Elster EK220 Operating Instructions And Installation Information

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EK220

Volume Conversion Device EK220

Operating Instructions and Installation Information

Operating Manual: 73020052 SW Version: from V1.20 Issued 01.09.2008 (b) Edition: 1

Volume Conversion Device EK220

2 © Elster GmbH

Volume Conversion Device EK220

All the figures and descriptions in this operating and instruction manual have been compiled only after careful checking. Despite this however, the possibility of errors cannot be completely eliminated. Therefore, no guarantee can be given for completeness or for the content. Also, the manual cannot be taken as giving assurance with regard to product characteristics. Furthermore, characteristics are also described in it that are only available as options.

The right is reserved to make changes in the course of technical development. We would be very grateful for suggestions for improvement and notification of any errors, etc.

With regard to extended product liability the data and material characteristics given should only be taken as guide values and must always be individually checked and corrected where applicable. This particularly applies where safety aspects must be taken into account.

Further support is available from your local branch office / agent. The addresses are avail able on the internet or from Elster GmbH.

Passing this manual to third parties and its duplication, in full or in part, are only allowed with written permission from Elster GmbH.

The guarantee becomes invalid if the product described here is not handled properly, repaired or modified by unauthorised persons or if replacement parts which are n ot genuine parts from Elster GmbH are used.

Mainz-Kastel, September 2008

Volume Conversion Device EK220

Contents

I Safety information................................ ................................ ................................ ..................... 6

II Items supplied and accessories ................................ ................................ ................................ 7

1 Brief description................................ ................................ ................................ ........................ 8

2 Operation................................ ................................ ................................ ................................ 10

2.1 Front panel................................ ................................ ................................ ....................... 10

2.2 Display ................................ ................................ ................................ ............................. 11

2.2.1 Line 1 = Labels................................ ................................ ................................ ........................ 11

2.2.2 Line 2 = Value with name and unit................................ ................................ ........................... 13

2.3 Keypad ................................ ................................ ................................ ............................. 13

2.3.1 Changing values................................ ................................ ................................ ...................... 14

2.3.2 Entering "sources"................................ ................................ ................................ ................... 15

2.3.3 Entry errors ................................ ................................ ................................ ............................. 15

2.4 Access rights ................................ ................................ ................................ .................... 16

2.4.1 Calibration lock................................ ................................ ................................ ........................ 16

2.4.2 Certification data log................................ ................................ ................................ ................ 17

2.4.3 Supplier's lock and customer's lock................................ ................................ .......................... 17

2.5 Formation of the list structure ................................ ................................ ........................... 17

3 Functional description................................ ................................ ................................ ............. 22

3.1 User-Liste................................ ................................ ................................ ......................... 23

3.2 Standard volume (volume at base conditions) list................................ ............................. 24

3.3 Actual volume (volume at measurement conditions) list................................ ..................... 26

3.4 Pressure list................................ ................................ ................................ ...................... 27

3.4.1 Submenu pressure sensor 2 „ SMenu Press. 2 “................................ ................................ ......30

3.4.2 Submenu pressure coefficients................................ ................................ ................................ 32

3.5 Temperature list................................................................ ................................ ................ 34

3.5.1 Submenu temperature coefficients ................................ ................................ .......................... 36

3.6 Volume corrector list................................ ................................ ................................ .........36

3.7 Archive list................................ ................................ ................................ ........................ 40

3.7.1 Find function for checking the archive entries................................ ................................ ..........43

3.7.2 Measurement period archive 2 ................................ ................................ ................................ 43

3.7.3 Flexible archives 1 to 4................................ ................................ ................................ ............43

3.8 Status list................................ ................................ ................................ .......................... 44

3.8.1 List of status messages ................................ ................................ ................................ ...........47

3.8.2 Status register addresses................................ ................................ ................................ ........52

3.9 System list................................ ................................ ................................ ........................ 53

3.10 Service list................................ ................................ ................................ ........................ 55

3.10.1 Submenu ambient temperature “SMenu Amb. temp.”................................ ............................... 59

3.10.2 Submenu revisal “SMenu Revisal”................................ ................................ ........................... 60

3.11 Input list................................ ................................ ................................ ............................ 60

3.12 Output list ................................ ................................ ................................ ......................... 65

3.12.1 Brief summary of output parameterisation................................ ................................ ................ 69

3.13 Interface list................................ ................................ ................................ ...................... 70

3.13.1 Submenu „GSM & SMS“................................ ................................ ................................ ..........76

3.13.2 Submenu "IDOM protocol"................................ ................................ ................................ .......78

3.13.3 Submenu “MODBUS parameters” ................................ ................................ ........................... 79

3.14 Energy list................................................................ ................................ ......................... 81

4 Applications................................ ................................ ................................ ............................ 82

4.1 Application in areas subject to explosion hazards................................ ............................. 82

4.1.1 Applications in Zone 1................................ ................................ ................................ .............82

4.1.2 Applications in Zone 2................................ ................................ ................................ .............82

4.1.3 Ex identification lable................................ ................................ ................................ ...............83

4.2 Rated operating conditions for the various conversion methods ................................ .......83

4.3 Connection of a counter with LF pulse transmitter ................................ ............................ 84

4.4 Applications for Interface 2 as RS485................................ ................................ ............... 85

4.4.1 FE260 Function Expansion................................ ................................ ................................ ......85

4.4.2 FE230 Function Expansion with modem ................................ ................................ ..................86

4 © Elster GmbH

Volume Conversion Device EK220

4.4.3 Devices with RS485 interface, without modem (also FE260 without modem).......................... 86

4.4.4 EK220 connected to RS485-Bus (real RS485)................................ ................................ ........ 86

4.5 Applications for Interface 2 as RS232................................ ................................ ............... 87

4.5.1 Modem with control signals................................ ................................ ................................ ..... 87

4.5.2 Modem without control signals................................ ................................ ................................ 87

4.5.3 Interface isolator MTL5051................................ ................................ ................................ ..... 88

4.5.4 Other devices with RS232 interface (no modem)................................ ................................ .... 89

4.5.5 Sending short messages by SMS................................. ................................ .......................... 89

4.5.6 Standard output data records for process data ("three-minute values") ................................ ... 89

4.6 Interface protocols................................ ................................ ................................ ............ 90

4.6.1 Modbus ................................ ................................ ................................ ................................ .. 90

4.6.2 Idom protocol................................ ................................ ................................ .......................... 90

5 Installation and maintenance ................................ ................................ ................................ ..91

5.1 Installation procedure ................................ ................................ ................................ ....... 91

5.2 Cable connection and earthing................................ ................................ ......................... 92

5.3 Checking the pressure sensor................................ ................................ .......................... 92

5.4 Terminal layout................................ ................................ ................................ ................. 93

5.5 Connection of a low-frequency pulse generator (reed contacts) ................................ ....... 94

5.6 Connection of the serial interface RS485................................ ................................ .......... 95

5.6.1 FE260 Function Expansion (with or without modem)................................ ............................... 95

5.6.2 FE230 Function Expansion................................ ................................ ................................ ..... 96

5.6.3 Other devices with RS485 interface (no modem)................................ ................................ .... 96

5.6.4 EK220 connected to RS485-Bus (real RS485)................................ ................................ ........ 97

5.7 Connection of the serial interface RS232................................ ................................ .......... 98

5.7.1 Modem with control signals................................ ................................ ................................ ..... 98

5.7.2 Industrial modem EM260 or Modem without control signals................................ .................... 98

5.7.3 Interface isolator MTL5051................................ ................................ ................................ ..... 99

5.7.4 Other devices with RS232 interface, EK220 battery powered................................ ................ 100

5.7.5 Other devices with RS232 interface, EK220 with external power supply................................ 100

5.8 Seals................................ ................................ ................................ .............................. 101

5.8.1 Seal layout of basic device ................................ ................................ ................................ ... 102

5.8.2 Seal layout of temperature sensor ................................ ................................ ........................ 104

5.8.3 Sealing layout of pressure sensor -Type CT30................................ ................................ ...... 105

5.8.4 Sealing layout of pressure sensor type 17002................................ ................................ ....... 106

5.9 Battery replacement ................................ ................................ ................................ ....... 107

A Approvals ................................................................ ................................ ............................. 109

A-1 EC Declaration of Conformance ................................ ................................ ..................... 109

A-2 Approval for Ex Zone................................ ................................ ................................ ...... 110

B Technical data ................................ ................................ ................................ ...................... 115

B-1 General data (mechanical) ................................ ................................ ............................. 115

B-2 Batteries................................ ................................ ................................ ......................... 115

B-3 External power supply ................................ ................................ ................................ .... 116

B-4 Pulse and status inputs ................................ ................................ ................................ .. 116

B-5 Signal and pulse outputs ................................................................ ................................ 117

B-6 Optical serial interface ................................ ................................ ................................ .... 117

B-7 Electrical serial interface (internal)................................ ................................ .................. 117

B-8 Pressure sensor ................................ ................................ ................................ ............. 118

B-8.1 Type CT30................................ ................................ ................................ ............................... 118

B-8.2 Type 17002................................ ................................ ................................ .............................. 118

B-8.3 Installation information ................................ ................................ ................................ ............. 118

B-9 Temperature sensor................................................................ ................................ ....... 119

B-10 Measurement uncertainty ................................ ................................ ............................... 119

C Index................................ ................................ ................................ ................................ ..... 120

Volume Conversion Device EK220

I Safety information

F The connections of the EK220 are freely accessible during setting up. Therefore, make

sure that no electrostatic discharge (ESD) can occur in order to avoid damage to the components. The person carrying out the installation can, for example, discharge himself/herself by touching the potential equalisation line.

F To avoid erroneous operation and problems, the operating manual must be read be-

fore putting the EK220 into operation.

The EK220 Volume Conversion Device (= Electronic Volume Corrector) can be used in Ex Zone 1 according VDE 0170 for gases of Temperature Class T4 (ignition temperature > 135°C, e.g. natural gas). See Appendix A-2 for EC prototype test certificate.

In this application it is essential to take note of the following information:

F Follow the relevant applicable national regulations and appropria te standards, e.g.

EN 60079-14 and EN 60079-11.

F Make sure that the limits quoted in the EC prototype test certificate (see Appendix A-2)

for the devices to be connected are not exceeded.

F The housing of the EK220 must be earthed directly to a potential equalisation strip. A

terminal screw is provided for this on the left housing wall.

F Repairs on the EK220 may only by carried out by Elster GmbH.

6 © Elster GmbH

II Items supplied and accessories

Items supplied:

The items supplied with the EK220 include:

a) EK220 Volume Conversion Device b) Dispatch list c) Configuration data sheet d) Operating Manual e) Bag of accessories, EK220

Volume Conversion Device EK220

Ordering information and accessories EK220 Volume Conversion Device, complete 83 462 540 EBL 50 Temperature Sensor Receptacle, complete with M10 x 1 we ld-in sleeve 73 012 634 EBL 67 Temperature Sensor Receptacle, complete with M10 x 1 weld-in sleeve 73 014 456 EBL 160 Temperature Sensor Receptacle, complete with G 3/4" weld-in sleeve

and seal EBL 250 Temperature Sensor Receptacle, complete with G 3/4" weld-in sleeve

and seal Three-way test tap 73 008 403 Shut-off ball valve with Ermeto 6L test connection 73 016 166 Minimess test connection 73 016 167 Operating manual, German 73 020 054 Operating manual, English 73 020 052 Plug-in terminal, 2-pole black 04 130 407 Calibration covering cap 73 017 456

Order no.

73 012 100

73 015 695

Battery module, 13 Ah 73 015 774 Bag of accessories, EK220 73 020 169

Volume Conversion Device EK220

1 Brief description

The EK220 Volume Conversion Device is used for the conversion of the gas volume measured in the operating state by a gas meter to the standard state and in the appropr iate energy.

The momentary values of pressure and temperature are measured for the determination of the operating state. The gas law deviation factor (K-value) can be computed alternatively according to S-GERG-88, AGA 8 GC method 1 or 2, AGA-NX19 or AGA-NX19 according Herning and Wolowsky or it can be entered as a constant. The volume is converted into energy using the adjustable calorific value.

The integral recording device includes the consumption profile of a number of months for a measurement period of 60 minutes.

Power supply:

· Battery operation with a service life depending on operating mode ³ 5 years.

· Optional double battery life by connection of an additional battery poss ible.

· Battery replacement possible without loss of data and without violation of calibration

seals.

· Data retention without battery supply due to internal non -volatile memory.

· Connection for external power supply unit.

Operator interface:

· Alphanumeric display with two lines of 16 characters.

· A display list freely assignable by the user.

· Programming via keypad possible.

· Calibration switch (separately sealed in the device).

· Two user locks (supplier's and customer's locks) with numerical codes.

· Access rights for each individual value can be set separately via interface (with appr o-

priate rights).

Counter / signal inputs:

· 3 inputs for reed contacts or transistor switches, programmable as pulse or signal in-

puts.

· Maximum counting frequency 2 Hz (adjustable).

· Pulse value for each input separately adjustable, also non -decade.

· Various counters for Vb and Vm as well as for each input (main and original counter,

disturbance volumes, totaliser, adjustable counter, measurement period counter).

· Each input can be separately sealed and secured under official calibration.

Pulse / signal outputs:

· 4 programmable transistor outputs, each freely programmable as alarm / warning ou t-

put, pulse output, signal output for limit monitoring.

· Each output can be separately sealed and secured under official calibration.

Data interface:

· Optical interface according to IEC 62056-21 (replaces IEC 61107 and EN61107).

· Permanently wired serial interface, as RS485 or RS232 usable

· MODBUS protocol via permanently wired serial interface.

· IDOM protocol via the permanently wired serial interface.

8 © Elster GmbH

Volume Conversion Device EK220

· Short message via SMS

· Programmable standard output data records for process data ("three -minute values").

Pressure sensor:

· Pressure sensor integrated in device, or external mounted.

· Connection of second pressure sensor possible (option).

· Alternatively absolute or gauge pressure measurement.

Temperature sensor:

· Pt500 (option Pt100) temperature sensor, different length

Mechanical details / housing:

· Suitable for wall mounting and meter installation (with mounting brack et).

· Mounting and device installation without violating the calibration seals.

· Ambient temperature range: -25°C...+55°C

Extended temperature with restricted functions possible.

Approvals:

· Approval by calibration authorities as Volume Conversion Device acc .

MID-Directive 2004/22/EG

· Ex approval for use in Ex Zone 1 according to II 2 G EEx ia [ia] IIC T4.

Monitoring functions

· Monitoring of signalling inputs.

· Monitoring of any values against programmable limits.

· All monitoring can trigger appropriate reaction s such as for example, entries in the

status register, log book, archive or signalling via outputs.

Archives

· Counter readings and maxima from the last 24 months for Vb and Vm.

· Mean values, maxima and minima from the last 24 months for pressure and temperature

as well as partially for the K-valueand conversion factor.

· Flexible archive for measurement period values (consumption profile) from the last

5 months for Vb, Vm, p, T, K and C (standard structure of archive) for a measurement period of 60 minutes. The measurement period can be set in the range from one minute upto one month.

· Archive for measurement period values for saving redundant measurement period archive

data from the last approx. 40 days for Vb, V, p, T, K and C for a measurement period of 60 minutes.

· Day archive with 600 entries. Measurement period values from the last 20 month for Vb,

Vm, p, T, K and C. Archiving once a day.

· Event logbook with 500 entries for events such as for example status changes, signal-

ling inputs, limit violations.

· Changes logbook ("audit trail") with entry of the last 200 changes to settings (param e-

terising steps).

· Certification data log with 50 entries for changing of some parameters relevant to calibra-

tion regulations. A data row for the value is entered before and after the change for each change to such a parameter.

· Four free configurable archives.

· Automatic summer time selection can be set.

Volume Conversion Device EK220

2 Operation

2.1 Front panel

The following are positioned on the front panel for operation:

· Two-line alphanumeric display with 16 characters per line.

· Four keys for the display and entry of values.

Identification label

10 © Elster GmbH

2.2 Display

Basic display structure (with an example):

Volume Conversion Device EK220

Prefix Archive

V m A 1 2 3 4 5 6 7 8 9

Both lines in the display are subdivided into fields which are described below.

2.2.1 Line 1 = Labels

The first line is subdivided into five fields of which four are labelled on the front panel.

1. Prefix (Type of computation)

The type of computation identifies so-called "initial values" (also termed "capture values"). These are values which have been formed over a time period (e.g. the adjustable mea surement period or one month). Labels:

- max Maximum – highest value within the time range

- min Minimum – lowest value within the time range

- D Change – volume within the time range

- Æ Mean – mean within the time range

2. Archive

If an arrow points upwards to the label "Archive", then the displayed value is an archived value. This was frozen at a defined point in time and cannot be changed.

Device status M e n u

A W B A c t. V.

m 3

Submenu

Volume Conversion Device EK220

3. Device status

Here a maximum of three of the most important items of status information are continually shown.

A flashing character signifies that the corresponding state is still present and the corr esponding message is present in the momentary status. A non-flashing character signifies that the corresponding state is past, but the message in the status register has not yet been cleared.

Meaning of the letters:

- A "Alarm"

At least one status message has occurred which has resulted in disturbance volumes being counted. Basically, all messages with numbers "1" or "2" represent alarms (e.g. "Alarm limits for pressure or temperature violated" ® 3.8). Alarm messages are copied into the status register and are retained here, even after rectification of the cause of the error, until they are manually cleared.

- W "Warning"

At least one status message has occurred which is valid as a warning. Basically, all messages with numbers in the range "3" to "8" represent warnings (e.g.

"Warning limits for pressure or temperature violated" or "Error on output" ® 3.8). Warning messages are copied into the status register and are retained here, even after rectification of the cause of the error, until they are manually cleared.

- B "Batteries discharged"

The remaining battery service life is less than 3 months. This display corresponds to Status Message "Batt. low" (® page 50).

- L "Calibration logbook full"

The calibration logbook is full; some parameters can now only be changed with the calibration lock open. (®PLogB, page 46 ) This display corresponds to the status message "PLogb full", (® page 50).

- If the calibration lock is opened with the calibration logbook full, it can only

be closed again after clearing the calibration logbook.

- P "Programming mode"

The programming lock (calibration lock) is open. This display corresponds to Status Message "Calibration lock" (® page 51).

- o "online"

A data transfer via the optical or permanently wired interface is running. In each case the other interface cannot then be used. This display corresponds to Status Message "online" (® page 50).

4. Menu

Here is displayed to which list according to Chapter 3 the currently displayed value belongs. In submenus (indicated by an arrow to the left, see below) its name is displayed which is identical with the abbreviated designation of the entry point.

5. Untermenü

- › Arrow to the right

indicates that the displayed value is the entry point of a submenu. This can be called with the key combination <ENTER>.

- ‹ Arrow to the left

‹

indicates that you are located in a submenu which can be quit with the key combination <ESC>. On pressing <ESC> you are returned to the entry point of the submenu.

12 © Elster GmbH

Volume Conversion Device EK220

f the

2.2.2 Line 2 = Value with name and unit

In the second line the name, value and (when available) the unit of the data are always shown.

Example:

V m A 1 2 3 4 5 6 7 8 9

2.3 Keypad

Key(s) Designation Effect

Downwards movement within the list: From the first value in the list movement is in the direction of the last value or from the last value directly to the first one.

Upwards movement within the list:

From the last value in the list movement is in the direction o first value or from the first value directly to the last one.

Movement to the right to a different list:

From the first list movement is in the direction of the last list or from the last list directly to the first one. With similar lists (e.g.: Vb and Vm skipping occurs to the appropriate value, otherwise to the first value.

Switchover to the second part of the value for values dis-

played on two lines:

- Counter readings divided into pre- and post-decimal places.

- Date and time (together one value) divided.

Down cursor key

Up cursor key

Right cursor key

m 3

Movement to the left to a different list:

- + ¯ Enter

¯ + ® Escape

¬ + -

¬ + ®

In the entry mode the keys change their functions, see Chapter 2.3.1.

Left cursor key

Home / Clear

Help

From the last list movement is in the direction of the first list or from the first list directly to the last one. With similar lists (e.g.: Vb and Vm skipping occurs to the appropriate value, otherwise to the first value in the adjacent list.

Depends on the value displayed (Data class, ® 2.3.1)

Activate the entry mode. Open the submenu. Update measurement (by pressing twice). Return from a submenu to the entry point in the higher level

main menu.

Cancel entry (the value remains unchanged). Skips to first value in the list Updates a value in the entry mode Displays the address (value number) of the value

Volume Conversion Device EK220

2.3.1 Changing values

The methods of entering and changing values differ depending on the value. These are therefore subdivided into so-called "data classes" (abbreviation: "DC"). Values in the same data class are treated identically during entry. A prerequisite for an entry is that the lock assigned to the value is open.

The following data classes (DC) are present in the EK220:

2 3 4

5 6

Type Entry, change using "ENTER"

Display test No change possible. Function Triggers the function by entering "1". Constant No change possible. Measure-

ment Status By pressing <ENTER> short texts for statusmessages are available. Initialisable

value Discrete

value

Permanent value

Archive heading

The value is updated by pressing <ENTER> twice.

After <ENTER> value initialisation (standard setting) by pressing the key combination <CLR> = ¬ + - .

After <ENTER> value change by selection from a list of possible values with the keys - and ¯ .

Value initialisation is possible with ¬ + - . After <ENTER>, setting to any value within the valid range is possible.

Selection of each individual character to be changed with ¬ and ® and changing with - und ¯ .

Value initialisation is possible with ¬ + - . Branching to the appropriate archive.

Combination

Counters As "Permanent value" (see above.).

Computation counter

Initial value No change possible, sometimes branching to a submenu.

Archive value

Status register

If a value is accommodated in a submenu, it cannot be changed independent of its data class by the keypad, since the key <ENTER> is then used for branching into the submenu.

Similar to "Permanent value" (see above) but masked entry, i.e. only the character currently being edited is visible, all others are masked out by a minus sign. With a closed lock it is opened on entering the correct combination. With an open lock, the combination is changed by the entry.

No change possible.

By pressing <ENTER> short texts for statusmessages are available. Initialisation (standard setting) by using menu-function <CLR>

14 © Elster GmbH

Volume Conversion Device EK220

2.3.2 Entering "sources"

At a number of points the entry of a "source" is required for parameterisation (e.g. SC.Qb in the standard volume list, SC.A1 in the output list).

The address of the desired value is entered as the source. It can be found in the tables at the beginning of each list (Chapter 3.1 ff.). In comparison to the addresses shown there however, the following supplements must be given:

- Completion of leading zeroes so that a total of four numbers exist in front of the colon.

- If the address includes no underscore "_", then "_0" should be appended.

Example 1: Source: 2:300 (Address of the standard volume Vb, see table in 3.1) Enter: 0002:300_0 (Supplements printed in bold)

Example 2: Source: 6:310_1 (Address of the temperature T, see table in 3.5) Enter: 0006:310_1 (Supplements printed in bold)

2.3.3 Entry errors

Entry error messages are displayed if incorrect entries are made via the keypad. Representation: ----x--- with x = Error code according to the following table.

Code

Description

The archive is empty, no values are available yet. The archive value cannot be read.

The archive has possibly just been opened by the interface for reading out. Parameter cannot be changed (constant). No authorisation for changing the value.

To change the value the appropriate lock must be opened. Invalid value.

Entered value is outside the permissible limits. Incorrect combination.

The entered combination (numerical code) is incorrect and the lock is not opened. Entry not possible due to special setting or configuration. The entry of the calorific value Ho.b in the energy list is not permitted. Please

change Ho.b in the Volume corrector list (® 3.6, page 36). The entry of this source (address) is not permitted. The function can only be executed after the clock (® 3.9, Time) has been set (ini-

tialised) to its starting value with the key combination ¬ + - .

Gas analysis parameters for AGA-NX-19 do not match. Example: For "H gas" (calorific value Ho.b over 11.055) the density ratio dr must not exceed the maximum value of 0.691. (® 3.6)

Value for the application-specific display is not defined.

The value to be displayed can be defined by the user by entering the address. No value is displayed because this has not yet occurred.

Because the certification data log is full the calibration lock must be opened for changing the parameter.

Volume Conversion Device EK220

2.4 Access rights

The EK220 differentiates between four access parties. Each access party has a lock and a corresponding code. The locks have the order of priority

Calibration lock – Manufacturer's lock1 – Supplier's lock – Customer lock.

The access rights apply both for keypad inputs as well as for accesses via the optical or electrical (permanently wired) interface. If the lock is locked, all attempts to set values are answered with an appropriate error message (see Chap. 2.3.2).

Also the reading of values via the interfaces is only possible, for reasons of data prote ction, when at least one of the locks is open.

Normally, in addition to the access rights assigned to each individual value, values can also be changed by the access parties with higher priority. A value, which for example has "S" ("Supplier") as access rights, can also be changed by calibration officials and a value subject to the customer's lock can also be changed by suppliers.

Each party with write access for a value can also change the access rights (write and read access for each party) for this value via interface. This means that also the rights of parties with higher priority can be changed.

2.4.1 Calibration lock

The calibration lock is used for securing parameters subject to calibration regulations. This includes all values which affect the volume counting.

The calibration lock is implemented as a pushbutton located within the EK220 housing b elow the circuit board cover panel. It can be secured with an adhesive seal.

The parameters protected under calibration regulations are each identified with "C" in the lists in the functional description.

Depending on the applications, values, which are not included as inputs subject to calibr ation regulations, can be placed under the user lock via the WinPADS parameterising software, for example to be able to use them as signalling inputs.

The calibration lock is opened by pressing the pushbutton (the symbol "P" flashes in the display) and is closed again when it is pressed again (symbol "P" goes out). Closure is

also possible by deleting the value "St.PL" (® 3.10) via the keypad or interface. On request (during order procedure) parameters which are normally protected under cal i-

bration lock can be protected under a different lock, e.g. supplier’s lock.

The manufacturer's lock is reserved for Elster GmbH and is not described here.

16 © Elster GmbH

Volume Conversion Device EK220

2.4.2 Certification data log

With the aid of the "certification data log" according to PTB-A 50.7 (® PLogB, chapter 3.8) some parameters relevant to calibration regulations can be changed also with the calibration lock closed. Prerequisites for this are:

The supplier’s lock (see below) must be open. At least three entries must be available in the certification data log.

The affected parameters (e.g. cp value, measurement period) are identified in the lists in chapter 3 with the access right "PL".

A data row for the value is entered before and after the change for each change to such a parameter with the calibration lock closed.

If the certification data log has been written full, it can be cleared with the calibration lock open using the command ClrPL (® chapter 3.8).

If the calibration lock is opened with the certification data log full, it can only be closed

again after clearing the certification data log.

2.4.3 Supplier's lock and customer's lock

The supplier's and customer's locks are used for securing all data which is not subject to calibration regulations, but which should also not be changed without aut horisation.

The parameters which are write-protected under the supplier or customer locks are each identified with "S" or "K" in the lists in the functional description (® 3). All values which are

shown with a minus symbol "-" cannot be changed, because they represent, for exa mple, measurements or constants.

The locks can be opened by entering a code (the "combination"). (® 3.10: St.SL, Cod.S, St.PL, Cod.C)

2.5 Formation of the list structure

The data display in the EK220 is structured in a tabular form. The individual columns in the table each contain associated values.

Values identified with S and Arc are submenus or archives which you can view by entering <ENTER> and leaving again with <ESC>. They each have, subordinate to the main menu, a dedicated list structure, which is written in the corresponding list ( ® 3).

The archives are subdivided into a number of data rows (also termed "data records" ). All values in the same data row are saved ("archived") at the same point in time. The maximum number of data rows and the number of values in a data row depends on the relevant archive. Within an archive the number of values and their meaning are the same for each data row. Switching to another archive data row occurs with the keys - (for "younger" data rows) and ¯ (for "older" data rows). After the last data row, the first follows again and vice versa. Switching to another value within a data row occurs with the keys ® and ¬ . After the last value, the first follows again and vice versa.

A summary of the standard main menu (list structure) is shown on the following pages. By changing the value Menu (see chapter 3.1 ), a minimum main menu can be selected.

Volume Conversion Device EK220

sens.2

User list

„Energ.“

Vol. at base cond. (pre-dec. places)

Actual vol. adjust. Flow at base cond. Actual flow Lower alarm limit

Pressure Disturbance quant. Disturbance quant. Upper alarm limit

Temperature Total quantity Total quantity Meas. range bottom

Compressibility factor

Compressibility factor at base cond.

Conversion factor Time of VnME Time of VbME Press. at base cond.

K subst. value Pressure mode

User

Vb «

VmA

K.F

VbME

Month end value Press. sensor type

Time

Time of VbME Serial no. of sensor

VmME

Month end value Submenu p coeff.

Time

Time of VmME

Dislpay menu Adjustment val. 2

Standard volume

Std.V.

Actual volume Pressure

Act.V.

Press

Vb « Vm « p «

Vol. at base cond. (post-dec. places)

VbD

VbT

VbA

Adjustable counter Adjustable counter Meas. range top

VbME

Month end value Month end value Substitute value

Time

Actual volume Pressure

VmD pMax

VmT MRL.p

VmA MRU.p

VmME p.F

Time pb

Md.p

Typ.p

SNp

pAdj1

pAdj2

pMin

SMenu p coeff. S

Adjustment val. 1

Prog

Accept adjust.

to „Temp.“

p.atm

p.Mes

Amb. press. fixed value

Pressure meas

p.Abs

Absolute press.

SMenu Press.2 S

Submenu p-sens. 2 (acc. to Selp2)

p2Mes

Pres. meas p(acc. to Selp2)

18 © Elster GmbH

Volume Conversion Device EK220

Temperature Conversion

Archive Status + Logbook

„Press“

Temp.

« T

Temperature Conversion factor Month archive 1 Status register

TMin

Lower alarm limit

TMax

Upper alarm limit

MRL.T

Meas. range bottom Tb for gasanalysis Meas. per. archive Logbook

MRU.T

Temperature Mode

Temp. sensor type

Serial no. of sensor

Submenu p coeff. Substitute value

Adjustment val. 1 K mode

Adjustment val. 2

Accept adjust.

Temp. meas.

Calorific value

K mode

Meas. range top

T.F

Substitute value

T at base cond.

Md.T

Typ.T

SNT

SMenu T coeff. S

TAdj1

TAdj2

Prog

T.Mes

Compressibility

pb for gasanalysis

Calorific value

Conv.

C «

ratio factor

pbX

(acc. to Md.K)

TbX

Ho.b

(acc. to Md.K)

CO2

Carbon diox. cont.

H2 FrMP

Hydrogen content (acc. to Md.K)

Rhob

Density gas at base cond. (acc. to Md.K)

Nitrogen content

(acc. to Md.K)

Density ratio

(acc. to Md.K)

K.F

Md.K

K mode changeo-

ver

Conversion factor

Substitute value

Md.K = 0

Conv.

Ho.n

K.F

Md.K

Archiv

ArMo1 Arc

ArMo2 Arc

Month archive 2 Momentary status

ArDay Arc

Day archive Clear S.Reg

ArMP Arc

MPer

Meas. period

MP.Re

Rem. time mea. p.

Freeze ArMP

Clr

Clear cert. data log

Status

S.Reg S

Stat S

Logb. Arc

AudTr Arc

Audit Trail

PLogB Arc

Certification data log (acc. to PL ® p. 58)

ClrPL

(acc. to PL ® p. 58)

to „System“

Volume Conversion Device EK220

cycle

Measurement cycle

System Service

„Status“

System

Serv.

Inputs

„Outp.“

« Time «

Date and time Remaining bat. life cp-value Input 1

MdTim

Daylight sav.: y-

es/no

Measurement

Operating cycle

Disp. switch-off

Disp. changover

Serial no. device Display contrast Limit 2 for I2

Ambient temp. Clock adjust. factor Stat. pointer mon. I2

Software version Savbe all data Status on Input 3

Software checksum Clear achives Select p sensor 2 Mode monitoring I3

MCyc

time

MCPul

triggered by input pulse

OCyc

time

Disp

time

Aut.V

time

SNo

Ta.Rg

Vers

Chk

Bat.R

Bat.C

Battery capacity cp-value Input 2

St.SL

Supplier lock

Cod.S

Supplier code

Status on Input 2

St.CL

Customer lock

Mode monitoring I2

Cod.C

Customer code

Source monitoring I2

St.PL

Calibration lock

Contr

Adj.T

Save

Clr.A Selp2

Clr.V SMenu Amb. temp. S

Clear counter

Submenu ambient temp.

Clr.X Addr

Initialise device Addr. user display Limit 1 for I3

Bin.T ...

Temp. binary value User display Stat. pointer mon. I3

Bin.p SMenu Revisal S

Pressure binary value Submenu Revisal Serial no. gas meter

Press. 2 binary value Frozen data

Select T sensor Freeze

Select p sensor Display test

Binp2 ArCal Arc

Sel.T

Sel.p

Frz

cp.I1

cp.I2

Md.I2

Mode for Input 2

St.I2

MdMI2

SC.I2

L1.I2

Limit 1 for I2

L2.I2

SpI2

St.I3

MdMI3

SC.I3

Source monitoring I3

L1.I3

SpI3

SNM

20 © Elster GmbH

Volume Conversion Device EK220

Outputs Interfaces Energy

„Inputs“

Md.O1

Mode for output 1 Mode interface 2 Energy

SC.O1 DF.S2 P

Source for output 1 Data format interface 2 Power

cp.O1

cp value output 1 Baud rate interface 2 W disturbance

SpO1

Status pointer for output 1

Md.O2

Mode for output 2 Bus mode RS485 on / off

SC.O2

Source for output 2

Outp. Ser.IO

Md.S2

Bd.S2

TypS2

Type interface 2

(acc. to Md.S2)

BusS2

(acc. to Md.S2)

Num.T

No. of ringing tones before

accept. call (acc. to Md.S2)

Energy

W.T

W total

W.A

W adjustable

Ho.b

Calorific value for W

cp.O2 M.INI WME

cp value output 2

SpO2

Status pointer for output 2

Md.O3

Mode for output 3

SC.O3

Source for output 3

Initialise modem

(acc. to Md.S2)

SMenu GSM&SMS S

Submenu GSM and SMS

parameter (acc. to Md.S2)

DProt IDOM Prot S

Submenu IDOM protocol

(acc. to Md.S2)

SMenu Modbus Par S

Submenu Modbus parame-

ter (acc. to Md.S2)

Month end value

Time

Time of WME

cp.O3 Bd.S1

cp value output 3 Baudrate interface 1

SpO3 CW1.S

Status pointer for output 3 Call window 1 start

Md.O4 CW1.E

Mode for output 4 Call window 1 end

SC.O4 CW2.S

Source for output 4 Call window 2 start

cp.O4 CW2.E

cp value output 4 Call window 2 end

Status pointer for output 4 Call window 3 start

SpO4

CW3.S

CW3.E

Call window 3 end

CW4.S

Call window 4 start

CW4.E

Call window 4 end

CWTst

Test call window

(acc. to Md.S2)

to „User“

Volume Conversion Device EK220

3 Functional description

The data display is structured in tabular form (list structure) (® 2.5). The individual col- umns in the table each contain associated values. The following functional description is orientated to this list structure.

Here, the following abbreviations are used:

- AD Abbreviated designation Designation of the value in the display

- Access Write access Indicates which lock must be opened to change the value (® 2.4.1, 2.4.3):

- C = Calibration lock

- PL = Certification data log (Calibration logbook, ® page 46)

- M = Manufacturer's lock

- S = Supplier's lock

- K = Customer's lock

- C / S = Calibration lock or supplier's lock, depending on national regulations In case of verification of device under calibration regulations (e.g. acc. MID) the write access C must be used. If the letter is located in brackets, the value can only be changed via the interface and not via the keypad.

- Address Address of the value. This is required especially for data transmission via the serial interface. The address can be displayed by pressing the keys ¬ + ® simultaneously.

- DC Data class The data class shows, amongst other properties, whether and how the value

can be changed. (® 2.3.1)

22 © Elster GmbH

Volume Conversion Device EK220

3.1 User-Liste

AD Designation / value Unit Access Address DC

Vb Volume at base conditions (pre-decimal places) m3 C / S 2:300_1 12 VmA Vm adjustable m3 S 4:303 12 p Pressure bar - 7:310_1 4 T Temperature °C - 6:310_1 4 Z Compressibility factor - 9:310 4 Zb Compressibility factor at base conditions C 9:312 8 C Conversion factor - - 5:310 4 K.F K-value, substitute value S 8:311 8 VbME Vb month end value m3 - 7:161 16 Time Date and time of Vb month end value - - 7:165 16 VmME V month end value m3 - 14:161 16 Time Date and time of Vm month end value - - 14:165 16 Menu Selection display menu - S 1:1A1 7

(Legends: see page 22)

With the exception of the first and last value (Vb and Menu), this list is user-specific, i.e. the user can himself set which values in this list are displayed. Ex-works, these are the above-mentioned values some of which are also displayed in anothe r list and described in the corresponding chapters.

The setting of the values to be displayed occurs by using the parameterisation software WinPADS.

Vb Volume at base conditions (pre-decimal places)

The volume at base conditions computed from the measured "actual volume" is summed here provided no alarm is present. An alarm is present when any message with the number "1" or "2" is urgent (® 3.8).

Vb = Vm ž C where Vm = Actual volume (® 3.3) C = Conversion factor (® 3.6) The post-decimal places of Vb are displayed in the standard volume list ( ® 3.2).

Vm Actual volume p Pressure T Temperature

Values which are also displayed in another list and described in the corresponding chapters.

Z Compressibility factor Zb Compressibility factor at base conditions

The computation of z and zb occurs according to S-Gerg-88, AGA-8 GC methode 1 or 2, AGA-NX19 or AGA-NX19 acc. Herning and Wolowsky, depending on the setting of Md.K. The gas analysis values Ho.b, CO2, H2 and N2 and Rhob (Md.K = 1) need to be included in the entries for this (® 3.6).

Volume Conversion Device EK220

C Conversion factor K.F K-value, substitute value VbME Vb month end value Time Date and time of Vb month end value VmME V month end value Time Date and time of Vm month end value These values are also displayed in other lists and are described in the appropriate

chapters.

Menu Selection display menu

With Menu the complete display structure of the EK220 can be switched between "complete" and "simple".

Menu = Meaning

1 Complete display structure 2 Only "User" column 3 Complete display structure without “Energy” column

Menu = 1 corresponds to the standard setting which is described in this manual.

With the setting Menu = 2, the display is limited to the column "User" described here. All other columns cannot be called.

3.2 Standard volume (volume at base conditions) list

AD Designation / value Unit Access Address DC

Vb Volume at base conditions (post-decimal places) m3 C / S 2:300_2 12 Qb Flow at base conditions m3/h - 2:310 4 VbD Vb disturbed m3 S 2:301 12 VbT Vb total m3 - 2:302 15 VbA Vb adjustable m3 S 2:303 12 VbME Month-end value m3 - 7:161 16 Time Time of VbME - - 7:165 16

(Legends: see page 22)

Vb Volume at base conditions (post-decimal places)

The volume at base conditions computed from the measured "actual volume" is summed here provided no alarm is present.

"Alarm" means any message with the number "1" or "2" ( ® 3.8). An alarm is present when any message "1" or "2" is urgent ( ® 3.8). Vb = Vm ž C where Vm = Actual volume (® 3.3) C = Conversion factor (® 3.6)

Qb Flow at base conditions

The pre-decimal places of Vb are displayed in the user list (® 3.1).

Momentary flow at base conditions (Volume at base conditions ). In the alarm state Qb is computed with the substitute values of the disturbed measurements.

24 © Elster GmbH

VbD Vb disturbed

Here the volume at base conditions is summed while ever an alarm is present, i.e. a message with the number "1" or "2" is located in any momentary status ( ® 3.8). In the alarm state the volume at base conditions is computed with the substitute values of the disturbed quantities. (® 3.4: p.F, 3.5: T.F)

VbT Vb total

Here the sum of Vb + VbD is always displayed. Entries for Vb or VbD therefore also have an effect here. No entry for VbT itself can be carried out.

VbA Vb adjustable

Here, as with VbT, the total quantity, i.e. disturbed and undisturbed volumes are counted. In contrast to VbT, VbA can however be changed manually.

The counter is typically used for tests.

VbME Vb month-end value

VbME saves the current month-end value at the change of month at the day boundary.

Time Time of VbME

Date and time of the saved VbME.

Volume Conversion Device EK220

3.3 Actual volume (volume at measurement conditions) list

AD Designation / value Unit Access Address DC

Vm Actual volume m3 C / S 4:300 12 Qm Actual flow rate m3/h - 4:310 4 VmD Vm disturbed m3 S 4:301 12 VmT Vm total m3 - 4:302 15 VmA Vm adjustable m3 S 4:303 12 VmME Month-end value m3 - 14:161 16 Time Time of VmME - - 14:165 16

(Legends: see page 22)

Vm Actual volume

The volume V1 (® 3.8) measured on the input is summed here provided no alarm is present. An alarm is present when a message "1" or "2" is located in any momentary status (® 3.8 ).

"Alarm" means any message with the number "1" or "2" ( ® 3.8).

Qm Actual flow rate

Momentary actual flow (actual flow rate). If the EK220 receives fewer than four pulses per hour on the counter input (terminal "DE1"), the flow rate is set to "0". The maximum inaccuracy of the indicated value corresponds to four pulses.

Example: The cp value of the pulse transmitter (® (Legends: see page 22)

cp.I1, page 60) is 0.1 pulses/m3 and the momentary flow rate is 3600 m3/h. Þ Pulse frequency = 3600 m3/h · 0.1 pulses/m3 = 360 pulses/h Þ max. inaccuracy = 4 pulses/h / 360 pulses/h = 1.11 %

VmD Vm disturbed

Here the actual volume is summed while ever an alarm is present, i.e. a message with the number "1" or "2" is located in any momentary status ( ® 3.8).

VmT Vm total

Here the sum of Vm + VmD is always displayed. Entries for Vm or VmD therefore also have an effect here. No entry for VmT itself can be carried out.

VmA Vm adjustable

Here, as with VmT, the total quantity, i.e. disturbed and undisturbed volumes are counted. In contrast to VmT, VmA can however be changed manually. This counter is typically set to the same reading as the gas meter in order to be able to easily detect deviations by comparison of the two counter readings.

VmME Vm month-end value

VmME saves the current month-end value at the change of month at the day boundary.

Time Time of VmME

Date and time of the saved VmME.

26 © Elster GmbH

Volume Conversion Device EK220

3.4 Pressure list

The values displayed in this list depend on whether a second pressure sensor is connected to the EK220 and is activated via Sel.p2 (see Chapter 3.10 ).

a) One pressure sensor connected to the EK220, Sel.p2 = 0 ("off"):

AD Designation / value Unit Access Address DC

p Pressure bar - 7:310_1 4 pMin Lower alarm limit pressure bar C 7:3A8_1 8 pMax Upper alarm limit pressure bar C 7:3A0_1 8 MRL.p Pressure meas. range lower limit bar C 6:224_1 8 MRU.p Pressure meas. range upper limit bar C 6:225_1 8 p.F Pressure substitute value bar S 7:311_1 8 pb Pressure at base conditions bar C 7:312_1 8 Md.p Pressure mode - C 7:317 7 Typ.p Pressure sensor type - C 6:223 8 SNp Serial no. of pressure sensor - C 6:222 8 SMenu p coeff. Submenu pressure coefficients - (C) 12:1C1 8 pAdj1 Adjustment value 1 for pressure bar C / S 6:260_1 8 pAdj2 Adjustment value 2 for pressure bar C / S 6:261_1 8 Prog Accept pressure adjustment - C / S 6:259 2 p.atm Ambient pressure fixed value bar C 6:212_1 8 p.Mes Pressure measurement bar - 6:211_1 4 p.Abs Absolute pressure measurement bar - 6:210_1 4

(Legends: see page 22)

Volume Conversion Device EK220

b) Two pressure sensors1 connected to the EK220, Sel.p2 = 1 ("CT30"):

AD Designation / value Unit Access Address DC

(Legends: see page 22)

The unit of the various pressure displays can vary depending on the device setting. The setting of the unit takes place via the WinPADS parameterisation software with the aid of parameter files. To do this the appropriate lock must be open. Possible units are: bar, kPa, psi and MPa.

Furthermore, representation as overpressure or absolute pressure is possible. Exceptions here are the adjustment values for the pressure (pAdj1, pAdj2, p2Ad1 and p2Ad2) and the atmospheric pressure (p.atm) which are always displayed as absolute pre ssure.

p Pressure pMin Lower alarm limit pressure pMax Upper alarm limit pressure

p is the pressure which is used for computing the conversion factor (® 3.6) and hence the volume at base conditions (® 3.2). If the measured pressure p.Abs (see below) is within the alarm limits pMin and

pMax, it is used as p: p = p.Abs.. If p.Abs is located outside the alarm limits, the substitute value p.F (see below) is used: p = p.F. In addition, disturbance quantities are then counted (® 3.2, 3.3) and the message "p Alarm Lim." displayed (® page 48).

It is only possible to connect two pressure sensors of type CT30!

28 © Elster GmbH

MRL.p Pressure meas. range lower limit MRU.p Pressure meas. range upper limit

These details of the measurement range are used to identify the pressure se nsor. They have no effect on the measurements.

p.F Pressure substitute value

If the measured pressure p.Abs is outside the alarm limits pMin and pMax (see below), p.F is used as pressure p for correction. p = p.F.

pb Pressure at base conditions

The pressure at base conditions is used for computing the conversion factor (® 3.6) and hence the volume at base conditions

Md.p Pressure mode

With Md.p = "1" the measured pressure p.Abs (see below) is used for correction, provided it does not violate the alarm limits.

With Md.p = "0" the fixed value (substitute value) p.F is always used for correction. No disturbance quantities are counted.

Typ.p Pressure sensor type SNp Serial no. of pressure sensor

Identification of the pressure sensor associated with the EK220.

SMenu Submenu pressure coefficients

Here, <ENTER> is used to recall the submenu with the coefficients for the pressure calculation (p.Mes) (® 3.4).

pAdj1 Adjustment value 1 for pressure pAdj2 Adjustment value 2 for pressure Prog Accept pressure adjustment

These values are used for the adjustment of the pressure measurement, i.e. for the internal computation of the equation coefficients for the pressure (see above). The adjustment takes place in three steps:

1. Apply measurement pressure 1 (= reference value 1) to the pressure sensor

and enter as pAdj1.

2. Apply measurement pressure 2 (= reference value 2) to the pressure sensor

and enter as pAdj2.

3. Enter Prog = "1" so that the EK220 calculates the equation coefficients.

Volume Conversion Device EK220

After applying the measurement pressure, you should either wait about one minute each time before entering the adjustment or press the key combination ENTER a number of times during the display of the pressure measurement p.Mes (see below) until the displayed value is stable. Approx. 0.4 ž pMax and approx. 0.9 ž pMax should be selected as adjustment values.

p.atm Ambient pressure fixed value p.Mes Pressure measurement p.Abs Absolute pressure measurement

p.Abs is the sum of p.atm and p.Mes: p.Abs = p.atm + p.Mes For p.atm, when an absolute sensor is used, "0" is entered and the ambient pres-

sure is entered when a gauge pressure sensor is used. p.Mes is absolute or gauge depending on the pressure sensor. If the absolute pressure p.Abs is within the alarm limits pMin and pMax (see

above), then it is used as the pressure p for correction: p = p.Abs.

Volume Conversion Device EK220

SMenu Press2

Here, <ENTER> is used to recall the submenu for the parameters of the second pressure sensor (® 3.4.1).

p2Mes Pressure measurement

p2Mes is the pressure measured by the second pressure sensor. Depending on the pressure sensor, p2Mes is displayed as the absolute pressure or overpre ssure.

3.4.1 Submenu pressure sensor 2 „ SMenu Press. 2 “

AD Designation / value Unit Access Address DC

p2.LW Lower warning limit pressure 2 bar S 15:150 8

p2.UW Upper warning limit pressure 2 bar S 15:158 8 MdM.W Mode for monitoring pressure 2 - S 15:157 7 MRLp2 Pressure 2 meas. range lower limit bar C 7:224_1 8 MRUp2 Pressure 2 meas. range upper limit bar C 7:225_1 8 Typp2 Pressure sensor 2 type - C 7:223 8 SNp2 Serial no. of pressure sensor 2 - C 7:222 8 E1p2 Coefficient 1 of pressure equation 2 - S 7:280 8 E2p2 Coefficient 2 of pressure equation 2 - S 7:281 8 E3p2 Coefficient 3 of pressure equation 2 - S 7:282 8 p2Ad1 Adjustment value 1 for pressure 2 bar S 7:260_1 8 p2Ad2 Adjustment value 2 for pressure 2 bar S 7:261_1 8 Prog Accept pressure adjustment 2 - S 7:259 2 p2Mes Pressure 2 measurement bar - 7:211_1 4 p2Abs Absolute pressure 2 measurement bar - 7:210_1 4

(Legends: see page 22)

p2.LW Lower warning limit pressure 2 p2.UW Upper warning limit pressure 2

These values are used to monitor the gas pressure p2Mes that is present at the second pressure sensor. The message "p2-warning limit" is entered in St.7 as soon as p2Mes exceeds the upper limit value p2.OW or falls below the lower limit value p2.UW. (® Page 3.4)

Several different results can in turn be programmed for this message, e.g. entry of the status change in the logbook (® 3.8) or activation of a signal output (® 3.12)

MdM.W Mode for monitoring pressure 2

Mode MdÜp2 facilitates the activation or deactivation of the monitoring of the gas pressure p2Mes at the second pressure sensor, taking the entered warning limits

p2.UW and p2.OW into account (see above)

MdÜp2 = "0": The gas pressure p2Mes is not monitored. MdÜp2 = "12": The monitoring of gas pressure p2Mes is performed within pro-

grammed warning limits.

F For reasons that are inherent in the system, further values are offered after e n-

try of the key combination ENTER, but which are not sensibly applicable here.

30 © Elster GmbH

MRLp2 Pressure meas. range lower limit MRUp2 Pressure meas. range upper limit

These details of the measurement range are used to identify the pressure se nsor. They have no effect on the measurements.

Typp2 Pressure sensor type SNp2 Serial no. of pressure sensor

Identification of the second pressure sensor associated with the EK220.

E1p2 Coefficient 1 of pressure equation 2 E2p2 Coefficient 2 of pressure equation 2 E3p2 Coefficient 3 of pressure equation 2

The coefficients of the quadratic equation for calculating the pressure p2Mes from the raw pressure value Binp2 (® 3.10):

p2Mes = E1p2 + E2p2 ž Binp2 + E3p2 ž Binp22 To adjust the pressure measurement, the 3 coefficients of the quadratic equation

can either be found by the EK220 itself or calculated and entered by the user. External to the EK220, the three coefficients can be calculated based on three values for Binp2 and the corresponding reference values. When the EK220 determines the coefficients, it uses the value for E3p2 available at the time of entering Prog (see below) and it calculates the corresponding E1p2

and E2p2 for this. The standard value for E3p2 is "0".

p2Ad1 Adjustment value 1 for pressure 2 p2Ad2 Adjustment value 2 for pressure 2 Prog Accept pressure adjustment

These values are used for the adjustment of the pressure measurement, i.e. for the internal computation of the equation coefficients for the pressure (see above).

The adjustment takes place in three steps:

1. Apply measurement pressure 1 (= reference value 1) to the pressure sensor and enter as p2Ad1.

2. Apply measurement pressure 2 (= reference value 2) to the pressure sensor and enter as p2Ad2.

3. Enter Prog = "1" so that the EK220 calculates the equation coefficients.

Volume Conversion Device EK220

After applying the measurement pressure, you should either wait about one minute each time before entering the adjustment or press the key combination ENTER a number of times during the display of the pressure measurement p2Mes (see below) until the displayed value is stable. Approx. 0.4 ž pMax and approx. 0.9 ž pMax should be selected as adjustment values.

p2Mes Pressure 2 measurement p2Abs Absolute pressure 2 measurement

p2Abs is the sum of p.atm and p2Mes: p2Abs = p.atm + p2Mes For p.atm, when an absolute sensor is used, "0" is entered and the ambient pre s-

sure is entered when a gauge pressure sensor is used. p2Mes is absolute or gauge depending on the pressure sensor.

Volume Conversion Device EK220

3.4.2 Submenu pressure coefficients

The values shown in this list depend on the set the type of pressure sensor Sel.p (® 3.10):

a) Pressure sensor type CT30, Sel.p = 1 ("CT30"):

AD Designation / value Unit Access Address DC

Eq1p Coefficient 1 of pressure equation - C / S 6:280 8 Eq2p Coefficient 2 of pressure equation - C / S 6:281 8 Eq3p Coefficient 3 of pressure equation - C / S 6:282 8

(Legends: see page 22)

Eq1p Coefficient 1 of pressure equation Eq2p Coefficient 2 of pressure equation Eq3p Coefficient 3 of pressure equation

The coefficients of the quadratic equation for calculating the pressure p.Mes from the raw pressure value Bin.p (® 3.10):

p.Mes = Eq1p + Eq2p ž Bin.p + Eq3p ž Bin.p2 To adjust the pressure measurement, the 3 coefficients of the quadratic equation

can either be found by the EK220 itself or calculated and entered by the user. External to the EK220, the three coefficients can be calculated based on three

values for Bin.p and the corresponding reference values. When the EK220 determines the coefficients, it uses the value for Eq3p available

at the time of entering Prog (see below) and it calculates the corresponding Eq1p and Eq2p for this. The standard value for Eq3p is "0".

32 © Elster GmbH

Volume Conversion Device EK220

b) Pressure sensor type 17002, Sel.p = 4 ("17002"):

AD Designation / value Unit Access Address DC

a0p1 Coefficient a0 of pressure equation - C / S 6:290_1 8 a1p1 Coefficient a1 of pressure equation - C 6:290_2 8 a2p1 Coefficient a2 of pressure equation - C 6:290_3 8 a3p1 Coefficient a3 of pressure equation - C 6:290_4 8 b0p1 Coefficient b0 of pressure equation - C / S 6:291_1 8 b1p1 Coefficient b1 of pressure equation - C 6:291_2 8 b2p1 Coefficient b2 of pressure equation - C 6:291_3 8 b3p1 Coefficient b3 of pressure equation - C 6:291_4 8 c0p1 Coefficient c0 of pressure equation - C 6:292_1 8 c1p1 Coefficient c1 of pressure equation - C 6:292_2 8 c2p1 Coefficient c2 of pressure equation - C 6:292_3 8 c3p1 Coefficient c3 of pressure equation - C 6:292_4 8 d0p1 Coefficient d0 of pressure equation - C 6:293_1 8 d1p1 Coefficient d1 of pressure equation - C 6:293_2 8 d2p1 Coefficient d2 of pressure equation - C 6:293_3 8 d3p1 Coefficient d3 of pressure equation - C 6:293_4 8 a.Up Coefficient a for pressure main value - C / S 6:272 8 b.Up Coefficient b for pressure main value - C / S 6:273 8 a.RB Coefficient a for pressure auxiliary value - C / S 6:27A 8 b.RB Coefficient b for pressure auxiliary value - C / S 6:27B 8

(Legends: see page 22)

a0p1 to a3p1 Coefficients a0 to a3 of pressure equation b0p1 to b3p1 Coefficients b0 to b3 of pressure equation c0p1 to c3p1 Coefficients c0 to c3 of pressure equation d0p1 to d3p1 Coefficients d0 to d3 of pressure equation a.Up Koeffizient a for pressure main value b.Up Koeffizient b for pressure main value a.RB Koeffizient a for pressure auxiliary value b.RB Koeffizient b for pressure auxiliary value

The coefficients are used to calculate the pressure pMes from the pressure raw value Bin.p (® 3.10).

Volume Conversion Device EK220

3.5 Temperature list

AD Designation / value Unit Access Address DC

T Temperature °C - 6:310_1 4 TMin Lower alarm limit temperature °C C 6:3A8_1 8 TMax Upper alarm limit temperature °C C 6:3A0_1 8 MRL.T Temperature meas. range lower limit °C C 5:224_1 8 MRU.T Temperature meas. range upper limit °C C 5:225_1 8 T.F Temperature substitute value °C S 6:311_1 8 Tb Temperature at base conditions K C 6:312 8 Md.T Temperature mode - C 6:317 7 Typ.T Temp. sensor type - C 5:223 8 SNT Serial number of temperature sensor - C 5:222 8 SMenu T coeff. Submenu temperature coefficients - (C) 11:1C1 8 Eq2T Coefficient 2 of temperature equation - C / S 5:281 8 Eq3T Coefficient 3 of temperature equation - C / S 5:282 8 TAdj1 Adjustment value 1 for temperature °C C / S 5:260_1 8 TAdj2 Adjustment value 2 for temperature °C C / S 5:261_1 8 Prog Accepts temperature adjustment - C / S 5:259 2 T.Mes Temperature measurement °C - 5:210_1 4

(Legends: see page 22) The unit of the various temperature displays, except for the standard temperature, can vary depending on the device setting. The setting of the unit takes place via the WinPADS

parameterisation software with the aid of parameter files. To do this the appropriate lock must be open. Possible units are: °C, K and °F

T Temperature TMin Lower alarm limit temperature TMax Upper alarm limit temperature

T is the temperature which is used for computing the conversion factor (® 3.6) and hence the volume at base conditions (® 3.1). If the measured temperature T.Mes (see below) is within the alarm limits TMin and TMax (see below), it is used as T: T = T.Mes. If T.Mes is located outside the alarm limits, the substitute value T.F (see below) is used: T = T.F. In addition, disturbance quantities are then counted (® 3.2, 3.3) and the message "T Alarm Lim." displayed (® page 48).

MRL.T Temperature meas. range lower limit MRU.T Temperature meas. range upper limit

These details of the measurement range are used to identify the temp. sensor.

T.F Temperature substitute value

If the measured temperature T.Mes is outside the alarm limits TMin and TMax (see below), T.F is used as temperature T for correction. T = T.F.

Tb Temperature at base conditions

The temperature at base conditions is used for computing the conversion factor (® 3.6) and hence the volume at base conditions.

34 © Elster GmbH

Md.T Temperature mode

With Md.T = "1" the measured temperature T.Mes (see below) is used for correction, provided it does not violate the alarm limits.

With Md.T = "0" the fixed value (substitute value) T.F is always used for correction. No disturbance quantities are counted.

Typ.T Temperature sensor type SNT Serial number of temperature sensor

Identification of the temperature sensor associated with the EK220.

SMenu Submenu temperature coefficients

Here, <ENTER> is used to recall the submenu with the coefficients for the temperature calculation (T.Mes) (® 3.5).

TAdj1 Adjustment value 1 for temperature TAdj2 Adjustment value 2 for temperature Prog Accept temperature adjustment

These values are used for the adjustment of the temperature measureme nt circuit, i.e. for the internal computation of the equation coefficients for the temperature (see above).

The adjustment takes place in three steps:

1. Apply measurement temperature 1 (= reference value 1) on the temperature sensor and enter as TAdj1.

2. Apply measurement temperature 2 (= reference value 2) on the temperature sensor and enter as TAdj2.

3. Enter Prog = "1" so that the EK220 calculates the equation coefficients.

After applying the measurement temperature, you should either wait about one minute each time before entering the adjustment or press ENTER number of times during the display of the temperature measurement T.Mes (see below) until the displayed value is stable.

To optimise the accuracy, the adjustment values should be located as close as possible to the measurement range limits MRL.T and MRU.T (e.g. -10°C and +60°C).

T.Mes Temperature measurement

If the measured temperature T.Mes is within the alarm limits TMin and TMax (see below), then it is used as the temperature T (see above) for correction. T = T.Mes.

Volume Conversion Device EK220

3.5.1 Submenu temperature coefficients

AD Designation / value Unit Access Address DC

Eq1T Coefficient 1 of temperature equation - C / S 5:280 8 Eq2T Coefficient 2 of temperature equation - C / S 5:281 8 Eq3T Coefficient 3 of temperature equation - C / S 5:282 8

(Legends: see page 22)

Eq1T Coefficient 1 of temperature equation Eq2T Coefficient 2 of temperature equation Eq3T Coefficient 3 of temperature equation

The coefficients of the quadratic equation for calculating the temperature T.Mes from the raw temperature value Bin.T (® 3.10):

T.Mes = Eq1T + Eq2T ž Bin.T + Eq3T ž Bin.T2 To adjust the temperature measurement circuit, the three coefficients of the quad-

ratic equation can either be found by the EK220 itself or calculated and entered by the user.

External to the EK220, the three coefficients can be calculated based on three values for Bin.T and the corresponding reference values.

When the EK220 determines the coefficients, it uses the value for Eq3T set at the time of entering Prog (see below) and it calculates the corresponding Eq1T and Eq2T for this.

3.6 Volume corrector list

The values shown in this list depend on the set computation method Md.K (see below) for the K-value (gas law deviation factor):

a) Computation according to S-Gerg-88 (Md.K = 1)

AD Designation / value Unit Access Address DC

C Conversion factor - - 5:310 4 K K-value - - 8:310 4 pbX Pressure at base conditions for gas analysis input bar S 7:314_1 8

TbX

Ho.b Calorific value kWh/m3 CO2 Carbon dioxide content % S 11:314 8 H2 Hydrogen content % S 12:314 8 Rhob Density gas at base conditions kg/m3 S 13:314_1 8 K.F K-value substitute value - S 8:311 8 Md.K K-value mode - C / S 8:317 7

Temperature at base conditions for gas analysis input

°C S 6:314_1 8

S 10:314_1 8

36 © Elster GmbH

Volume Conversion Device EK220

b) Computation according to AGA-NX19 (Md.K = 2)

AD Designation / value Unit Access Address DC

C Conversion factor - - 5:310 4 K K-value - - 8:310 4 pbX Pressure at base conditions for gas analysis input bar S 7:314_1 8 TbX Temp. at base conditions for gas analysis input °C S 6:314_1 8 Ho.b Calorific value kWh/m3

S 10:314_1 8 CO2 Carbon dioxide content % S 11:314 8 N2 Nitrogen content % S 14:314 8 dr Density ratio - S 15:314 8 K.F K-value substitute value - S 8:311 8 Md.K K-value mode - C / S 8:317 7

c) Computation according to AGA 8 Gross characterization method 1 (Md.K = 3)

AD Designation / value Unit Access Address DC

C Conversion factor - - 5:310 4 K K-value - - 8:310 4 pbX Pressure at base conditions for gas analysis input bar S 7:314_1 8 TbX Temperature at base cond. for gas analysis input °C S 6:314_1 8 Ho.b Calorific value kWh/m3

S 10:314_1 8 CO2 Carbon dioxide content % S 11:314 8 dr Density ratio - S 15:314 8 K.F K-value substitute value - S 8:311 8 Md.K K-value mode - C / S 8:317 7

d) Computation according to AGA 8 Gross characterization method 2 (Md.K = 4)

AD Designation / value Unit Access Address DC

C Conversion factor - - 5:310 4 K K-value - - 8:310 4 CO2 Carbon dioxide content % S 11:314 8 N2 Nitrogen content % S 14:314 8 dr Density ratio - S 15:314 8 K.F K-value substitute value - S 8:311 8 Md.K K-value mode - C / S 8:317 7

e) Computation according to AGA-NX19 following Herning & Wolowsky (Md.K = 5)

AD Designation / value Unit Access Address DC

Volume Conversion Device EK220

f) Constant K value (Md.K =0)

AD Designation / value Unit Access Address DC

C Conversion factor - - 5:310 4 Ho.b Calorific value kWh/m3

S 10:314_1 8 K.F K-value substitute value - S 8:311 8 Md.K K-value mode - C / S 8:317 7

(Legends: see page 22)

The rated operating conditions applying to the various conversion methods are described in Chapter 4.1.

C Conversion factor

The conversion factor is calculated according to the following formula:

C ××=

(p, pb: ® 3.4, T, Tb ® 3.5, K: see below)

K Compressibility factor ratio (K-value)

The K-value is used for computing the conversion factor (see above). It is calculated according to the following formula:

K =

where z = compressibility factor and zb = compressibility factor at base conditions. The computation of z and zb takes place according to S-Gerg-88 or AGA-NX19,

depending on the setting of Md.K. The gas analysis values Ho.b, CO2, H2 and Rhob (Md.K = 1), resp. N2 and dr (Md.K = 2, 3 and 4) need to be included in the entries for this (® 3.6). If the K-value mode Md.K (see below) is set to "fixed value" (= "0"), K is not computed, but the substitute value K.F (see below) is used instead.

pbX Pressure at base conditions for gas analysis input TbX Temperature at base conditions for gas analysis input

The base condition described by pbX and TbX is valid for the gas analysis input (Ho.b, CO2, … dr, see below) only. By contrast, the conversion factor C (® 3.6) and the volume at base conditions Vb (® 3.2) will be computed using the base condition described by pb and Tb (® 3.4 resp. 3.5). Any change of pb or Tb will change pbX resp. TbX to the same value. To get di fferent values, change pbX or TbX after pb or Tb.

38 © Elster GmbH

Volume Conversion Device EK220

Ho.b Calorific value CO2 Carbon dioxide content H2 Hydrogen content (only for Md.K = 1) Rhob Density gas at base conditions (only for Md.K = 1) N2 Nitrogen content (only for Md.K = 2 and 4) dr Density ratio (only for Md.K = 2, 3 and 4)

Depending on the set K-value mode these four gas analysis values must be entered so that the K-value K can be computed. For computations according to S-Gerg-88 (Md.K = 1) and AGA-NX19 (Md.K = 2 and 5) only, the range of validity is:

Ho.b 6,0 ... 13,0 kWh/m3 CO2 0,0 ... 30,0 Mol-% H2 0,0 ... 10,0 Mol-% (only for Md.K = 1) Rhob 0,71 ... 1,16 kg/m3 (only for Md.K = 1) N2 0,0 ... 30,0 mol-% (only for Md.K = 2) dr 0,554 ... 0,900 (only for Md.K = 2)

F Furthermore, the following limits must be ensured by the gas supplier:

Methane CH4 50 - 100 % Propane C3H8 0 - 5 % Ethane C2H6 0 - 20 % Nitrogen N2 0 - 50 % Butane C4H10 0 - 1 % Pentane C5H12 0 - 0,5 %

F The respective new value is determined from the value entered during entry of the

K.F K-value substitute value

Md.K K-value mode

density gas at base conditions Rhob or of the density ratio dr!

If the K-value mode Md.K (see below) is set to "fixed value" (= "0"), the constant K.F is used instead of the calculated K-value K for the computation of the conver-

sion factor C (see above).

With Md.K you can set whether the conversion factor C (® 3.6) and hence the volume at base conditions Vb (® 3.1) are determined with the calculated K-value or

with the constant K-value, K.F:

Md.K = "0": The fixed value (substitute value) K.F is used. Md.K = "1": The K-value is calculated according to S-Gerg-88. Md.K = "2": The K-value is calculated according to AGA-NX19. Md.K = "3": The K-value is calculated according to AGA 8 gross char. method 1. Md.K = "4": The K-value is calculated according to AGA 8 gross char. method 2. Md.K = "5": The K-value is calc. acc. to AGA-NX19 following Herning & Wolowsky

Volume Conversion Device EK220

3.7 Archive list

AD Designation / value Unit Access Address DC

ArMo1 Monthly archive 1 - (S) 1:A30 8 ArMo2 Monthly archive 2 - (S) 2:A30 8 ArDay Day archive - (S) 7:A30 8 ArMP Measurement period archive - (S) 3:A30 8 MPer Measurement period Minutes S 4:150 8 MP.Re Remaining time of measurement period Minutes - 4:15A 15 FrMP Measurement period archive, freeze - S 3:A50 2

(Legends: see page 22)

The contents of the archives described here are suitable for processing with the "WinLIS" evaluation program. The data is allocated there to so-called "device numbers". Within each "device number" the so-called "channel number", indicating the type of data, is located at the fifth position from the right (ten thousands position).

Channel

Value

number

1 VbT Total volume at base conditions 2 Vb Volume at base conditions (undisturbed) 3 VmT Actual volume (total) 4 Vm Actual volume (undisturbed) 5 C Conversion factor 6 T Gas temperature 7 p Gas pressure 8 K K-value

Examples:

· Device number: 1438004 Þ Channel number = 3 Þ VmT (Actual volume, total)

· Device number: 1479321 Þ Channel number = 7 Þ p (Gas pressure)

ArMo1 Monthly archive 1

Entry point for the first monthly archive in which counter readings and consumption maxima from the last 24 months are saved. The day boundary (= month boundary ) "06:00 hrs." can be changed via the serial interfaces under the address 2:141.

"Check"

Each archive data row has the following entries: ABNo

Block number Storage time

VbDy max Time Stat Vm VmT VmMP max Time

Month's maximum

Stat VmDy max Time Stat St.2 St.4 Check

Status for VmMP max

Time Vb VbT VbMP max Time Stat

Time-point VbDy max

Month's maximum

Volume at base cond.

Status for VbDy max

Time-point VmDy max

Totaliser Vb

Actual volume

Status for VmDy max

Month's maximum

Totaliser Vm

Status 2 (incl. Vb)

Time-point VbMP max

Month's maximum

Status 4 (incl. Vm)

Status for VbMP max

Time-point VmMP max

Checksum

To "ABNo"

40 © Elster GmbH

Volume Conversion Device EK220

Temperature

ArMo2 Monthly archive 2

Entry point for the second monthly archive in which maxima, minima and some mean values for Qb, Qm, p, T from the last 24 months are saved.

The day boundary (= month boundary ) "06:00 hrs." can be changed via the serial interfaces under the address "2:141".

"Check"

Each archive data row has the following entries:

« ABNo

Block num-

ber

Time «

Storage time

« Qb max Time Stat Qb min Time Stat «

Month's ma-

ximum

Time-point Qb max

Status for Qb max

Month's minimum

Time-point Qb min

Status for Qb min

« Qm max Time Stat Qm min Time Stat «

Month's ma-

ximum

Time-point Qm max

Status for Qm max

Month's minimum

Time-point Qm min

Status for Qm min

« p.Mon Ø p.Mon max Time Stat p.Mon min Time Stat

Pressure

mean

Month's maximum

Time-point p max

Status for p max

Month's minimum

Time-point p min

Status for p min

« T.Mon Ø T.Mon max Time Stat T.Mon min Time Stat

mean

Month's maximum

Time-point T max

Status for T max

Month's minimum

Time-point T min

Status for T min

« K.Mon Ø C.Mon Ø St.7 St.6 St.8 St.5 Check «

K-value

mean

C factor mean

Status 7 (incl. p)

Status 6 (incl. T)

Status 8 (incl. K)

Status 5 (incl. C)

Checksum

To "ABNo"

ArMP Measurement period archive

Entry point for the measurement period archive where counter readings an d measurements are archived in the cycle of the measurement period MPer.

The archive structure of the measurement period archive is flexible and can be p arameterised with the aid of the "WinPADS" parameterisation software with the supplier's lock open.

F With deviations of the archive structure from standard the read-out data cannot

be used by the software from Elster GmbH for processing.

F Processing of the read-out data by the appropriate software from Elster GmbH

is possible if the archive structure is retained. This means that the settings of which counters and associated counter increments are saved in this archive are possible with the aid of the "WinPADS" parameterisation software with the su pplier's lock open and the read-out data can be processed.

The archive has approx. 3600 data rows with standard parameterisation, corr esponding to a memory depth of about 5 months for a measurement period of 60 minutes.

Volume Conversion Device EK220

Each archive data row has the following entries for standard paramete risation:

ABNo

"Check"

Block no. Saving time

D Vm

Counter progress

St.2 St.4 St.7 St.6 St.Sy Er Check

Status 2 (incl. Vb)

Time Vb

Volume at base cond.

VmT

Totaliser Vm

Status 4 (incl. Vm)

D VmT

Counter progress

Status 7 (incl. p)

D Vb

Counter progress

VbT

Totaliser Vb

D VbT

Counter progress

Actual volume

p.MP Ø T.MP Ø K.MP Ø C.MP Ø

Pressure mean

Status 6 (incl. T)

Temperature mean

System status

Inv. compr. ratio factor mean

Triggering event

Conversion factor mean

Checksum

The progress of the counters in comparison to the corresponding previous entries are identified with a "D". They are only shown in the display and are not read out via the interface. Normally, a flow (consumption) within a measurement period is involved. This only becomes relevant when an archive line has been entered due to a special event (e.g. setting of the clock or a counter, appearance of an important status me ssage). Then the segment "D" and the abbreviated designation flash at the dis- played counter progress to indicate this special occurrence to the user.

ArDay Day archive

Entry point for the day archive in which counter readings and measurements are daily archived. The archive has approx. 600 data rows, corresponding to a me mory depth of approx. 1.5 years. The structure and content correspond to the measurement period archive ArMP for standard parameterisation (see above), whereby the means of p, T, K and C now relate to the day.

MPer Measurement period

With the measurement period that can be set here, all values related to the measurement period are formed. These are: VbMP D (® 3.2), VmMP D (® 3.3), p.MP Ø (® 3.4) , T.MP Ø (® 3.5) as well as values present in the measurement period archive ArMP (see above). MPer must be an integer multiple of the operating cycle OCyc (® 3.9) so that the measurement period values (e.g. VbMP D, VbDy Æ, p.MP Æ, T.MP) can be concluded at the correct points in time. With the default setting for OCyc the following values for MPer are practicable and usual: 5, 10, 15, 20, 30 or 60 minutes.

FrMP Measurement period archive, freeze

A data row can be saved in the measurement period archive ArMP (see above) with this function. Based on the "trigger event" EvTr which is also saved, it can be seen in the data row whether it was saved automatically due to the expired measurement period or by triggering of FrMP.

to "ABNo."

42 © Elster GmbH

Volume Conversion Device EK220

3.7.1 Find function for checking the archive entries

The measurement period has more than a thousand and a few hundred entries respe ctively. In order to be able to display individual values from this amount of data for checking purposes, the device has a find function for archive entries. Values can be sought in the following columns:

· Block number

· Date and time

· Counter reading

First, the search occurs by choosing the desired column (block number, date/time or counter reading) in any archive line. Then pressing the "ENTER" key-combination enables the input of the desired value in this column. After terminating the input with "ENTER" the display skips to the archive line containing the entered value. If the entered value does not exist, it skips to the entry most closely resembling the sought value.

3.7.2 Measurement period archive 2

Measurement period archive 2 is used for saving redundant measurement period archive data. These are archived at intervals of the measurement period MPer. The structure and content correspond to the measurement period archive ArMP for standard parameterisation (see above). The archive structure cannot be changed. The archive has approx. 100 0 data rows which corresponds to a memory depth of approx. 40 days for a measurement period of 60 minutes.

Measurement period archive 2 is not displayed on the device and can be read out with the aid of the "WinPADS" parameterisation software.

3.7.3 Flexible archives 1 to 4

The archive structures of these archives are flexible and can be parameterised with the aid of the "WinPADS" parameterisation software with the supplier's lock open.

F Processing of the read-out data by software from Elster GmbH is not possible!

The flexible archives 1 to 4 are not displayed on the device and can be read out with the aid of the "WinPADS" parameterisation software.

Volume Conversion Device EK220

3.8 Status list

The values shown in this list depend on the set the functionality of certification data log PL (see page 58):

a) Functionality of certification data log activ, PL = 1 ("on"):

AD Designation / value Unit Access Address DC

S.Reg Status register, total - (S) 1:101 19 Stat Momentary register, total - - 1:100 5 Clr Clear status register - S 4:130 2 Logb. Logbook - (S) 4:A30 8 AudTr Audit trail - (S) 5:A30 8 PLogB Certification data log (calibration logbook) - - 9:A30 8 ClrPL Clear certification data log - C 9:A52 2

b) Functionality of certification data log inactiv, PL = 0 ("off"):

AD Designation / value Unit Access Address DC

S.Reg Status register, total - (S) 1:101 19 Stat Momentary register, total - - 1:100 5 Clr Clear status register - S 4:130 2 Logb. Logbook - (S) 4:A30 8 AudTr Audit trail - (S) 5:A30 8

(Legends: see page 22)

S.Reg Status register, total Stat Momentary register, total

The EK220 supplies two types of status information: Momentary status (also known as "status") and the status register.

Messages in the momentary status point to current statuses such as for example, e rrors that are present. When the state is no longer present, the corresponding me ssage in the momentary status disappears. Manual deletion is not possible. Alarms, warnings and reports (i.e. messages with numbers in the range from "1" to "16") are displayed in the momentary statuses.

- In the status register all messages since the last manual clearing are collected. Here, you can also see what has happened, for example, since the last station inspection. The messages can be cleared in this list with the command "Clr". Only alarms and warnings (i.e. messages with numbers in the range from "1" to "8") are displayed in status registers. Reports are not entered because they identify states which are not problematical or may even be intended (e.g. "Daylight saving", "Calibration lock open" or "Data transfer running").

44 © Elster GmbH

Volume Conversion Device EK220

- S.Reg and Stat initially show all existing messages as numbers. With the entry of <ENTER> they can be recalled individually as short texts: First the most important

message (with the lowest number) is displayed. With the keys ® and ¬ you can change to the next, respectively the previous message. In addition to the short text the display also shows

- in the upper row to the right the associated status register name and

- in the lower row to the left the message number (prefixed with "#"'). You need the status register name and the message number, for example, for ente r-

ing a "status pointer" for the outputs (SpO1 ... Sp04, page 67). All status messages are listed in Chapter 3.8.1 (from page 47). Deleting messages: After entering <

ENTER

> the messages in SReg (not in Stat) can be cleared (acknowledged) singly by pressing the key combination ¬ + - . With the command Clr (see below) all messages in "SReg" can be cleared simultaneously.

Clr Clear status register

This enables you to clear all the status register contents, i.e. "S.Reg" and its complete submenu: By pressing <ENTER> a “0” appears right justified on the display. By switching to “1” and finish with <ENTER> all statusregisters were cleared. If the alarm or warning states are however still present, they are again directly entered as me ssages. The messages in SReg can also be cleared singly: see SReg.

Logb. Logbook (event logbook)

Entry addresses for the logbook in which the last 500 status changes are archived. Each archive data row has the following entries:

ABNo

to "Check"

Block number Saving time Trigger event Checksum

Time Er Check

to "ABNo"

AudTr Audit trail (changes logbook)

Entry addresses for the changes logbook (audit trail) in which the last 200 settings changes (parameterisations) are archived.

Each archive data row has the following entries:

to "Check"

ABNo

Block number Saving time Address changed val. Old value New value

St.PL St.ML St.SL St.CL Check

Calibration lock Manuf. lock Supplier lock Customer lock Checksum

Time Addr o n

to "ABNo"

Volume Conversion Device EK220

PLogB Certification data log (Calibration logbook)

With the aid of the "Certification data log" according to PTB-A 50.7 some parameters relevant to calibration regulations can be changed also with the calibration lock closed. Prerequisites for this are:

- The supplier's lock (see below) must be open.

- At least three free entries must be available in the certification data log.

The affected parameters (e.g. cp value, measurement period) are identified with the access right "PL" in the lists in this capital. For each change of such a parameter with the calibration lock closed a data row is in each case entered with the value before and after the change. Additionally, an entry is always made on opening and closing the calibration lock. The calibration logbook has 50 data rows. Since the first data row always logs the closure of the calibration lock and the last data row is always kept free for opening the calibration lock, a maximum of 48 parameter changes can be entered. With a logbook which is fully written up the status message "PLogb full"is displayed in the system status (® page 50) and "L" (® page 12) flashes in the display field "Status". The certification data log can be cleared with the calibration lock open using the command ClrPL (see below).

F If the calibration lock is opened with the certification data log full, it can only be

closed again after clearing the certification data log.

F The affected values are subjected to the calibration lock when the calibration

logbook is deactivated. (see Addr, Page 58)

The data rows of the certification data log have the following entries:

ABNo

to "Check"

Block number Saving time Address changed val. Old value New value

St.PL St.ML St.SL St.CL Check

Calibration lock Manuf. lock Supplier lock Customer lock Checksum

ClrPL Clear certification data log

This means that all entries in the calibration logbook PlogB (see above) can be deleted:

After calling by ENTER, an "0" is positioned right-justified in the display. The function is triggered, i.e. all records are cleared, after switching to "1" (with -) and terminating with <ENTER>.

Time Addr o n

to "ABNo"

46 © Elster GmbH

Calibration lock

3.8.1 List of status messages

Volume Conversion Device EK220

Code

in status Short text Meaning

1 StSy SRSy Restart Restart of the device 1 St.5 SR.5 C-fact.err. Conversion factor cannot be computed 1 St.6 SR.6 T Alarm Lim. Alarm limits for temperature violated

1 St.7 SR.7 p Alarm Lim. Alarm limits for pressure violated 1 St.8 SR.8 K-val. error Inv. compr. ratio factor cannot be computed

Alarm

1 St.9 SR.9 Z-fact. err. Compressibility factor cannot be computed 2 St.5 SR.5 T Inp. Error No usable input values for temperature 2 St.6 SR.6 p Inp. error No usable input values for pressure 3 StSy SRSy Dat.restore Data has been restored 4 St.1 SR.1 Outp.1 error Error on Output 1 4 St.2 SR.2 Outp.2 error Error on Output 2 4 St.3 SR.3 Outp.3 error Error on Output 3 4 St.4 SR.4 Outp.4 error Error on Output 4

5 St.2 SR.2 I2 Pulse cmp Error during pulse comparison on Input 2 6 St.6 SR.6 T Warn Lim. Warning limits for temperature violated 6 St.7 SR.7 p Warn Lim. Warning limits for pressure violated

Warning

7 StSy SRSy Soft. error Software error 8 StSy SRSy Settings e. Setting error 8 St.2 SR.2 I2 Warn.sig. Warning signal on Input I2 8 St.3 SR.3 I3 Warn.sig. Warning signal on Input I3 8 St.7 SR.7

p2 Warn Lim. Warning limits for pressure 2 violated

9 StSy Batt. low Battery service life below limit 10 StSy Repair mode Repair mode switched on 11 StSy Clock n. set Clock not set 12 StSy PLogb full Certification data log (calibration logbook) full 13 StSy online Data transmission running 13 St.2 I2 Rep.sig. Report signal on Input I2 13 St.3 I3 Rep.sig. Report signal on Input I3 14 St.1

Calibration lock open 14 St.2 Man.lock o. Manufacturer's lock is open 14 St.3 Supp.lock o. Supplier's lock is open

Report

14 St.4 Cust.lock o. Customer's lock is open 15 StSy Batt.operat. Battery operation 15 St.1 Call Win.1+ Extended call acceptance time window 1 16 StSy Dayl.Sav.Tim The displayed time is summer time 16 St.1 Call Win.1 Call acceptance time window 1 is active 16 St.2 Call Win.2 Call acceptance time window 2 is active 16 St.3 Call Win.3 Call acceptance time window 3 is active 16 St.4 Call Win.4 Call acceptance time window 4 is active

Alarm: Instead of the relevant measurement the substitute value is used; quantities are

counted in disturbance quantity counters.

Warning: The message is retained in the status register until it is manually deleted.

Report: The message is not retained in the status register.

Volume Conversion Device EK220

Restart Restart of the device Message 1 in StSy

The device was started without usable data. Counter readings and archives are empty, the clock has not been set.

C-fact. err. Conversion factor cannot be computed Message 1 in St.5

The conversion factor C (® 3.6) cannot be computed because the temperature T (® 3.5) is outside the range or no usable K-value K (® 3.6) is available (cf. mes- sage "K-val. error."). Possibly the temperature sensor is not connected correctly or the substitute value for the K-value K.F (® 3.6) has the value "0". The conversion factor is set to "0" and disturbance quantities for Vb are counted in VbD (® 3.2). With the correct device setting, this message does not occur, because, for example, when an alarm limit, TMin or TMax (® 3.5), is exceeded, the temperature substitute value T.F is used.

T Alarm Lim. Alarm limits for temperature violated Message 1 in St.6

The measured gas temperature T.Mes is located outside of the set alarm limits TMin, TMax (® 3.5).

While ever this message is present in St.6, the substitute temperature T.F (® 3.5) is used for volume correction and disturbance quantities are counted for Vb and Vm

(® 3.2, 3.3). The alarm limits can be changed with the calibration lock open. If they are set to the same value, they are ignored, i.e. they cannot give rise to any alarm messages nor disturbance quantities.

p Alarm Lim. Alarm limits for pressure violated Message 1 in St.7

The measured gas pressure p.Abs is located outside of the set alarm limits pMin, pMax (® 3.4).

While ever this message is present in St.7, the substitute pressure p.F (® 3.4) is used for volume correction and disturbance quantities are counted for Vb and Vm

K-val. error Inv. compr. ratio factor cannot be computed Message 1 in St.8

The K-value K (® 3.6) cannot be computed because no valid compressibility factor could be determined. (cf. message "C-fact. err.")

While ever this problem exists, the substitute value K.F is used for the K-value and disturbance quantities are counted for Vb and Vm (® 3.2, 3.3).

Z-fact. err. Compressibility factor cannot be computed Message 1 in St.9

At least one of the gas analysis values Ho.b, CO2, H2, Rhob (® 3.6) is located outside of the permissible range.

While ever this problem exists, the last valid value for each of the affected gas anal ysis values is used and disturbance quantities are counted for Vb and Vm (® 3.2,

3.3). If a valid value has not yet been able to be calculated (because the gas analysis has not till now been correct), the compressibility factor is set to "0". Consequently therefore, also no K-value can be computed. (See above: message "K-val. error").

48 © Elster GmbH

Volume Conversion Device EK220

T Inp. Error No usable input values for temperature Message 2 in St.5

The signal, Bin.T (® 3.10), measured on the temperature input is outside the valid range. Perhaps the sensor is not correctly connected.

In this case the substitute temperature T.F (® 3.5) is used for volume correction and disturbance quantities are counted for Vb and Vm (® 3.2, 3.3).

p Inp. error No usable input values for pressure Message 2 in St.6

The signal, Bin.p (® 3.10 Service list), measured on the pressure input is outside the valid range. Perhaps the sensor is not correctly connected.

In this case the substitute pressure p.F (® 3.4) is used for volume correction and disturbance quantities are counted for Vb and Vm (® 3.2, 3.3).

Dat. restore Data has been restored Message 3 in StSy

The device was temporarily without any power supply. Possibly during battery replacement, the battery was removed before the new one was connected. Data has been retrieved from the non-volatile memory (EEPROM). The retrieved counter readings and the clock values are possibly out of date: If a manual data backup was carried out with the command "Save" before the voltage failure (® 3.10), the counter readings and clock values correspond to the state at the time of the data backup. Without manual data backup, the counter readings and clock values are retrieved with the state at the end of the last day before the voltage failure.

Outp.1 error Error on Output 1 Message 4 in St.1 Outp.2 error Error on Output 2 Message 4 in St.2 Outp.3 error Error on Output 3 Message 4 in St.3 Outp.4 error Error on Output 4 Message 4 in St.4

The volume pulses to be passed through an output are temporarily saved in a pulse buffer. The buffer can accommodate 65535 pulses. If the volume to be output is co ntinuously greater than that which can be output in the form of pulses, the pulse buffer continually fills and will eventually reach its maximum state. If then further pulses arrive, these can no longer be temporarily saved and are lost. The pulse buffer remains at its maximum state in this case.

If the pulse buffer drops below the level of 65000 pulses, the message is cleared again. To rectify the cause of this problem, the cp value of the output (® 3.12, Output

list) can be reduced or the output frequency (address 1:617) increased with an AS 200 Read-out Device or the WinPADS Parameterization Software.

With a change of the output cp value, the corresponding input buffer is cleared .

I2 Pulse cmp Error during pulse comparison on Input 2 Message 5 in St.2

Input 2 (E2) can be parameterised for monitoring as a pulse or signal input. When used as a pulse input, the pulses arriving on E2 can, for example, be compared with those on Input 1. With a deviation which is too large, this message is displayed. Settings for the pulse comparison can be made with MdMI2, SC.I2, L1.I2, G3.I2 und SpI2. Further explanation for this: ® 3.11.

T Warn Lim. Warning limits for temperature violated Message 6 in St.6

The measured temperature T.Mes is located outside of the set warning limits . The limits can be set with WinPADS. Supplier’s lock must be open.

p Warn Lim. Warning limits for pressure violated Message 6 in St.7

The measured gas pressure p.Mes is located outside of the set warning limits . The limits can be set with WinPADS. Supplier’s lock must be open.

Volume Conversion Device EK220

Soft. error Software error Message 7 in StSy This message is used for diagnosis at the factory. If it occurs during operation, con-

tact Elster GmbH or your local representative.

Settings e. Setting error Message 8 in StSy

On account of the programming that has been carried out, an unusable combin ation of settings arose, e.g. a value which cannot be processed in a certain mode.

Detailed information can be called up with special read-out programs via the serial interface under the address 1:1FA. However, they are coded and can only be inte rpreted by Elster GmbH.

I2 Warn.sig. Warning signal on Input E2 Message 8 in St.2

Input 2 can be parameterised for monitoring as a pulse or signal input . When set as signalling input, here this message is displayed while ever an active signal is present, i.e. the terminals are connected through a low resistance. For connection of a contact for tamper detection, the warning input can also be set such that message "8" is di splayed here while ever an inactive signal is present, i.e. the terminals are open. Settings for the message input can be made with MdMI2, SC.I2, L1.I2, G3.I2 und SpI2. Further explanation for this: ® 3.11.

I3 Warn.sig. Warning signal on Input E3 Message 8 in St.3

This message is displayed, for example, while ever an active signal is present, i.e. the terminals are connected through a low resistance. For conne ction of a contact for tamper detection, the warning input can also be set such that this message is di splayed while ever an inactive signal is present, i.e. the terminals are open. Settings for the message input can be made with MdMI3, SC.I3, L1.I3, G3.I3 and SpI3. Further explanation for this: ® 3.11.

p2 Warn Lim. Warning limits for pressure 2 violated Message 6 in St.7

The measured gas pressure p2Mes is located outside of the set warning limits p2.LW, p2.UW (® 3.4.1).

Batt. low Battery service life below limit Message 9 in StSy

The calculated remaining battery service life Bat.R (à Service list, Chapter 3.10) has fallen below the set limit.

The limit can be changed via the serial interface under the address 2:4A1. The standard setting is 3 months. So long as this message is displayed, the "B" in the display field "Status" flashes (à 2.2.1).

Repair mode Repair mode switched on Message 10 in StSy

The device is in the repair mode. This is switched on and off with Rep. (à 3.10).

Clock n. set Clock not set Message 11 in StSy

The running accuracy of the internal clock has been optimised in the factory by frequency measurement and a corresponding setting of the adjustment factor Adj.T

(® 3.10 Service list). The error message indicates that this has not yet been carried out.

PLogb full Certification data log full Message 12 in StSy

The certification data log (calibration logbook) is full. Without the calibration lock a change of the parameters identified with the access "PL" is only possible again when the content of the certification data log is cleared (® ClrPL, page 46). The calibration lock can only be closed again after clearing the certification data log.

online Data transmission running Message 13 in StSy

Data is currently being transmitted via one of the two serial interfaces (optical or permanently wired).

The data transmission cannot take place over both interfaces simultan eously. While ever this message is displayed, the "o" in the display field "Status" flashes (® 2.2.1).

50 © Elster GmbH

Volume Conversion Device EK220

I2 Rep.sig. Report signal on Input E2 Message 13 in St.2

Input 2 (E2) can, for example, be used as a time-synchronous input. As long as the input receives an active signal (i.e. the terminals are connected through low resistance), this message is displayed.

Settings for the message input can be made with MdMI2, SC.I2, L1.I2, G3.I2 und SpI2. Further explanation for this: ® 3.11.

I3 Rep.sig. Report signal on Input 3 Message 13 in St.3

Input 3 (E3) can, for example, be used as a time-synchronous input. As long as the input receives an active signal (i.e. the terminals are connected through low resi stance), this message is displayed. Settings for the message input can be made with MdMI3, SC.I3, L1.I3, G3.I3 and SpI3. Further explanation for this: ® 3.11. With special parameterization for the connection an FE230 Function Expansion, this message means "Data transmission running via FE230".

Calibration lock Calibration lock open Message 14 in St.1

For protection against unauthorised parameterization or reading out via a serial inte rface, the EK220 has a total of four locks in the following order of priority: Calibration, manufacturer's, supplier's and customer's locks. The calibration lock can be opened and closed using a sealable pushbutton which is

located inside the device (® 5.8.1). Closure is also possible by deleting the value "St.PL" (® 3.10) via the keypad or interface. While ever this message is displayed in St.1, the "P" in the display field "Status" flashes (® 2.2.1).

Man.lock o. Manufacturer's lock is open Message 14 in St.2

For protection against unauthorised parameterization or reading out via a serial inte rface, the EK220 has a total of four locks: Calibration, manufacturer's, supplier's and customer's locks. The manufacturer's lock is normally only opened for special applications by Elster GmbH staff and includes access for changing all values not subject to official calibr ation. It can only be opened and closed via a serial interface with an AS-200 Read-out Device or the WinPADS Parameterization Software.

Supp.lock o. Supplier's lock is open Message 14 in St.3

For protection against unauthorised parameterization or reading out via a serial inte rface, the EK220 has a total of four locks: Calibration, manufacturer's, supplier's and customer's locks. The supplier's lock is normally used by gas suppliers. It gives access for changing various values which are not subject to official calibration. The relevant values are identified in the lists (® 3) with an "S".

The supplier's lock can be opened and closed with "Cod.S" and "St.SL" ( ® 3.10).

Cust.lock o. Customer's lock is open Message 14 in St.4

For protection against unauthorised parameterization or reading out via a serial interface, the EK220 has a total of four locks: Calibration, manufacturer's, supplier's and customer's locks.

The customer's lock is normally used by gas customers. It gives access for changing some values which are not subject to official calibration. The relevant values are

identified in the lists (® 3) with a "K". The customer's lock can be opened and closed with "Cod.C" and "St.CL" ( ® 3.10 ).

Batt. operat. Battery operation Message 15 in StSy

This message is always displayed when the device is being supplied by its internal batteries, i.e. not by an external power supply.

Volume Conversion Device EK220

Call Win.1+ Extended call acceptance time window 1 Message 15 in St.1

This message is needed for the operation of an FE230 Function Expansion to switch on the FE230 power supply via an output terminal set as a status output.

The message largely corresponds to the message Call Win.1 (see below). If a data transmission is still running at the end of Call acceptance window 1, the message Call Win.1+ remains however entered until the data transmission has finished.

Dayl.Sav.Tim The displayed time is summer time Message 16 in StSy

In the system list (® 3.9) you can set under MdTim whether the EK220 carries out automatic daylight saving switchover or not.

Call Win.1 Call acceptance time window 1 is active Message 16 in St.1 Call Win.2 Call acceptance time window 2 is active Message 16 in St.2 Call Win.3 Call acceptance time window 3 is active Message 16 in St.3 Call Win.4 Call acceptance time window 4 is active Message 16 in St.4

The EK220 provides four time windows within which a modem connected to the serial interface accepts calls for data interrogation. Outside of these time windows calls are ignored, so that, for example, a person located in the station can be called via a telephone connected to the same telephone line.

The messages indicates that the responsible time window ( ® 3.13, Interface list) is.

3.8.2 Status register addresses

To read out the status information via the interface or to accept it into the user list (® page 23), its addresses are needed (cf. table on page 47):

AD * Stat Total momentary status 1:100 SReg Total status register 1:101 StSy System momentary status 2:100 SRSy System status register 2:101 St.1 Momentary status 1 1:110 SR.1 Status register 1 1:111 St.2 Momentary status 2 2:110 SR.2 Status register 2 2:111 St.3 Momentary status 3 3:110 SR.3 Status register 3 3:111 St.4 Momentary status 4 4:110 SR.4 Status register 4 4:111 St.5 Momentary status 5 5:110 SR.5 Status register 5 5:111 St.6 Momentary status 6 6:110 SR.6 Status register 6 6:111 St.7 Momentary status 7 7:110 SR.7 Status register 7 7:111 St.8 Momentary status 8 8:110 SR.8 Status register 8 8:111 St.9 Momentary status 9 9:110 SR.9 Status register 9 9:111

Description Address AD * Description Address

* "AD" = Abbreviated designation (value designation on the display)

52 © Elster GmbH

Volume Conversion Device EK220

3.9 System list

AD Designation / value Unit Access Address DC

Time Date and time - S 1:400 12 MdTim Daylight saving: yes / no - S 1:407 7 MCyc Measurement cycle time Seconds C 1:1F0 8 MCPul Measurement cycle triggered by input pulse - C 1:1FB_2 7 OCyc Operating cycle time Seconds S 1:1F1 8 Disp Time before display switches off Minutes S 2:1A0 8 Aut.V Time to changeover to standard display Minutes C 1:1A0 8 SNo Serial number of device - C 1:180 8 Ta.Rg Ambient temperature range - C 3:424 8 Vers Software version number - - 2:190 3 Chk Software checksum - - 2:191 4

(Legends: see page 22)

Time Date and time

The date and time are displayed separately. When moving to the right within the list structure, the date is displayed after the time. When moving to the left, only the time is displayed. After pressing the key combination ENTER for entry (set clock), the date and time are displayed together (initially without seconds). The input mark (cursor) is located on the right-hand display position, then after pressing ® again, the com- plete value is moved to the left so that the seconds can also be changed. The time is updated in synchronism with the operating cycle OCyc (see below) or

MdTim Daylight saving

MCyc Measurement cycle time

after key operation.

"0" = Automatic changeover between summer and winter time OFF. "1" = Automatic changeover between summer and winter time:

Summer time begins on the last Sunday in March at 2:00 hrs. and ends on the last Sunday in October at 2:00 hrs.

"2" = Switchover at set times

The start and finish of daylight saving is set under the addresses 1:4A0 and 1:4A8. The times must be set each year.

Measurements (e.g. pressure, temperature), computed values (e.g. K-value, conversion factor) and counter readings are updated on this cycle. To ensure all functions, MCyc must only be set to integer factors of 60 seconds, e.g. 5, 10, 15, 20, 30 or 60 seconds. In addition MCyc must be an integer factor of OCyc (see below). Entries of values not satisfying these conditions are, where possible, corrected automatically. If the EK220 does not find any suitable value during the correction attempt, it rejects the entry with error message "6". ( ® 2.3.2)

In applications subject to official calibration EN 12405 MCyc must be less than or equal to 30 seconds.

The standard setting is 30 seconds. With settings less than 30 seconds the battery service life is reduced. (® B-2)

Volume Conversion Device EK220

MCPul Measurement cycle triggered by input pulse

MCPul defines whether measurements and counter readings are acquired on the same interval as the measurement cycle time (see above) or with each counter impulse on Input 1:

"0" = Measurement at the intervals of the measurement cycle time MCyc (see above)

"1" = Measurement only for a counting pulse on Input 1 (DE1): If more than one input pulse is counted on Input 1 (DE1) during a measurement cycle MCyc (see above), then the next measurement occurs after the current measurement cycle has expired.

OCyc Operating cycle time

The time and all values which relate to a time interval (e.g. measurement period, 1 day, 1 month) are updated on this cycle. The latter includes in particular all values

for which a type of computation is displayed (® 2.2.1). OCyc must only be set to values which are integer factors or multiples of 60 se conds and which are also integer multiples of MCyc (see above). Entries of other values are, where possible, corrected automatically. If the EK220 does not find any suitable value during the correction attempt, it rejects the entry with error me ssage "6". (® 2.3.2) In addition, OCyc must be an integer factor of the measurement period MPer (® 3.7) so that the measurement period values can be concluded at the correct points in time. The standard setting is 300 seconds (= 5 minutes).

With settings less than 300 seconds the battery service life is reduced. (® B-2)

Disp Time before display switches off

In order to conserve the batteries the display switches off after key operation once the set time has expired.

The setting "0" signifies that the display is always switched on. With settings of "0" or greater than 10 minutes, the battery service life is reduced.

Ta.Rg Ambient temperature range

The permissible ambient temperature for the EK220 in operation subject to c alibration regulations.

Aut.V Time to changeover to standard display

The display automatically changes over to the standard display once the time set here has expired without any key operation. The setting "0" signifies that the display is not switched over. In applications subject to official calibration this setting is not however permissible. The standard setting is 1 minute. The number of the display column, to the first value of which switching takes place, can be set via the interface under address "1:01F2". The standard setting is "1", i.e. switching takes place to the standard volume column (® 3.2) with the first value Vb.

SNo Serial number

The serial number of the Volume Conversion Device (same number as on the identification label).

54 © Elster GmbH

Volume Conversion Device EK220

Vers Software version number Chk Software checksum

Version number and checksum provide clear identification of the software impl emented in the EK220.

By pressing the key combination <ENTER> ( - + ¯ ) during the display of Vers, the size (number of entries) of the measurement period archive ArMP (® 3.7) can be called. Return to Vers is with the key combination <ESC> ( - + à ).

3.10 Service list

AD Designation / value Unit Access Address DC

Bat.R Remaining battery service life Months - 2:404 15 Bat.C Battery capacity Ah S 1:1F3 8 St.SL Supplier's lock: Status / close - K 3:170 7 Cod.S Supplier's combination, enter / change - S 3:171 11 St.CL Customer's lock: Status / close - K 4:170 7 Cod.C Customer's combination, enter / change - or - K 4:171 11 St.PL Calibration lock: Status / close - C 1:170 7 Contr Display contrast - S 1:1F6 8 Adj.T Clock adjustment factor - C 1:452 8 Save Save all data - S 1:131 2 Clr.A Clear measurement archives - PL 1:8FD 8 Clr.V Clear counters (incl. archive) - C 2:130 2 Clr.X Initialise device - C 1:130 2 Bin.T Temperature binary value - - 5:227 4 Bin.p Pressure binary value - - 6:227 4 Bin2p Pressure 2 binary value - - 7:227 4 Sel.T Temperature sensor selection - C 5:239 7 Sel.p Pressure sensor selection - C 6:239 7 Selp2 Pressure sensor 2 selection - C 7:239 7 SMenu

Amb.temp.

Submenu ambiant temperature

- (C) 14:1C1 8

Addr Address for user display - S 14:1C2 21

... User display (value under address "Addr") ... ... ... ...

SMenu

Revisal

Submenu Revisal - (C) 15:1C1 8

ArCal Frozen values - (S) 6:A30 8 Frz. Freeze - S 6:A50 2

- Display test - - 1:1F7 1

(Legends: see page 22)

Volume Conversion Device EK220

Bat.R Remaining battery service life

The calculation of the remaining battery service life occurs in dependence of the consumed capacity (which is measured) and a consumption expected for the future (which gives the remaining battery service life). Therefor e, for applications with high current consumption the remaining battery service life may reduce quicker than stated by the figure for the remaining service life!

If Bat.R is less than 3 months, "Batt. low" (® page 50) is displayed in the system status and "B" flashes in the display status field (® 2.2.1). Recalculation of the remaining battery service life is carried out automatically after the entry of a new battery capacity Bat.C (see below). The settings of the measurement cycle MCyc (® 3.9), operating cycle OCyc (® 3.9), input mode Md.I1 (® 3.11) and display switch-off Disp (® 3.9) are taken into account during the computation of the remaining battery service life. Future operating conditions, e.g. changing the settings, duration of readouts or frequency of key operations cannot be foreseen however and therefore lead to a correspon ding uncertainty for the displayed remaining battery service life. For data readouts, a mean future duration of 15 mi nutes per month is estimate. To increase the service life two batteries instead of one can be used. In this case double the value (e.g. 26.0 Ah) must be entered for Bat.C (see below) after inser ting the batteries.

Bat.C Battery capacity

Here, the original capacity and not the residual capacity of the batteries last used is displayed. After a battery replacement the capacity of the battery used must be entered here so that recalculation of the remaining battery service life is initiated. The capacity to be entered need not necessarily correspond to the typical capacity quoted by the battery manufacturer. Apart from these details, the capacity depends on the application conditions such as ambient temperature and the device current consumption. In view of this and as a precaution, the minimum and not the typical value should be used. When used in ambient temperatures between –10°C and +50°C, the value to be entered is normally about 80% of the capacity quoted by the manufacturer. With the use of the size "D" battery obtainable from Elster GmbH, the value 13.0 Ah should be entered for Bat.C and 26.0 Ah when two cells are used.

Contr Display contrast

Setting the contrast of the display. Changes only become effective after confirmation of entry with <ENTER>. Valid range: 0 bis 255.

St.SL Supplier's lock (status / close) Cod.S Supplier's combination (enter / change) St.CL Customer's lock (status / close) Cod.C Customer's combination (enter / change)

Basic principle of operation of lock and combination: ® 2.4.3. Open lock: Enter the correct combination (numerical code) Close lock: Clear St.SL resp. St.CL. ( ¬ + - in the entry mode, ® 2.3.1,

Data Class 6).

Change combination: Entry of a new combination (code) with lock open.

(irrespective of the above mentioned access rights) The individual characters of the combination code in hexadecimal notation, i.e. they take on values from 0 to 9 and from A to F. "A" follows "9" and "F" is followed again by "0", i.e. the key - changes "9" to "A" and "F" to "0".

56 © Elster GmbH

St.PL Calibration lock (status / close)

Basic principle of operation of the calibration lock: ® 2.4.1. Opening the calibration lock: Only with the sealed pushbutton ( ® 5.8.1). Closing the calibration lock: Either by pressing the pushbutton again or by clearing St.PL via the interface or keypad ( ¬ + - in the entry mode, ® 2.3.1, Data

Class 6).

Adj.T Clock adjustment factor

Adj.T is the deviation of the running accuracy of the clock at room temperature in per mil (ž10-3). The EK220 uses Adj.T to optimise the running accuracy of the clock. The adjustment of the clock is carried out in the factory. Provided no value has been entered for Adj.T, the EK220 displays the message "Batt. low" in the status Stat.

Save Save all data

This function should be executed before any battery replacement in order to save the counter readings, date and time in the non-volatile memory (EEPROM).

Clr.A Clear measurement archives

All measurement archives (not log book and changes log book "audit trail") are cleared. This function is particularly practicable after the measuring point of the EK220 is changed.

In order that the archives are not unintentionally deleted, the following safety mechanism is integrated: To clear the archives the EK220 serial number (found on the name-plate of the device) must be entered.

Clr.V Clear counters (incl. archive)

All the counter readings and archives are cleared.

Clr.X Initialise device

All data (counter readings, archives and settings) are cleared. To ensure that this function cannot be executed with the calibration lock open, the

following safety mechanism is included: Clr.X can only be executed after the clock (® 3.9, Time) has been set (initialised) to its starting value with the key combination ¬ + - . Otherwise, an attempt to execute Clr.X results in the error message "13" appearing in the display.

Bin.T Temperature binary value Bin.p Pressure binary value Bin2p Pressure 2 binary value

These are the raw values measured directly on the respective input and which are converted to the corresponding measurement quantities with the adjustments made (® 3.4, 3.5).

Sel.T Temperature sensor selection

With this value the EK220 is informed of which temperature sensor is installed: 0 = No temperature sensor 1: Pt500 2: Pt100 3-6: No function. On changing this value the designation of the temperature sensor Typ.T (® 3.5) is

appropriately changed automatically.

Volume Conversion Device EK220

Sel.p Pressure sensor selection

With this value the EK220 is informed of which pressure sensor is installed: 0: No pressure sensor 2: CT30 4: 17002 2, 3, 5 and 6: no function On changing this value the designation of the pressure sensor type (® 3.4) is ap-

propriately changed automatically.

Sel2p Pressure sensor 2 selection

With this value the EK220 is informed of which second pressure sensor is installed: 0: No pressure sensor 1: CT30 2-6: no function

On changing this value the designation of the pressure sensor type (® 3.4) is ap- propriately changed automatically.

SMenu Amb. temp.

With <ENTER> the submenu for the parameters for the determination and display of the ambient temperature is called here.

Addr Address for user display ... User display (value under the address "Addr")

The address of any value can be entered under Addr to read it in the display point

below it (shown here with "..."). The address 9:A51 is programmed to the default value PL for the activation or deactivation of the calibration logbook function.

PL = "0" = "off" : The calibration logbook function is deactivated. PL = "1" = "on" : The calibration logbook function is activated.

The affected parameters are subjected to the calibration lock and the display list is reduced (® 3.10) when the calibration logbook is deactivated

SMenu Revisal

With <ENTER> the submenu for the parameters for the checking measurement are called here.

58 © Elster GmbH

ArCal Frozen values Frz. Freeze

ArCal is the entry address for the calibration archive which contains the two last manually frozen data rows with measurements. Freezing is carried out with Frz. (see below). The calibration archive is especially intended for operating points checks.

Each archive data row has the following entries, whereby the abbreviated design ations for the counter progress values ("D...") normally flash:

Volume Conversion Device EK220

« ABNo

to "Check"

Block number

« VbRp

Repair counter

« K C Qb Qm Check

Inv. compr. ratio factor

Time Vb

Saving time

D VbRp

Counter progress

Conversion factor

Volume at base cond.

VmRp

Repair counter

Flow at base cond.

D Vb

Counter progress

D VmRp

Counter progress

Actual flow Checksum

Actual volume

p T «

Pressure Temperature

D Vm

Counter progress

to "ABNo"

- Display test

The display flashes to test all segments.

3.10.1 Submenu ambient temperature “SMenu Amb. temp.”

Ta Ambient temperature °C - 3:410_1 4 BinTa Ambient temperature binary value - - 3:427 4 Eq1Ta Coefficient 1 of temperature equation - C 3:480 8 Eq2Ta Coefficient 2 of temperature equation - C 3:481 8 Eq3Ta Coefficient 3 of temperature equation - C 3:482 8 PrgTa Accepts ambient temperature adjustment - C 3:459 2 TaAdj Adjustment value for ambient temperature °C C 3:460_1 8

(Legends: see page 22)

Ta Ambient temperature

Ta is the ambient temperature in the immediate vicinity of the circuit board.

BinTa Ambient temperature binary value

This is the directly measured raw value which is converted by means of the adjustments made (see below) for the measurement quantity.

Eq1Ta Coefficient 1 of temperature equation Eq2Ta Coefficient 2 of temperature equation Eq3Ta Coefficient 3 of temperature equation

The coefficients of the quadratic equation for calculating the ambient temperature Ta from the raw temperature value Bin.Ta.

PrgTa Accepts ambient temperature adjustment TaAdj Adjustment value for ambient temperature

These values are used for the adjustment of the ambiente temperature measurement circuit.

Volume Conversion Device EK220

3.10.2 Submenu revisal “SMenu Revisal”

WRp Repair counter W kWh S 1:305 12 VbRp Repair counter Vb m3 S 2:305 12 VmRp Repair counter Vm m3 S 4:305 12 Rep. Repair mode on / off - C 1:173 7

(Legends: see page 22)

WRp Repair counter W VbRp Repair counter Vb VmRp Repair counter Vm Rep. Repair mode on / off

The repair mode is switched by entering "1" for Rep. In the repair mode all the

counters located in the actual volume, standard volume and energy lists are stopped and all the measured quantities are counted in WRp, VbRp and VmRp.

The repair mode is switched off again, thereby returning to the normal operating mode, by entering "0" for Rep.

3.11 Input list

AD Designation / value Unit Access Address DC

cp.I1 cp value for Input 1 1/m3 PL 1:253 8 cp.I2 cp value for Input 2 1/m3 S 2:253 8 Md.I2 Mode for Input 2 - S 2:207 7 St.I2 Status on Input 2 - - 2:228 4 MdMI2 Mode for monitoring Input 2. - S 11:157 7 SC.I2 Source for monitoring Input 2. - S 11:154 8 L1.I2 Limit 1 for monitoring Input 2. - S 11:150 8 L2.I2 Limit 2 for monitoring Input 2. - S 11:158 8 SpI2 Status pointer for monitoring Input 2. - S 11:153 8 St.I3 Status on Input 3 - - 3:228 4 MdMI3 Mode for monitoring Input 3. - S 12:157 7 SC.I3 Source for monitoring Input 3. - S 12:154 8 L1.I3 Limit 1 for monitoring Input 3. - S 12:150 8 SpI3 Status pointer for monitoring Input 3. - S 12:153 8 SNM Serial number of gas meter - S 1:222 8

(Legends: see page 22)

cp.I1 cp value Input 1

Pulse constant (parameter of the connected gas meter) for conversion of the pulses counted on Input 1 into the volume counter V1 (see below); the increase in

volume is directly accepted into the total actual volume VmT (® 3.3). cp.I1 indicates how many pulses correspond to the volume 1 m3.

60 © Elster GmbH

cp.I2 cp value Input 2

If Input 2 is set as a counting input (Md.I2 = 1, see below), the pulse constant must be entered here which is used for the conversion of the pulses to the volume V2 (see below).

cp.I2 is not subject to the calibration lock because it has no influence on Vm or Vb. Input 2 can only be used for pulse comparison with Input 1 ( ® MdMI2, see below). If Input 2 is set as a status input (Md.I2 = 2, see below), cp.I2 has no significance.

Md.I2 Mode for Input 2

The application of Input 2 (I2) can be defined here. 0: Switched off (input is not used). 1: Counting input. 2: Status input. When the input is used as a counting input, the EK220 can, for example, be parameterised such that it carries out a pulse comparison of Inputs 1 and 2 and si gnals impermissibly large deviations. With the setting "status input" the EK220 can, for example, signal attempts at tampering on a pulse generator of the gas meter, provided the meter also supports this. After setting Md.I2 the function on Input 2 is particularly defined with MdMI2 (see below).

St.I2 Status on Input 2

If Md.I2 = "2" (see above), the status of Input 2 is displayed here: St.I2 = 0: Input signal is inactive (no signalling). St.I2 = 1: Input signal is active (signalling).

MdMI2 Mode for monitoring E2 SC.I2 Source for monitoring E2 L1.I2 Limit 1 E2 L2.I2 Limit 2 E2 SpI2 Status pointer for monitoring E2

Volume Conversion Device EK220

F For MdMI2 only enter one of the values described here: "2", "3", "5" or "17".

Depending on the system and after entering the key combination ENTER, other values are offered which are however not meaningfully applicable here.

Depending on the application of Input 2 as counting or status input (see above: Md.I2), the following functions can be realised by setting these values:

If Input 2 is a counting input, the function "pulse comparison" can be set. If Input 2 is a status input, the functions "active warning input", "inactive warning

input", "active reporting input", "inactive reporting input" and "time -synchronous input" can be set. "Warning input" signifies that the status message "I2 Warn.sig." is affected. This is entered in the momentary status St.2 and in the status register SR.2. "Reporting input" signifies that the status message "I2 Rep.sig." is affected. This is only entered in the momentary status St.2 and not in the status register. "Active": A signal arises when the input terminals are short-circuited (switch to switching point "on", ® B-4). "Inactive": A signal arises when the input terminals are parted (switch to switching point "off", ® B-4).

Volume Conversion Device EK220

Programming takes place according to the following table:

E2 is a counting input (Md.I2 = "1")

- Pulse comparison on Inputs 1 and 2

Value Setting Comment

Md.I2 1 Input mode "counting input" MdMI2 17 Monitoring mode "pulse comparison" SC.I2 01:226_0 = "PulE1" Address of pulse counter for Input 1 L1.I2 4 Maximum number of disturbance pulses L2.I2 1000 Pulse windows per disturbance pulse SpI2 0.05_02:1.1 = I2 Pulse cmp- Pointer to message "5" in status 2

With this setting the pulses counted on Inputs 1 and 2 are compared: If the pulse counters on Input 1 and Input 2 differ by more than 4 pulses (= L2.I2) in 4000 pulses (= L1.I2 ž L2.I2), the message "I2 Pulse cmp" is displayed in the status Stat.

E2 is a status input (Md.I2 = "2")

- Input 2 is an active warning input (input for warning signal):

Value Setting Comment

Md.I2 2 Input mode "status input" MdMI2 2

Monitoring mode: "Signal when SC.I2 ³ L1.I2"

SC.I2 02:228_0 = "St.I2" Status on Input 2 L1.I2 1 Comparative value L2.I2 - (Not used here) SpI2 0.08_02:1.1 = I2 Warn.sig.- Pointer to message "8" in status 2 (warning)

- Input 2 is an inactive warning input (e.g. tamper detection):

Value Setting Comment

Md.I2 2 Input mode "status input" MdMI2 3 Monitoring mode: "Signal when SC.I2 < L1.I2" SC.I2 02:228_0 = "St.I2" Status on Input 2 L1.I2 1 Comparative value L2.I2 - (Not used here) SpI2 0.08_02:1.1 = I2 Warn.sig.- Pointer to message "8" in status 2 (warning)

- Input 2 is an active reporting input (input for report signal):

Value Setting Comment

Md.I2 2 Input mode "status input" MdMI2 2

Monitoring mode: "Signal when SC.I2 ³ L1.I2"

SC.I2 02:228_0 = "St.I2" Status on Input 2 L1.I2 1 Comparative value L2.I2 - (Not used here) SpI2 0.13_02:1.1 = I2 Rep.sig.- Pointer to message "13" in status 2 (report)

62 © Elster GmbH

Volume Conversion Device EK220

- Input 2 is an inactive reporting input (input for report signal):

Value Setting Comment

Md.I2 2 Input mode "status input" MdMI2 3 Monitoring mode: "Signal when SC.I2 < L1.I2" SC.I2 02:228_0 = "St.I2" Status on Input 2 L1.I2 1 Comparative value L2.I2 - (Not used here) SpI2 0.13_02:1.1 = I2 Rep.sig.- Pointer to message "13" in status 2 (report)

- Input 2 is time-synchronised input:

Value Setting Comment

Md.I2 2 Input mode "status input" MdMI2 5 Monitoring mode: "Time-synchronised input" SC.I2 02:228_0 = "St.I2" Status on Input 2 L1.I2 1 Comparative value L2.I2 - (Not used here) SpI2 0.13_02:1.1 = I2 Rep.sig.- Pointer to message "13" in status 2 (report)

Time synchronisation can occur under the following conditions:

- There must be a pulse on the input within one minute before or after a full hour. The

deciding factor is the time in the EK220.

- Only one synchronisation per hour can occur.

St.I3 Status on Input 3

Here the status of Input 3 is displayed which is used as status input: St.I3 = 0: Input signal is inactive

(terminals open or voltage > 3V)

St.I3 = 1: Input signal is active

(terminals connected through low resistance or voltage < 0.8V)

MdMI3 Mode for monitoring E3 Qu.I3 Source for monitoring E3 L1.I3 Limit 1 E3 SpI3 Status pointer for monitoring E3

By setting these values the following functions can be realised for Input 3 (Input 3 is only used as status input):

- Input 3 is an active warning input (input for warning signal):

Value Setting Comment

MdMI3 2

Monitoring mode: "Signal when SC.I3 ³ L1.I3"

SC.I3 03:228_0 = "St.I3" Status on Input 3 L1.I3 1 Comparative value SpI3 0.08_03:1.1 = I3 Warn.sig.- Pointer to message "8" in status 3

- Input 3 is an inactive warning input (e.g. tamper detection):

Value Setting Comment

MdMI3 3 Monitoring mode: "Signal when SC.I3 < L1.I3" SC.I3 03:228_0 = "St.I3" Status on Input 3 L1.I3 1 Comparative value SpI3 0.08_03:1.1 = I3 Warn.sig.- Pointer to message "8" in status 3

Volume Conversion Device EK220

- Input 3 is an active reporting input (input for report signal):

Value Setting Comment

MdMI3 2

Monitoring mode: "Signal when SC.I3 ³ L1.I3"

SC.I3 03:228_0 = "St.I3" Status on Input 3 L1.I3 1 Comparative value SpI3 0.13_03:1.1 = I3 Warn.sig.- Pointer to message "13" in status 3 (report)

This setting is also established by loading a special parameter file for the connection of an FE230 Function Expansion.

- Input 3 is an inactive reporting input (input for report signal):

Value Setting Comment

MdMI3 3 Monitoring mode: "Signal when SC.I3 < L1.I3" SC.I3 03:228_0 = "St.I3" Status on Input 3 L1.I3 1 Comparative value SpI3 0.13_03:1.1 = I3 Warn.sig.- Pointer to message "13" in status 3 (report)

- Input 3 is time-synchronised input:

Value Setting Comment MdMI3 5 Monitoring mode: "Time-synchronised input" SC.I3 03:228_0 = "St.I3" Status on Input 3 L1.I3 1 Comparative value SpI3 0.13_03:1.1 = I3 Rep.sig.- Pointer to message "13" in status 3

Time synchronisation: See "Input 2 is time-synchronised input" (page 63).

SNM Serial number of gas meter

The serial number of the gas meter connected to the counting input E1.

64 © Elster GmbH

Volume Conversion Device EK220

3.12 Output list

AD Designation / value Unit Access Address DC

Md.O1 Mode for Output 1 - S 1:605 7 SC.O1 Source for Output 1 - S 1:606 21 cp.O1 Cp value for Output 1 1/m3 S 1:611 8 SpO1 Status pointer for Output 1 - S 1:607 8 Md.O2 Mode for Output 2 - S 2:605 7 SC.O2 Source for Output 2 - S 2:606 21 cp.O2 Cp value for Output 2 1/m3 S 2:611 8 SpO2 Status pointer for Output 2 - S 2:607 8 Md.O3 Mode for Output 3 - S 3:605 7 SC.O3 Source for Output 3 - S 3:606 21 cp.O3 Cp value for Output 3 1/m3 S 3:611 8 SpO3 Status pointer for Output 3 - S 3:607 8 Md.O4 Mode for Output 4 - S 4:605 7 SC.O4 Source for Output 4 - S 4:606 21 cp.O4 Cp value for Output 4 1/m3 S 4:611 8 SpO4 Status pointer for Output 4 - S 4:607 8

(Legends: see page 22)

The function of the outputs can be set with the values described here. The ex-works standard setting is:

- Output 1: Pulse output VbT (total volume at base conditions), 1 pulse per m

;

changes to the settings only possible with open supplier's lock.

- Output 2: Pulse output VmT (total actual volume), 1 pulse per m

;

changes to the settings only possible with open supplier's lock.

- Output 3: Status output alarm or warning, logic active;

Changes to the settings only possible with open supplier's lock.

- Output 4: Pulse output VbT (total volume at base conditions), 1 pulse per m

changes to the settings only possible with open supplier's lock.

;

With the aid of the WinPADS Parameterization Software the access rights (® 2.4) men- tioned here can be changed for each output with an appropriately open lock. In this respect there are the following alternatives:

- Changes to the settings only possible subject to the calibration lock.

- Changes to the settings possible subject to the supplier's and calibration locks.

- Changes to the settings possible subject to the customer's, supplier's and calibration locks.

Md.O1 ... Md.O4 Mode for Outputs 1...4

The four signal outputs of the EK220 can be set for various functions. The basi c function is defined with the mode Md.A... Depending on this, the source (SC.A..., see below), the cp value (cp.A..., see below) or the status pointer (SpO..., see below) must also be parameterised, where necessary, for the relevant output.

In the following table, apart from the setting possibilities for Md.A... it is shown for each setting whether SC.A..., cp.A... or SpO... must be parameterised.

Volume Conversion Device EK220

Md.A..

Meaning

To program:

SC.A... cp.A... SpO...

Output switched off (transistor blocking, "switch open")

Volume pulse output, logic active

Status output, logic active (signalling active => output

switched on) Time-synchronised output, logic active

Output switched on (transistor conducting, "switch closed")

Volume pulse output, logic inactive

Status output, logic inactive (signalling active => output

switched off) Time-synchronised output, logic inactive

Event output, logic active (message active => output

switched on)

Event output, logic inactive (message active => output switched off)

Continuous pulse (for test purposes)

SC.O1 ... SC.O4 Source for Outputs 1...4

These values are only of significance if the mode Md.A... of the same output is set to "1", “5” (volume pulse output), "3" or “7” (time -synchronised output). Depending on this, the following settings for SC.A are practicable:

- for modes "1" and “5” (volume pulse output)

- - -

Yes Yes -

- - Yes

Yes - -

- - -

Yes Yes -

- - Yes

Yes - -

- - Yes

- - -

SC.A... Meaning 02:300_0 Vb Volume at base conditions, undisturbed 02:301_0 VbD Volume at base conditions, disturbance quantity 02:302_0 VbT Volume at base conditions, total quantity (undisturbed + disturbed) 04:300_0 Vm Actual volume, undisturbed 04:301_0 VmD Actual volume, disturbed 04:302_0 VmT Actual volume, total quantity (undisturbed + disturbed)

The period duration and pulse duration can be set individually for each output via

the serial interface under the addresses "1:617" to "4:617" (period duration) or

"1:618" to "4:618" (pulse duration) as a multiple of 125 ms. The period duration

must always be greater than the pulse duration.

66 © Elster GmbH

Volume Conversion Device EK220

- for modes "3" and "7" (time-synchronised output)

By programming SC.A... according to the following table, you can set at which time points the time-synchronised output issues a pulse:

SC.A... Pulse is output

01:143_0 At the beginning of each month at 0 hrs. 02:143_0 At the beginning of each month at 6 hrs. The day boundary (= month

boundary ) "06:00 hrs." can be changed via the serial interfaces under

the address "2:141". 01:142_0 At the beginning of each day at 0 hrs. 02:142_0 At the beginning of each day at 6 hrs. The day boundary "06:00 hrs."

can be changed via the serial interfaces under the address 2:141. 01:403_0 At the beginning of each hour. 01:402_0 At the beginning of each minute. 04:156_0

The pulse duration can be set individually for each output via the serial interfaces under the addresses "1:618" to "4:618" as a multiple of 125 ms. If a mode other than "1" or "3", "3", "5" or "7" is set, SC.A... has no significance.

cp.O1 ... cp.O4 cp value for Outputs 1...4

If the output is programmed as a volume pulse output (Md.A...= 1), the increase in volume is converted with cp.A... into the number of pulses to be output. The conversion takes place according to the formula: i = V ž cp.A...

where i: Number of output pulses and V: Volume increase which is to be output as a pulse.

cp.A... therefore states how many pulses are to be output for 1 m3. If a mode other than "1" is set, cp.A... has no significance. This also applies to the setting "time-synchronised output" (see above), although then cp.A... is displayed dependent on SC.A... with a time unit. With a change of the output cp value, the corresponding input buffer is cleared . (cf. messages "Outp.1 Error" to "Outp.4 Error, page 49).

SpO1 ... SpO4 Status pointer for Outputs 1...4

The status pointers SpO1 ... Sp04 determine which status messages an output represents which is parameterised as a status or event output.

The display of the status pointer occurs as a short text according to Chapter 3.8 with a following arrow pointing upwards "-" (e.g. "I3 Warn.sig."). Here, the symbol "-" indicates that the "signal arrives".

For entry a special numerical display is implemented (e.g. "08_03:1.1"), because a text entry on the device would only be possible with a great deal of effort.

If the output is programmed as status or event output "with active logic" (Md.A...= 2 or 9), then Sz.A... sets with which status messages of the momentary

status ® (3.8) the output is to be switched on. If none of the selected messages is present, the output remains switched off.

If the output is programmed as status or event output "with inactive logic" (Md.A...= 6 or 10), then Sz.A... sets with which status messages of the momentary status the output is to be switched off. If none of the selected messages is present, the output remains switched on (!).

In contrast to the status output, an event output is reset automatically after an a djustable time to its basic state. This time can be set with WinPADS.

At the beginning of each measurement period MPer (® 3.7)

Volume Conversion Device EK220

There are two basic ways of selecting status messages with SpO...:

- Selection of a single message.

- Selection of a message group. Example of a "message group":

"Messages 1 to 8" signify that the output is switched while ever one or more of

the messages with the number "1" to "8" is present in the momentary status. "Message groups" always start with the message "1" ("any of the messages 1 to ..."). It is not possible, for example, to select the messages "3 to 5".

All the possible settings for SpO... are described in the following. Here, "mm" sign ifies the message, i.e. one of the messages "1" to "16" can be selected with "mm".

a) A message in a status St.1 to St.9

SpO... = „mm_0s:1.1“ where s = 1 to 9 for St.1 to St.9 Example: "0.08_03:1.1“ signifies message 8 in Status St.3 ("I3 Warn.sig.“ ® page 50).

b) A message in the system status St.Sy

SpO... = "mm_02:2.1" Example: "0.03_02:2.1" signifies: Message 3 in the system status St.Sy ("Data restore" ® page 49)

c) A message in the system status Stat

Since Stat combines the messages of all statues, this setting means that the output is switched while ever the message "mm" is present in any of the statuse s St.Sy or St.1 to St.9. SpO... = "mm_01:2.1" Example: "0.08_01:2.1" signifies: Message 8 in any status St.Sy or St.1 to St.9. (After the entry "Message 8- “ is displayed.)

d) Message group in a status St.1 to St.9

SpO... = "1.mm_0s:1.1" where s = 1 to 9 for St.1 to St.9 Example: "1.06_04:1.1" means: Any of the messages 1 to 6 in the status St.4. (After the entry "St.4:M1-6- “ is displayed.)

e) Message group in the system status St.Sy

SpO... = "1.mm_02:2.1" Example: "1.03_02:2.1" signifies: Any of the messages 1 to 3 in the system status St.Sy. (After the entry "StSy:M1-3- “ is displayed.)

f) Message group in the total status Stat

The output is switched while ever one of the messages 1 to mm is present in any of the statuses St.Sy or St.1 to St.9.

SpO... = "1.mm_01:2.1" Example:

"1.08_01:2.1" signifies: Any of the messages 1 to 2 in any status St.Sy or St.1 to St.9, i.e. any alarm or any warning. (After the entry "Stat:M1-8- “ is displayed.)

68 © Elster GmbH

Volume Conversion Device EK220

3.12.1 Brief summary of output parameterisation

s Volume pulse output ........................................................... Md.A.. = 1 or 5

¢ Selection of the volume counter:

- Vb Volume at base conditions, undisturbed ...... SC.A... = 0002:300_0

- VbD Volume at base conditions, disturbance quantity SC.A... = 0002:301_0

- VbT Volume at base conditions, total quantity..... SC.A... = 0002:302_0

- Vm Actual volume, undisturbed ...........................SC.A... = 0004:300_0

- VmD Actual volume, disturbed................................ SC.A... = 0004:301_0

- VmT Actual volume, total quantity.......................... SC.A... = 0004:302_0

Setting of the cp value ...................................................... cp.A... = ...

s Status output, logic active or inactive ............................... Md.A.. = 2 or 6

s or event output, logic active or inactive ............................ Md.A = 9 or 10

' Selection of status message(s):

- A message in a status St.1 to St.9 ...................................... SpA... = 0.mm_0s:1.1 *

- A message in the system status StSy............................... SpA... = 0.mm_02:2.1 *

- A message in the total status Stat..................................... SpA... = 0.mm_01:2.1 *

- Message group in a status St.1 to St.9............................. SpA... = 1.mm_0s:1.1 *

- Message group in the system status StSy ....................... SpA... = 1.mm_02:2.1 *

- Message group in the total status Stat.............................. SpA... = 1.mm_01:2.1 *

s Time-synchronised output, logic active or inactive ......... Md.A.. = 3 or 7

'Setting of the time-point:

- At the start of each month at 0 hrs. ................................... SC.A... = 0001:143_0

- At the start of each month at 6 hrs. ................................... SC.A... = 0002:143_0

- At the start of each day at 0 hrs......................................... SC.A... = 0001:142_0

- At the start of each day at 6 hrs......................................... SC.A... = 0002:142_0

- At the beginning of each hour. ........................................... SC.A... = 0001:403_0

- At the beginning of each minute. ....................................... SC.A... = 0001:402_0

- At the beginning of each measurement period.................SC.A... = 0004:156_0

s Continuous pulse (for test)................................................. Md.A.. = 99

s Output switched on............................................................. Md.A.. = 4

s Output switched off............................................................. Md.A.. = 0

* mm = Message (1...16), s = Status number (1...9 for St.1 ... St.9)

Volume Conversion Device EK220

3.13 Interface list

The values shown in this list depend on the set interface mode Md.S2 (see below):

a) All modes except "IDOM protocol" and "MODBUS" (Md.S2 ¹ 11, Md.S2 ¹ 13):

AD Designation / value Unit Access Address DC

GSM & SMS

Submenu GSM & SMS - (C) 5:1C1 8

Bd.S1 Baud rate, Interface 1 Bd S 1:709 7 CW1.S Call acceptance window 1, start - S 5:150 8 CW1.E Call acceptance window 1, end - S 5:158 8 CW2.S Call acceptance window 2, start CW2.E Call acceptance window 2, end CW3.S Call acceptance window 3, start CW3.E Call acceptance window 3, end CW4.S Call acceptance window 4, start CW4.E Call acceptance window 4, end CWTst Test acceptance window

- S 6:150 8

- S 6:158 8

S S S

16:150 8 16:158 8 17:150 8

- S 17:158 8

- S 2:727 3

b) Mode "IDOM protocol" (Md.S2 = 11):

AD Designation / value Unit Access Address DC

Md.S2 Mode, Interface 2 - S 2:705 7 DF.S2 Data format, Interface 2 - S 2:707 7 Bd.S2 Baud rate, Interface 2 Bd S 2:708 7 DProt IDOM protocol - (C) 2:7E6 8 Bd.S1 Baud rate, Interface 1 Bd S 1:709 7 CW1.S Call acceptance window 1, start - S 5:150 8 CW1.E Call acceptance window 1, end - S 5:158 8 CW2.S Call acceptance window 2, start - S 6:150 8 CW2.E Call acceptance window 2, end - S 6:158 8 CW3.S Call acceptance window 3, start - S 16:150 8 CW3.E Call acceptance window 3, end - S 16:158 8 CW4.S Call acceptance window 4, start - S 17:150 8 CW4.E Call acceptance window 4, end - S 17:158 8

(Legende: siehe Seite 18)

70 © Elster GmbH

Volume Conversion Device EK220

c) Mode "MODBUS" (Md.S2 = 13)

AD Designation / value Unit Access Address DC

Md.S2 Mode, Interface 2 - S 2:705 7 DF.S2 Data format, Interface 2 - S 2:707 7 Bd.S2 Baud rate, Interface 2 Bd S 2:708 7 TypS2 Type,Interface 2 - S 2:70A 7 BusS2 Bus mode RS485 on / off - S 2:704 7 SMenu Modbus parameter - (C) 1:1C1 8 Bd.S1 Baud rate, Interface 1 Bd S 1:709 7 CW1.S Call acceptance window 1, start - S 5:150 8 CW1.E Call acceptance window 1, end - S 5:158 8 CW2.S Call acceptance window 2, start - S 6:150 8 CW2.E Call acceptance window 2, end - S 6:158 8 CW3.S Call acceptance window 3, start - S 16:150 8 CW3.E Call acceptance window 3, end - S 16:158 8 CW4.S Call acceptance window 4, start - S 17:150 8 CW4.E Call acceptance window 4, end - S 17:158 8

(Legends: see page 22)

Md.S2 Mode, Interface 2

This value informs the EK220 of which device is connected to the internal (permanently wired) interface and how it is to be controlled.

All modes that can be set are described here. You can quickly find the setting suitable for your application in Chapter 4.4. Some examples of possible wiring are shown in Chapters 5.6 and 5.7.

Md.S2 =

1 "With control line"

Suitable for the connection of a device with RS232 interface which does not

Modem

control

RS232

control lines

Battery

operation

Baud rate selec-

no yes yes yes

tion

need modem control, e.g. PC, PLC or also a modem with automatic call acceptance.

2 „Modem“ (no GSM-Modem)

Suitable for the connection of a commercially available modem.

Modem

control

RS232

control lines

Battery

operation

Baud rate se-

lection

yes yes yes no

For GSM modems Mode 2 can also be used, but Mode 7 is more suitable (see below), because then monitoring of the link to the GSM network also occurs. Num.T (see below) is effective.

Volume Conversion Device EK220

Md.S2 =

3 " Modem with return messages"

Modem

control

Suitable for the connection of an FE260 Function Expansion, an industrial

yes no no no

modem EM2601 or a modem and an external power supply. The EK220 controls the modem via the data lines using "return messages".

The activation of the return messages occurs with the modem command "ATQ0V1".

Num.T (see below) is activated.

5 "Without control lines"

Modem

control

The baud rate selection can be bypassed in this mode by setting the values

yes no yes yes

under the addresses 02:708 (Bd.S2) and 02:709 to the same value. Exworks the setting is: 02:708 = 02:709 = 19200 Bd. For this mode the EK220 needs an external power supply.

6 "Modem with return messages, battery mode"

Modem

control

In the mode Md.S2 = 6 the EK220 handles, as with Md.S2 = 3 (see above),

yes no yes no

the control of the modem via the data lines using "return messages". The modem is not parameterised for automatic call acceptance. Num.T (see below) is activated.

7 "GSM modem"

Modem

control

Suitable for the connection of a commercially available GSM modem.

yes yes yes no

This mode largely corresponds to Mode 2 (see above), but checks the EK220 daily shortly after midnight for whether the modem is still ("logged in") with the GSM network and, if required, establishes the connection. Num.T (see below) is effective.

RS232

control lines

RS232

control lines

RS232

control lines

RS-232

control lines

Battery

operation

Battery

operation

Battery

operation

Battery

operation

Baud rate se-

lection

Baud rate se-

lection

Baud rate se-

lection

Baud rate se-

lection

Delivery from mid of 2008!

Volume Conversion Device EK220

Md.S2 = 9 "Without control lines, battery operation"

Modem

control

RS-232

control lines

Battery

operation

Baud rate selec-

tion

no no yes yes

Md.S2 = 9 works like Md.S2 = 5 but can also be used in battery operation.

The current requirement of the device in this mode is increased during the complete call acceptance time window. The time window should therefore be restricted as far as possible. For the special application "FE230" (à 4.4.2, 5.6.2) the setting can however be carried out using existing parameter files such that the power requirement is also in mode 9 only increased during the actual communication.

11 "IDOM protocol"

In the mode Md.S2 = 11 the IDOM protocol is available via the permanently wired interface. Further details à 3.13.2, page 78.

Modem

control

RS-232

control lines

Battery

operation

Baud rate selec-

tion

no no yes no

13 "MODBUS"

In the mode Md.S2 = 13 MODBUS protocol is available over the permanently wired serial interface. Further details à 3.13.3, page 79

Modem

control

RS-232

control lines

Battery

operation

Baud rate selec-

tion

no yes yes no

15 "GSM modem without control lines with call acceptance"

Md.S2 = 15 corresponds to Md.S2 = 5 (see above), but also makes available

Modem

control

RS-232

control lines

Battery

operation

Baud rate selec-

tion

no no no yes

the GSM network parameters such as Reception Level and Network Operator.

Suitable for connection of following devices:

- GSM-Modem with automatic call acceptance without control lines.

However, Mode 3 (see above) is recommended for a GSM modem in or on an FE260.

17 " GSM modem with control lines with call acceptance"

Modem control RS-232

control lines

Battery

operation

Baud rate selec-

tion

no yes yes yes Md.S2 = 17 corresponds to Md.S2 = 1 (see above), but also makes available the GSM network parameters such as Reception Level and Network Operator. With this setting the battery lifetime will be greatly reduced in some applications as e.g. for FE230 operation. But it is possible to set Md.S2=17 for several minutes during the installation of the FE230 to check the GSM-level.

Volume Conversion Device EK220

Md.S2 = 19 " GSM modem without control lines, call acceptance, battery mode"

Modem control RS-232

no no yes yes

Md.S2 = 19 corresponds to Md.S2 = 9 (see above), but also makes available the GSM network parameters such as Reception Level and Network Operator.

DF.S2 Data format, Interface 2

Here the number of data bits, parity bit usage and number of stop bits are set fo r the data interchange between the EK220 and a device connected to the interface terminals. For this there are three possible settings:

- "0" = 7e1 = 7 data bits, even parity, 1 stop bit

- "1" = 7o1 = 7 data bits, odd parity, 1 stop bit

- „2“ = 8n1 = 8 data bits, no parity, 1 stop bit "0" (7e1) is the basic setting which is described in the applicable IEC 62056-21 in-

terface standard.

Bd.S2 Baud rate, Interface 2

Here, the baud rate (speed) for the data transmission between the EK220 and a device connected to the interface terminals can be set.

Possible settings: 300, 600, 1200, 2400, 4800, 9600, 19200 With the application of baud rate selection the baud rate is generally set according

to IEC 62056-21 to "300". It is then only used briefly for initiating and terminating the data interchange. The actual baud rate for transferring the useful data is aut omatically increased. With a modem connected (also within an FE260 Function Expansion) normally no automatic baud rate selection occurs. Bd.S2 should then be set to "19200".

TypS2 Type, Interface 2

The interface type can be set here: "1" = RS-232 (e.g. for connecting a commercially available modem) "2" = RS-485 (e.g. for connecting an "FE260" function expansion) In the setting "2" (RS485) BusS2 (see below) sets whether the RS485 interface is operated in the two-wire (bus) mode or four-wire mode.

BusS2 Bus mode RS485 on / off

When TypS2 (see above) is set to "2" (RS485), the RS485 interface can be set with BusS2 to two-wire (bus) mode or four-wire mode:

"0" = Bus mode off (four-wire mode ® )

for the connection of an FE260 or FE230 or an RS232 device.

"1" = Bus mode on (two-wire mode)

e.g. for the connection of several EK220s to an RS485 bus.

When TypS2 is on "1" (RS232), BusS2 must always be set to "0".

control lines

Battery

operation

Baud rate selec-

tion

Num.T Number of ringing tones before answering

With some settings for Md.S2 (see above) the setting can be made here of how many ringing tones the EK220 awaits until it accepts the call ("lifts receiver"). For entries, values in the range from 1 to 12 are accepted. Depending on the type of modem, the function is however only ensured with additional restrictions. (Refer to the instruction manual for the connected modem and to Chaps. 5.6 and 5.7).

When using a GSM modem, Num.T must be set to 1 ringing tone. Possible values are 1 to 12.

M.INI Initialise modem

With this command you can initialise a connected modem when you, for example, are connecting an unparameterised modem or when the modem has lost its se ttings.

In particular when connecting a new modem, it must be ensured that a suitable in itialization string is available under the address "2:0721" of the EK220. This can then be loaded using the "WinPADS" parameterization software.

SMenu Submenu GSM & SMS

Here the submenu for the GSM and SMS parameters is called with <ENTER>.

DProt IDOM protocol

Here the submenu for the IDOM protocol parameters is called with <ENTER>.

SMenu Submenu Modbus parameter

Here the submenu for the Modbus parameters is called with <ENTER>.

Bd.S1 Baud rate, Interface 1

Here, the baud rate (speed) for the data transmission between the EK220 and a device connected to the optical interface can be set.

The standard setting is 9600 Bd. If problems occur with the data transmission, then this is probably due to the readout lead. Then set Bd.S1 to 4800 Bd to give a slower data transmission or use a different readout lead. Depending on the system, Bd.S1 can also be set to 19200 Bd. With this setting, the data transmission does not function correctly. Therefore, avoid using this se tting.

Volume Conversion Device EK220

CW1.S Call acceptance window 1, start CW1.E Call acceptance window 1, end CW2.S Call acceptance window 2, start CW2.E Call acceptance window 2, end CW3.S Call acceptance window 3, start CW3.E Call acceptance window 3, end CW4.S Call acceptance window 4, start CW4.E Call acceptance window 4, end

With these values four different time windows can be set within which a data transmission is possible each day via the internal permanently wired interface . The EK220 does not respond outside of this time window. It the value "0" is written to the two so-called "Pointers to the time windows" (addresses 2:722, 2:723, 2:724 and 2:725) using the parameterization software ("WinPADS"), communication is always possible independent of the time windows.

The EK220 compares the four time windows with the running time of day on a rhythm with the operating cycle, OCyc, (® 0). If, for example, with a standard operating cycle of 5 minutes, the start of a time window is at 6:53 hrs., then it is first activated at 6:55 hrs. For the connection of an FE230 Function Expansion special parameter files are available which are installed with the "WinPADS" parameterising program and which can also be loaded with it into the device.

CWTst Call acceptance window

The Test call window enables the GSM modem to be switched on for a parame terised time (e.g. 30 minutes) to make, for example, test calls. The smallest possible entry is two minutes. After initiating the function the display is refreshed every minute and indicates the remaining open time of the call window. This call window is also opened for two minutes if the GSM parameters in the display are to be updated and in this period no Call window 1 to 4 (see above) is open.

3.13.1 Submenu „GSM & SMS“

KB Bezeichnung / Wert Einheit Zugriff Adresse DK

GSM.N GSM network operator - - 2:775 4 GSM.L Reception level % - 2:777 4 StM Status of modem (GSM) - - 2:77C_1 4 P.Sta Reply to PIN-Code - - 2:77A 20 PIN PIN-Code - S 2:772 11 Resp1 Reply to short message 1 - - 2:742 20 Resp2 Reply to short message 2 - - 2:74A 20 Send Send short message (SMS) - S 2:734 2

(Legends: see page 22)

GSM.N GSM network operator GSM.L Reception level

When using a mobile radio modem and with a suitable setting of Md.S2 (see above), information regarding the mobile radio network can be re called here once the EK220 has logged in. The information is automatically updated each night at 0:00 and after a failure of the external power supply. If required, an update can be carried out by pressing the key combination <ENTER> during the display of GSM.N or GSM.L.

Under GSM.N the GSM network operator is displayed in text.

StM Status of modem (GSM)

F This value is only valid when using a GSM modem.

This value indicates in which network the GSM modem is registered: not registered The GSM modem is currently not registered.

Possible causes: Call window off, no SIM card inserted,

SIM-PIN not entered. own network The GSM modem is registered in its own network. network search... The GSM modem is currently registering in a network. rejected external The registration of the GSM modem was rejected. network The modem is registered in an external network ("ro aming"). no command The modem command for reading out the modem status is not

parameterised. If this text is displayed with the GSM modem

connected, the EK220 is not correctly parameterised.

P.Sta Reply to PIN-Code PIN PIN-Code

Volume Conversion Device EK220

F These values are only valid when using a GSM modem.

Under PIN the "Personal Identification Number" of the SIM card is entered in order to be able to use it. The status with regard to the PIN can be seen under P.Sta:

Message Meaning PIN NEW The PIN has not yet been entered.

PIN READY The SIM card is being used without a PIN. PIN OK The PIN has been entered correctly, the SIM card is ready for op-

eration.

Resp1 Reply to short message 1 Resp 2 Reply to short message 2 SEND Send short message (SMS)

PIN ERROR The PIN has been entered incorrectly.

F These values are only valid when using a GSM modem

With the occurrence of definable events, the EK220 is able to send a short me ssage by SMS, e.g. to a mobile phone. In this respect the message content, recipient and triggering events can be set using the WinPADS parameterisation program. By entering "1" for SEND, the defined short message can be immediately sent.

Volume Conversion Device EK220

3.13.2 Submenu "IDOM protocol"

AD Designation / value Unit Access Address DC

cycl. Cyclical output Minutes S 13:150 8 daily Daily output - S 3:141_1 8 Print Immediate output - S 2:7E5 2

(Legends: see page 22)

In the mode Md.S2 = 11 a data block can be sent cyclically via interface 2 according to the IDOM protocol. The data block contains the momentary values of the standard volumes, actual volumes, pressure and temperature as well as a disturbance signal.

cycl. Cyclical output

Here you can set the cycle for outputting the IDOM protocol data block in the range from 1 to 60 minutes. Entering "0" signifies: No cyclical output.

daily Daily output

Here you set a time at which a daily output of the IDOM protocol data block occurs in addition or alternatively to the cyclical output.

print Immediate output

With the entry of "1" you can initiate the immediate output of an IDOM protocol

All values are ASCII coded with a terminating "Return" character (0D hexadecimal). They are sent in the following order:

data block.

Value Name Format Unit Actual volume (VmT) Va: 8 places without decimal places m3 Standard volume (VbT) Vr: 8 places without decimal places m3 Gas pressure (p) P 1 or 2 places before, 3 after decimal point bar Gas temperature (T) T 1 or 2 places before, 2 after decimal point

°C

Negative values with minus symbol "-"

Disturbance signal @ - -

The disturbance signal "@" is sent if a status message with a code 12 or lower is entered in the momentary status. (® Chap. 3.8.1, page 47)

Examples of IDOM protocol data block: Va:00000006¿Vr:00000005¿P1.230¿T26.05¿ Va:00000036¿Vr:00000024¿P12.000¿T-6.20¿@¿

Volume Conversion Device EK220

3.13.3 Submenu “MODBUS parameters”

AD Designation / value Unit Access Address DC

MBDir Data direction - S 2:7B0 7 MBTrM Transmission mode - S 2:7B1 7 MBAdr Device address (slave address) - S 2:7B2 8 MBRSz Size of register - S 2:7B8 7 MBAMd Adressing mode - S 2:7B9 7

(Legends: see page 22)

In the mode Md.S2 = 13 MODBUS protocol is available over the permanently wired serial interface, only. You can read and write values. All archives can read out.

The functions “Read holding registers” (3), “Read Input Registers” (4), “Preset Single Re gister” (6) and “Preset Multiple Registers” (16) of the protocol are implemented. To read out the values and the archives please refer to separate document, available from Elster GmbH.

For the MODBUS communication external power-supply to the EK220 is necessary and at least one “call acceptance window” has to be open. In addition, in the Interface list “Ser.IO” (® 3.13) Md.S2 must be set to “13”, Bd.S2 to 9600 and DF.S2 to ”0” or “2”, depending on the transmission mode MBTrM (see below).

MBDir Data direction

0 = most significant word in the first register 1 = least significant word in the first register

MBTrM Transmission mode

0 = ASCII-Mode – the contents of each register are transmitted as four ASCII

coded hexadecimal digits. DF.S2 must be set to “0”

1 = RTU-Mode – the contents of each register are transmitted as two bytes.

DF.S2 must be set to “2”.

2 = RTU-TCP-Mode – Transmission like RTU-Mode with additional information of

Modbus –TCP-Protocol.

MBAdr Device address (slave address)

Address of the EK220 in a MODBUS environment. Range from 1 to 247 (0 = broadcast).

MBRSz Size of register

2 = Size of register 2 byte 4 = Size of register 4 byte

MBAMd Adressing mode

The Modbus addresses parameterised in the device are assigned based on the logical addressing. Depending on the recall software employed, it may be necessary to change the addressing in the protocol to the physical addressing. 0 = Logical addressing of the Modbus registers with addresses starting at 1. 1 = Physical addressing of the Modbus registers with addresses starting at 0.

Volume Conversion Device EK220

Modbus standard settings:

Reg. AD Designation / value Format

code

Unit Lis-200

address

1 Bat.R Remaining battery service life 3 months 2:404 2 Stat Actual status, total 3 1:100 3 VT Total actual volume (post-decimal places) 3 10-4 m3 4:302_2 4 VbT Total volume at base conditions (post-

3 10-4 m3 2:302_2

decimal places)

5 W.T Total Energy (post-decimal places) 3 10-4 kWh 1:302_2 101 VT Total actual volume (pre-decimal places) 4 m3 4:302_1 103 VbT Total volume at base conditions (pre-

4 m3 2:302_1

decimal places) 105 W.T Total Energy (pre-decimal places) 4 kWh 1:302_1 301 pb Base pressure 32 bar 7:312_1 303 Tb Base temperature 32 °C 6:312_1 305 p.Abs Absolute pressure measurement 32 bar 6:210_1 307 p.Mes Pressure measurement 32 bar 6:211_1 309 T.Mes Temperature measurement 32 °C 5:210_1 311 C Conversion factor 32 5:310 313 K K-value 32 8:310 315 p.F Substitude pressure 32 bar 7:311_1 317 T.F Substitude temperature 32 °C 6:311_1 319 N2 Nitrogen content 32 % 14:314 321 H2 Hydrogen content 32 % 12:314 323 CO2 Carbon dioxide content 32 % 11:314 325 Rhob Density gas at base conditions 32 kg/m3 13:314_1 327 Q Flow rate 32 m3/h 4:310 329 Qb Flow rate at base conditions 32 m3/h 2:310 331 P Power 32 kW 1:310 333 Ho.b Calorific value 32 kWh/m3 10:314_1 335 dr Density ratio 32 15:314 337 p Pressure 32 bar 7:310_1 339 T Temperature 32 °C 6:310_1 501 VT Total actual volume 9 m3 4:302 504 VbT Total volume at base conditions 9 m3 2:302 507 W.T W, total 9 kWh 1:302 801 VT Total actual volume 17 10-4 m3 4:302 805 VbT Total volume at base conditions 17 10-4 m3 2:302 809 W.T Total Energy 17 10-4 kWh 1:302 813 Time Date and time 17 1:400 817 SNo Serial number 16 1:180 820 DayB Day boundary 12 2:141_1

A change of the Modbus register assignment can be made with the aid of the "WinPADS" parameterisation software via the optical interface.

Volume Conversion Device EK220

3.14 Energy list

AD Designation / value Unit Access Address DC

W Energy kWh S 1:300 12 P Power kW - 1:310 4 WD W disturbance kWh S 1:301 12 W.T W total kWh - 1:302 15 W.A W adjustable kWh S 1:303 12 Ho.b Calorific value kWh/m3 S 10:312_1 8 WME W month end value kWh - 33:161 16 Time Time of W.ME - - 33:165 16

(Legends: see page 22)

W Energy

The energy is calculated from the measured volume at base conditions and the entered calorific value according to the following equation :

W = Vb ž Ho.b where Vb = volume at base conditions (® 3.2) Ho.b = calorific value (® 3.6)

The energy is summed in the counter W provided no alarm is present.

P Power

WD W disturbance

WT W total

WA W adjustable counter

Ho.b Calorific value

WME W month end value Time Time of WME

An alarm is present when any message "1" or "2" is urgent ( ® 3.8).

Momentary power (energy per hour). P = Qb ž Ho.b

Here the energy is summed so long as an alarm is present, i.e. a message "1" or "2" is present in any momentary status (® 3.8).

Here the sum W + WD is displayed. Entries for W or WD therefore arrive here. No entries can be made for WT itself.

As with WT, here the total quantity, i.e. disturbed and undisturbed quantities, are counted. In contrast to WT, WA can however be changed manually. This counter is typically used for tests.

This calorific value is used to compute the energy. Please note that it may differ from the calorific value of the gas analysis (®3.6, page 36) if pnX differs from pn (® 3.4) or TnX differs from Tn (® 3.5).

The entry of the calorific value Ho.b in the energy list is not permitted (entry error code “6” will occur). Please change Ho.b only in the volume corrector list (® 3.6, page 36).

Here, the counter reading is saved with associated time stamp at the first day boundary of each month.

Volume Conversion Device EK220

4 Applications

4.1 Application in areas subject to explosion hazards

F If the EK220 is operated outside of Ex Zone 1, application again in Ex Zone 1 is only

admissible after prior checking of the volume corrector at Elster GmbH.

4.1.1 Applications in Zone 1

The EK220 is suitable for applications in Ex Zone 1 for gases in the temperature class T4 (ignition temperature > 135°C, e.g. natural gas). (Certificate of conformance: ® Appendix

A-2) With applications in Zone 1 connected devices must not exceed the conditions and limits

quoted in the certificate of conformance (® A-2). Furthermore, all safety information (® Chapter I) must be followed.

4.1.2 Applications in Zone 2

The device may also be used in Zone 2 under all conditions which enable application in Zone 1.

Furthermore, the device may be used according to DIN EN 60079-14 (VDE 0165 Part 1), Section 5.2.3 c) in Zone 2 for gases of temperature class T1 (e.g. natural gas) if the insta llation is implemented according to DIN EN 60079-14 (VDE 0165 Part 1) and the operating conditions quoted in these instructions are fulfilled.

In particular they are:

· Ambient temperature according to Chapter B-1.

· Batteries according to Chapter B-2.

· Correct wiring, in particular no active outputs switching one against the other.

· Voltage of an external power supply according to Chapter B-3 has a maximum of

9.9 V (manufacturer's rating of the connected device).

· Switching of the digital inputs DE1...DE3 according to Chapter B-3 only with reed

contacts, transistor switches or encoder interface.

· Switching voltage of the device connected to the outputs DA1..DA4 with a maximum

of 30 V according to Chapter B-5 (manufacturer's rating of the connected devices).

· Only connect devices which conform to the RS-232 or RS-485 standard to the elec-

trical serial interface according to Chapter B-7.

· Unused cable glands must be closed off according to DIN EN 60079 -14 (VDE 0165

Part 1), Section 14.3.2 with plugs or suitable screw caps.

· Installation, cables and lines according to DIN EN 60079-14 (VDE 0165 Part 1), in par-

ticular Sections 9, 12.1, 12.2 and 14.3.

Volume Conversion Device EK220

4.1.3 Ex identification lable

Elster GmbH

0044

Typ EK220

TÜV 08 ATEX 554344

Elektr. Daten: siehe EG - Baumuster-Prüfbescheinigung

55252 Mainz-Kastel

II 2 G Ex ia [ia] IIC T4

-30 °C < T < +60 °C

73020153

4.2 Rated operating conditions for the various conversion methods

In determining the actual permissible measurement range for the pressure and temper ature of the gas, apart from the technical possibilities offered by the connected measur ement sensor, the conversion method must also to be considered. The alarm limits Tmin, Tmax, pmin and pmax can lie outside of the measurement range and differ by up to 5% (for pressure) or 1°C (for temperature) from the measurement range limits. In this way tes ting of the device at the measurement range limits for temperature and pressure is simpl ified.

On reaching or exceeding the alarm limits, an alarm is triggered and counting takes place in the disturbance quantity counters.

The following correction methods are available for certain applications:

Fixed value K=1 (Md.K = 0, see Chapter 0) This fixed value can be used when the gas shows only slight deviations (up to 0.25%) from

the ideal gas behaviour. For natural gases and their mixtures, i.e. gas mixtures, which have a high methane content, this applies at temperatures above -10°C up to an absolute pressure of 1.5 bar or an overpressure of 0.5 bar.

The pressure range can be extended to 2.0 bar absolute pressure or 1.0 bar overpressure if the temperature is always higher than

- +5 °C for gases with H

- +12 °C for gases with H

< 11.5 kWh/m³

o,b

³ 11.5 kWh/m³

o,b

Wider pressure and temperature ranges can be set for the gas composition present at a measuring point if compliance with the error limit is proven by calculations. This also applies to other fuel gases (e.g. town gas). For the calcul ations the conditions given in the following section apply.

Fixed value K¹1 (Md.K = 0, see Chapter 0) Fixed values for K, which differ from 1, may be suitable for measuring points, the absolute

pressure of which always lies below 11 bar and for which the gas pressure and the gas temperature only vary within known limits. The fixed value must be calculated using one of the following methods:

- S-Gerg 88 after testing the reliability of the method (see below)

- AGA8-DC92 according to ISO 12213 Part 2 /1/ Through a calculation using the same method, it must be proven that the K-values only

deviate by at the most 0.25% from this fixed value in the permissible measurement range (i.e. with compliance to the pressure and temperature limits). The pri nciples of the calculation and the calculated results at the limits of the measurement range must be r ecorded in the operational and rating data book, page "Proof of measures implemented". The alarm limits p

min

, p

max

, T

min

and T

must be set according to the measurement range (see

max

above).

Volume Conversion Device EK220

S-Gerg 88 (Md.K = 1, see Chapter 0) This method is suitable for natural gases and their mixtures

1.) at temperatures between -10°C and +60°C and for absolute pressures up to 26 bar

2.) at temperatures between -10°C and +60°C, also at absolute pressures above 26 bar, when the following conditions are fulfilled

- The amount of substance of the propane xC3 [in mol%] must lie within the limits given by the following equation in relationship to the amount of substance of the ethane xC2 [in mol%].

0.3 . x

– 1.0 < x

< 0.3 . x

+ 1.0 (1)

- The sum of the amounts of substance of n-butane, isobutane and higher hydrocarbons xC4 [in mol%] must lie within the limits given by the following equation in relationship to the amount of substance of the ethane xC2 [in mol%].

0.1 . x

– 0.3 < x

< 0.1 . x

C4+

+ 0.3 (2)

3.) For other gas compositions (e.g. processed biogas), temperature ranges and pressure ranges, when it is proven through comparative calculations using the method AGA8 -DC92 for the expected pressure and temperature ranges, which are safeguarded by alarms, as well as the present gas composition, that no deviations of more than 0.1% occur.

The principles of the calculation and the calculation results at the limits of the measur ement range must be recorded in the operational and rating data book, page "Proof of measures implemented", unless the calculation method S-Gerg 88 is generally accepted for the present application due to a national regulation.

AGA8 Gross characterisation method 1 und 2 (Md.K = 3 and 4, see Chapter 0) This method is suitable for temperatures between 0°C and 55°C for gas mixtures, whose

relative density lies between 0.554 and 0.87, whose calorific value is between 5.2 kWh/m³ and 12.5 kWh/m³ and whose components comprise the following amounts of substances

[in mol-%]:

³ 45 £ 50 £ 30 £ 10 £ 4 £ 1

C4H10: Sum of n-butane and i-butane; C5H12: Sum of n-pentane and i-pentane; C6+: Sum of all hydrocarbons with at least 6 carbon atoms

CO2 C2H6 C3H8 C4H

C5H

£ 0.3 £ 0.2 £ 0.2 £ 10 £ 3 £ 0.05 £ 0.02

He H

CO H2O H2S

AGA-NX19 and AGA-NX19 according to Herning and Wolowsky (Md.K = 2 and 5, see Chapter 0)

This method is suitable for applications for which it has been shown by a comparative calculation with the reference method AGA8-DC92 or (in its application range) S-Gerg 88 that no deviations of more than 0.1% occur.

4.3 Connection of a counter with LF pulse transmitter

Ex-works the maximum counting frequency of the EK220 Volume Conversion Device is parameterised to 2 Hz. Reparameterising to a maximum of 10 Hz is possible by trained specialist personnel with the calibration lock open. Changes to the input frequency must be noted in the operational and rating data book on the page "Proof of measures carried out".

Volume Conversion Device EK220

4.4 Applications for Interface 2 as RS485

4.4.1 FE260 Function Expansion

F Connection see Chap. 5.6.1, page 95

The FE260 is a mains-powered function expansion incl. Ex isolation and supply for the EK220. It has may have alternatively an integral modem or a connection for a comme rcially available modem.

For the connection of an FE260 with integral or separately connected modem, the follo wing settings should be made under the interface list ( ® 3.13):

- Md.S2 = 3 With modem control by "return messages" via data lines, without baud rate selection. Num.T is activated.

or = 5 * Without modem control. Either the modem accepts the call

automatically or another device is connected to the FE260 (no modem). Num.T is not activated.

- Bd.S2 = 19200 * Baud rate 19200 Bd (or lower, depending on the device connected to the FE260)

- TypS2 = RS485 Type of interface 2: RS485

- BusS2 = 0 No bus mode.

- Num.T = ... Num.T is only activated with Md.S2 = 3. Possible values are dependent on the modem used, e.g.:

- Standard modem (Insys) integrated in FE260 ............ 2 to 9

- ISDN modem (Insys) integrated in FE260 .................. 2 to 9

- GSM modem (Wavecom) integrated in FE260 .......... 1 to 9

- Separate GSM modem Siemens M20T or TC35T ...... 1

- Separate analogue modem EM200 or Insys Onbit ..... 2 to 9

* Normally, modems do not execute any baud rate selection so that with Md.S2 = "5" the

values under the addresses 02:708 (Bd.S2) and 02:709 must be equal. For the connection of a device with baud rate selection, the starting baud rate (normally 300 Bd) must be set under the Bd.S2 (address 02:708) and the baud rate identification under address 02:709.

Volume Conversion Device EK220

4.4.2 FE230 Function Expansion with modem

F Connection see Chap. 5.6.2

The FE230 is a battery-powered function expansion with integral modem. For this application extended parameterization of the device via the optical interface is re-

quired. Special parameter files are available for this which are installed with the "WinPADS" program and which can also be loaded into the device using the program.

After the parameterising process with "Md.S2 = 6", the settings for the read-out time window should be made under the interface list (® 3.13).

- Md.S2 = 6 Without modem control. The modem accepts the call automatically. Battery operation is possible. The EK220 controls the modem and the call acceptance. Num.T is activated.

- Bd.S2 = 19200 Baud rate 19200 Bd

- TypS2 = RS485 Type of interface 2: RS485

- BusS2 = 0 No bus mode.

- Num.T = ... Num.T is not activated.

After the parameterisation process particularly the settings for the readout time window must be adjusted under the interface list (® 3.13), because the battery service life of

the FE230 crucially depends on them.

4.4.3 Devices with RS485 interface, without modem (also FE260 without modem)

F For this applications the EK220 needs an external power supply. F Connection see Chap. 5.6.1, page 95.

For the connection of a device with RS485 interface without a modem, the following settings must be made under the interface list (® 3.13):

- Md.S2 = 5 No modem control by the EK220, without control signals, baud rate selection possible

- Bd.S2 = 300 With application of baud rate selection according to IEC 62056-21 (procedure as for the optical interface) 1

or = 19200 Baud rate selection bypassed

- TypS2 = RS485 Type of interface 2: RS485

- BusS2 = 0 No bus mode.

4.4.4 EK220 connected to RS485-Bus (real RS485)

F For this applications the EK220 needs an external power supply. F Connection see Chap. 5.6.1, page 95.

The set baud rate is only used briefly for initiating the data interchange. The actual baud

rate for transmitting the useful data is increased automatically to 9600 Bd.

Volume Conversion Device EK220

To connect the EK220 to an RS485 bus as a slave, the following settings must be carried out under the interface list (® 3.13):

- Md.S2 = 5 No modem control through the EK220, without control signals

- Bd.S2 = 19200 Baud rate 19200 Bd

- TypS2 = RS485 Type of interface RS485

- BusS2 = 1 Bus mode

In addition the bus device address 2:070E of the EK220 must be set to a value ¹ 0 with the aid of the "WinPADS" parameterisation software. The serial number, for example, of the EK220 as shown on the nameplate can be used as the device address.

4.5 Applications for Interface 2 as RS232

4.5.1 Modem with control signals

F Connection see Chap. 5.7, page 98

A commercially available modem with RS232 interface is connected to the internal serial interface of the EK220. For this application the EK220 needs an external power supply.

For the connection of a modem it must be parameterised for automatic call acceptance and the following settings must be made under the interface list (® 3.13):

- Md.S2 = 1 No modem control by the EK220, with RS232 control lines, baud rate selection possible

- Bd.S2 = 19200 19200 Bd - without application of baud rate selection

4.5.2 Modem without control signals

F For this applications the EK220 needs an external power supply. F Connection see Chap. 5.7.2, page 98

The following settings should be made under the interface list ( ® 3.13):

- Md.S2 = 3 The EK220 controls the modem by "return messages" via data lines; without baud rate selection; Num.T is activated.

or = 5 * Without modem control by the EK220, without baud rate se-

lection. Num.T is not activated. The modem accepts the call automatically.

- Bd.S2 = 19200 * 19200 Bd

- Num.T = ... Only activated with Md.S2 = 3. Possible values depend on modem used, e.g.:

- GSM modem Siemens M20T or TC35T ............. 1

- Analogue modem EM200 or Insys Onbit ............ 2 to 9

* Normally, modems do not execute any baud rate selection so that with Md.S2 = "5" the

values under the addresses 02:708 (Bd.S2) and 02:709 must be equal.

For the special case of a modem with baud rate selection, the starting baud rate (e.g. 300

Bd) must be set under the Bd.S2 (address 02:708) and the baud rate identification (e.g. 19200 Bd) under address 02:709.

The ex-works setting is: 02:708 = 19200 Bd and 02:709 = 19200 Bd.

Volume Conversion Device EK220

4.5.3 Interface isolator MTL5051

F For connection see Chap. 5.7.3, page 99).

For this application it is necessary to send the wake-up call (NULL character string) according to IEC 62056-21.

The following settings should be made:

a) Using the baud rate selection (recommended), maximum 19200 Bd:

- Md.S2 = 1

- Bd.S2 = 300 (Starting baud rate)

- 2:0709 = 19200 (Changeover baud rate)

b) Without using the baud rate selection (recommended), maximum 9600 Bd:

- Md.S2 = 1

- Bd.S2 = 9600 (Start baud rate)

- 2:0709 = 9600 (Changeover baud rate)

When using the baud rate selection, Bd.S2 is used only briefly to initiate the data traffic. Then, the actual baud rate for transferring the useful data is automatically selected. This can be set using the WinPADS parameterisation software under address 2:0709. The standard setting is 19200 Bd.

Without using the baud rate selection reliable data transmission is possible up to a maximum of 9600 Bd.

If a PC with the WinPADS parameterisation software is connected to the MTL5051, the following settings are to be carried out under WinPADS:

a) With the use of the baud rate selection:

Settings > Interface > Link formation > ...................Local connection

Settings > Interface > Local connection options

> Local connection baud rate > .................. 300

Settings > Interface > Local connection options

> Baud rate selection > ............................. with

b) Without use of the baud rate selection:

Settings > Interface > Link formation > ...................Local connection

Settings > Interface > Local connection options

> Local connection baud rate > ................ 9600

Settings > Interface > Local connection options

> Baud rate selection > ........................... None

Volume Conversion Device EK220

4.5.4 Other devices with RS232 interface (no modem)

a) EK220 battery powered

F Connection see Chap. 5.7.4, page 100.

The following settings must be made under the interface list (® 3.13):

- Md.S2 = 1 No modem control by the EK220; with RS232 control line; baud rate selection possible

- Bd.S2 = 300 300 Bd - with the use of baud rate selection (procedure as for t he optical interface) 1

b) EK220 with erternal power supply

F Connection see Chap. 5.7.5, page 100.

The following settings must be made under the interface list ( ® 3.13):

- Md.S2 = 5 No modem control by the EK220; without RS232 control lines; without baud rate selection

- Bd.S2 = 19200 19200 Bd - without the use of baud rate selection

4.5.5 Sending short messages by SMS.

F It is not possible to send short messages with an FE230.

If a modem (except FE230) is connected to Interface 2, then with definable events the EK220 can send a brief message by a short message (Short Message Service in the GSM mobile radio network). To do this, a large number of settings are needed which cannot be made by means of the keypad on the device, but instead with the aid of the "WinPADS" parameterisation software.

The settings which can be made include the event which triggers the message, one or two recipients and any eight volume corrector values as the message content.

With SEND (® page 77) you can send the defined message also with the keypad.

4.5.6 Standard output data records for process data ("three-minute values")

Process data can be synchronously temporarily stored in short cycles (e.g. 3 minutes) and interrogated over the interface. To output these data records the mode "Data readout"" in "Mode C" according to IEC 62056-212 is used.

In order to obtain practicable values, buffer storage of the process data has to be act ivated. In this respect

- the value "21" is written to the address "13:0157.0" via the interface and

- the operating cycle OCyc (® 54) is set to an integer divisor of 3 minutes.

Through these measures the battery service life of the EK220 is slightly reduced. The expected remaining service life is displayed under Bat.R (® page 56).

The set baud rate is only used briefly for initiating the data interchange. The actual baud

rate for transmitting the useful data is increased automatically within the framework of the protocol e.g. to 19200 Bd.

IEC 62056-21: formerly IEC 1107 or EN 61107

Volume Conversion Device EK220

Volume at base conditions,

Output of the data records The data records are labelled on recalling with the addresses 1:01CD ... 15:01CD. (Other

addresses are used to set the content, see above.) In the factory setting the following data are output:

No. Address Assignment Meaning Example

1. 1:01CD 1:0180 EK220 serial number 1:1CD.10(4102758)

2. 2:01CD 1:0400 Time stamp 2:1CD.12(2007-02-26,13:24:35) 3:01CD 2:0300 Volume at base conditions 3:1CD.12(12340*m3)

4. 4:01CD 2:0301

disturbed

4:1CD.12(0*m3)

5. 5:01CD 4:0300 Actual volume 5:1CD.12(134560*m3)

6. 6:01CD 4:0301 Actual volume, disturbed 6:1CD.12(0*m3)

7. 7:01CD 5:0310 Conversion factor 7:1CD.11(0.89531)

8. 8:01CD 7:0310_1 Gas pressure 8:1CD.11(0.98862* bar)

9. 9:01CD 6:0310_1 Gas temperature 9:1CD.11(24.32*°C)

10. 10:01CD 8:0310

Inverted compressibility factor ratio

10:1CD.11(1.00068)

11. 11:01CD 2:0310 Flow at base conditions 11:1CD.11(32.23*m3|h)

12. 12:01CD 4:0310 Actual flow 12:1CD.11(36*m3|h)

13. 13:01CD 2:0110 Status 2 (incl. Vb) 13:1CD.13(0)

14. 14:01CD 4:0110 Status 4 (incl. Vm) 14:1CD.13(0)

15. 15:01CD 2:0100 System status 15:1CD.13(13)(15)

Setting the data record content You can freely set the content of the process data with the aid of the "WinPADS" Parameterising Software". The addresses 1:01CF ... 15:01CF are used for setting values.

Archiving the data records For tracing (e.g. after a mains failure) the last 200 process data records can be saved in

Archive 10. Archiving starts once the buffer storage of the process data has been activated (see above).

4.6 Interface protocols

Apart from the standard protocol according to DIN IEC 62056-21, the following protocols can also be set:

4.6.1 Modbus

see Chap. 3.13.3, page 79

4.6.2 Idom protocol

see Chap. 3.13.2, page 78

Volume Conversion Device EK220

5 Installation and maintenance

The EK220 is suitable for wall mounting and for installation on a gas meter. The holes for wall mounting become accessible after opening the housing cover. For installation on a meter a mounting bracket is required.

The installation and first test can occur without the presence of a calibration official, because all relevant areas are secured by adhesive labels.

5.1 Installation procedure

The following steps must be carried out to install the device:

1. Mounting of the EK220 on the gas meter, on a bracket or on the wall.

2. Connection of the pulse transmitter, pressure line and insertion of the temperature se nsor in the thermowell.

3. If required, connection of the following equipment to the power supply input, serial interface or pulse/signal outputs.

F If the EK220 is used in a hazardous area (Zone 1), then only intrinsically safe electri-

cal circuits of certificated "associated operating equipment " must be connected. Their certificated electrical data must conform to the requirements stated in the certificate of conformance for the EK220.

4. With unused union screw joints the insertion seal must be replaced by one the enclosed blind insertion seals.

5. Sealing of the device by the weights and measures office or test station according to the seal layout.

6. Close the housing.

F When closing the housing, make sure that no cables are pinched.

Volume Conversion Device EK220

5.2 Cable connection and earthing

The EK220 housing must always be earthed in order to divert high energy and high voltage electromagnetic interference. An M6 screw is provided for this on the left-hand side of the housing.

The earthing must be low resistance. The best conditions are obtained when a direct co nnection is provided to the local potential equalisation strip through a cable which is as short and as thick (at least 4mm²) as possible.

All permanently connected cables must have a screen which must be earthed at both ends to prevent interference due to high frequency electromagnetic fields. The screen must be connected all round, complete and flat. The EK220 has special EMC cable glands for this purpose.

With correct connection of the cable screens and correct laying of the cables effects due to circulation should not be expected. If, however, interference due to earthing points with potential differences occur, potential equalisation lines can be laid in parallel to the cables. These should then be connected as close as possible to the cable screen connection points.

Additional requirements are placed on the earthing of conducting screens between Ex areas and non-Ex areas. The relevant installation requirements, e.g. EN 60079-14, must be followed.

5.3 Checking the pressure sensor

The pressure sensor must be checked for leaks during the recurring pressure tests of the system.

Volume Conversion Device EK220

5.4 Terminal layout

Connection of the individual cables is made to the corresponding terminals on the circuit board in the housing cover. When positioning the cables, make sure that no cables are pinched as the cover is closed.

X54

X55

+ - + - + -

X87 Druck

X92 Temp.

DE1 DE2 DE3

+ - + - + DE1 DE2 DE3

Inputs:

DE1 Digital Input 1 DE2 Digital Input 2 DE3 Digital Input 3

Outputs: DA1 Digital Output 1 DA2 Digital Output 2

+ - + - + - + DA1 DA2 DA3 DA4

X100

Fig. 2: Terminal layout

+ DA4

T+ T- R+ R- Uext GND RS485

DTR TxD DCD RxD RI GND RS232

DA3 Digital Output 3 DA4 Digital Output 4

Volume Conversion Device EK220

When using the lead available from Elster GmbH with

Serial interface, Version RS485: GND Signal ground (Ground) Uext External power supply + R- Received data R+ Received data + T- Transmitted data T+ Transmitted data +

Serial interface, Version RS232:

GND Signal ground (Ground) RI Controlsignal / External power supply + RxD Received data DCD Controlsignal TxD Transmitted data DTR Controlsignal

Pressure and temperature sensors: X92 Temperature sensor, four-wire X87 Pressure sensor (Option: two pressure sensors)

Batteries: X54 Battery 1 X55 Battery 2

Others:

X100

If the EK220 is not employed in Ex Zone 1, the jumper X100 should be plugged onto both pins of the male connector when connecting an exte rnal power supply. In this way any interference introduced by the connected device, which may otherwise cause erroneous measurements, can be led away.

5.5 Connection of a low-frequency pulse generator (reed contacts)

A pulse generator must always be connected to the terminal "DE1". In addition, a second pulse generator can be connected to terminal "DE2", e.g. for a pulse comparison (® page 62). Any polarity can be chosen. Connection scheme:

the order no. 73017093 (about 70 cm long), the following wires should be connected: Terminal DE1: Brown and white Terminal DE2: Yellow and green

Pulse

generator 1

Pulse

generator 2

(on request)

DE1

DE2

Volume Conversion Device EK220

5.6 Connection of the serial interface RS485

F If the EK220 is not employed in Ex Zone 1, the supplied jumpers should be plugged

onto both pins of the X100 male connector (position: in front of the terminals) when connecting a following device (e.g. modem or power supply unit). In this way any interference introduced by the connected device, which may otherwise cause erroneous measurements, can be led away.

5.6.1 FE260 Function Expansion (with or without modem)

F Before connection the display should no longer be active. When connecting, it must be

ensured that first the external power supply and then the communication lines are connected.

A four-wire connection (one core each for T+, T-, R+, R-, full duplex) should be made.

Connection diagram:

R + R +

EK220 FE260

R - R -

T + T +

T - T -

Uext U +

GND

U -

Volume Conversion Device EK220

5.6.2 FE230 Function Expansion

F For this application the connection of the external power supply is not possible.

Connection diagram:

R + R +

EK220 FE230

R - R -

T + T +

T - T -

Ri Ri

GND GND

DA4 + DA4 +

DA4 -

5.6.3 Other devices with RS485 interface (no modem)

F Before connection the display should no longer be active. When connecting, it must be

ensured that first the external power supply and then the communication lines are connected.

F For this applications the EK220 needs an external power supply.

A four-wire connection (one core each for T+, T-, R+, R-) should be made, two-wire connection (half duplex) is not possible.

Connection diagram:

EK220

R + T + (Send data +)

R - T - (Send data -)

T + R + (Receive data +)

T - R - (Receive data -)

Uext Power supply +

GND

Device with RS485 interface

(no FE260, no FE230)

Power supply -

Volume Conversion Device EK220

5.6.4 EK220 connected to RS485-Bus (real RS485)

F Before connection the display should no longer be active. When connecting, it must be

ensured that first the external power supply and then the communication lines are connected.

F For this applications the EK220 needs an external power supply. F No termination resistance should be connected to the RS485 bus.

Connection diagram:

EK220

additional devices

("Slaves")

Uext

Gnd

R+

Data+

R- Data-

T+

T-

Data+

Data-

External power supply

Bus-Master

Volume Conversion Device EK220

5.7 Connection of the serial interface RS232

F If the EK220 is not employed in Ex Zone 1, the X100 jumpers (position: in front of the

terminals) should be plugged onto both pins of the male connector when connecting a device to the serial interface (e.g. modem or power supply unit). In this way any interference introduced by the connected device, which may otherwise cause erroneous measurements, can be led away.

5.7.1 Modem with control signals

F For this application the connection of the external power supply is not possible.

Connection diagram:

EK220 Colour *

TxD

RxD

GND

DTR

DCD

gr 5

Pin *

Modem

TxD

RxD

Ring

GND

DTR

DCD

* Pin numbers of the DSUB-9 plug and core colours when using a ready-made cable

available from Elster GmbH, e.g. Order No. 73016923 (2 m) or 73017268 (10 m).

5.7.2 Industrial modem EM260 or Modem without control signals

F For this application the EK220 needs an external power supply. F EK220 on EM260 only functions with an EM260 shipped from mid -2008 onwards.

Connection diagram:

EK220

TxD

RxD

Uext

GND

DTR

DCD

not connected

EM260

TxD

RxD

+9V

GND

5.7.3 Interface isolator MTL5051

Connection diagram:

Device

with

RS232

MTL5051

Volume Conversion Device EK220

EK220

(RxD)

(TxD)

alle

n.c.*

(Gnd)

24V

* n.c. = not connected

Settings of MTL5051:

ì í î

Tx Rx

Rx Tx

5V/12V

Ground Ground

1a = OFF 1b = ON

2a = OFF 2b = ON

n.c.*

TxD

RxD

DTR

DCD

Ri / Uext

GND

RS232

n.c.*

Volume Conversion Device EK220

5.7.4 Other devices with RS232 interface, EK220 battery powered

F For this application the connection of the external power supply is not possible.

Connection diagram:

EK220

Connected device

(RS232)

TxD

RxD

GND

DTR

DCD

not connected

RxD

TxD

GND

5.7.5 Other devices with RS232 interface, EK220 with external power supply

F For this application the EK220 needs an external power supply.

Connection diagram:

EK220

TxD RxD

RxD TxD

Uext

GND

DTR

DCD

not connected

Connected device

(RS232)

Power supply +

Power supply -

Elster EK220 Operating Instructions And Installation Information

Specifications and Main Features

Frequently Asked Questions

User Manual