

PMIN_ALARM_WINDOW

PMAX_ALARM_WINDOW

TEMPERATURE_UNIT

TMIN_ALARM_WINDOW

TMAX_ALARM_WINDOW

ENTER_RESET_CODE

OPERATING_HOURS

STATUS_HISTORY

HIGHEST_CATEGORY

Cal. unit

Pmin alarm window

Pmax alarm window

Temp. eng. unit

Tmin. alarm window

Tmax. alarm window

Enter reset code

Operating hours

Alarm history

-

Diagnostic Transducer Block

35

36

37

25

26

27

22

23

24

17

18

19

20

21

12

13

14

15

16


(Byte)

10

11

Unsigned8 1

Unsigned16 2

D

S

Storage

Class x x

Read Writ e x

BLK_MODE

AUTO, OOS,

MAN

Unsigned16 2

Unsigned8 1

Unsigned16 2

Float 4

Unsigned16 2

S

D

D

D

D x x x x x x x x

OOS

AUTO, OOS,

MAN

AUTO, OOS,

MAN

Unsigned16 2

Unsigned16 2

Unsigned16 2

Unsigned16 2

Unsigned8 1

D

D

D

D

S x x x x x x

28

29

33

34

30

31

32

Unsigned8

Unsigned8

Unsigned16 2

1

1

Unsigned8

Float

Float

Unsigned16 2

Float 4

Float 4

Unsigned16 2

Float 4

Float 4

Unsigned16 2

1

4

4

D

S

S

D

D

D

S

D

S

S

S

S

S x x x x x x x x x x x x x x x x x x x x x x x x

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

Unsigned32 4

Visible String 18

Unsigned8 1

D

D

D x x x

Reset codes

7864

7864

7864

7864

7864

Reset codes

7864, 333

7864

7864

7864

7864, 333

7864

7864

7864

7864

48 Endress+Hauser



FF912_CONFIG_AREA

FF912_STATUS_SELECT1














FSAFE_TYPE

FSAFE_VALUE

HIHI_ALM_OUT_D

HI_ALM_OUT_D

LO_ALM_OUT_D

LOLO_ALM_OUT_D

ALARM_MODE

ALARM_OUT_D

BLOCK_ERR_DESC_1


DEVICE_DIALOG

SW_LOCK

STATUS_LOCKING

FLOW_MEAS_TYPE

SUPPRESSED_FLOW

STD_FLOW_UNIT

CUSTOMER_UNIT_FLOW

CUSTOMER_UNIT_FACTOR_FLOW

LOW_FLOW_CUT_OFF

SET_LOW_FLOW_CUT_OFF

FLOW_MAX

PRESSURE

MAX_PRESS_FLOW

PRESSURE_UNIT

TOTALIZER_1_VALUE

Endress+Hauser


FF912ConfigArea

Status Select Event 115 39














(Byte)

38 DS271 30

Storage

Class

S

Read Writ e x x

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

Enumerated 1

S

S

S

S

S

S

S

S

S

S

S

S

S x x x x x x x x x x x x x x x x x x x x x x x x x x

BLK_MODE

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

Analog Input Blocks


Fsafe_Type

Fsafe_Value

High high alarm output discrete

High alarm output discrete

Low alarm output discrete

Low low alarm output discrete

Select alarm mode

39

40

41

42

43

Alarm output discrete

Block error description


(Byte)

37 Unsigned8 1

38 Float 4

44

45

DS66

DS66

DS66

DS66

Unsigned8

DS66

2

2

2

2

1

2

Unsigned32 4

Storage

Class

S

S

D

D

D

D

S

D

D

Read Write BLK_MODE x x x x x x x x x x x x x x x x x

OOS, MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

AUTO, OOS,

MAN

Reset codes

7864

7864

7864

7864

7864

7864

7864

7864

7864

7864

7864

7864

7864

7864

Reset codes

DP Flow Block


Device dialog

Insert PIN no.

Status locking

Flow. meas. type

Suppressed flow

Unit flow

Customer unit F

Cust. unit fact. F

Low flow cut-off

Set. l. fl. cut-off

Max. flow

Pressure

Max. press. flow

Cal. unit

Totalizer 1


(Byte)

16

17

18

19

20

21

22

23

24

25

11

12

13

14

15

Unsigned8 1

Unsigned16 2

Unsigned16 2

Unsigned8 1

Float 4

Unsigned16 2

Visible String 8

Float 4

Unsigned8

Float

Float

1

4

4

Float

Float

Unsigned16 2

DS-65 5

4

4

S

S

S

S

S

S

S

D

D

S

D

S

D

D

S

Storage

Class

Read Write BLK_MODE x x x x x x x x x x x x x x x x x x x x x x x x x

OOS

Reset codes

AUTO, OOS, MAN 7864, 333

OOS 7864

AUTO, OOS, MAN 7864

OOS 7864

OOS

OOS

OOS

7864, 333

7864, 333

7864, 333

OOS

OOS

7864

7864, 333

7864, 333

49



TOTALIZER_1_UNIT

TOTALIZER_1_MODE

TOTALIZER_1_FAIL_SAFE_MODE

TOTALIZER_1_RESET

CUSTOMER_UNIT_TOT_1

CUSTOMER_UNIT_FACTOR_TOT_1

TOTALIZER_2_VALUE

TOTALIZER_2_UNIT

TOTALIZER_2_MODE

CUSTOMER_UNIT_TOT_2

CUSTOMER_UNIT_FACTOR_TOT_2


Total. 1 eng. unit

Neg. flow tot. 1

Fail safe mode

Reset totalizer 1

Tot. 1 user unit

Fact. u. u. total. 1

Totalizer 2

Total. 2 eng. unit

Neg. flow tot. 2

Tot. 2 user text

Fact. u. u. total. 2

32

33

34

35

36

27

28

29

30

31


(Byte)

26 Unsigned16 2

Unsigned8

Unsigned8

Unsigned8

Visible String 8

Float 4

1

1

1

Float 4

Unsigned16 2

Unsigned8 1

Visible String 8

Float 4

D

S

S

S

S

S

S

D

S

S

Storage

Class

S

Read Write BLK_MODE x x x x x x x x x x x x x x x x x x x x x

OOS

OOS

Reset codes

7864

7864, 333

OOS

AUTO, OOS, MAN 7864

OOS 7864

OOS

OOS

7864

7864, 333

AUTO, OOS, MAN 7864

OOS 7864

6.3.9

Methods

The FOUNDATION Fieldbus Specification includes the use of methods to make device operation easier. A method is a sequence of interactive steps to be carried out in the specified order so as to configure certain device functions.

The following methods are available for Deltabar S:

• Restart (Resource Block)

• Troubleshooting information, Config. Error No, Alarm Table (Diagnostic Block)

• Peakhold indicator, HistoROM (Service Block)

• Sensor Trim (TRD Block)

For further information on accessing methods, see the description of the FF configuration program used.

50 Endress+Hauser


6.4

Local operation – onsite display connected

If the onsite display is connected, the three operating keys are used to navigate through the operating menu,

 ä 37, Section 6.2.3 "Function of the operating elements – onsite display connected".

6.4.1

Menu structure

The menu is split into four levels. The three upper levels are used to navigate while you use the lowest level to enter numerical values, and select and save options.

The structure of the MEASURING MENU depends on the measuring mode selected, e.g. if

"Pressure" is selected as the measuring mode, only the functions needed for this measuring mode are displayed.

Measured value

GROUP SELECTION

LANGUAGE MEASURING MODE QUICK SETUP

➀

OPERATING MENU

SETTINGS

POSITION ADJUSTMENT BASIC SETUP

➁

EXTENDED SETUP

DISPLAY

➃

POS. ZERO ADJUST

POS. INPUT VALUE

CALIB. OFFSET

➂


3

4

1

2

1st selection level

2nd selection level

Function groups

Parameters

The MEASURING MODE parameter is only displayed via the onsite display on the 1st selection level. In FieldCare, the LANGUAGE parameter is displayed in the DISPLAY group and the parameters for configuring the measuring mode are displayed in the Measuring

Mode menu.

Endress+Hauser 51

Operation

52


6.4.2

Selecting an option

Example: Selecting the "Pressure" measuring mode.

Onsite display Operation

"Flow" has been selected as the measuring mode. The option currently active is indicated by a 3in front of the menu text.

MEASURINGMODE_Flow

Use "+" or "–" to select "Pressure" as the operating mode.

MEASURINGMODE_Press

1. Press "E" to confirm your choice. The option currently active is indicated by a 3 in front of the menu text. (The "Pressure" measuring mode is selected.)

2. Go to the next menu item with "E" .

MEASURINGMODE_Press-1

6.4.3

Editing a value

Example: changing the DAMPING VALUE function from 2.0 s to 30.0 s.  ä 37,

Section 6.2.3 "Function of the operating elements – onsite display connected".


The onsite display indicates the parameter to be modified. The value highlighted in black can be modified. The unit "s" is prespecified and cannot be changed.


1. Press "+" or "–" to enter the editing mode.

2. The first digit is highlighted in black.


1. Use the "+" key to change the digit "2" to "3".

2. Press the "E" key to confirm "3". The cursor goes to the next position (highlighted in black).


The decimal point is highlighted in black. This means you can now edit this digit.


Endress+Hauser


Onsite display

Operation

Operation

1. Press "+" or "–" until "0" is displayed.

2. Press the "E" key to confirm "0".

The cursor goes to the next position.  is displayed and highlighted in black.  See next graphic.


Press "E" to save the new value and exit the editing mode.  See next graphic.


The new value for the damping is 30.0 s.

– Go to the next parameter with "E" .

– Press "+" or "–" to go back to the editing mode.


6.4.4

Accepting pressure present at device as value

Example: performing position adjustment.


The bottom line on the onsite display displays the pressure present, 3.9 mbar in this example.


Use "+" or "–" to switch to the "Confirm" option. The active option is highlighted in black.


Using the "E" key, assign the value (3.9 mbar) to the

POS. ZERO ADJUST parameter. The device confirms the adjustment and goes back to the parameter, here POS.

ZERO ADJUST (see next graphic).


Go to the next parameter with "E" .


Endress+Hauser 53

Operation

54


6.5

HistoROM

®

/M-DAT (optional)

NOTICE

Device could be destroyed!

Detach HistoROM ® /M-DAT from the electronic insert or attach it to the insert in a deenergized state only.

HistoROM ® /M-DAT is a memory module, which is attached to the electronic insert and fulfills the following functions:

• Back-up copy of configuration data

• Copying configuration data from one transmitter to another transmitter

• Cyclic recording of pressure and sensor-temperature measured values

• Recording diverse events, such as alarms, configuration changes, counters for measuring range undershoot and overshoot for pressure and temperature, overshooting and undershooting user limits for pressure and temperature, etc.

• The HistoROM ® /M-DAT can be retrofitted at any time (Order No.: 52027785).

• To analyze and evaluate the data and events saved in the HistoROM ® /M-DAT, you require the Endress+Hauser FieldCare operating program. A CD with the operating program and documentation is provided for devices that were ordered with the "HistoROM/M-DAT" option.

 ä 57, Section 6.6 "FieldCare". It is also possible to copy configuration data from one

transmitter to another transmitter with an FF configuration program.

• The HistoROM data and the data in the device are analyzed once a HistoROM ® /M-DAT is attached to the electronic insert and power is reestablished to the device. During the analysis, the messages "W702, HistoROM data not consistent" and "W706, Configuration in HistoROM and device not identical" can occur. For remedial measures,

 ä 93,

Section 9.2 "Diagnostic information on local display".

6.5.1

Copying configuration data

on

➁ off 1 2

1 2 on off

0%

S ensor

Zero

D i sp l ay

H W

T M

FOUNDATION

H W-Vers

SW-Vers i on :

1

2

➀


1

2

Electronic insert with optional HistoROM ® /M-DAT memory module

Optional HistoROM ® /M-DAT

To copy configuration data from the HistoROM/ operation must be unlocked (DIP switch 1, position "Off", parameter INSERT PIN No = 100). Please refer also

Section 6.7 "Locking/unlocking operation".

® M-DAT to a device or from a device to a HistoROM ® /M-DAT module,

 ä 57,

Local operation via onsite display (optional) or remote operation

Copying configuration data from a device to a HistoROM ®

Operation must be unlocked.

/M-DAT:

1. Disconnect the device from the supply voltage.

2. Remove the protection cap, attach the HistoROM ® /M-DAT to the electronic insert.

3. Reestablish supply voltage to the device.

4. The option selected for the DOWNLOAD SELECT. parameter (OPERATION menu) does not affect uploading from the device to the HistoROM.

Endress+Hauser


Endress+Hauser

Operation

5. Operation via an FF configuration program: using the DAT_HANDLING/ HistoROM

CONTROL parameter in the Service Transducer Block, select the "Device  HistoROM" option for the data transfer direction.

Operation via FieldCare: using the HistoROM CONTROL parameter, select the "Device 

HistoROM" option for the data transfer direction. (Menu path: OPERATING MENU 

OPERATION).

Using the DOWNLOAD SELECT. parameter (OPERATION menu), select which parameters should be overwritten.

The following parameters are overwritten depending on the option selected:

– Configuration copy :

All the parameters apart from the TRANSMITTER SERIAL NO., DEVICE

DESIGNATION and the parameters of the POSITION ADJUSTMENT and PROCESS

CONNECTION group.

– Device replacement:

All the parameters apart from the TRANSMITTER SERIAL NO., DEVICE

DESIGNATION and the parameters of the POSITION ADJUSTMENT and PROCESS

CONNECTION group.

– Electronics replace:

All parameters apart from the parameters of the POSITION ADJUSTMENT group

.

Factory setting: Configuration copy

6. Using the HistoROM CONTROL parameter, select the "Device  HistoROM" option for the data transfer direction.

7. Wait approx. 40 seconds. Configuration data are uploaded from the device to the

HistoROM ® /M-DAT. The device is not restarted.

8. Disconnect the device from the supply voltage again.

9. Detach the memory module.


Copying configuration data from a HistoROM ®

Operation must be unlocked.

/M-DAT to a device :

1. Disconnect the device from the supply voltage.

2. Attach the HistoROM ® /M-DAT to the electronic insert. Configuration data from another device are stored in the HistoROM ® /M-DAT.



CONTROL parameter in the Service Transducer Block, select the "HistoROM  Device" option for the data transfer direction.

Operation via FieldCare: using the HistoROM CONTROL parameter, select the

"HistoROM  Device" option for the data transfer direction (menu path: OPERATING

MENU  OPERATION).

Using the DOWNLOAD SELECT. parameter (OPERATION menu), select which parameters should be overwritten.

The following parameters are overwritten depending on the option selected:

– Configuration copy (factory setting)

All the parameters apart from the DEVICE SERIAL No., DEVICE DESIGN, PD-TAG,

DESCRIPTOR, DESCRIPTION, DEVICE ID, DEVICE ADDRESS and the parameters in the

POSITION ADJUSTMENT, PROCESS CONNECTION, SENSOR TRIM and SENSOR DATA group.

– Device replacement

All the parameters apart from the DEVICE SERIAL No., DEVICE ID, DEVICE DESIGN and the parameters in the POSITION ADJUSTMENT, PROCESS CONNECTION,

SENSOR TRIM and SENSOR DATA group.

– Electronics replace

All parameters apart from the parameters of the SENSOR DATA group.

Factory setting: Configuration copy

55



CONTROL parameter in the Service Transducer Block, select the "HistoROM  Device" option for the data transfer direction.

Operation via FieldCare: using the HistoROM CONTROL parameter, select the

"HistoROM  Device" option for the data transfer direction. (Menu path: OPERATING

MENU  OPERATION).

6. Using the HistoROM CONTROL parameter (OPERATION menu), select the "HistoROM

 Device" option for the data transfer direction.

7. Wait approx. 40 seconds. Configuration data are loaded from the HistoROM ® to the device. The device is restarted.

/M-DAT

8. Before removing the HistoROM ® /M-DAT again from the electronic insert, disconnect the device from the supply voltage.

56 Endress+Hauser


6.6

FieldCare

FieldCare is Endress+Hauser's plant asset management tool based on FDT technology.

You can use FieldCare to configure all Endress+Hauser devices as well as third-party devices which support the FDT standard. Hardware and software requirements you can find on the internet: www.endress.com  select your country  Search: FieldCare  FieldCare

Technical Data.

FieldCare supports the following functions:

• Configuration of transmitters in offline and online mode

• Loading and saving device data (upload/download)

• HistoROM ® /M-DAT analysis

• Documentation of the measuring point

Connection options:

• Service interface with Commubox FXA291 and ToF adapter FXA291 (USB).

• In the "Level Standard" measuring mode, the configuration data that were loaded with FDT upload cannot be written again (FDT download). These data are only used to document the measuring point.

• For further information, see  www.endress.com

6.7

Locking/unlocking operation

Once you have entered all the parameters, you can lock your entries against unauthorized and undesired access.

The operation can be locked/unlocked in the following ways:

• Via a DIP switch on the electronic insert, locally on the display.

• Via communication e.g. FieldCare.

The -symbol on the onsite display indicates that operation is locked. Parameters which refer to how the display appears, e.g. LANGUAGE and DISPLAY CONTRAST, can still be altered.

• If operation is locked by means of the DIP switch, you can only unlock operation again by means of the DIP switch. If operation is locked by means of remote operation e.g.

FieldCare, you can only unlock operation again by means of remote operation.

The table provides an overview of the locking functions:

Locking via

DIP switch

Remote operation

View/read parameter

Yes

Yes

Modify/write via 1)

No

No

Unlocking via

DIP switch

Yes

No

Remote operation

No

Yes

1) Parameters which refer to how the display appears, e.g. LANGUAGE and DISPLAY CONTRAST, can still be altered.

Endress+Hauser 57


6.7.1

Locking/unlocking operation locally via DIP switch

➀

➁ on

➂

1 2 off on

1 2 off

1 2 on o ff

0 %

Sen s or

Z ero

D i sp l ay

HW

TM

F

OUNDATION

HW -V er

S W -V er s i on on

:

:

1

2

– + E


Fig. 34:

1

2

3

"Hardware locking" DIP switch position on the electronic insert

If necessary, remove onsite display (optional)

DIP switch is set to "On": operation is locked.

DIP switch is set to "Off": operation is unlocked (operation possible)

6.7.2

Locking/unlocking operation via remote operation

Locking operation

Unlocking operation

Description

1. Operation via FF configuration program: select SWLOCK parameter in the

Resource Block.

Operation via FieldCare: select INSERT PIN No. parameter.

Menu path: OPERATING MENU  OPERATION  INSERT PIN No.

2. To lock operation, enter "0" for the parameter.

1. Operation via FF configuration program: select SWLOCK parameter in the

Resource Block.

Operation via FieldCare: select INSERT PIN No.parameter.

2. To unlock operation, enter "100" for the parameter.

58 Endress+Hauser


6.8

Simulation

The function of the Analog Input Block, such as input and output scaling, can be simulated as follows:

1. Set the "Simulation" DIP switch on the electronic insert to "On".

2. In the Analog Input Block, select the "Active" option by means of the SIMULATION parameter, ENABLE_DISABLE element.

3. Set the Analog Input Block to the AUTO block mode.

4. Enter the value and status for the SIMULATION_VALUE and SIMULATION_STATUS elements. During the simulation, the output value and status of the Pressure

Transducer Block are replaced by the simulated value and status. The OUT parameter shows the result.

5. End simulation (SIMULATION parameter, ENABLE_DISABLE element, "Disabled" option).

You can check your adjustment for the transmitter by means of the SIMULATION_MODE and SIMULATION_VALUE parameters in the Diagnostic Transducer Block.  See Operating

Instructions BA303 "Description of Device Functions Cerabar S/Deltabar S/Deltapilot S",

SIMULATION_MODE and SIMULATION_VALUE parameter descriptions.

6.9

Factory setting (reset)

• Total reset: Press zero-key for at least 12 seconds. The LED on the electronic insert lights up briefly if a reset is being carried out.

• By entering a certain code, you can completely, or partially, reset the entries for the parameters to the factory settings. (  For the factory settings, see Operating Instructions

BA00303P "Cerabar S/Deltabar S/Deltapilot S, Description of Device Functions").

Enter the code by means of the ENTER RESET CODE parameter (OPERATION menu).

There are various reset codes for the device. The following table illustrates which parameters are reset by the particular reset codes. Operation has to be unlocked to be able to perform a reset (

 ä 57, Section 6.7).

• Any customer-specific configuration carried out by the factory is not affected by a reset

(customer-specific configuration remains). If, after a reset, you wish the parameters to be reset to the factory settings, please contact Endress+Hauser Service.

• The OUT Value parameter may have to be rescaled after resetting with code 7864. See also

 ä 79, Section 7.9 "Scaling the OUT parameter".

6.9.1

Performing reset via an FF configuration program

If operating via an FF configuration program, enter the code by means of the

RESET_INPUT_VALUE/ENTER RESET CODE parameter in the Diagnostic Transducer Block.

The index tables on  ä 45 ff. indicate which parameters are reset by the particular reset

code.

• The RESET FF parameter gives you the option of deleting links between function blocks and resetting FF parameters to default values and manufacturer-specific parameters to the factory setting.  See also Operating Instructions BA00303P, RESTART parameter description.

Endress+Hauser 59

Operation

60


6.9.2

Performing reset via the FieldCare operating program

If operating via FieldCare, enter the code via the ENTER RESET CODE parameter (menu path:

OPERATING MENU  OPERATION).

The following table illustrates which parameters are reset by the particular reset codes.

Reset code

7864

333

2710

2509

1846

8888

Description and effect 1)

Total reset

– This reset resets the following parameters:

– POSITION ADJUSTMENT function group

– BASIC SETUP function group

– EXTENDED SETUP function group

– LINEARIZATION function group (an existing linearization table is deleted)

– TOTALIZER SETUP function group

– OUTPUT group

– INFO function group, TAG_DESC parameter

– MESSAGES function group

– All configurable messages ("Error" type) are set to "Warning".

 ä 93, Section 9.2 "Diagnostic information on local display" and

 ä 108,

Section 9.6 "Response of outputs to errors".

– USER LIMITS function group

– Any simulation which may be running is ended.

– The device is restarted.

User reset

– This reset resets the following parameters:


– BASIC SETUP function group, apart from customer-specific units

– EXTENDED SETUP function group

– TOTALIZER SETUP function group

– OUTPUT group



Reset Level measuring mode

– Depending on the settings for the LEVEL MODE, LIN MEASURAND, LINd

MEASURAND or COMB. MEASURAND parameters, the parameters needed for this measuring task will be reset.



Example LEVEL MODE = linear and LIN. MEASURAND = level

• HEIGHT UNIT = m

• CALIBRATION MODE = wet

• EMPTY CALIB. = 0

• FULL CALIB. = sensor end value converted to mH

2 sensor : 50.99 mH

2

O

O, e.g. for a 500 mbar (7.5 psi)

Sensor adaption reset

– This reset resets the upper and lower sensor calibration limit and the value for position adjustment.


– PRESSURE_1_LOWER_CAL/LO_TRIM_MEASURED and

PRESSURE_1_HIGHER_TRIM_MEASURED/HI_TRIM_MEASURED parameters

These parameters are not available by means of the FieldCare operating program.



Display reset

– This reset resets all parameters which have to do with how the display appears

(DISPLAY group).



HistoROM reset

The measured value and event buffers are deleted. During the reset, the HistoROM has to be attached to the electronic insert.

Endress+Hauser


Reset code

62

Description and effect 1)

PowerUp reset (warm start)

– This reset resets all the parameters in the RAM. Data are read back anew from the

EEPROM (processor is initialized again).



1) The table uses the group and parameter names as they appear in FieldCare. See

 ä 45, Section 6.3.8

"Index tables of Endress+Hauser parameters" for the assignment of the FieldCare parameter names and the

FF configuration program.

Endress+Hauser 61

Commissioning

62


7 Commissioning

The device is configured for the Pressure measuring mode as standard. The measuring range and the unit in which the measured value is transmitted correspond to the specifications on the nameplate.

!

WARNING

Exceeding the maximum allowable working pressure!

Risk of injury due to bursting of parts! Warning messages are generated if pressure is too high.

‣

If a pressure greater than the maximum permitted pressure is present at the device, the messages "E115 Sensor overpressure" and "E727 Sensor pressure error - overrange" are output in succession! Use the device only within the sensor range limits

NOTICE

Shortfall of the allowable working pressure!

Output of messages if pressure is too low.

‣

If a pressure smaller than the minimum permitted pressure is present at the device, the messages "E120 Sensor low pressure" and "E727 Sensor pressure error - overrange" are output in succession! Use the device only within the sensor range limits

7.1

Configuring messages

• The messages E727, E115 and E120 are "Error"-type messages and can be configured as a

"Warning" or an "Alarm". The factory setting for these messages is "Warning". This setting prevents the BAD status from being transmitted in applications (e.g. cascade measurement) where the user is aware of the risk of the sensor range being overshot.

• We recommend setting messages E727, E115 and E120 to "Alarm" in the following instances:

– It is not necessary to violate the sensor range for the measuring application.

– A position adjustment must be carried out that has to correct a large measured error as a result of the orientation of the device.

7.2

Function check

Carry out a post-installation and a post-connection check as per the checklist before commissioning the device.

• "Post-installation check" checklist



see Section 4.4

• "Post-connection check" checklist



see Section 5.4

7.3

Commissioning via an FF configuration program

• The device is configured for the Pressure measuring mode as standard. The measuring range and the unit in which the measured value is transmitted, as well as the digital output value of the Analog Input Block OUT, correspond to the data on the nameplate. Following

a reset with code 7864, the OUT parameter may have to be rescaled (79, Section 7.9

"Scaling the OUT parameter").

• The standard order configuration is illustrated on

 ä 40, Section 6.3.6 "Deltabar S block model".

1. Switch on the device.

2. Note the DEVICE_ID.

 ä 40, Section 6.3.5 "Device identification and addressing" and

 ä 10, Section 3.2.1 "Nameplates" for the device serial number.

3. Open the configuration program.

4. Load Cff and device description files into the host system or the configuration program.

Make sure you are using the right system files.

Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Commissioning

5. Identify the device using the DEVICE_ID (  see Point 2). Assign the desired tag name to the device by means of the PD_TAG parameter.

Configuring the Resource Block

1. Open the Resource Block.

2. If necessary, disable the lock for device operation.  ä 57, Section 6.7 "Locking/ unlocking operation". Operating is unlocked as standard.

3. If necessary, change the block name. Factory setting: RS_452B481009-xxxxxxxxxxx

4. If necessary, assign a description to the block by means of the TAG_DESC parameter.

5. If necessary, change other parameters as per the requirements.

Configuring the Transducer Blocks

Deltabar S has the following Transducer Blocks:

• Pressure Transducer Block

• Service Transducer Block

• DP Flow Block

• Display Transducer Block

• Diagnostic Transducer Block

The explanation that follows is an example for the Pressure Transducer Block.


2. Set the block mode to OOS using the MODE_BLK parameter, TARGET element.

3. Configure the device in accordance with the measuring task.  See also these

Operating Instructions Section 7.4 to Section 7.9.

4. Set the block mode to Auto using the MODE_BLK parameter, TARGET element.

The block mode must be set to "Auto" for the Pressure, Service and DP Flow Block for the measuring device to function correctly.

Configuring the Analog Input Blocks

Deltabar S has 3 Analog Input Blocks that can be assigned as required to the various process variables.


2. Set the block mode to OOS using the MODE_BLK parameter, TARGET element.

3. Use the CHANNEL parameter to select the process variable which should be used as the input value for the Analog Input Block. The following settings are possible:

– CHANNEL = 1: Primary value, a pressure, level or flow value depending on the measuring mode selected

– CHANNEL = 2: Secondary value, here the sensor temperature

– CHANNEL = 6: Totalizer 1

Factory setting:

– Analog Input Block 1: CHANNEL = 1: Primary Value (pressure measured value)

– Analog Input Block 2: CHANNEL = 2: Secondary Value (sensor temperature)

– Analog Input Block 3: CHANNEL = 6: Totalizer 1

4. Use the XD_SCALE parameter to select the desired unit and the block input range for

the process variable.  ä 79, Section 7.9 "Scaling the OUT parameter".

Make sure that the unit selected suits the process variable selected. If the process variable does not suit the unit, the BLOCK_ERROR parameter reports "Block

Configuration Error" and the block mode cannot be set to "Auto".

5. Use the L_TYPE parameter to select the type of linearization for the input variable

(factory setting: Direct).

Make sure that the settings for the XD_SCALE and OUT_SCALE parameters are the same for the "Direct" linearization type. If the process values and units do not match, the

BLOCK_ERROR parameter reports "Block Configuration Error" and the block mode cannot be set to "Auto".

Endress+Hauser 63

Commissioning Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

6. Enter the alarm and critical alarm messages by means of the HI_HI_LIM, HI_LIM,

LO_LIM and LO_LO_LIM parameters. The limit values entered have to be within the value range specified for the OUT_SCALE parameter.

7. Specify the alarm priorities by means of the HI_HI_PRI, HI_PRI, LO_LO_PRI and LO_PRI parameters. Reporting to the field host system only takes place with alarms with a priority greater than 2.

8. Set the block mode to Auto using the MODE_BLK parameter, TARGET element. For this purpose, the Resource Block must also be set to the "Auto" block mode.

Additional configuration

1. Depending on the control or automation task, configure additional function blocks and output blocks.  See also Operating Instructions BA00303P "Description of Device

Functions Cerabar S/Deltabar S/Deltapilot S".

2. Link the function blocks and output blocks.

3. After specifying the active LAS, download all the data and parameters to the field device.

7.4

Selecting the language and measuring mode

7.4.1

Local operation

The MEASURING MODE parameter is on the 1st selection level.  ä 51, Section 6.4.1

"Menu structure".

The following measuring modes are available:

• Pressure

• Level

• Flow

7.4.2

Selecting the language and measuring mode by means of the

FieldCare operating program

Selecting the measuring mode

The parameters for setting the measuring mode are displayed in the FieldCare "Measuring mode" menu:

64

Fig. 35: "Measuring mode" menu

Betriebsart-de

Endress+Hauser


The following measuring mode settings are available:

Primary Value Type

Pressure

Flow

Level, mass, volume

Level, mass, volume

Level, mass, volume, tank content in %



Linearization

None

Root function

None

None

None

Level linearized

Level combined

Level selection

-

-

Level Easy Pressure

Level Easy Height

Level Standard

Level Standard

Level Standard

Selecting the language

Select the menu language for FieldCare using the "Language Button" in the configuration window. Select the menu language for the FieldCare frame by means of the "Extra" menu 

"Options" "Display"  "Language".

The following languages are available:

• Deutsch

• English

• Français

• Español

• Chinese

• Japanese

7.5

Position adjustment

Due to the orientation of the device, there may be a shift in the measured value, i.e. when the container is empty or partly filled, the measured value parameter does not display zero.

There are three options to choose from when performing position adjustment.

• Onsite display menu path: GROUP SELECTION  OPERATING MENU  SETTINGS 

POSITION ADJUSTMENT

• FieldCare menu path: OPERATING MENU  SETTINGS  POSITION ADJUSTMENT

7.5.1

Performing position adjustment via the onsite display or

FieldCare

The parameters listed in the following table can be found in the POSITION ADJUSTMENT group (menu path: OPERATING MENU  SETTINGS  POSITION ADJUSTMENT).

Parameter name

POS. ZERO ADJUST

Entry

Description

Position adjustment – the pressure difference between zero (set point) and the measured pressure need not be known.

Example:

– MEASURED VALUE = 2.2 mbar (0.032 psi)

– Correct the MEASURED VALUE via the POS. ZERO ADJUST parameter with the

"Confirm" option. This means that you are assigning the value 0.0 to the pressure present.

– MEASURED VALUE (after pos. zero adjust) = 0.0 mbar

The CALIB. OFFSET parameter displays the resulting pressure difference (offset) by which the MEASURED VALUE was corrected.

Factory setting:

0.0

Endress+Hauser 65


Parameter name

POS. INPUT VALUE

Input

CALIB. OFFSET

Entry

Description

Position adjustment – the pressure difference between zero (set point) and the measured pressure need not be known. To correct the pressure difference, you need a reference measurement value (e. g. from a reference device).

Example:


– For the POS. INPUT VALUE parameter, specify the desired set point for the

MEASURED VALUE, e.g. 2.0 mbar (0.029 psi).

(The following applies: MEASURED VALUE new

= POS. INPUT VALUE)

– MEASURED VALUE (after entry for POS. INPUT VALUE) = 2.0 mbar (0.029 psi)

– The CALIB. OFFSET parameter displays the resulting pressure difference (offset) by which the MEASURED VALUE was corrected.

The following applies: CALIB. OFFSET = MEASURED VALUE old

– POS. INPUT

VALUE, here: CALIB. OFFSET= 0.5 mbar (0.0073 psi) – 2.0 mbar (0.029 psi) = – 1.5 mbar (0.022 psi)

Factory setting:

0.0

Position adjustment – the pressure difference between zero (set point) and the measured pressure is known. (A reference pressure is not present at the device.)

Example:


– Via the CALIB. OFFSET parameter, enter the value by which the MEASURED

VALUE should be corrected. To correct the MEASURED VALUE to 0.0 mbar, you must enter the value 2.2 here.

(The following applies: MEASURED VALUE new

= MEASURED VALUE

CALIB. OFFSET)

– MEASURED VALUE (after entry for calib. offset) = 0.0 mbar old

–

Factory setting:

0.0

66 Endress+Hauser


7.6

Flow measurement

7.6.1

Preparatory steps

• The Deltabar S PMD75 is usually used for flow measurement.

• Before calibrating the Deltabar S, the pressure piping must be cleaned and the device filled with fluid.  See the following table.

Valves

1 Close 3.

Meaning Preferred installation

2 Fill measuring system with fluid.

Open A, B, 2, 4.

Fluid flows in.

3 Clean pressure piping if necessary 1) :

– by blowing out with compressed air in the case of gases

– by rinsing out in the case of liquids.

I

II

6

+

3

7

–

2 4

Close 2 and 4.

Open 1 and 5.

Close 1 and 5.





Block off device.

Blow out/rinse out pressure piping.

Close valves after cleaning.

4 Vent device.

Open 2 and 4.

Close 4.

Open 3.

Open 6 and 7 briefly, then close them again.

Introduce fluid.

Close negative side.

Balance positive and negative side.

Fill device completely with fluid and remove air.

5 Carry out pos. zero adjustment if the following conditions are met. If the conditions are not met, then do not carry out the pos. zero adjustment until after step 6.

 ä 69, Section 7.6.3 and

 ä 65, Section 7.5.

Conditions:

– The process cannot be blocked off.

– The tapping points (A and B) are at the same geodetic height.

6 Set measuring point to operation.

Close 3.

Open 4.

Shut off positive side from negative side.

Connect negative side.

Now

– 1

 , 3, 5  , 6 and 7 are closed.

– 2 and 4 are open.

– A and B are open (if present).

7 Carry out pos. zero adjustment if the flow can be blocked off. In this case, step 5 is not applicable.

 ä 69,

Section 7.6.3 and  ä 65, Section 7.5.

8 Carry out calibration.

 ä 68, Section 7.6.2

III

+

A

1

I

II

+

A

2

6

+

3

7

–

–

B

4

B

5

III

Fig. 36:


Above: preferred installation for gases

Below: preferred installation for liquids

I

II

Deltabar S PMD75


III Separator

1, 5 Drain valves

2, 4 Inlet valves

3 Equalizing valve

6, 7 Vent valves on Deltabar S

A, B Shutoff valves

1) For arrangement with 5 valves

Endress+Hauser 67


7.6.2

Information on flow measurement

In the "Flow" measuring mode, the device determines a volume or mass flow value from the differential pressure measured. The differential pressure is generated by means of primary devices such as Pitot tubes or orifice plates and depends on the volume flow or mass flow.

Four flow measuring modes are available: volume flow, norm volume flow (European norm conditions), standard volume flow (American standard conditions) and mass flow.

In addition, the Deltabar S software is equipped with two totalizers as standard. The totalizers add up the volume or the mass flow. The counting function and the unit can be set separately for both totalizers. The first totalizer (totalizer 1) can be reset to zero at any time while the second (totalizer 2) totalizes the flow from commissioning onwards and cannot be reset.

• By means of the FieldCare operating program, a Quick Setup menu is available for each of the measuring modes pressure, level and flow which guides you through the most important basic functions. With the setting in the MEASURING MODE parameter, you

specify which Quick Setup menu should be displayed.  ä 64, Section 7.4 "Selecting the language and measuring mode". No Quick Setup menus are available for the FF

configuration programs.

• For a detailed description of the parameters, see Operating Instructions BA00303P

"Cerabar S/Deltabar S/Deltapilot S, Description of Device Functions"

– FF, Pressure Transducer Block Table

– FF, DP Flow Block Table

– FieldCare, POSITION ADJUSTMENT Table

– FieldCare, BASIC SETUP Table

– FieldCare, EXTENDED SETUP Table

– FieldCare, TOTALIZER SETUP Table

!

WARNING

Changing the measuring mode affects the span (URV)!

This situation can result in product overflow.

‣

If the measuring mode is changed, the span setting (URV) must be verified in the

"Calibration"  "Basic Setup" operating menu and, if necessary, reconfigured!

68 Endress+Hauser


7.6.3

Quick Setup menu for the Flow measuring mode (FieldCare)

M E A S U R E D V AL U E

GRO UP S E L E C T I O N

1 )

LA N G U AG E

1 )

M E A S U R IN G M O D E

1 )


2 )

P re ssu re L e v e l

QUICK S E T UP

Flow

P O S . ZE RO A D JU S T

M AX F LO W

M AX . P R E SS . F LO W

D A MPIN G V AL U E

1 ) O n si te d isplay on ly

2 ) Fi e l d Ca re on ly

O P E RAT IN G M E NU P RO FI L E VI E W

2 )


Fig. 37: Quick Setup menu for the "Flow" measuring mode

Local operation

Measured value display

Onsite display: Switch from the measured value display to GROUP SELECTION with F .

GROUP SELECTION

Select MEASURING MODE.

MEASURING MODE

Select "Flow" option.

GROUP SELECTION

Select QUICK SETUP menu.

POS. ZERO ADJUST

Due to orientation of the device, there may be a shift in the measured value. You correct the MEASURED

VALUE via the POS. ZERO ADJUST parameter with the "Confirm" option, i.e. you assign the value 0.0 to the pressure present.

MAX. FLOW

Enter maximum flow of primary device.

(  See also layout sheet of primary device).

MAX. PRESS. FLOW

Enter maximum pressure of primary device.


DAMPING VALUE

Enter damping time (time constant  ). The damping affects the speed at which all subsequent elements, such as the onsite display, measured value and the

OUT Value of the Analog Input Block react to a change in the pressure.

FieldCare



Measuring Mode

Select the Primary Value Type parameter.

Primary Value Type

Select "Flow" option.

POS. ZERO ADJUST



MAX. FLOW

Enter maximum flow of primary device.


MAX. PRESS. FLOW

Enter maximum pressure of primary device.


DAMPING VALUE



For onsite operation, see also


 ä 51, Section 6.4 "Local operation – onsite display connected".

Endress+Hauser 69


7.7

Level measurement

7.7.1

Preparatory steps

Open container

• The Deltabar S PMD75, and FMD77 are usually suitable for level measurement in an open container.

• FMD77: the device is ready for calibration immediately after opening a shutoff valve (may or may not be present).

• PMD75: before calibrating the device, the pressure piping must be cleaned and filled with fluid.  See the following table.

Valves Meaning

1 Fill container to a level above the lower tap.


Open A.

Open shutoff valve.

3 Vent device.

Open 6 briefly, then close it again.



Now

– B and 6 are closed.

– Axis open.


 ä 73, Section 7.7.2.

Installation

6

A

I

II

B

II

B

+

Deltabar S PMD75

Separator

Vent valves on Deltabar S

Shutoff valve

Drain valve

A

6

+

I

– p atm


70 Endress+Hauser


Closed container

• All Deltabar S versions are suitable for level measurement in closed containers.

• FMD77: the device is ready for calibration immediately after opening the shutoff valves

(may or may not be present).

• FMD78: the device is ready for calibration immediately.


Valves Meaning



Close 3.


Installation

B

Open A and B.

Open shutoff valves.

3 Vent positive side (empty negative side if necessary).

Open 2 and 4.

Introduce fluid on positive side.


Fill positive side completely with fluid and remove air.


Now

– 3, 6 and 7 are closed.

– 2, 4, A and B are open.


 ä 73, Section 7.7.2.

III

+

A

1

I

II

2

6

+

3

I

II

Deltabar S PMD75


III Separator

1, 2 Drain valves

2, 4 Inlet valves


6, 7 Vent valve on Deltabar S

A, B Shutoff valve

7

–

4

5

III


Endress+Hauser 71


Closed container with superimposed steam

• All Deltabar S versions are suitable for level measurement in containers with superimposed steam.

• FMD77: the device is ready for calibration immediately after opening the shutoff valves

(may or may not be present).



Valves Meaning



Open A and B.

Open shutoff valves.

Installation

Fill the negative pressure piping to the level of the condensate trap.

3 Vent device.

Open 2 and 4.

Close 4.

Open 3.

Introduce fluid.






Close 3.



Open 4.

Now

– 3, 6 and 7 are closed.

– 2, 4, A and B are open.


 ä 73, Section 7.7.2.

III

+

A

1

I

II

2

6

+

3

7

–

4

5

B

III

Fig. 40:

I

II

Deltabar S PMD75


III Separator

1, 5 Drain valves

2, 4 Inlet valves



A, B Shutoff valves


Closed container with superimposed steam

72 Endress+Hauser


7.7.2

Information on level measurement

• A Quick Setup menu is available for each of the measuring modes Pressure and Level which guides you through the most important basic functions.  For the "Level" Quick

Setup menu,  ä 75.

• Furthermore, three level modes are available for the level measurement, namely "Level easy pressure", "Level easy height" and "Level standard". For the "Level standard" level mode, you can choose between the "Linear", "Pressure linearized" and "Height linearized" level types. The table in the "Overview of level measurement" section that follows provides you with an overview of the various measuring tasks.

– With regard to the "Level easy pressure" and "Level easy height" level modes, the values entered are not tested as extensively as in the "Level standard" level mode. In the "Level easy pressure" and "Level easy height" level modes, the values entered for EMPTY

CALIBRATION/FULL CALIBRATION, EMPTY PRESSURE/FULL PRESSURE and EMPTY

HEIGHT/FULL HEIGHT have to be at least 1% apart. The value will be rejected with a warning message if the values are too close together . Further limit values are not checked; i.e. the values entered must be appropriate for the sensor and the measuring task so that the measuring device can measure correctly.

– The "Level easy pressure" and "Level easy height" level modes comprise fewer parameters than the "Level standard" mode and are not used to quickly and easily configure a level application.

– Customer-specific units of level, volume and mass, or a linearization table, can only be entered in the "Level standard" level mode.

• For a detailed description of the parameters and configuration examples, see Operating

Instructions BA00303P "Cerabar S/Deltabar S/ Deltapilot S, Description of Device

Functions".

!

WARNING



‣



Endress+Hauser 73


7.7.3

Overview of level measurement

Measuring task

The measured variable is in direct proportion to the measured pressure.

Calibration is performed by entering two pressure-level value pairs.


Calibration is performed by entering the density and two height-level value pairs.


LEVEL

SELECTION/

LEVEL MODE

LEVEL

SELECTION:

Level Easy

Pressure

LEVEL

SELECTION:

Level Easy

Height

LEVEL

SELECTION:

Level standard/

LEVEL MODE :

Linear

The measured variable is not in direct proportion to the measured pressure as, for example, with containers with a conical outlet. A linearization table must be entered for the calibration.

LEVEL

SELECTION:

Level standard/

LEVEL MODE:

Pressure

Linearized

– Two measured variables are required or

– The container shape is given by value pairs, such as height and volume.

The 1st measured variable

%-height or height must be in direct proportion to the measured pressure. The

2nd measured variable volume, mass or % must not be in direct proportion to the measured pressure.

A linearization table must be entered for the 2nd measured variable. The 2nd measured variable is assigned to the 1st measured variable by means of this table.

LEVEL

SELECTION:

Level standard/

LEVEL MODE:

Height

Linearized

Measured variable options

Via OUTPUT UNIT parameter: %, level, volume or mass units.

Via OUTPUT UNIT parameter: %, level, volume or mass units.

Via LIN.

MEASURAND parameter:

– % (Level)

– Level

– Volume

– Mass

Via LIN.

MEASURAND:

– Pressure + %

– Pressure +

Volume

– Pressure + Mass

Via COMB.

MEASURAND parameter:

– Height + Volume

– Height + Mass

– Height + %

– %-Height +

Volume

– %-Height + Mass

– %-Height + %

Description Comment Measured value display

– Calibration with reference pressure - wet calibration, see Operating Instructions

BA00303P.

– Calibration without reference pressure - dry calibration, see Operating

Instructions BA00303P.


BA00303P.




BA00303P.



– Calibration with reference pressure: semiautomatic entry of linearization table, see Operating Instructions

BA00303P.

– Calibration without reference pressure: manual entry of linearization table, see Operating Instructions

BA00303P.

– Calibration with reference pressure: wet calibration and semiautomatic entry of linearization table, see


BA00303P.

– Calibration without reference pressure: dry calibration and manual entry of linearization table, see Operating Instructions

BA00303P.

– Incorrect entries are possible

– Customized units are not possible

The measured value display and the

LEVEL BEFORE LIN. parameter show the measured value.

– Incorrect entries are possible

– Customized units are not possible



– Incorrect entries are rejected by the device

– Customized level, volume and mass units are possible





The measured value display and the TANK

CONTENT parameter show the measured value.



The measured value display and the TANK

CONTENT parameter show the 2nd measurand value

(volume, mass or %).

The LEVEL BEFORE LIN parameter displays the

1st measured value

(%-height or height).

74 Endress+Hauser


7.7.4

Quick Setup menu for Level measuring mode

• Some parameters are only displayed if other parameters are appropriately configured. For example, the EMPTY CALIB. parameter is only displayed in the following cases:

– LEVEL SELECTION "Level Easy Pressure" and CALIBRATION MODE "Wet"

– LEVEL SELECTION "Level Standard", LEVEL MODE "Linear" and CALIBRATION MODE

"Wet"

You can find the LEVEL MODE and the CALIBRATION MODE parameter in the BASIC

SETTINGS function group.

• The following parameters are set to the following values in the factory:

– LEVEL SELECTION: Level Easy Pressure

– CALIBRATION MODE: Wet

– OUTPUT UNIT or LIN. MEASURAND: %

– EMPTY CALIB: 0.0

– FULL CALIB: 100.0

• The quick setup is suitable for simple and quick commissioning. If you wish to make more complex settings, e.g. change the unit form "%" to "m", you will have to calibrate using the

BASIC SETTINGS group.  See Operating Instructions BA00303P.



1 )

LA N G U AG E

1 )


1 )

L E V E L S E L E C T I O N

1 )


2 )

QUICK S E T UP

P re ssu re L e v e l


3 )

E MP TY C AL IB.

3 )

FU LL C AL IB.

O P E RAT IN G M E NU

Flow

D A MPIN G V AL U E



3 ) – L E V E L S E L E C T I O N " L e v e l E asy P re ssu re " a n d C AL IB RAT I O N M O D E " W et "

– L E V E L S E L E C T I O N = " L e v e l S t a n d a r d ",

L E V E L M O D E = " L i ne a r " a n d

C AL IB RAT I O N M O D E = " W et "

Fig. 41: Quick Setup menu for "Level" measuring mode

P RO FI L E VI E W

2 )


Local operation



GROUP SELECTION


MEASURING MODE

Select "Level" option.

LEVEL SELECTION

Select level mode. For an overview see

 ä 74.

GROUP SELECTION


FieldCare



Measuring Mode


Primary Value Type

Select "Level" option.

Level Selection

Select level mode. For an overview see

 ä 74.

Endress+Hauser 75


Local operation

POS. ZERO ADJUST



EMPTY CALIB. 1)

Enter level for the lower calibration point.

For this parameter, enter a level value which is assigned to the pressure present at the device.

FULL CALIB. 1

Enter level for the upper calibration point.


DAMPING VALUE



FieldCare

POS. ZERO ADJUST



EMPTY CALIB. 1

Enter level for the lower calibration point.


FULL CALIB. 1

Enter level for the upper calibration point.


DAMPING VALUE



1) – LEVEL SELECTION "Level Easy Pressure" and CALIBRATION MODE "Wet"

– LEVEL SELECTION "Level Standard", LEVEL MODE "Linear" and CALIBRATION MODE "Wet"




76 Endress+Hauser


7.8

Differential pressure measurement

7.8.1

Preparatory steps

• The Deltabar S PMD75 and FMD78 are usually used for differential pressure measurement.



Valves

1 Close 3.

Meaning Preferred installation


Open A, B, 2, 4.

Fluid flows in.

3 Clean pressure piping if necessary: 1)

– by blowing out with compressed air in the case of gases

– by rinsing out in the case of liquids.

I

II

6

+

3

7

–

2 4

Close 2 and 4.

Open 1 and 5.



Block off device.

Blow out/rinse out pressure piping.

Close valves after cleaning.

Close 1 and 5.



4 Vent device.

Open 2 and 4.

Close 4.

Open 3.


Introduce fluid.





Close 3.


III

+

A

I

II

+

A

6

+

3

7

–

–

B

B

III

2 4

Open 4.


Now

– 1

 , 3, 5  , 6 and 7 are closed.

– 2 and 4 are open.

– A and B are open (if present).

6

Carry out calibration if necessary.  ä 77, Section 7.8.2.

1 5

Fig. 42:


Above: preferred installation for gases

Below: preferred installation for liquids

I

II

Deltabar S PMD75


III Separator

1, 5 Drain valves

2, 4 Inlet valves



A, B Shutoff valve

1) For arrangement with 5 valves

7.8.2

Information on differential pressure measurement

• By means of the FieldCare operating program, a Quick Setup menu is available for each of the measuring modes pressure, level and flow which guides you through the most important basic functions. With the setting in the MEASURING MODE parameter, you

specify which Quick Setup menu should be displayed.  ä 64, Section 7.4 "Selecting the language and measuring mode". No Quick Setup menus are available for the FF

configuration programs.

Endress+Hauser 77

Commissioning

78


• For a detailed description of the parameters, see Operating Instructions BA00303P

"Cerabar S/Deltabar S/Deltapilot S, Description of Device Functions"

– FF, Table, Pressure Transducer Block

– FieldCare, Table, POSITION ADJUSTMENT

– FieldCare, Table, BASIC SETUP

– FieldCare, Table, EXTENDED SETUP

!

WARNING



‣



7.8.3

Quick Setup menu for Pressure measuring mode



1 )

LA N G U AG E

1 )


1 )


2 )

QUICK S E T UP

P re ssu re


D A MPIN G V AL U E

O P E RAT IN G M E NU

L e v e l



Fig. 43: Quick Setup menu for "Pressure" measuring mode

P RO FI L E VI E W

2 )

Flow


Local operation



GROUP SELECTION


MEASURING MODE

Select "Pressure" option.

GROUP SELECTION


POS. ZERO ADJUST



DAMPING VALUE



FieldCare



Measuring Mode


Primary Value Type

Select "Pressure" option.

POS. ZERO ADJUST



DAMPING VALUE






Endress+Hauser


7.9

Scaling the OUT parameter

In the Analog Input Block, the input value or input range can be scaled in accordance with the automation requirements.

Example:

The measuring range 0 to 500 mbar (7.5 psi) should be rescaled to 0 to 100 %.

• Select XD_SCALE group.

– For EU_0, enter "0".

– For EU_100, enter "500".

– For UNITS_INDEX, enter "mbar".

• Select OUT_SCALE group.

– For EU_0, enter "0".

– For EU_100, enter "10000".

– For UNITS_INDEX, select "%" for example.

The unit selected here does not have any effect on the scaling. This unit is not displayed on the onsite display or in the operating program such as FieldCare.

• Result:

At a pressure of 350 mbar (5.25 psi), the value 70 is output to a downstream block or to the PCS as the OUT value.

PRIMARY_VALUE

= 350 mbar

Output Pressure

Transducer Block

UNITS_INDEX: mbar

EU_100

500

XD_SCALE

Analog Input Block

L_TYPE: Indirect

1

0.7

OUT_SCALE

EU_0

0

0 0.7

1

0

EU_0

0 70

EU_100

100

UNITS_

INDEX:

%

OUT Value = 70

P01-xMx7xxxx-05-xx-xx-en-008

!

CAUTION

Note Dependencies when setting parameters!

‣

If you have selected the "Direct" mode for the L_TYPE parameter, you cannot change the values and units for XD_SCALE and OUT_SCALE.

‣

The L_TYPE, XD_SCALE and OUT_SCALE parameters can only be changed in the OOS block mode.

‣

Make sure that the output scaling of the Pressure Transducer Block SCALE_OUT matches the input scaling of the Analog Input Block XD_SCALE.

Endress+Hauser 79


Event severity

Highest severity

7.10

Configuring event behavior in accordance with

FOUNDATION Fieldbus Specification FF912 Field

Diagnostic Profile

The device complies with FOUNDATION Fieldbus Specification FF912. Among other things, this means that:

• The diagnostic category according to NAMUR Recommendation NE107 is transmitted via the fieldbus in a format that is independent of the manufacturer:

– F: Failure

– C: Function check

– S: Out of specification

– M: Maintenance required

• The user can change the diagnostic category of the event groups specified in accordance with the requirements of the particular application.

• Certain events can be separated from their group and handled separately:

– e.g. 115: Sensor overpressure

– e.g. 715: Sensor over temperature

• Additional information and troubleshooting measures are transmitted with the event message via the fieldbus.

7.10.1 Event groups

The diagnostic events are divided into 16 groups, depending on the source and the severity of the event. A default event category is assigned to each group at the factory. One bit of the assignment parameters belongs to every event group.

Default event category

Failure (F)

Event source Bit

Sensor 31

Electronics 30

Configuration 29

Process 28

Events in this group

• 122: F>Sensor not connected

• 716: F>Process isolating diaphragm broken

• 110: F>Checksum error in EEPROM: configuration segment

• 113: F>ROM failure in transmitter electronic

• 121: F>Checksum error in factory segment of EEPROM

• 130: F>EEPROM is defect.

• 131: F>Checksum error in EEPROM: min/max segment

• 132: F>Checksum error in totalizer EEPROM

• 133: F>Checksum error in History EEPROM

• 135: F>Checksum error in EEPROM FF segment

• 728: F>RAM error



• Not used

• Not used

80 Endress+Hauser


Event severity

High severity


Check (C)

Event source Bit

Sensor 27

Electronics

Configuration 25

Process

26

24


• 101: C>Sensor electronic EEPROM error

• 725: C>Sensor connection error, cycle disturbance

• 747: C>Sensor software not compatible to electronics

• 703: C>Measurement error






• 742: C>Sensor connection error (upload)

• 743: C>Electronic PCB error during initialization

• 744: C>Main electronic PCB error

• 746: C>Sensor connection error - initializing

• 748: C>Memory failure in signal processor

• 106: C>Downloading - please wait

• 613: C>Simulation active

• Not used

Event severity

Low severity


Out of specification

(S)

Event source Bit

Sensor 23

Electronics 22

Configuration 21

Process 20


• 115: S>Sensor overpressure

• 120: S>Sensor low pressure

• 715: S>Sensor over temperature

• 720: S>Sensor under temperature

• 726: S>Sensor temperature error - overrange

• 717: S>Transmitter over temperature

• 718: S>Transmitter under temperature

• 701: S>Adjustment outside sensor nominal range

• 710: S>Set span too small. Not allowed.

• 727: S>Sensor pressure error - overrange

• 740: S>Calculation overflow, bad configuration

Endress+Hauser 81


Event severity

Lowest severity


Maintenance required

(M)

Event source Bit Events in this group

Sensor

Electronics

19 • 745: M>Sensor data unknown

18 • 102: M>Checksum error in EEPROM: peakhold segment

• 134: M>EEPROM lifetime WARNING

• 700: M>Last configuration not stored

• 702: M>HistoROM data not consistent

Configuration 17 • 116: M>Download error, repeat download

• 602: M>Linearization curve not monoton

• 604: M>Linearization table invalid. Min. 2 points.

• 706: M>Configuration in HistoROM and device not identical.

• 707: M>X-VAL. (TAB_XY_VALUE) of lin. table out of edit limits

• 711: M>LRV or URV out of edit limits

• 713: M>100% POINT (LEVEL_100_PERCENT_VALUE) level out of edit limits

• 719: M>Y-VALUE (TAB_XY_VALUE) of lin. table out of edit limits

• 721: M>ZERO POSITION (LEVEL_OFFSET) level out of edit limits

• 722: M>EMPTY CALIB. (SCALE_OUT, EU_0) or FULL CALIB. (SCALE_OUT,

EU_100) out of edit limits

• 723: M>Max. flow (SCALE_OUT, EU_100) out of edit limits

• 741: M>TANK HEIGHT (LEVEL_TANK_HEIGHT) out of edit limits

• 750: M>Configuration not permitted

Process 16 • 730: M>Pmin ALARM WINDOW (PRESSURE_1_USER_LOW_LIMIT) undershot

• 731: M>Pmax ALARM WINDOW (PRESSURE_1_USER_HIGH_LIMIT) overshot

• 732: M>Tmin ALARM WINDOW (TEMPERATURE_1_USER_LOW_LIMIT) undershot

• 733: M>Tmax ALARM WINDOW (TEMPERATURE_1_USER_HIGH_LIMIT) overshot

7.10.2 Assignment parameters

The event categories are assigned to the event groups via four assignment parameters.

These parameters are located in the RESOURCE (RB2) Block:

• FD_FAIL_MAP : for event category Failure (F)

• FD_CHECK_MAP : for event category Check (C)

• FD_OFFSPEC_MAP : for event category Out of Specification (S)

• FD_MAINT_MAP : for event category Maintenance Required (M)

Each of these parameters comprises 32 bits with the following meaning:

• Bit 0 : reserved by the Fieldbus Foundation. Is also set if 1 TRD is not in the AUTO mode.

• Bits 1 to 15 : configurable area; certain diagnostic events can be assigned here irrespective of the event group they are in. They are not excluded from the event group and their behavior can be configured individually (

 ä 85). In the case of Deltabar S, the following

events can be assigned to the configurable area:

– e.g. 115: Sensor overpressure

– e.g. 715: Sensor over temperature

• Bits 16 to 31 : standard area; these bits are permanently assigned to the event groups. If the bit is set to 1 this event group is assigned to the particular event category.

The factory setting of the assignment parameters is indicated in the following table. In the factory setting, there is a clear assignment between the event severity and the event category (e.g. the assignment parameter).

82 Endress+Hauser


Event severity

Event source 1)

Bit

FD_FAIL_MAP

FD_CHECK_MAP

FD_OFFSPEC_MAP

FD_MAINT_MAP

Factory setting of assignment parameters

Standard area

0

0

1

0

S

Highest severity

E C P S

High severity

E C P S

Low severity

E C P S

Lowest severity

E C P

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16

1

0

1

0

1

0

0

1

0

1

0

1

0

1

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

1

0

1

0

1

0

1

0

0

1

0

1

0

1

0

1

1) S: Sensor; E: Electronics; C: Configuration; P: Process

Configurable area

15...1

0

0

0

0

Proceed as follows to change the diagnostic behavior of an event group:

1. Open the assignment parameter to which the group is currently assigned.

2. Change the bit of the event group from 1 to 0 . If using FieldCare, this is done via the

FF912 module by disabling the appropriate check box (see the following example).

3. Open the assignment parameter to which the group should be assigned.

4. Change the bit of the event group from 0 to 1 . If using FieldCare, this is done via by enabling the appropriate check box (see the following example).

Example

The Highest Severity / Electronics group contains the events 131: Checksum error in

EEPROM: min/max segment, among others. These should no longer be categorized as

Failure (F) , and should be categorized as Check (C) instead.

1. In the FieldCare navigation window navigate to Expert  Field Device Diagnostic 

Configuration

Endress+Hauser 83


2. In the Failure column search for the Highest Severity Electronic group and disable the associated check box (A). Enable the appropriate check box in the Function column (B).

Please note that the "Accept" button must be pressed to confirm each entry.

(A) (B)

It must be ensured that the appropriate bit is set in at least one of the assignment parameters for each event group. Otherwise a category is not transmitted with the event via the bus. The control system will therefore generally ignore the presence of the event.

The detection of diagnostic events and the transmission of the messages on the bus is configured on the FieldCare page Expert  Field Device Diagnostic  Configuration . The

"Mask" column is used for the transmission of the message on the bus. It must be noted that device messages can still be transmitted by polling the active bits in Status 1 and 2. The mask check box acts as a negative check box, i.e. if a field is selected the associated events are not transmitted on the bus. The Resource Block must be set to the Auto mode to transmit status information on the bus.

84 Endress+Hauser


7.10.3 Configurable area

The event categories can be individually defined for the following events - irrespective of the event group to which they are assigned in the factory setting:

• 115 : Sensor overpressure

• 120: Sensor low pressure

• 715: Sensor over temperature

• 717: Transmitter over temperature

• 718: Transmitter under temperature

• 720: Sensor under temperature

• 726: Sensor temperature error-overrange

• 727: Sensor pressure error-overrange

• 730: LRV user limits exceeded

• 731: URV user limits exceeded

• 732: LRV-Temp. user limits exceeded

• 733: URV-Temp. user limits exceeded

• 740: Calculation Overflow, bad configuration

To change the event category, the event must first be assigned to one of the bits 1 to 15. The

FF912ConfigArea_1 to FF912ConfigArea_15 parameters in the DIAGNOSTIC

(TRDDIAG) Block are used for this purpose. The appropriate bit can then be set from 0 to 1 in the desired assignment parameter.

Example

Error 115 "Sensor overpressure" should no longer be categorized as Out of Specification

(S) , and should be categorized as Function (C) instead.


Configuration .

Endress+Hauser 85


2. Select the "Configurable area" tab. In the factory setting, all the bits in the Configurable

Area Bits column have the value not assigned (A).

(A) (B) (C)

3. Select one of these bits (here Configurable Area Bit 15 , for instance) and select the

Sensor overpressure (B) option from the associated picklist. Confirm your choice by pressing "Accept".

4. Enable the check box for the bit concerned (here: Configurable Area Bit 15 ) (C).

Confirm your choice by pressing "Accept".

Additional information:

The "Status 1" and "Status 2" tabs indicate whether an event is active.

86

Changing the error category for Sensor overpressure does not affect an error that already exists. The new category is only assigned if this error occurs again after the change has been made. The "Status 1" and "Status 2" tabs indicate whether an event is active.

Endress+Hauser


The "Simulation" tab makes it possible to simulate an event.

Endress+Hauser 87


7.10.4 Transmission of independent event messages on the bus

Event priority

Event messages are only transmitted on the bus if their priority is between 2 and 15. Priority

1 events are displayed but are not transmitted on the bus. Events whose priority is 0 are ignored. All events are assigned the priority 0 in the factory setting. It is possible to change the priority individually for the four assignment parameters.

Example

The priority of the "Failure" category is to be set to "2" .

1. In the FieldCare navigation window navigate to Expert  Field Device Diagnostics 

Configuration

2. Select the "Standard area" tab and set the priority to "2" in the "Failure" column (D).

(D)

88

Suppressing certain events

It is possible to suppress certain events during transmission on the bus using a "mask" check box. While these events are still displayed, they are not transmitted as alert objects on the bus. This mask check box can be found in FieldCare under Expert  Field Device Diagnostic

 Configuration . The mask check box acts as a negative check box, i.e. if a field is selected the associated events are not transmitted on the bus.

Endress+Hauser


7.10.5 Overview of the settings made and the current events

1. In the FieldCare navigation window navigate to Diagnose  Alarm Indication

(Polling)

2. The following overview is displayed:

– "Troubleshooting information" if an event has occurred

– "Setting made" in the configurable area

– "Current events" in the various categories

7.10.6 Information about the current events


Actual Alarm Condition

Endress+Hauser

2. The following overview is displayed:

– "Troubleshooting information" if an event has occurred

– "FF912 Field Diagnostic Profile" version

– "Information about the current events" in the various categories

7.10.7 Setting the status of the flexible alarms

The event category can be individually defined for the following events - irrespective of the event group to which they are assigned in the factory setting:

• 115 : Sensor overpressure

• 120: Sensor low pressure

• 715: Sensor over temperature

• 717: Transmitter over temperature

• 718: Transmitter under temperature

• 720: Sensor under temperature

• 726: Sensor temperature error-overrange

• 727: Sensor pressure error-overrange

• 730: LRV user limits exceeded

• 731: URV user limits exceeded

• 732: LRV-Temp. user limits exceeded

• 733: URV-Temp. user limits exceeded

89


• 740: Calculation Overflow, bad configuration

To change the assigned status (Bad, Uncertain, Good) of an event, select the desired status from the associated picklist.

Example

The status of error 115 "Sensor overpressure" should no longer be indicated as "Uncertain" and should instead be indicated as "Bad".

1. In the FieldCare navigation window navigate to Expert  Field Device Diagnostics 

PV Status Config

2. All the bits of the Status Select Events have the status "Uncertain" in the factory setting.

90

3. Select the "Bad" option for the "Status Select Event 115" row. Press Enter to confirm your entry.

Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Maintenance

8 Maintenance

Deltabar S requires no maintenance.

8.1

Cleaning instructions

Endress+Hauser offer flushing rings as accessories to clean process isolating diaphragms without taking the transmitters out of the process.

For further information please contact your local Endress+Hauser Sales Center.

8.1.1

Deltabar FMD77, FMD78

We recommend you perform CIP (cleaning in place (hot water)) before SIP (sterilization in place (steam)) for pipe diaphragm seals.

A frequent use of sterilization in place (SIP) will increase the stress on the process isolating diaphragm. Under unfavorable circumstances in the long term view we cannot exclude that a frequent temperature change could lead to a material fatigue of the process isolating diaphragm and possibly to a leakage.

8.2

Exterior cleaning

Please note the following points when cleaning the device:

• The cleaning agents used should not attack the surface and the seals.

• Mechanical damage to the process isolating diaphragm, e.g. due to pointed objects, must be avoided.

• Observe degree of protection. See therefor nameplate if necessary (  ä 10).

Endress+Hauser 91

Diagnostics and troubleshooting Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus

9 Diagnostics and troubleshooting

9.1

Troubleshooting

9.1.1

General errors

Error

Device is not responding.

No display

Device measures incorrectly.

Possible cause

The supply voltage does not match the specifications on the nameplate.

Supply voltage has incorrect polarity.

Remedy

Apply correct voltage.

No contact between connecting cables and terminals.

Reverse polarity of supply voltage.

Check the contacting of the cables and correct if necessary.

Onsite display is set too bright or too dark.

• Set the local display brighter by simultaneously pressing O and F.

• Set the local display darker by simultaneously pressing S and F.

Connector for local display is not plugged in correctly.

Ensure connector is plugged in correctly.

Onsite display is defective.

Configuration error.

Replace onsite display.

Check and correct parameter configuration

(see below).

9.1.2

Displaying messages:

• Onsite display:

– The measured value display shows the message with the highest priority.  See the

"Priority" column.

– The ALARM STATUS parameter shows all the messages present in descending order of priority. You can scroll through all the messages pending using the S or O key.

• FieldCare:

The DIAGNOSTIC_CODE/DIAGNOSE_CODE parameter displays the message with the highest priority.

 See the "Priority" column.



See also Section 9.6 "Response of outputs to errors".

• Diagnose Transducer Block (FF configuration program):

The DIAGNOSTIC_CODE/DIAGNOSE_CODE parameter displays the message with the highest priority. 

See also Section 9.6 "Response of outputs to errors". Every message is

also output as per the FOUNDATION Fieldbus Specification by means of the XD_ERROR and BLOCK_ERROR parameters in the Pressure, Service and DP Flow Block. Numbers are

given for these parameters in the following table which are explained on 95.

• You can see a list of all the active alarms via the Diagnostic code/ACTUAL_ALARM_INFOS parameter.

• You can see a list of all the alarms that are no longer active (event log) via the Last Diag.

Code/LAST_ALARM_INFOS parameter.

92 Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Diagnostics and troubleshooting

9.2

Diagnostic information on local display

9.2.1

Diagnostic message

Faults detected by the self-monitoring system of the measuring device are displayed as a diagnostic message in alternation with the measured value display.

Error categories

F

"Failure"

A device error has occurred. The measured value is no longer valid.

C

"Check"

The device is in the service mode (e.g. during a simulation) or is performing a self-check.

S

M

"Out of specification"

The device is being operated:

• Outside its technical specifications (e.g. during warmup or cleaning processes).

• Outside the parameter configuration undertaken by the user (e.g. pressure outside of nominal operating range)

"Maintenance required"

Maintenance is required. The measured value is still valid.

Diagnostic event and event text

The fault can be identified using the diagnostic event. The event text helps you by providing information about the fault.

Status signal

Diagnostic event

Event number

Event text with category information

Example E115 S>Sensor overpressure

3-digit number

• If the device detects a defect in the onsite display during initialization, special error messages are generated. 

For the error messages, see  ä 93, Section 9.2.2 "Onsite display error messages".

• For support and further information, please contact Endress+Hauser Service.

• 

See also Section 9.8, Section 9.9 and Section 9.10.

• If the category of a diagnostic event is being changed, an empty field might be displayed instead of "F, C, S, M".

9.2.2

Onsite display error messages

If the device detects a defect in the onsite display during initialization, the following error messages can be displayed:

Endress+Hauser 93


Message

Initialization, VU Electr. Defect A110



Initialization, VU Checksum Err. A110



Measure

Exchange onsite display.

9.3

Diagnostic event in the operating tool

If a diagnostic event is present in the operating tool, the status signal appears in the top left status area along with the corresponding symbol for event behavior in accordance with NAMUR NE

107:

• Failure (F)

• Check (C)

• Maintenance required (M)

• Out of specification (S)

94

P01-xMx7xxxx-05-xx-xx-en-008

Calling up remedy information

1. Navigate to the "Diagnostics" menu. The diagnostic event along with text about the event is displayed in the "Actual diagnostics" parameter.

2. On the right in the display area, hover the cursor over the "Actual diagnostics" parameter. A tool tip with remedy information for the diagnostic event appears.

Endress+Hauser


9.4

Diagnostic messages in the DIAGNOSTIC Transducer

Block (TRDDIAG)

• The Actual Diagnostics parameter shows the message with the highest priority. Every message is also displayed as per the FOUNDATION Fieldbus Specification by means of the

XD_ERROR and BLOCK_ERROR parameters.

• You can view the active alarm with the highest priority via the Diagnosis parameter.

• You can view the last alarm that is no longer active via the Last Diagnosis parameter.

9.4.1

Explanation of XD_ERROR, BLOCK_ERROR and response of outputs

Alarm 747 17 General Error

707 18 Calibration Error


0

0

0





0

0

0

0


719 19 Configuration

Error


0

0

0

Other

Other

Other

Other

Other

Other

Other

Other

Other

Other

122 20 Electronics Failure 7














Sensor Failure BAD_SENSOR_FAILURE

Other BAD_SENSOR_FAILURE

Other

Other

BAD_SENSOR_FAILURE

BAD_SENSOR_FAILURE

Sensor Failure BAD_DEVICE_FAILURE

Other BAD_DEVICE_FAILURE

Other

Other

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

Other

Other

Other

Other

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE



Endress+Hauser

BAD_SENSOR_FAILURE

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

BAD_NON_SPECIFIC

Pressure, Level, Flow All

Level Primary Value(1)

Level, Flow Primary Value(1)

Totalizer 1 (6)

Level

Level

Level

Flow

Level

Level

Primary Value(1)

Primary Value(1)

Primary Value(1)

Primary Value(1)

Totalizer 1 (6)

Primary Value(1)

Primary Value(1)

Pressure, Level, Flow Primary Value(1)

Pressure(3)

Maximum Pressure(4)

Counter P > Pmax(5)

Totalizer 1 (6)















95


Alarm 113 20 Electronics Failure 0




0 110 23 Data Integrity

Error

130 23 Data Integrity

Error

0


Error


Error


Error


Error


Error

0

0

0

0

Other

Other

Other

Other

Other

Other

Other

Other

Other

Other

Other

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE

GOOD

BAD_DEVICE_FAILURE

GOOD

BAD_DEVICE_FAILURE

BAD_DEVICE_FAILURE







Pressure, Level, Flow None

Flow Totalizer 1 (6)

Pressure, Level, Flow None



96 Endress+Hauser


Alarm/

Warning

115

120

17

17

General Error

General Error

0

0

Other

Other

– BAD_NON_SPECIFIC

– STATUS_UNCERTAIN

– GOOD



– GOOD


Pressure(3)

Maximum Pressure(4)

Counter P > Pmax(5)

Totalizer 1 (6)


Pressure(3)

Maximum Pressure(4)

Counter P > Pmax(5)

Totalizer 1 (6)

Pressure, Level, Flow All 717

718

720

715




730

731

732

733

17

17

17

17

19

19

19

19

General Error

General Error

General Error

General Error

Configuration

Error

Configuration

Error

Configuration

Error

Configuration

Error

0

0

0

7

0

0

0

0

Other

Other



– GOOD



– GOOD

Other – BAD_NON_SPECIFIC


– GOOD

Sensor Failure – BAD_NON_SPECIFIC


– GOOD



– GOOD



– GOOD



– GOOD

Other GOOD

Other

Other

Other

GOOD

GOOD

GOOD

Pressure, Level, Flow










All

Sensor Temperature(2)

Sensor Temperature(2)

All

All

All

None

None

None

None

Endress+Hauser 97


Warning 106

134

116

613

17

17

17

17

General Error

General Error

General Error

701 17 General Error


General Error

0

0

0

0

0

0

Other

Other

Other

Other

Other

Other




Error


Error

0



Error

0


Error


Error

0

0

0

0

Other

Other

Other

Other

Other

Other

Other

Other

STATUS_UNCERTAIN

GOOD



– GOOD




All

None

All

UNCERTAIN_CONFIG_ERROR Pressure, Level, Flow All

STATUS_UNCERTAIN Pressure, Level, Flow All

UNCERTAIN_SIM Pressure, Level, Flow Primary Value(1)

Maximum Pressure(4)

Counter P > Pmax(5)

Totalizer 1 (6)

GOOD

GOOD



UNCERTAIN_CONFIG_ERROR Level

None

None

Primary Value(1)

UNCERTAIN_CONFIG_ERROR Level

STATUS_UNCERTAIN

GOOD


Primary Value(1)

All

Pressure, Level, Flow Maximum Pressure(4)

Counter P > Pmax(5)

Pressure, Level, Flow All STATUS_UNCERTAIN

GOOD Pressure, Level, Flow None

98 Endress+Hauser


9.5

Overview of diagnostic events

9.5.1

Failure (F)

Diagnostic

Code

Error response

101 Alarm

110

113

121

122 Alarm

130

Alarm

Alarm

Alarm

Alarm

Message/description XD_

ERROR

Value Bit

EEPROM error

20

F>Checksum error in

EEPROM: configuration segment

23

20

BLOCK_

ERROR

Value Bit

0

0

0

Cause

– Electromagnetic effects are greater than specifications in the technical data.

( 

See Section 10.) This

message normally only appears briefly.

– Sensor defect.

– The supply voltage is disconnected when writing.


( 

See Section 10.)

– Main electronics defect.


Measure

– Wait a few minutes.

– Restart the device. Perform reset (Code 62).

– Block off electromagnetic effects or eliminate source of disturbance.

– Replace sensor.

– Reestablish supply voltage.

Perform reset if necessary

(code 7864) and recalibrate the device.

– Block off electromagnetic effects or eliminate sources of disturbance.

– Replace main electronics.


Priority

19

6

1 F>ROM failure in transmitter electronic

F>Checksum error in factory segment of

EEPROM

F>Sensor connected not

23

20

0

7



5

14

F>EEPROM is defect.

23 0

– Cable connection sensor – main electronics disconnected.


( 

See Section 10.)


– Sensor defect.


– Check cable connection and repair if necessary.



– Replace sensor.


11

131

132

133

135

703

705

Alarm

Alarm

Alarm

Alarm

Alarm

Alarm

F>Checksum error in

EEPROM: min/max segment

F>Checksum error in totalizer EEPROM

F>Checksum error in

History EEPROM

23

23

23

F>Checksum error in

EEPROM FF segment

23

F>Measurement error 20


0

0

0

0

0

0



– An error occurred when writing.





– Perform reset (code 7864) and recalibrate the device.



9

7

8

10

– Fault in the main electronics. – Briefly disconnect device from the power supply.

24




23



Endress+Hauser 99


Diagnostic

Code

Error response

716 Alarm

725 Alarm

728

729

736

737

738

739

Alarm

Alarm

Alarm

Alarm

Alarm

Alarm

742 Alarm

743 Alarm

744 Alarm


ERROR

Value Bit diaphragm broken

20 error, cycle disturbance

F>RAM error

F>RAM error

F>RAM error error (upload)

F>Electronic PCB error during initialization

F>Main error

20

20

20

20




20

20

20

BLOCK_

ERROR

Value Bit

0

Cause

– Sensor defect.

0

0

0

0

0

0

0

0

7

0

Measure

– Replace sensor.

– Reduce pressure.

Priority

26


( 

See Section 10.)

– Setscrew loose.


27

– Retighten setscrew with 1 Nm

(0.74 lbf ft) (see

Section 4.3.9).

– Sensor or main electronics defect.

– Replace sensor or main electronics.




2




3




4


22




21




25



( 






20

– Check cable connection and repair if necessary.

– Cable connection sensor – main electronics disconnected.

– Sensor defect.


( 



– Replace sensor.



15 /

16



( 

See Section 10.)






12

100 Endress+Hauser


Diagnostic

Code

Error response

747

748

Alarm

Alarm


ERROR

Value Bit

F>Sensor software not compatible to electronics

F>Memory failure in signal processor

17

20

BLOCK_

ERROR

Value Bit

0

7

Cause

– Sensor does not suit the device (electronic sensor nameplate).


( 

See Section 10.)


Measure

– Replace sensor with a suitable sensor.

18



Priority

17

9.5.2

Check (C)

Diagnostic

Code

Error response

106 Warning

602 Warning

604

613

Warning

Warning

701 Warning

704 Alarm

707 Alarm


ERROR

Value Bit

C>Downloading please wait

17

C>Linearization not monoton

19

C>Linearization table invalid. Min. 2 points.

C>Simulation active sensor nominal range

C>X-VAL.

(TAB_XY_VALUE) of lin. table out of edit limits.

19

17

17

C>Measurement error 20

18

BLOCK_

ERROR

Value Bit

0

Cause

0

0

0

0

7

0

Measure Priority

– Downloading.

– The linearization table is not monotonic increasing.

– Wait for download to complete.

61

– Add to or correct linearization table. Then accept linearization table again.

67

Note! There is no min. span for the y-points as of software version

"03.00.00".

– The linearization table has fewer than 2 points.

1. Add to linearization table.

Perform the linearization again if necessary.

2. Correct the linearization table and accept it again.

68

– Simulation is switched on, i.e. the device is not measuring at present.

– Switch off simulation. 70

– The adjustment carried out would cause a breach of the nominal sensor range.

– Carry out calibration again.

63


13



– At least one X-VALUE

(TAB_XY_VALUE) in the linearization table is either below the value for

SCALE_IN, EU_0/HYDR.

PRESS MIN. or LINEAR_

LEVEL_MIN/MIN. LEVEL or above the value for


PRESS. MAX. or

LINEAR_LEVEL_MAX/

LEVEL MAX.

– Perform calibration again

(  See Operating Instructions

BA00303P, parameter description), Section 5).

45

Endress+Hauser 101


Diagnostic

Code

Error response

710

711

Warning

Alarm


ERROR

Value Bit

B>Set span too small.

Not allowed.

18

C>LRV or URV out of edit limits

18

BLOCK_

ERROR

Value Bit

0

Cause

0

Measure Priority

– Values for calibration (e.g. lower range value and upper range value) are too close together.

– The sensor was replaced and the customer-specific configuration does not suit the sensor.

– Unsuitable download carried out.

– Adjust calibration to suit sensor (  see Operating

Instructions BA00303P, parameter description),

CAL_MIN_SPAN/MINIMUM

SPAN parameter).

– Adjust calibration to suit sensor.


– Check configuration and perform download again.

– Lower range value and/or upper range value undershoot or overshoot the sensor range limits.

– Reset the LRV and/or URV to suit the sensor. Pay attention to position adjustment.

60

37

713 Alarm 0

– The sensor was replaced and the customer-specific configuration does not suit the sensor.


– The sensor was replaced.

– Reset the LRV and/or URV to suit the sensor. Pay attention to position adjustment.




46

719 Alarm

POINT

(LEVEL_100_PERCEN

18

T_VALUE) level out of edit limits

C>Y-VAL

(TAB_XY_VALUE) of lin. table out of edit limits

19 0

721 Alarm

722 Alarm

723 Alarm

741 Alarm

POSITION

(LEVEL OFFSET) level out of edit limits

(SCALE_OUT, EU_0) or FULL CALIB.

(SCALE_OUT,


18

FLOW

(SCALE_OUT,


18

HEIGHT

(LEVEL_TANK_HEIGH

T) out of edit limits

18

0

0

0

0

– At least one Y-VALUE

(TAB_XY_VALUE) in the linearization table is below the SCALE_OUT, EU_0/

TANK CONTENT MIN. or above the SCALE_OUT,

EU_100/TANK CONTENT

MAX.


(  See Operating Instructions

BA00303P, parameter description), Section 5).

– LEVEL MIN

(LINEAR_LEVEL_ MIN) or

LEVEL MAX

(LINEAR_LEVEL_MAX) has been changed.

– LINEAR_ LEVEL_MIN/LEVEL

MIN or

LINEAR_LEVEL_MAX/

LEVEL MAX has been changed.



47

48

49/50

– FLOW_TYPE/FLOW-MEAS.

TYPE has been changed.

– LINEAR_LEVEL_MIN/LEVEL

MIN or

LINEAR_LEVEL_MAX/

LEVEL MAX has been changed.



51

52

102 Endress+Hauser


Diagnostic

Code

Error response

746 Warning

750 Warning


ERROR

Value Bit error - initializing

20

C>Configuration permitted

18

BLOCK_

ERROR

Value Bit

0

Cause

0


( 



– Overpressure or low pressure present.

– By means of the operation profile, options were selected for the configuration of the device but the options do not suit one another. For example, if the option "1"

(linearization table) was selected for LIN_TYPE and the unit "1347 (m 3 /s)" was selected for

PRIMARY_VALUE_UNIT.

Measure




– Reduce or increase pressure.

– Check configuration.


Priority

28

53

Endress+Hauser 103


9.5.3

Maintenance required (M)

Diagnostic

Code

Error response

102 Warning

116 Warning

134 Warning

700 Warning

702 Warning

706 Warning


ERROR

Value Bit

M>Checksum error in

EEPROM: peakhold segment

23 repeat download

M>EEPROM

WARNING not stored

23

M>HistoROM data not consistent

17

17

17 in

HistoROM and device not identical

23

BLOCK_

ERROR

Value Bit

0

Cause

0

0

0

0

0

Measure Priority


Correct measurement can continue as long as you do not need the peak hold indicator function.

– The file is defect.


– Use another file.

– During the download, the data are not correctly transmitted to the processor, e.g. because of open cable connections, spikes (ripple) on the supply voltage or electromagnetic effects.

– Check cable connection PC – transmitter.

– Block off electromagnetic effects or eliminate sources of disturbance.


– Repeat download.

62

38

– Writing too often to

EEPROM.

– An error occurred when writing or reading configuration data or the power supply was disconnected.


– Reduce write accessing to

EEPROM.


65

63

– Data were not written correctly to the HistoROM, e.g. if the HistoROM was detached during the writing process.

– HistoROM does not have any data.


– Repeat upload.


64

– Configuration (parameters) in the HistoROM and in the device not identical.

– Copy suitable data to the

HistoROM. (  ä 54,

Section 6.5.1 "Copying configuration data".)

– Copy data from the device to the HistoROM. (

 ä 54,

Section 6.5.1 "Copying configuration data".)

– Copy data from the HistoROM

to the device. (  ä 54,

Section 6.5.1 "Copying configuration data".) The

message remains if the

HistoROM and the device have different software versions. The message disappears if you copy the data from the device to the

HistoROM.

– Device reset codes such as 1 or 40864 do not have any effect on the HistoROM. That means that if you perform a reset, the configurations in the HistoROM and in the device can be different.

69

104 Endress+Hauser


Diagnostic

Code

Error response

740 Alarm/ warning

745 Warning


ERROR

Value Bit

M>Calculation overflow, bad configuration

20

M>Sensor unknown

17

BLOCK_

ERROR

Value Bit

7

Cause

0

Measure Priority

– Level measuring mode: the measured pressure has undershot the value for


PRESS. MIN. or overshot the value for SCALE_IN,

EU_100/HYDR. PRESS MAX.

– Level measuring mode: the measured level has undershot the value for LEVEL MIN or overshot the value for LEVEL

MAX

– Flow measuring mode: the measured pressure has undershot the value for

SCALE_IN, EU_100/MAX.

PRESS FLOW.

– Sensor does not suit the device (electronic sensor nameplate). Device continues measuring.

– Check configuration and recalibrate if necessary.

– Select a device with a suitable measuring range.

29

– Check configuration and recalibrate the device if necessary (  see Operating

Instructions BA00303P, parameter description, LEVEL

MIN. parameter).

– Check configuration and recalibrate if necessary.

– Select a device with a suitable measuring range.


66

Endress+Hauser 105


9.5.4

Out of specification (S)

Diagnostic

Code

Error response

115 Alarm/ warning

120 Alarm/ warning

715 Alarm/ warning

717 Alarm/ warning

718 Alarm/ warning

720 Alarm/ warning


ERROR

Value Bit

S>Sensor overpressure 17

S>Sensor low pressure 17

S>Sensor over temperature

S>Transmitter over temperature

S>Transmitter under temperature

S>Sensor under temperature

17

17

17

17

BLOCK_

ERROR

Value Bit

0

Cause

0

7

0

0

0

Measure Priority

– Overpressure present.

– Reduce pressure until message disappears.

– Replace sensor.

– Sensor defect.

– Pressure too low.

– Increase pressure until message disappears.

– Replace sensor.

– Sensor defect.

– The temperature measured in the sensor is greater than the upper nominal temperature of the sensor. (  See also


BA00303P, parameter description for

TEMPERATURE_1

_SENSOR_LIMIT_HIGH/

Tmax SENSOR or these

Operating Instructions)

– Reduce process temperature/ ambient temperature.

31

32

34


– The temperature measured in the electronics is greater than the upper nominal temperature of the electronics

(+88 °C (+190 °F)).


– The temperature measured in the electronics is smaller than the lower nominal temperature of the electronics

(–43 °C (-45 °F)).



– Reduce ambient temperature. 36


– Increase ambient temperature. Insulate device if necessary.


– Increase process temperature/ambient temperature.

37

35 – The temperature measured in the sensor is lower than the lower nominal temperature of the sensor (  see Operating

Instructions BA00303P, parameter description,

TEMPERATURE_1

_SENSOR_LIMIT_LOW/

Tmin SENSOR parameter).


– Loose connection at sensor cable.


– Wait a short period of time and tighten the connection, or avoid loose connection.

106 Endress+Hauser


Diagnostic

Code

Error response

726 Alarm/ warning

727 Alarm/ warning

730 Alarm/

Warning

731 Alarm/

Warning

732 Alarm/

Warning


ERROR

Value Bit

S>Sensor temperature error - overrange

20

S>Sensor pressure error - overrange

S>Pmin ALARM

WINDOW

(PRESSURE_1_USER_

LOW_LIMIT) undershot

S>Pmax ALARM

WINDOW

(PRESSURE_1_UER_

HIGH_LIMIT) overshot

S>Tmin ALARM

WINDOW

(TEMPERATURE_1_

USER_LOW_LIMIT) undershot

20

19

19

19

BLOCK_

ERROR

Value Bit

7

Cause


( 

See Section 10.)

– Process temperature is outside permitted range.

7

0

0

0

Measure


Priority

33

– Sensor defect.

– Check temperature present, reduce or increase if necessary.

– If the process temperature is within the permitted range, replace sensor.



( 

See Section 10.)

– Pressure is outside permitted range.

– Sensor defect.

– Pressure measured value has undershot the value specified for the PRESSURE_1_USER_

LOW_LIMIT/Pmin ALARM

WINDOW parameter.


– Pressure measured value has overshot the value specified for the PRESSURE_1_USER_

HIGH_LIMIT/Pmax ALARM

WINDOW parameter.

– Temperature measured value has undershot the value specified for the

TEMPERATURE_1_USER_

LOW_LIMIT/Tmin ALARM

WINDOW parameter.


30

– Check pressure present, reduce or increase if necessary.

– If the pressure is within the permitted range, replace sensor.

– Check system/pressure measured value.

– Change value for

PRESSURE_1_

USER_LOW_LIMIT/Pmin

ALARM WINDOW if necessary.

(  See also Operating

Instructions BA00303P, parameter description or these Operating Instructions)

55


– Check system/pressure measured value.


PRESSURE_1_USER_ HIGH_

LIMIT/Pmax ALARM

WINDOW if necessary.



54

– Check system/temperature measured value.


TEMPERATURE_1_

USER_LOW_LIMIT/Tmin





57

Endress+Hauser 107


Diagnostic

Code

Error response

733 Alarm/

Warning


ERROR

Value Bit

S>Tmax ALARM

WINDOW

(TEMPERATURE_1_

USER_HIGH_LIMIT) overshot

19

BLOCK_

ERROR

Value Bit

0

Cause

– Temperature measured value has overshot the value specified for the

TEMPERATURE_1_

USER_HIGH_LIMIT/Tmax

ALARM WINDOW parameter.

Measure

– Check system/temperature measured value.


TEMPERATURE_1_

USER_HIGH_LIMIT/Tmax




Priority

56

9.6

Response of outputs to errors

The device makes a distinction between the output behavior "Alarm", "Warning" and "Error".

 See the following table and

 ä 93, Section 9.2 "Diagnostic information on local display".

Certain problems can be assigned the "GOOD" status via FF communication, see Section 9.4.1.

Output

FOUNDATION

Fieldbus

Onsite display

Remote operation (FF configuration program/FieldCare)

A (Alarm)

The process variable in question is transmitted with the status BAD.

– The measured value and message are displayed alternately

– Measured value display: -symbol is permanently displayed.

Message display

– A + 3-digit number such as A122 and

– Description

In the event of an alarm, the ALARM

STATUS/ALARM_STATUS 1) parameter displays a 3-digit number such as 122 for "Sensor connection error, incorrect data".

W (Warning)

Device continues measuring. The process variable in question is transmitted with the status UNCERTAIN.


– Measured value display: flashes.

-symbol

Message display:

– W + 3-digit number such as W613 and

– Description

In the case of a warning, the ALARM

STATUS/ALARM_STATUS

 parameter

displays a 3-digit number such as 613 for "Simulation is active".

E (Error: Alarm/Warning)

For this error, you can enter whether the device should react as in the event of an alarm or as in the event of a warning.

See appropriate column for "Alarm" or

"Warning"

(  see Operating Instructions

BA00303P, parameter description),

REACTION_ON_ ALARM_NR/SELECT

ALARM TYPE parameter).

The GOOD status can also be assigned to the individual error via the parameters

FF912_STATUS_SELECT_1 to

FF912_STATUS_SELECT _131.


– Measured value display: see corresponding "Alarm" or "Warning" column

Message display:

– E + 3-digit number such as E731 and

– Description

In the case of an error, the ALARM

STATUS/ALARM_STATUS  parameter

displays a 3-digit number such as 731 for "Pmax ALARM WINDOW undershot".

1) FF configuration program: Diagnostic Transducer Block. Menu path FieldCare: OPERATING MENU  MESSAGES

9.6.1

Analog Input Block

If the Analog Input Block receives an input or simulation value with the status BAD, the

Analog Input Block uses the failsafe mode defined in the FSAFE_TYPE 1 parameter.

The following options are available by means of the FSAFE_TYPE parameter:

• Last Good Value

The last valid value is used for further processing with the status UNCERTAIN.

• Fail SafeValue

108 Endress+Hauser


The value specified by means of the FSAFE_VALUE processing with the status UNCERTAIN.

1 parameter is used for further

• Wrong Value

The current value is used for further processing with the status BAD.

Factory setting:

• FSAFE_TYPE: FsafeValue

• FSAFE_VALUE: 0

The failsafe mode is also activated if the "Out of service" option was selected by means of the

MODE_BLK parameter, "Target" element.

1 These parameters are not available by means of the FieldCare operating program.

9.7

Confirming messages

Depending on the settings for the ALARM_HOLD_ON_TIME/ALARM DISPL. TIME and

ACKNOWLEDGE_ALARM_MODE/ACK. ALARM MODE parameters, the following measures should be taken to clear a message:

Settings 1)

– ALARM_HOLD_ON_TIME/

ALARM DISPLAY TIME = 0 s

– ACKNOWLEDGE_ALARM_MODE

/ACK. ALARM MODE = off

Measures

– Rectify the cause of the message (see also Section 9.5).


ALARM DISPL. TIME > n s


/ACK. ALARM MODE = off


– Wait for the alarm display time to elapse.


ALARM DISPL. TIME = 0 s


/ACK. ALARM MODE = on


ALARM DISPL. TIME > n s


/ACK. ALARM MODE = on


– Confirm message using ACKNOWLEDGE_ALARM/ACK. ALARM parameter.


– Confirm message using ACKNOWLEDGE_ALARM/ACK. ALARM parameter.

– Wait for the alarm display time to elapse. If a message appears and the alarm display time elapses before the message has been acknowledged, the message is cleared once it has been acknowledged.

1) FF configuration program: The parameters are in the Diagnostic Transducer Blocks.

FieldCare: Menu path for ALARM DISPL. TIME and ACK. ALARM MODE: OPERATING MENU 

DIAGNOSTICS  MESSAGES

9.8

Repair

The Endress+Hauser repair concept provides for measuring devices to have a modular design

and also that the customer may carry out repairs  ä 110 "Spare Parts" on ).

• For certified devices, please consult the "Repair of Ex-certified devices" section.

• For more information on service and spare parts contact the Endress+Hauser Service.

(  See www.endress.com/worldwide.)

Endress+Hauser 109


9.9

Repair of Ex-certified devices

!

WARNING

Limitation of electrical safety due to incorrect connection!

Risk of explosion!

When repairing Ex-certified devices, please note the following:

• Only specialist personnel or Endress+Hauser may undertake repairs of certified devices.

• Relevant standards, national hazardous area regulations and Safety Instructions and

Certificates must be observed.

• Only genuine Endress+Hauser spare parts may be used.

• When ordering spare parts, please check the device designation on the nameplate.

Identical parts may only be used as replacements.

• Electronic inserts or sensors already in use in a standard instrument may not be used as spare parts for a certified device.

• Carry out repairs according to the instructions. After repairs, the device must fulfill the requirements of the specified individual tests.

• A certified device may only be converted into another certified variant by Endress+Hauser.

• All repairs and modifications must be documented.

9.10

Spare Parts

• Some replaceable measuring device components are identified by means of a spare part nameplate. This contains information about the spare part.

• All the spare parts for the measuring device along with the order code are listed In the

W@M Device Viewer (www.endress.com/deviceviewer) and can be ordered. If available, users can also download the associated Installation Instructions.

Measuring device serial number:

• Located on the device and spare part nameplate.

• Can be read out via the "DEVICE SERIAL No" parameter in the "TRANSMITTER DATA" submenu.

9.11

Return

The measuring device must be returned if repairs or a factory calibration are required, or if the wrong measuring device has been ordered or delivered. According to legal regulations,

Endress+Hauser, as a ISO-certified company, is required to follow certain procedures when handling returned products that are in contact with process fluids.

To ensure swift, safe and professional device returns, please read the return procedures and conditions on the Endress+Hauser website at www.services.endress.com/return-material.

9.12

Disposal

When disposing, separate and recycle the device components based on the materials.

110 Endress+Hauser

Deltabar S FMD77, FMD78, PMD75 with FOUNDATION Fieldbus Technical data

Date

9.13

Software history

Software version Changes to the software

03.2005 02.00.zz

08.2008 03.00.zz

01.2013 04.00.zz

Original software.

Compatible with:

– ToF Tool Field Tool Package, version 2.04 or higher

Compatible with:

– FieldCare version 2.15.00

FF912 Field Diagnostic Profile Integration

Documentation

Operating Instructions Description of Device

Functions

BA301P/00/EN/04.05

52027497

BA301P/00/EN/11.05

71009597

BA303P/00/EN/04.05

52027502

BA303P/00/EN/04.05

52027502

BA301P/00/EN/10.07

71043305

BA301P/00/EN/12.07

71043305

BA301P/00/EN/05.08

71071735

BA301P/00/EN/08.08

71077522

BA303P/00/EN/04.05

52027502

BA303P/00/EN/04.05

52027502

BA303P/00/EN/04.05

52027502

BA303P/00/EN/08.08

71076564

BA301P/00/EN/06.09

71095421

BA301P/00/EN/05.10

71111781

BA301P/00/EN/13.11

71139766

BA00301P/00/EN/14.12

71161885

BA00301P/00/EN/15.13

71207382

BA00301P/00/EN/16.14

71254467

BA00301P/00/EN/17.14

71270387

BA00301P/00/EN/18.15

71281256

BA00301P/00/EN/19.16

71336231

BA303P/00/EN/06.09

71095456

BA303P/00/EN/05.10

71111814

BA303P/00/EN/13.11

71139808

BA303P/00/EN/13.11

71139808

BA00303P/00/EN/14.13

71207399

BA00303P/00/EN/15.14

71254484

BA00303P/00/EN/16.14

71254484

BA00303P/00/EN/16.14

71254484

BA00303P/00/EN/17.16

71336364

10 Technical data

For technical data, please refer to Technical Information TI00382P for Deltabar S.

Endress+Hauser 111


Index

Symbols

"Level" Quick Setup menu . . . . . . . . . . . . . . . . . . . . . . . . . 75

"Pressure" Quick Setup menu . . . . . . . . . . . . . . . . . . . . . . 78

A

Assignment of Transducer Blocks (CHANNEL). . . . . . . 43

B

Block configuration, delivery status . . . . . . . . . . . . . . . . 42

Block model, Deltabar S . . . . . . . . . . . . . . . . . . . . . . . . . . 40

C

Cable specification. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

CHANNEL-Parameter . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

Current consumption . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

D

Designated use. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

Device addressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Device identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Diaphragm seals, installation instructions . . . . . . . . . . . 21

Diaphragm seals, vacuum application. . . . . . . . . . . . . . . 22

Differential pressure measurement . . . . . . . . . . . . . . . . 77

Differential pressure measurement, installation. . . . . . 19

Differential pressure measurement, preparatory steps 77

Differential pressure measurement, Quick Setup menu 78

Display. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34

E

Electrical connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

Error messages. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

F

Factory setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59

Flow measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68

Flow measurement, installation . . . . . . . . . . . . . . . . . . . 14

Flow measurement, preparatory steps . . . . . . . . . . . . . . 67

Flow measurement, Quick Setup menu . . . . . . . . . . . . . 69

FOUNDATION Fieldbus system architecture . . . . . . . . . 38

G

Grounding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

H

Hazardous area . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

HistoROM/M-DAT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54

I

Incoming acceptance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

Index tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

K

Keys, onsite, function . . . . . . . . . . . . . . . . . . . . . . . . . 36–37

Keys, position . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

L

Level measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73

Level measurement, installation . . . . . . . . . . . . . . . . . . . 16

112

Level measurement, preparatory steps . . . . . . . . . . . . . . 70

Level measurement, Quick Setup menu . . . . . . . . . . . . . . 75

Locking operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57

M

Measuring arrangement for differential pressure measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Measuring arrangement for flow measurement. . . . . . . 14

Measuring arrangement for level measurement . . . . . . 16

Menu structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51

Methods . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50

N

Nameplate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10

Network configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Number of devices. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

O

Onsite display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34

Operating elements, function . . . . . . . . . . . . . . . . . . 36–37

Operating elements, position . . . . . . . . . . . . . . . . . . . . . . 36

Operational safety. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

Overvoltage protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

P

Pipe mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Position adjustment, FF configuration program . . . . . . . 65

Position adjustment, FieldCare . . . . . . . . . . . . . . . . . . . . . 65

Position adjustment, onsite . . . . . . . . . . . . . . . . . . . . . . . . 36

Product safety . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

Q

Quick Setup menu flow (FieldCare) . . . . . . . . . . . . . . . . . 69

R

Repair . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109

Repair of Ex-certified devices . . . . . . . . . . . . . . . . . . . . 110

Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59

Returning devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

Rotating the housing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

S

Scaling OUT parameter. . . . . . . . . . . . . . . . . . . . . . . . . . . . 79

Scope of delivery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12

Selecting the language . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64

Selecting the measuring mode . . . . . . . . . . . . . . . . . . . . . 64

Separate housing, assemble and mount. . . . . . . . . . . . . . 28

Shielding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

Sicherheitshinweise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

Simulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59

Software history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111

Spare Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110

Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

Supply voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

T

Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

Endress+Hauser


U

Unlocking operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57

W

Wall mounting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Warnings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

Workplace safety . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

Endress+Hauser 113

71336231

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