m2x3c i500c en m c manual gb

8/13/2019 m2x3c i500c en m c Manual Gb

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M2x3&I500CommunicationsManual

Communications Manual

iSTAT M2x3 & I500

Publication Reference: M2x3C+I500C/EN/M/C

M2x3C+I500C/EN/M/C2011.ALSTOM,theALSTOM logoandanyalternativeversionthereofaretrademarksandservicemarksofALSTOM.Theothernamesmentioned,registeredornot,arethepropertyoftheirrespectivecompanies.Thetechnicalandotherdatacontainedinthisdocumentisprovidedforinformationonly.NeitherALSTOM,itsofficersoremployeesacceptresponsibilityfor,orshouldbetakenasmakinganyrepresentationorwarranty(whetherexpressorimplied),astotheaccuracyorcompletenessofsuchdataortheachievementofanyprojectedperformancecriteriawheretheseareindicated.ALSTOMreservestherighttoreviseorchangethisdataatanytimewithoutfurthernotice.

GRID


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Technical Manual M2x3C+I500C/EN M/C

iSTAT M2x3 & I500 Modbus & DNP3.0 Page 1

CONTENT

1. COMMUNICATIONS SETUP 31.1 Setup communications on the M2x3 and I500 31.2 Ethernet 31.2.1 Using Fixed IP address 31.2.2 Local Port 31.3 Ethernet (XPort) communication 32. MODBUS INFORMATION 62.1 introduction 62.2 Transactions 62.3 Request 62.4 Response 62.5 Request - response cycle example 62.5.1 Request Frame 72.5.2 Response Frame 72.6 Framing 72.7 RTU framing 73. MODBUS SUPPORTED FUNCTIONS AND USAGE 83.1 03 read from holding registers 83.1.1 Request Frame 83.1.2 Response Frame 83.2 04 read from input registers 83.2.1 Request Frame 83.2.2 Response Frame 93.3 06 write to a single holding register 93.3.1 Request Frame 93.3.2 Response Frame 93.4 16 (10 HEX) write to one or more registers 93.4.1 Request Frame 93.4.2 Response Frame 103.5 17 (11HEX) report slave id 103.5.1 Request Frame 103.5.2 Response Frame 103.6 77 (4D HEX) read measurement string 103.6.1 Request Frame 103.6.2 Response Frame 103.6.3 Value Codes 113.7 82 (52 HEX) re-read output buffer 12


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M2x3C+I500C/EN M/C Technical Manual

Page 2 iSTAT M2x3 & I500 Modbus & DNP3.0

3.7.1 Request Frame 123.7.2 Response Frame 124. MODBUS ERROR RESPONSES 134.1 Exception codes 135. MODBUS REGISTER MAPS 146. MODBUS DATA FOR M2X3 AND I5MT/MR/MQ 156.1 SYSTEM DATA 156.2 MEASUREMENTS 176.3 NORMALIZED MEASUREMENTS 276.4 HARMONIC DATA 316.5 MEASUREMENTS (IEEE 754) 336.6 PRODUCT SETTINGS 376.7 OUTPUT PARAMETERS 576.8 OUTTYPES 586.9 MODBUS DATA TYPES 656.10 FLASH DATA 687. MODBUS DATA FOR I5MC/MV/MS/ML 707.1 MEASUREMENTS 707.2 NORMALISED MEASUREMENTS 717.3 MEASUREMENTS (IEEE 754 ) 747.4 PRODUCT SETTINGS 757.5 MODBUS DATA TYPES 758. DNP3.0 PROGRAMMING FOR M2X3 AND I5MT/MR/MQ 778.1 DNP 3.0 DEVICE PROFILE DOCUMENT 778.2 DNP3.0 REGISTER MAP 798.3 DATA TYPES DECODING 818.4 100% VALUE CALCULATIONS 819. RELATED DOCUMENTS 83


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1. COMMUNICATIONS SETUP

The Setup of the communications on the I500 or M2x3 is achieved using the QDSPconfiguration software. QDSP can communicate with the iSTAT products via RS232, RS485,USB and Ethernet. The option used will depend on which communication port is fitted to theproduct.

The QDSP software always uses Modbus protocol to communicate with the product.

1.1 Setup communications on the M2x3 and I500

The setup of the communication ports is done using the QDSP software and is detailed in aseparate manual.

It is suggested that the communications channel for the product required by the application isinitially set up using QDSP running on a PC. Then when that is working correctly the productcan be connected to the required intelligent device.

1.2 Ethernet

When using the QDSP over Ethernet the set-up will depend on how the PC and the productare connected. The Communication interface must have a unique IP address in the Ethernetnetwork. Two modes for assigning IP are available:

Fixed IP address: In most installations a fixed IP address is required. A system providerusually defines IP addresses. An IP address should be within a valid IP range, unique foryour network and in the same Subnet mask as your PC.

DHCP: Automatic method of assigning IP addressed (DHCP) is used in most networks. Ifyou are not sure if DHPC is used in your network, check it with your system provider.

1.2.1 Using Fixed IP address

When the PC is directly connected to the Instrument a Fixed IP address will have to be usedwith the PC configured in the local area connection. If the connection is made without a Hub

or Switch, the connection has to be made with a Crossover Ethernet cable.

The fixed IP address can be set in the product using QDSP.

1.2.2 Local Port

Is the physical connector on a device enabling the connection to be made. Use a nonreserved port number from 1025 to 65535. If using Redirector software, the port numbershould be between 14000 and 14009.

Port numbers Function

1 1024, 9999,30718

Reserved numbers

14000 14009 Reserved for Redirector

1.3 Ethernet (XPort) communication

There are 2 types of Ethernet interfaces used on the M2x3. QDSP will always allow thesetting of the IP address, but on the older version it does not allow the setting of Local Portetc. If required this has to be accessed using an internet browser.

Any internet browser available can be used to access the interface in the product, type in theIP address of the product as the required internet address.

The browser will communicate with the instrument and then display a request for password;press OK without entering a password and the XPORT screen will be displayed.


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Select to display Network settings where Subnet Mask and Default Gateway canbe modified if required.

Select to show connection settings, where local port can bemodified.


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No other settings need to be changed.

When changes are complete select

After downloading the settings it is necessary to reset the M2x3 device to make the changesactive.


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2. MODBUS INFORMATION

2.1 introduction

The Modbus protocol is a widely supported open interconnect protocol originally designed byModicon that can be enabled on the M2x3 and I500 via RS232, RS485, USB or Ethernet

communication.

There are two Modbus protocol types: Modbus RTU for serial communication (and USB) andModbus TCP for Ethernet communication. It is also possible to pass Modbus RTUcommunications over Ethernet.

On Serial Communication, Modbus is a single master multiple slave protocol suitable for amulti-drop configuration as provided by the RS485 connection. Up to 32 devices can beconnected in this way. Single - drop RS232 or USB connection is also possible.

2.2 Transactions

Communication operates on a master-slave basis where only one device (the master) caninitiate transactions called 'Requests'. The other devices (slaves) respond by supplying the

requested data to the master. This is called the 'Request - Response Cycle'.Master to slave request:

Device address Function Code nx8 bit data bytes Error check

Slave to master response:

Device address Function Code nx8 bit data bytes Error check

2.3 Request

This Master to Slave transaction takes the form:

Device address: Master addressing a slave (Address 0 is used for the broadcastaddress, which all slave devices recognise.).

Function code: E.g. 04 ask the slave to read its Input Registers and respond withtheir contents.

Data bytes: Tells the slave which register to start at and how many registersto read.

2.4 Response

This Slave to Master transaction takes the form:

Device address: To let the master know which slave is responding.Function code: This is an echo of the request function code.

Data bytes: Contains the data collected from the slave.

2.5 Request - response cycle example

Ia 160.00 A = 16000* 10-2A

Data type T3 32 bitunsigned

FE 00 3E 80(16)

Data held in Modbus

addresses

30036(10) & 30037(10)

30036(10)- 30000 (10)= 36 (10) 00 24 (16)


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2.5.1 Request Frame

Starting Register Register Count CRC

Slave AddressHI LO

Function code HI LO LO HI

21 04 00 24 00 02

2.5.2 Response Frame

Register Data CRC

Slave AddressLO HI

Function code Byte Count HI LO HI LO

21 04 04 FE 00 3E 80

2.6 Framing

There are two types of message framing for the serial communications, ASCII or RTU.

iSTAT products supports RTU framing.

2.7 RTU framing

In RTU mode, messages start and end with a silent interval of at least 3.5 character times(t1-t2-t3-t4 as shown below).

The advantage of this mode of framing is that it enables a greater character density and abetter data throughput. However, each message must be transmitted in a continuous stream.If a silent interval of more than 1.5 character times occurs before completion of the frame,the device flushes the incomplete message and assumes that the next byte will be theaddress field of a new message.

Start Address Function Data CRC Check End

t1-t2-t3-t4 8 bits 8 bits n x 8 bits 16 bits t1-t2-t3-t4

The Cyclic Redundancy Check (CRC) field is two bytes, containing a 16 bit binary value. TheCRC value is calculated by the transmitting device, which appends the CRC to the message.The receiving device recalculates a CRC during receipt of the message, and compares thecalculated value to the actual value it received in the CRC field. If the two values are notequal an error results. The CRC-16 calculation is an industry standard method used for errordetection.

One frame is transmitted as 1 start bit, 8 data bits and 2 stop bit. If parity is selected then theframe is transmitted as 1 start bit, 8 data bits, and 1 stop bit.

Where n > 1 data is transmitted most significant byte first.

The CRC check is transmitted least significant byte first.


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3. MODBUS SUPPORTED FUNCTIONS AND USAGE

Code Code Function References

DEC HEX

3 03 to read from holding registers (4XXXX memory references)

4 04 to read from input registers (3XXXX memory references)

6 06 to write to a single holding register (4XXXX memory references)

16 10 to write to one or more holding registers (4XXXX memory references)

17 11 report slave ID 6 characters

77 4D read measurement string 1 byte value code (request)

82 52 re-read output buffer Use after broadcast request

3.1 03 read from holding registers

Reads the binary content of holding registers (4X references) in the slave. Broadcast is also

supported.

3.1.1 Request Frame

The query message specifies the starting register and quantity of registers (1 to 28) to beread. Registers are addressed starting at zero.

Here is an example of a request to read registers 40009 ... 40010 from slave device 33:


Slave Address Function Code HI LO HI LO LO HI

21 03 00 09 00 02


The register data in the response message is packed as two bytes per register, with thebinary contents right justified within each byte. For each register, the first byte contains thehigh order bits and the second contains the low order bits.

Data is scanned in the slave at the rate of 28 registers per scan. The response is returnedwhen the data is completely assembled.

Here is an example of a response to the query:

Register Data CRC

Slave Address Function Code Byte Count HI LO HI LO LO HI

21 03 04 75 03 42 15

The contents of registers 40009 ... 40010 are 75 03 and 42 15 hex.

3.2 04 read from input registers

Reads the binary content of input registers (3X references) in the slave. Broadcast is alsosupported

3.2.1 Request Frame

The query message specifies the starting register and quantity (1 to 28) of registers to beread. Registers are addressed starting at zero.

Here is an example of a request to read registers 30036 ... 30037 from slave device 33:



21 04 00 24 00 02


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The register data in the response message is packed as two bytes per register, with thebinary contents right justified within each byte. For each register, the first byte contains thehigh order bits and the second contains the low order bits.

Data is scanned in the slave at the rate of 28 registers per scan. The response is returned

when the data is completely assembled.

Here is an example of a response to the query:

Register Data CRC

Slave Address Function Code Byte Count HI LO HI LO LO HI

21 04 04 FE 00 3E 80

The contents of registers 30036 ... 30037 are FE 00 and 3E 80 hex.

3.3 06 write to a single holding register

Pre-sets a value into a single holding register (4X reference). When broadcast, the functionpre-sets the same register reference in all attached slaves.

3.3.1 Request Frame

The query message specifies the register reference to be pre-set. Registers are addressedstarting at zero; register 1 is addressed as 0.

Here is an example of a request to pre-set register 40010 to 42 15 hex in slavedevice 33:

Register Address Register Data CRC


21 06 00 0A 42 15


The normal response is an echo of the query, returned after the register contents have beenpre-set. Here is an example of a response to the query:

Register Address Register Data CRC


21 06 00 0A 42 15

3.4 16 (10 HEX) write to one or more registers

Pre-sets values into a sequence of holding registers (4x references). When broadcast thefunction pre-sets the same register references in all attached slaves.

3.4.1 Request Frame

The query message specifies the register references to be pre-set. Registers are addressedstarting at zero; register 1 is addressed as 0. Here is an example of a request to pre-set tworegisters starting at 40000 to 41 42 and 43 44 hex (Enter Password ABCD), in slave device33:

SlaveAddress

FunctionCode

StartingRegister

RegisterCount

Byte

Count

Register

DataCRC

HI LO HI LO HI LO HI LO LO HI

21 16 00 00 00 02 04 41 42 4344


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The normal response returns the slave address, function code, starting address, andquantity of registers pre-set. Here is an example of a response to the query shown above.

Slave

Address

Function

Code


HI LO HI LO LO HI

21 16 00 00 00 02

If the password is not correct (L1 or L2 or BP), the response to the query is:

Slave

Address

Function

Code


HI LO HI LO LO HI

21 16 00 00 00 02

3.5 17 (11HEX) report slave id

Returns a description of the type of controller present at the slave address.

3.5.1 Request Frame

Here is an example of a request to report the ID of slave device 33:

CRC

Slave Address Function Code LO HI

21 11


The format of a normal response is shown below:

Slave Address Function Code Byte Count Register Data CRC

HI LO HI LO HI LO LO HI

21 11 06 20 4D 30 32 32 30

3.6 77 (4D HEX) read measurement string

Reads the measurement value as an ASCII string. Broadcast is also supported. See list ofvalue codes in section 4.6.3

3.6.1 Request Frame

The query message specifies the value code of the measurement to be read.

Here is an example of a response to read Total Real Power from slave device 33:

Slave

Address

Function

Code

Value Code CRC

LO HI

21 4D 04


The ASCII string in the response message is packed as data bytes. The quantity of databytes depends on the value code.

Here is an example of the query:

Slave

Address

Function

Code

Byte Count String Data CRC

1. 2. 3. 4. 5. 6. 7. 8. LO HI

21 4D 08 2B 32 31 2E 31 33 35 6B 49 35


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3.6.3 Value Codes

The value codes are described in the following table:

ValueCode DEC

ValueCodeHex

Measurement ValueByteCount

Example String Data

00 00 Energy counter 1 15 "0000004.46kWh"

01 01 Energy counter 2 15 "0000001.24kvarh"

02 02 Energy counter 3 15 "0000005.71kWh"

03 03 Energy counter 4 15 "0000002.86kvarh"

04 04 Total Real Power 8 "+21.135k"

05 05 A Phase Real Power 8 "+7046.3"

06 06 B Phase Real Power 8 "+7037.3"

07 07 C Phase Real Power 8 "+7051.1"

08 08 Total Reactive Power 12 "1208.7 var L"

09 09 A Phase Reactive Power 12 "0400.2 var L"

10 0A B Phase Reactive Power 12 "0406.4 var L"

11 0B C Phase Reactive Power 12 "0400.9 var L"

12 0C Total I 7 "93.671"

13 0D IA 7 "31.227"

14 0E IB 7 "31.222"

15 0F IC 7 "31.222"

16 10 Average V 7 "226.06"

17 11 VA 7 "226.08"

18 12 VB 7 "225.83"

19 13 VC 7 "226.27"

20 14 Total Apparent Power 7 "21.170k"

21 15 A Phase Apparent Power 7 "7057.3"

22 16 B Phase Apparent Power 7 "7049.0"

23 17 C Phase Apparent Power 7 "7062.8"

24 18 Total Power Factor 8 "+0.998 L"25 19 Power Factor A 8 "+0.998 L"

26 1A Power Factor B 8 "+0.998 L"

27 1B Power Factor C 8 "+0.998 L"

28 1C Frequency 7 "46.008"

29 1D Frequency 7 "46.008"

30 1E Frequency 7 "46.008"

31 1F Frequency 7 "46.008"

32 20 Total Power Angle 7 "+003.26"

33 21 Power Angle A 7 "+003.25"

34 22 Power Angle B 7 "+003.30"

35 23 Power Angle C 7 "+003.25"


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ValueCode DEC

ValueCodeHex

Measurement ValueByteCount

Example String Data

36 24 IN 6 "93.67"

37 25 Angle AB 7 "+000.00"

38 26 Angle BC 7 "+000.01"

39 27 Angle CA 7 "-000.01"

40 28 Average Vxy 6 "000.3"

41 29 VAB 6 "000.2"

42 2A VBC 6 "000.24"

43 2B VCA 6 "000.2"

44 2C Dynamic Demand Value 1 13 "Pt=+9.818kW"

45 2D Dynamic Demand Value 2 12 "Qt=6.504kvar"

46 2E Dynamic Demand Value 3 12 "St=12.89kVA"

47 2F Dynamic Demand Value 4 12 "It=56.91 A"

48 30 Max Demand Since Reset 1 13 "Pt=+11.26kW"

49 31 Max Demand Since Reset 2 12 "Qt=14.64kvar"

50 32 Max Demand Since Reset 3 12 "St=18.46kVA"

51 33 Max Demand Since Reset 4 12 "It=81.01 A"

52 34 Time Stamp MD 1 12 "03.SEP 14:11"

53 35 Time Stamp MD 2 12 "03.SEP 14:10"

54 36 Time Stamp MD 3 12 "03.SEP 14:10"

55 37 Time Stamp MD 4 12 "03.SEP 14:12"

3.7 82 (52 HEX) re-read output buffer

This function should be used after the broadcast request. The addressed slave transmits theresponse frame of the previous request.

3.7.1 Request Frame

Here is an example of a request to re-read the output buffer of slave device 33:

CRC

Slave Address Function Code LO HI

21 52


The response to the query depends on the previous function code.


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4. MODBUS ERROR RESPONSES

When a slave detects an error other than a CRC error, a response will be sent to the master.The most significant bit of the function code byte will be set to 1 (i.e. the function code sentfrom the slave will be equal to the function code sent from the master plus 128). Thefollowing byte will be an exception code indicating the type of error that occurred.

The slave will ignore transmissions received from the master with CRC errors.

An example of an illegal request and the corresponding exception response is shown below.The request in this example is to read registers 0201H to 0209H. If these addresses are notsupported in the slave then the following occurs:

Request Message

Starting Register Register Count

Address Function Code HI LO HI LO CRC

01 01 02 01 00 08 6D B4

Exception Response Message

Address Function Code Exception Code CRC

01 81 02 C1 91

4.1 Exception codes

Code Name Meaning

01 ILLEGAL FUNCTION The function code transmitted is notone of the functions supported by theslave.

02 ILLEGAL DATA ADDRESSES The data address received in therequest is not an allowable value forthe slave.Write to password protected registers.

03 ILLEGAL DATA VALUE The value referenced in the data fieldtransmitted by the master is not withinfamily for the selected data address.The register count is greater than 28(functions 03 and 04).

06 SLAVE DEVICE BUSY The slave is engaged in processing along duration program command. Themaster should re-transmit themessage later when the slave is free.


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5. MODBUS REGISTER MAPS

The Modbus register map consists of the following columns:

Code Function codes as described in Section 4.0.

Address 16 bit register address starting from zero.Please Note:

Most Modbus master devices assume that 30001 or 40001 aresubtracted from the defined address for the registers. TheM2x3 and i500 subtract 30000 and 40000, meaning that theaddresses may have to be offset by 1.

Contents Description of parameters assigned to registers.

Data type MODBUS data types T1 etc. are described in section 7.

UNSIGNEDINTEGER

family 0 ... 65535

one 16-bit register

SIGNED INTEGER family 32768 ... 32767one 16-bit register

ASCII Family 32159

16 bit registers (two ASCII codes per register)

BINARY FLAGS Each bit of a 16 bit register can be used as abinary flag

Indicator Each bit of a 16-bit register can be either assigned as flags or filledwith binary data.

Values Definitions of settings, data values and any dependencies that existbetween settings.

Register type Declares whether a register is to be read/write register (setting) or aread register (data).

Min, max step The minimum and maximum numerical family and the incremental stepsize.

Password There is a numerical password that allows save/abort settings and afactory accessible password constructed from the serial number thatallows entry/exit to and from the calibration and configuration settings.


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6. MODBUS DATA FOR M2X3 AND I5MT/MR/MQ

6.1 SYSTEM DATA

Code Address Contents Data Ind Values and Dependencies

04 30001 30018 Model Number Str_16

04 30009 30012 Serial Number Str_8

04 30013 Software Ref 1 T1 Software version

04 30014 Hardware Ref Str_2 Hardware version

30015 Calibration voltage T4 mV

30016 Voltage auto-range T1 1=auto-range

30017 Calibration current T4 mA

30018 Current auto-range T1 1=auto-range

30019 Accuracy class T17 50 = 0.5%20 = 0.2%

30020 MiNet Flag T1 0

30021 Language Pack T1

30022 LCD type T1 0 128x64 yellow green

1128x64 yellow greennegative

2 128x64 red negative

30023 Power supply T1 0 Unknown

1

Universal AC 48-276V:

DC 20 300V

2 57.64v, 50/60Hz

3 63.5v, 50/60Hz

4 100v, 50/60Hz

5 110v, 50/60Hz

6 230v, 50/60Hz

7 400v, 50/60Hz

8 500v, 50/60Hz

9Universal AC 48 77V:

DC 20 100V

10Universal AC 70 276V;

DC 70 300V

30024 COM1: communication type T1 0 No communication

1 RS232

2 RS485

3 RS232 & RS485

4 Ethernet (X-Port)

5 Ethernet & USB

6 Ethernet7 USB

30025 COM2: communication type T1 0 No communication

1 RS232

2 RS485


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30026 30027 Reserved

30028 Memory type T1 0 No memory

1 2Mb flash

2 4Mb flash3 8Mb flash

30029 I/O 1 T1 0 No I/O

1 Unipolar analogue output

2 Bipolar analogue output

3 Jumperless analogue output

4 Pulse output

5 Tariff Input

6 Bistable alarm output

7 Relay alarm output

8 Analogue output 20mA

9 Analogue input

10 Digital input

11 Pulse input

12 S0 output

13 Fast Analogue Output

14Jumperless unipolar Analogoutput

15 Watch dog output

16 Reserved17 RS232

18 RS485

19 Reserved

20 COM2 - Ex

30030 I/O 2

30031 I/O 3

30032 I/O 4


30044 Status Register (M2x3 only) T1 0 Locked

1 Wrong Connection

2 Low Battery

3 Low Supply

4 Clock not Set

30045 30046 Configuration time stamp T10

30047 30048 Calibration time stamp T10

30049 30050 Last upgrade time stamp T10

30051 Digital input 1 voltage range T1 0 230V

1 63 110V

2 48V

30052 Digital input 2 voltage range T1 See Digital input 1




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30055 30057 Ethernet MAC Address T_Hex6

30058 Ethernet Software Reference T1 Ethernet Software Version

30059 30060 Ethernet IP Address T_Hex4 Actual Ethernet IP Address

30061 30097 Reserved location30098 Active communications port T1 1 COM1

2 COM2

30099Modbus max.register read atonce

T1

6.2 MEASUREMENTS


ACTUAL MEASUREMENTS

04 30101 30104 Actual time T_Time

04 30105 30106 Frequency T5

04 30107 30108 U1 T5

04 30109 30110 U2 T5

30111 30112 U3 T5

04 30113 30114 Uavg (phase to neutral) T5

04 30115 j12 (angle between U1 and U2) T17



04 30118 30119 U12 T5

04 30120 30121 U23 T5

04 30122 30123 U31 T5

04 30124 30125 Uavg (phase to phase) T5

04 30126 30127 I1 T5

04 30128 30129 I2 T5

04 30130 30131 I3 T5

0430132 30133

INc T504 30134 30135 INm - reserved T5

04 30136 30137 Iavg T5

04 30138 30139 I T5

30140 30141 Active Power Total (Pt) T6

30142 30143 Active Power Phase L1 (P1) T6



30148 30149 Reactive Power Total (Qt) T6

30150 30151 Reactive Power Phase L1 (Q1) T6




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30156 30157 Apparent Power Total (St) T5

30158 30159 Apparent Power Phase L1 (S1) T5



30164 30165 Power Factor Total (PFt) T7

30166 30167 Power Factor Phase 1 (PF1) T7



30172 Power Angle Total(atan2(Pt,Qt))

T17

30173 1 (angle between U1 and I1) T17



30176 U unbalance T16


30181 Internal Temperature T17

THD HARMONIC DATA

30182 U1 THD% T16

30183 U2 THD% T16

30184 U3 THD% T16

30185 U12 THD% T16

30186 U23 THD% T16

30187 U31 THD% T16

30188 I1 THD% T16

30189 I2 THD% T16

30190 I3 THD% T16


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I/O STATUS

30191 Alarm Status Flags (No.116)

T1 bit-i Alarm i+1

30192 Alarm Status Flags (No.1732)

T1 bit-i Alarm i+17

30193 I/O 1 Value T17

30194 I/O 2 Value T17

30195 I/O 3 Value T17

30196 I/O 4 Value T17


MAXIMUM MEASUREMENTS

30201 30204 Last reset time T_Time

30205 30206 Frequency T5

30207 30208 U1 T5

30209 30210 U2 T5

30211 30212 U3 T5

30213 30214 Reserved: T5

30215 Reserved:12 (angle betweenU1 and U2)

T17

30216 Reserved: 23 (angle betweenU2 and U3)

T17


T17

30218 30219 U12 T5

30220 30221 U23 T5

30222 30223 U31 T5

30224 30225 Reserved: Uavg (phase tophase)

T5

30226 30227 I1 T5

30228 30229 I2 T5

30230 30231 I3 T5

30232 30233 Reserved: INc T5

30234 30235 Reserved: INm T5

30236 30237 Reserved: Iavg T5

30238 30239 Reserved: I T5





30248 30249 Reserved: Reactive Power Total(Qt)

T6

30250 30251 Reserved: Reactive Power Phase T6


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L1 (Q1)

30252 30253 Reserved: Reactive Power PhaseL2 (Q2)

T6

30254 30255 Reserved: Reactive Power Phase

L3 (Q3)

T6





30264 30265 Reserved: Power Factor Total(PFt)

T7

30266 30267 Reserved: Power FactorPhase 1 (PF1)

T7


T7


T7

30272 Reserved: Power Angle Total(atan2(Pt,Qt))

T17

30273 Reserved: 1 (angle betweenU1 and I1)

T17


T17


T17



THD HARMONIC DATA

30282 Reserved: U1 THD% T16






30288 Reserved: I1 THD% T16





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MINIMUM MEASUREMENTS

30301 30304 Last reset time T_Time

30305 30306 Frequency T5

30307 30308 U1 T5

30309 30310 U2 T5

30311 30312 U3 T5

30313 30314 Reserved: Uavg (phase toneutral)

T5

30315 Reserved:12 (angle betweenU1 and U2)

T17


T17


T17

30318 30319 U12 T5

30320 30321 U23 T5

30322 30323 U31 T5

30324 30325 Reserved: Uavg (phase tophase)

T5

30326 30327 I1 T5

30328 30329 I2 T5

30330 30331 I3 T5

30332 30333 Reserved: INc T5

30334 30335 Reserved: INm T5

30336 30337 Reserved: Iavg T5

30338 30339 Reserved: I T5




30346 30347 Active Power Phase L3 (P3) T630348 30349 Reserved: Reactive Power

Total (Qt)T6

30350 30351 Reserved: Reactive PowerPhase L1 (Q1)

T6


T6


T6





30364 30365 Reserved: Power Factor Total T7


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(PFt)


T7


T7


T7

30372 Reserved: Power Angle Total(atan2(Pt,Qt))

T17


T17


T17

30375 Reserved: 3 (angle betweenU3 and I3) T17



THD HARMONIC DATA











ENERGY

30401 Energy Counter 1 Exponent T2




30405 Current Active Tariff T1

30406 30407 Energy Counter 1 T3




30414 30415 Energy Counter 1 Tariff 1 T330416 30417 Energy Counter 2 Tariff 1 T3

30418 30419 Energy Counter 3 Tariff 1 T3



25/88
















30446 30447 Energy Counter 1 Cost T3





DEMAND VALUES

DYNAMIC DEMAND VALUES

30501 Time Into Period (minutes) T130502 30503 I1 T5

30504 30505 I2 T5

30506 30507 I3 T5


30510 30511 Active Power Total (Pt) -(positive)

T6

30512 30513 Active Power Total (Pt) -(negative)

T6

30514 30515 Reactive Power Total (Qt) - L T630516 30517 Reactive Power Total (Qt) - C T6

MAX DEMAND SINCE LAST RESET

30518 30519 I1 T5

30520 30523 Time Stamp T_Time

30524 30525 I2 T5


30530 30531 I3 T5




30542 30543 Active Power Total (Pt) -(positive)

T6


26/88





30548 30549 Active Power Total (Pt) -(negative)

T6

30550 30553 Time Stamp T_Time30554 30555 Reactive Power Total (Qt) - L T6


30560 30561 Reactive Power Total (Qt) - C T6



FLICKERS (M253 & i5MQ only)

30580 Flicker Pst1 T17


27/88




30610 Frequency Variations 1: % /Period

T16

30611 Frequency Variations 1: % /Year

T16

30612 Frequency Variations 2: % /Period

T16

30613 Frequency Variations 2: % /Year

T16

30614 Voltage Unbalances: % /Period

T16

30615 Voltage Unbalances: % / Year T16

30616 Voltage Variations 1 - L1: % /Period

T16

30617 Voltage Variations 1 - L1: % /Year T16


T16

30619 Voltage Variations 1 - L2: % /Year

T16


T16


T16

30622 Voltage Variations 2 - L1: % /Period T16


T16


T16


T16


T16


T16

30628 THD's - L1: % / Period T16

30629 THD's - L1: % / Year T16

30630 THD's - L2: % / Period T16

30631 THD's - L2: % / Year T16

30632 THD's - L3: % / Period T16

30633 THD's - L3: % / Year T16

30634 Harmonics - L1: % / Period T16

30635 Harmonics - L1: % / Year T16





28/88





30640 Short term Flickers - L1: % /Period

T16

30641 Short term Flickers - L1: % /Year T16


T16

30643 Short term Flickers - L2: % /Year

T16


T16

30645 Short term Flickers - L3: % /Year

T16

30646 Long term Flickers - L1: % /Period T16

30647 Long term Flickers - L1: % /Year

T16

30648 Long term Flickers - L2: % /Period

T16

30649 Long term Flickers - L2: % /Year

T16

30650 Long term Flickers - L3: % /Period

T16

30651 Long term Flickers - L3: % /Year T16

30652 Transients - L1: No. / Period T1

30653 Transients - L1: No. / Year T1





30658 Temporary Overvoltages - L1:

No. / Period

T1

30659 Temporary Overvoltages - L1:No. / Year

T1

30660 Temporary Overvoltages - L2:No. / Period

T1


T1

30662 Temporary Overvoltages - L3:No. / Period

T1


T1

30664 Voltage Dips - L1: No. / Period T1

30665 Voltage Dips - L1: No. / Year T1



29/88







30670 Short Interruptions - L1: No. /Period

T1

30671 Short Interruptions - L1: No. /Year

T1


T1


T1


T1


T1

30676 Long Interruptions - L1: No. /Period

T1

30677 Long Interruptions - L1: No. /Year

T1


T1


T1


T1


T1


PREVIOUS PERIOD QUALITY (M253 & i5MQ only)

30701 30781 Last finished period quality See Actual period quality

6.3 NORMALIZED MEASUREMENTS


NORMALIZED ACTUAL MEASUREMENTS

30801 U1 T16

30802 U2 T16

30803 U3 T16

30804 Uavg (phase to neutral) T16

30805 U12 T16

30806 U23 T1630807 U31 T16

30808 Uavg (phase to phase) T16

30809 I1 T16


30/88




30810 I2 T16

30811 I3 T16

30812 I T16

30813 I neutral (calculated) T16

30814 I neutral (measured) T16

30815 Iavg T16

30816 Active Power Phase L1 (P1) T17



30819 Active Power Total (Pt) T17

30820 Reactive Power Phase L1 (Q1) T17



30823 Reactive Power Total (Qt) T17

30824 Apparent Power Phase L1 (S1) T16



30827 Apparent Power Total (St) T16

30828 Power Factor Phase 1 (PF1) T17

30829 Power Factor Phase 2 (PF2) T1730830 Power Factor Phase 3 (PF3) T17

30831 Power Factor Total (PFt) T17

30832 CAP/IND P. F. Phase 1 (PF1) T17



30835 CAP/IND P. F. Total (PFt) T17




30839Power Angle Total(atan2(Pt,Qt))

T17

30840 12 (angle between U1 and U2 T17



30843 Frequency T17

30844 U unbalance T16

30845 I1 THD% T16

30846 I2 THD% T16

30847 I3 THD% T16

30848 U1 THD% T16


31/88




30849 U2 THD% T16

30850 U3 THD% T16

30851 U12 THD% T16

30852 U23 THD% T16

30853 U31 THD% T16

MAX DEMAND SINCE LAST RESET

30854Active Power Total (Pt) -(positive) T16

30855Active Power Total (Pt) -(negative) T16

30856 Reactive Power Total (Qt) - L T16

30857 Reactive Power Total (Qt) - C T16


30859 I1 T16

30860 I2 T16

30861 I3 T16


30862Active Power Total (Pt) -(positive) T16

30863Active Power Total (Pt) -(negative) T16

30864 Reactive Power Total (Qt) - L T16

30865 Reactive Power Total (Qt) - C T16


30867 I1 T16

30868 I2 T16

30869 I3 T16

ENERGY

30870 Energy Counter 1 T17




30874 Energy Counter 1 Cost T17




30878 Total Energy Counter Cost T17

30879 Active Tariff T130880 Internal Temperature T17



32/88




FAST RESPONCE normalised actual measurements

30901 U1 T16

30902 U2 T16

30903 U3 T16

30904 Uavg (phase to neutral) T16

30905 U12 T16

30906 U23 T16

30907 U31 T16

30908 Uavg (phase to phase) T16

30909 I1 T16

30910 I2 T16

30911 I3 T16

30912 I T16

30913 I neutral (calculated) T16

30914 I neutral (measured) T16

30915 Iavg T16




30919 Active Power Total (Pt) T17

30920Reactive Power Phase L1(Q1)

T17


T17


T17

30923 Reactive Power Total (Qt) T17

30924Apparent Power Phase L1(S1)

T16


T16


T16





30931 Power Factor Total (PFt) T17




30935 CAP/IND P. F. Total (PFt) T17


33/88







30939Power Angle Total(atan2(Pt,Qt))

T17

3094012 (angle between U1 andU2)

T17


T17


T17

30943 Frequency T17

30944U unbalance

T1630945 I1 THD% T16

30946 I2 THD% T16

30947 I3 THD% T16

30948 U1 THD% T16

30949 U2 THD% T16

30950 U3 THD% T16

30951 U12 THD% T16

30952 U23 THD% T16

30953 U31 THD% T16


6.4 HARMONIC DATA


PHASE VOLTAGE HARMONIC DATA

U1 Harmonic Data

31001 31002 Base for % calculation T531003 U1 1 Harmonic Abs % T16

31004 U1 1 Harmonic Phase Angle T17

31006 31126 U1 Harmonics from 2 to 62 T17

31127 U1 63 Harmonic Abs % T16


U2 Harmonic Data

31129 31130 Base for % calculation T5






34/88





U3 Harmonic Data







LINE VOLTAGE HARMONIC DATA

U12 Harmonic Data







U23 Harmonic Data



31516 U23 1 Harmonic Phase Angle T1731518 31638 U23 Harmonics from 2 to 62 T17



U31 Harmonic Data







PHASE CURRENT HARMONIC DATA

I1 Harmonic Data


31771 I1 1 Harmonic Abs % T16

31772 I1 1 Harmonic Phase Angle T17

31774 31894 I1 Harmonics from 2 to 62 T17



I2 Harmonic Data



35/88









I3 Harmonic Data








6.5 MEASUREMENTS (IEEE 754)


MEASUREMENTS (IEEE 754)

32484 32485 Uavg (phase to neutral) T_float

32486 32487 Uavg (phase to phase) T_float

32488 32489 I T_float

32490 32491 Active Power Total (Pt) T_float

32492 32493 Reactive Power Total (Qt) T_float

32494 32495 Apparent Power Total (St) T_float

32496 32497 Power Factor Total (PFt) T_float

32498 32499 Frequency T_float

32500 32501 U1 T_float

32502 32503 U2 T_float

32504 32505 U3 T_float32506 32507 Uavg (phase to neutral) T_float

32508 32509 U12 T_float

32510 32511 U23 T_float

32512 32513 U31 T_float

32514 32515 Uavg (phase to phase) T_float

32516 32517 I1 T_float

32518 32519 I2 T_float

32520 32521 I3 T_float

32522 32523 I T_float

32524 32525 I neutral (calculated) T_float

32526 32527 I neutral (measured) T_float


36/88




32528 32529 Iavg T_float

32530 32531 Active Power Phase L1 (P1) T_float



32536 32537 Active Power Total (Pt) T_float

32538 32539 Reactive Power Phase L1 (Q1) T_float



32544 32545 Reactive Power Total (Qt) T_float

32546 32547Apparent Power Phase L1(S1) T_float




32554 32555 Power Factor Phase 1 (PF1) T_float



32560 32561 Power Factor Total (PFt) T_float

32562 32563 CAP/IND P. F. Phase 1 (PF1) T_float



32568 32569 CAP/IND P. F. Total (PFt) T_float

32570 32571 1 (angle between U1 and I1) T_float



32576 32577Power Angle Total(atan2(Pt,Qt)) T_float

32578 3257912 (angle between U1 andU2) T_float



32584 32585 Frequency T_float

32586 32587 U unbalace T_float

32588 32589 I1 THD% T_float

32590 32591 I2 THD% T_float32592 32593 I3 THD% T_float

32594 32595 U1 THD% T_float

32596 32597 U2 THD% T_float


37/88




32598 32599 U3 THD% T_float

32600 32601 U12 THD% T_float

32602 32603 U23 THD% T_float

32604 32605 U31 THD% T_float

MAX DEMAND SINCE LASTRESET

32606 32607Active Power Total (Pt) -(positive) T_float

32608 32609Active Power Total (Pt) -(negative) T_float

32610 32611 Reactive Power Total (Qt) - L T_float

32612 32613 Reactive Power Total (Qt) - C T_float

32614 32615 Apparent Power Total (St) T_float32616 32617 I1 T_float

32618 32619 I2 T_float

32620 32621 I3 T_float


32622 32623Active Power Total (Pt) -(positive) T_float

32624 32625Active Power Total (Pt) -(negative) T_float

32626 32627 Reactive Power Total (Qt) - L T_float32628 32629 Reactive Power Total (Qt) - C T_float


32632 32633 I1 T_float

32634 32635 I2 T_float

32636 32637 I3 T_float

ENERGY

32638 32639 Energy Counter 1 T_float




32646 32647 Energy Counter 1 Cost T_float




32654 32655 Total Energy Counter Cost T_float

32656 32657 Active Tariff T_float

32658 32659 Internal Temperature T_float

ANALOGUE INPUTS


38/88




32660 32661 Analog input 1 T_float






39/88



6.6 PRODUCT SETTINGS

Address Contents Data Ind Values/Dependencies Min Max P.level

SYSTEM COMMANDS

40001 40002 User Password (L1,L2)

T_Str4AZ

Password to attempt user accesslevel upgrade

0

40003 40005 Factory Password(FAC)

T_Str6 AZ Password to attempt factory accesslevel upgrade 0

40006 40007 Level 1 - Userpassword

T_Str4 AZ 1

40008 40009 Level 2 - Userpassword

T_Str4 AZ 2


40012 Operator CommandRegister

T1 1Save Settings

2

2 Abort Settings3 Restart Instrument

4 Restart Ethernet

5 Save Settings and Restart Ethernet

40013 Reset commandregister 1

T1 Bit-0 Reset counter 1 1

Bit-1 Reset counter 2



Bit-4 Reset counter 1 Cost




Bit-8 Reset Minimum/Maximum values

Bit-9 Synchronize MD

Bit-10 Reset last period MD

Bit-11 Reset MD values

40014Reset commandregister 2

T1 Bit-0 Reset alarm output relay 1 1

Bit-1 Reset alarm output relay 2




GENERAL SETTINGS

40101 40120 Description Str_40 2

40121 40140 Location Str_40 2

40141 Password activation Reserved

40142 Password lock time T1 Minutes, 0 = No lock 0 60 2

40143 Conection Mode T1 0 No mode 1 5 2

1 1b - Single Phase2 3b - 3 phase 3 wire balanced

3 4b - 3 phase 4 wire balanced

4 3u - 3 phase 3 wire unbalanced

5 4u - 3 phase 4 wire unbalanced


40/88




40144 CT Secondary T4 mA 2

40145 CT Primary T4 A/10 2

40146 VT Secundary T4 mV 2

40147 VT Primary T4 V/10 240148 Current input range

(%)T16 10000 for 100% 5.00 260.00 2

40149Voltage input range(%)

T16 10000 for 100% 2.50 100.00 2

40150Frequency nominalvalue

T1 Hz 10 1000 2

40151 CT Connection T1 0 Normal 0 1 1

1 Disable wrong connectionchecking

40152 MD Time constant T1 minutes (0=disabled) 0 255 2

40153 MD Number ofsliding windows

T1 0=thermal 0 15 2

40154Starting total currentfor PFt & Pat

T16 2000 for 20mA 0 10000 2

40155Starting current forall powers

T16 200 for 2mA 0 4000 2

40156 Language T1 0 English 0 12 0

1 French

2 German

3 Spanish

4

5 Russian

6 Danish

7 Italian

8 US English

9

10 Polish

11 Portuguese

12

40157 40158 Currency Str_4 2

40159 Temperature unit T1 0 C 0 1 2

1 F

40160 Date format T1 0 DD.MM.YYYY 0 1 1

1 MM/DD/YYYY

40161 40162 Time T9 1

40163 40164 Date T10 1

40165 Reserved T1 Reserved

40166Automatic changeS/W time

T1 0 No 0 1 1

1 Yes

40167

Starting voltage for

SYNC

T1 5000 for 5V 1000 16000

2

40168 Min/Max reset mode T1 0 Manual reset 0 4 2

1 Day reset (00:00)

2 Week reset (Monday, 00:00)


41/88




3 Month reset (First day of the month,00:00)

4 Year reset (January 1st, 00:00)

40169

Harmonics

calculation

T1 0 % of RMS 0 1 2

1 % of 1st Harmonics

40170 Comm. & LCDaverage interval

T1 3 8 periods (0.16s @50Hz) 3 8 2

4 16 periods (0.32s @50Hz)

5 32 periods (0.64s @50Hz)

6 64 periods (1.28s @50Hz) default

7 128 periods (2.56s @50Hz)

8 256 periods (5.12s @50Hz)

40171 LCD Contrast T2 -10 10 2

40172 LCD Back LightIntesnity

T1 0=No Backlight 0 102

40173 LCD Back Light TimeOff

T1 Minutes (0=Always on) 0 602

40174 LCD Demo cyclingperiod

T1 Seconds 1 602

40175LCD Custom screen1 - Line 1

T1 See OutTypes 0 1002



















42/88




COMMUNICATION

40201 Port 1: DeviceAddress (DNP3)

T1 0 65519 2

40202 Port 1: DeviceAddress (Modbus)

T1 1 247 2

40203 Port 1: Baud Rate T1 0 Baud rate 1200 1 7 2

1 Baud rate 2400

2 Baud rate 4800

3 Baud rate 9600

4 Baud rate 19200

5 Baud rate 38400

6 Baud rate 57600

7 Baud rate 115200

40204 Port 1: Stop Bit T1 0 1 Stop bit 0 1 2

1 2 Stop bits

40205 Port 1: Parity T1 0 No parity 0 2 2

1 Odd parity

2 Even parity

40206 Port 1: Data Bits T1 0 8 bits 0 1 2

1 7 bits

40207 Port 1: TCP Port T1 1024 65535 2

4020840227

Port 1: IP Host NameT_Str_40

40228 40229 Port 1: IP Address T_Hex4

40230 40231 Port 1: Subnet Mask T_Hex4

40232 40233Port 1: DefaultRouter

T_Hex4


40251Port 2: DeviceAddress (DNP3)

T1 0 65519 1

40252Port 2: DeviceAddress (Modbus)

T1 1 247 2

40253 Port 2: Baud Rate T1 See PORT 1 1 7 2

40254 Port 2: Stop BitT1

See PORT 1 0 1 2

40255 Port 2: Parity T1 See PORT 1 0 2 2

40256 Port 2: Data Bits T1 See PORT 1 0 0 2


40301 40400 Reserved Port 3 -Port 4

ENERGY

40401 Active Tariff T1 0 Tariff input 0 5 1

1..4 Tariff 1..4

5 Tariff clock

40402 Common EnergyCounter Exponent

T2 -3 42

40403 Common EnergyCost Exponent

T2 -6 32


43/88



40404 Common Tariff PriceExponent

T2 -6 32

40405 Tariff 1: 1kWh Price T1 0 65500 2




40409 Tariff 1: 1kvarh Price T1 0 65500 2




40413 Tariff 1: 1kVAh Price T1 0 65500 2





40420Reactive powercalculation

T10 Standard calculation (Q

2=S

2 P

2)

0 1 2

1 Delayed Current method

40421Energy Counter 1Parameter

T10 No Parameter

0 19 2

1 Active Power

2 Reactive power

3 Apparent Power

5 Active Power Phase 1

6 Reactive power Phase 1

7 Apparent Power Phase 1







16 Pulse input 1 (reg 40402 not used)

17 Pulse input 2 (reg 40402 not used)

18 Pulse input 3 (reg 40402 not used)19 Pulse input 4 (reg 40402 not used)

40422Energy Counter 1Configuration

T1 Bit-0Quadrant I Enabled

0 63 2

Bit-1 Quadrant II Enabled

Bit-2 Quadrant III Enabled

Bit-3 Quadrant IIII Enabled

Bit-4 Absolute Value

Bit-5 Invert Value

40423Energy Counter 1Divider

T1 01

0 4 2

1 10

2 100

3 1000

4 10000


44/88



40424Energy Counter 1Tariff Selector

T1Bit-0

Tariff 1 Enabled0 15

2

Bit-1 Tariff 2 Enabled





T1see Energy Counter 1 Parameter

0 192


T1see Energy Counter 1 Configuration

0 632


T1see Energy Counter 1 Divider

0 42


T1 see Energy Counter 1 TariffSelector

0 152




0 192



0 632



0 42



0 152




0 192



0 632



0 42



0 152


TARIFF CLOCK

40501 Tariff Table 1 DaySelector

T1 Bit-0 Monday 0 1023 2

Bit-1 Tuesday

Bit-2 Wednesday

Bit-3 Thursday

Bit-4 Friday

Bit-5 Saturday

Bit-6 Sunday

Bit-7 Holiday

Bit-8 Hebrew Holiday 1

Bit-9 Hebrew Holiday 2


T1 see Tariff Table 1 Day Selector 0 1023 2





40505 Start date of Season 1 T10A 0.0. for unused season 2




45/88




SEASON 1, TARIFF TABLE 1

40509 Time 1 T9A 24:00 for unused time 2

40510 Tariff Value 1 T1 1 4 2

40511 Time 2 T9A 24:00 for unused time 240512 Tariff Value 2 T1 1 4 2







40517 40524 TARIFF TABLE 2 See TARIFF TABLE 1 2





SEASON 2, TARIFF TABLE 1..4

40541 40572 SEASON 2,

TABLE 14

See SEASON 1

2


40573 40604 SEASON 3,

TABLE 14

See SEASON 1

2


40605 40636 SEASON 4,

TABLE 14

See SEASON 1

2

HOLIDAY DAY TABLE

40637 Holiday Date 1 T10A 0.0. for unused date 2




















46/88





INPUTS / OUTPUTS

PULSE OUTPUTS

40701 Pulse Output 1Energy Counter T1 0 Alarm output 0 5 2

1 Counter 1

2 Counter 2

3 Counter 3

4 Counter 4

5 Tariff Clock

40702Pulse Output 1 No.Of pulses

T1 1 65535 2

40703Pulse Output 1Energy unit

T1 * 10^(Common Energy CounterExponent)

1 65535 2

40704Pulse Output 1 Pulselength

T1 ms 2 1000 2

40705Pulse Output 1 TariffSelector

T1 Bit-0 Tariff 1 enabled 0 15 2

Bit-1 Tariff 2 enabled



40706Pulse Output 2Energy Counter T1

0 5 2


T1 1 65535 2



1 65535 2

40709Pulse Output 2 Pulselength T1 ms

2 1000 2


T1 0 15 2


0 5 2


T1 1 65535 2



1 65535 2


2 1000 2


T1 0 15 2


0 5 2


T1 1 65535 2



1 65535 2


2 1000 2


T1 0 15 2

ALARM OUTPUT, OUTPUT 1

40721Enabled Alarmgroups

T1 Bit-0 Alarm group 1 enabled 0 15 2


47/88



Bit-1 Alarm group 2 enabled



40722 Output signal T1 0 Normal 0 8 2

1 Permanent

2 Pulsed

3 Always ON

4 Always OFF

5 Normal inverse

6 Permanent Inverse

7 Pulse Inverse

8 Start

40723 Output pulse length T1 Seconds 1 999 2


40724 40726 ALARM OUTPUT 2 See ALARM OUTPUT 1 2






ANALOGUE OUTPUT, OUTPUT 1


40803 Output 1 Type T1 0 1 mA 0 5 2

1 5 mA

2 10 mA

3 20 mA (Constant for M2x3)

4 1 V

5 10 V

40804 Output 1 Parameter T1 See OutTypes 0 110 2

40805Output 1 FunctionType T1

0Linear

0 1 2

1 Quadratic

40806

Output 1 Number of

Breakpoints T1 0 6

2

40807Output 1 Lower XPoint (X0) T17

% of parameter value-300 300

2

40808Output 1 Lower YPoint (Y0) T17

% of output type-300 300

2

40809Output 1 XBreakpoint 1 (X1) T17


2

40810Output 1 YBreakpoint 1 (Y1) T17


2



2

40812

Output 1 Y

Breakpoint 2 (Y2) T17

% of output type

-300 300

2



2



2


48/88





2



2



2



2



2



2

40821Output 1 Averageinterval (i5xx only) T1 0 1 period (0.02s@ 50Hz) default 0 8 2

1 2 period (0.04s@ 50Hz)

2 4 period (0.08s@ 50Hz)

3 8 period (0.16s@ 50Hz)

4 16 period (0.32s@ 50Hz)

5 32 period (0.64s@ 50Hz)

6 64 period (1.28s@ 50Hz)

7 128 period (2.56s@ 50Hz)

8 256 period (05.12s@ 50Hz)



40824 40842 ANALOG OUTPUT 2 See ANALOG OUTPUT 1 2








ANALOGUE INPUTs

40901 Input 1 Serial number T1 0 0 65535 r.o.

40902 Input 1 Type T1 0 Unknown 0 3 r.o.

1 DC Current 20mA

2 DC Voltage 10V

3 Resistance / Temperature

40903Input 1 ZeroCalibration point(Type 3) T17 wire resistance (Ohm) -25 25 2

40904 Input 1 Function T1 Input type 1 (DC Current 20mA) 0 7 2

0 DC Curent 20mA

1 DC Curent 2mA

Input type 2 (DC Voltage 10V)

0 DC Voltage 10V

1 DC Voltage 1V

Input type 3 (Resistance /Temperature)

0 Resistance 2 Kohm (2 wire)


49/88



1 Resistance 200 ohm (2 wire)

2 Resistance 2 Kohm (3 wire)

3 Resistance 200 ohm (3 wire)

4 Pt 1000 (2 wire)

5 Pt 100 (2 wire)

6 Pt 1000 (3 wire)

7 Pt 100 (3 wire)

40905 40906 Input 1 Unit Str_4 2

40907 Input 1 Exponent T2 -12 12 2

40908 Input 1 Zero Point T17 value at 0% input -300 300 2

40909 Input 1 End Point T17 value at 100% input -300 300 2


40917 40932 Input 2 See Input 1




ALARMS

41001Alarm Enable Flags116

T1 Bit-iEnable Alarm i

2

41002Alarm Enable Flags1732

T1 Bit-iEnable Alarm i

2

ALARM GROUP 1 (1..8)

41003Thermal function timeconstant

T1minutes

1 255 2

41004 Compare time delay T1 seconds 0 900 2

41005Hysteresis

T16% of compare value, if 0 then % ofnominal value

0 1000 2


ALARM 1

41008 Alarm 1 parameter T1 See OutTypes 0 1023 2

41009 Alarm 1 function T1 Bit-1 Reserved: Store into memory (all) 0 255 2

Bit-2 Store into memory (1 per minute)

Bit-3 Activate LED

Bit-4 Activate Alarm Output

Bit-5 Activate Beep Output

Bit-6 Alarm Condition > (< if 0)

Bit-7 Use Thermal function

41010Alarm 1 comparevalue

T17 % of parameter value -300 300 2

ALARM 2

41011 41013 ALARM 2 See ALARM 1 2

ALARM 3

41014 41016 ALARM 3 See ALARM 1 2

ALARM 4

41017 41019 ALARM 4 See ALARM 1 2

ALARM 5

41020 41022 ALARM 5 See ALARM 1 2

ALARM 6


50/88



41023 41025 ALARM 6 See ALARM 1 2

ALARM 7

41026 41028 ALARM 7 See ALARM 1 2

ALARM 8

41029 41031 ALARM 8 See ALARM 1 2


41032 41060

ALARM GROUP 2

(No. 916) See ALARM GROUP 1 2


41061 41089

ALARM GROUP 3

(No. 1724) See ALARM GROUP 1 2


41090 41118

ALARM GROUP 4

(No. 2532) See ALARM GROUP 1 241119 41998 Reserved

MEMORY

41999 42500 Memory Settings

POWER SUPPLY QUALITY (M253 & i5MQ only)

42501 Monitoring mode T1 0 No mode 0 1 2

1 EN50160

42502 Energetic system T1 0 Low voltage 0 1

1 Medium voltage

2 Low voltage (Islanded system)

3 Medium voltage (Islanded system)

42503Nominal SupplyVoltage

T16 % of VT Primary 5.00 120.00 2

42504Nominal PowerFrequency T1 0 50 Hz 0 1 2

1 60 Hz

42505 Monitoring period T1 Weeks 1 10 2

42506 Monitoring start day T1 0 Monday 0 6 2

1 Tuesday

2 Wednesday

3 Thursday

4 Friday

5 Saturday

6 Sunday

42507 Voltage Hysteresis T16 %o of Nominal Supply Voltage 0.00 5.00 2


FREQUENCY VARIATIONS

42510 Average interval T1 0 10 sec

42511

Frequency variation 1

Upper Limit %

T16 0.01 25.00 2

42512Frequency variation 1Lower Limit %

T16 0.01 25.00 2

42513Frequency variation 1Required Quality

T16 75.00 100.00 2


51/88



42514Frequency variation 1Period T1 0 No monitoring

0 3 2

1 Info only

2 Monitoring time

3 Year


42516 Frequency variation 2Upper Limit %

T16 0.01 25.00 2

42517 Frequency variation 2Lower Limit %

T16 0.01 25.00 2

42518 Frequency variation 2Required Quality

T16 75.00 100.00 2

42519 Frequency variation 2Period

T1 See Frequency variation 1 Period 0 3 2


VOLTAGE VARIATIONS

42530 Average interval T1 2 10 min

42531 Voltage variation 1Upper Limit %

T16 0.01 25.00 2

42532 Voltage variation 1Lower Limit %

T16 0.01 25.00 2

42533 Voltage variation 1Required Quality

T16 75.00 100.00 2

42534 Voltage variation 1Period



VOLTAGE VARIATIONS

42536 Voltage variation 2Upper Limit %

T16 0.01 25.00 2

42537 Voltage variation 2Lower Limit %

T16 0.01 25.00 2

42538 Voltage variation 2Required Quality

T16 75.00 100.00 2

42539 Voltage variation 2Period



42541 Voltage AsymmetryLimit %

T16 0.01 25.00 2

42542 Symmetry RequiredQuality

T16 75.00 100.00 2

42543 Symmetry Period T1 See Frequency variation 1 Period 0 3 2


VOLTAGE INTERRUPTIONS

42551 Voltage Dip Limit % T16 50.00 99.00 2

42552 Allowed No. ofVoltage Dips

T1 0 10000 2

42553 Voltage Dips Period T1 See Frequency variation 1 Period 0 3 2

42554 Interruption Limit % T16 1.00 25.00 2

42555 Short Interruption

time

T1 Seconds 1 300 2

42556 Allowed No. of ShortInterruptions

T1 0 10000 2

42557 Short InterruptionsPeriod



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42558 Allowed No. of LongInterruptions

T1 0 10000 2

42559 Long InterruptionsPeriod



TRANSIENTS42561 Transient Limit % T16 1.0 10.00 2

42562 Transient Rate of rice T16 5.00 600.00 2

42563 Allowed No. ofTransients

T1 0 10000 2

42564 Transients Period T1 See Frequency variation 1 Period 0 3 2


OVERVOLTAGES AND FLICKERS

42567 Average interval(Flicker)

T1 2 10 min

42568 Short term Pst FlickerLimit % T16 0.01 25.00 2

42569 Flicker Pst RequiredQuality

T16 75.00 100.00 2

42570 Flicker Pst Period T1 See Frequency variation 1 Period 0 3 2

42571 Average interval(Flicker)

T1 4 2 hour

42572 Long term Plt FlickerLimit %

T16 0.01 25.00 2

42573 Flicker Plt RequiredQuality

T16 75.00 100.00 2

42574 Flicker Plt Period T1 See Frequency variation 1 Period 0 3 2

42575 TemporaryOvervoltage Limit %

T16 101.00 150.00 2

42576 Allowed No. ofOvervoltages

T1 0 10000 2

42577 Overvoltage Period T1 See Frequency variation 1 Period 0 3 2


HARMONICS & THD

42581 Average interval T1 2 10 min

42582 THD Limit % T16 0.01 25.00 2

42583THD RequiredQuality

T1675.00 100.00 2

42584 THD Period T1 See Frequency variation 1 Period 0 3 2

42585 Harmonics RequiredQuality

T16 75 100 2

42586 Harmonics Period T1 See Frequency variation 1 Period 0 3 2

42587 2. Harmonic Limit % T16 0.01 25.00 2

42588 3. Harmonic Limit % T16 0.01 25.00 2

42589 4. Harmonic Limit % T16 0.01 25.00 2

42590 5. Harmonic Limit % T16 0.01 25.00 2

42591 6. Harmonics Limit % T16 0.01 25.00 2

42592 7. Harmonic Limit % T16 0.01 25.00 242593 9. Harmonic Limit % T16 0.01 25.00 2

42594 11. Harmonic Limit % T16 0.01 25.00 2

42595 13. Harmonic Limit % T16 0.01 25.00 2

42596 15. Harmonic Limit % T16 0.01 25.00 2


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42597 17. Harmonic Limit % T16 0.01 25.00 2

42598 19. Harmonic Limit % T16 0.01 25.00 2

42599 21. Harmonic Limit % T16 0.01 25.00 2

42600 23. Harmonic Limit % T16 0.01 25.00 2

42601 25. Harmonic Limit % T16 0.01 25.00 2


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Values/Dependencies Min Max Step Pass

M233 0

Software version 208 0

(=6 if incorrect divider @40025)(1)

-6 9 1 0

(=6 if incorrect divider @40026)(1) -6 9 1 0

(=6 if incorrect divider @40027)(1) -6 9 1 0

(=6 if incorrect divider @40028)(1)

-6 9 1 0

Total export active energy (default) -99999999 899999999 1 0

Total import reactive energy (default) -99999999 899999999 1 0

Pulse output 1 -99999999 899999999 1 0

Pulse output 2 -99999999 899999999 1 0

W 0

W 0

W 0

W 0

var L(if > 0); var C (if < 0) 0

var L(if > 0); var C (if < 0) 0

var L(if > 0); var C (if < 0) 0

var L(if > 0); var C (if < 0) 0

A 0

A 0

A 0

A 0V 0

V 0

V 0

V 0

VA 0

VA 0

VA 0

VA 0

mHz 00.000 65.535 0.001 Hz 0

mHz 00.000 65.535 0.001 Hz 0

mHz 00.000 65.535 0.001 Hz 0

mHz 00.000 65.535 0.001 Hz 0

0.01 deg -180.00 +179.99 0.01 deg 0

0.01 deg -180.00 +179.99 0.01 deg 0

0.01 deg -180.00 +179.99 0.01 deg 0

0.01 deg -180.00 +179.99 0.01 deg 0

A 0

0.01 deg -180.00 +179.99 0.01 deg 0

0.01 deg -180.00 +179.99 0.01 deg 0

0.01 deg -180.00 +179.99 0.01 deg 0

V 0


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V 0

V 0

V 0

Total active power 0

Total absolute reactive power 0

Total apparent power 0

Total I 0

Total active power 0

Total absolute reactive power 0

Total apparent power 0

Total I 0

0.01 % 0.00 400.00 0.01 % 00.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

0.01 % 0.00 400.00 0.01 % 0

Reset Counter 1 1

Reset Counter 1

Reset pulse output Counter 1

Reset pulse output Counter 2

Synchronise MD

Reset last period MD

Reset MD Values

1 V 0

10 A/10 = 1 A 50 A/10 = 5 A 0.1 V 0

2300 for 230 V 0.1 V 2

Unsigned integer value 1 15999 1

Unsigned exponent 0 3 1

10 775 1 V, 5 V 2

1 4000 1 2

Single phase 2

3 phase 3 wire balanced

3 phase 4 wire balanced

3 phase 3 wire unbalanced

3 phase 4 wire unbalanced1200 baud 2

2400 baud

4800 baud


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9600 baud

19200 baud

38400 baud

57600 baud115200 baud

1 => 2 stop bits; 0 => 1 stop bit

1 => Odd parity; 0 => Even parity

1 => Parity; 0 => No parity

1 => 7 bits; 0 => 8 bits (read only)

> 10 ms response time

Disable 2

Time constant (window period;interval of sub-period)

Thermal function

Fixed window

Sliding window; # of periods

Enable quadrant 1 2

Enable quadrant 2

Enable quadrant 3

Enable quadrant 4

Absolute value

Inverted value

1 => Reactive energy; 0 => Activeenergy

Enable quadrant 1

Enable quadrant 2

Enable quadrant 3

Enable quadrant 4

Absolute value

Inverted value

1 => Reactive energy; 0 => Activeenergy

Same as Counter 2 mode 2

Same as Counter 1 mode

1, 10, 100, 1000, 10000(1)

2

1, 10, 100, 1000, 10000(1)

2

1, 2, 5, 10, 20, 50, , 50000(1)

2

1, 2, 5, 10, 20, 50, , 50000(1)

2

320 for 0.2% 3-128 127 1 3

I1, family HI 3

I2, family HI


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I3, family HI

I1, family LO

I2, family LO

I3, family LO

U1

U2

U3

Power angle phase L1, family HI



Power angle phase L1, family LO

Power angle phase L2, family LOPower angle phase L3, family LO

Calibrate voltage inputs 3

Calibrate current inputs

Calibrate phase angles

English 2

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Danish

Only 0 can be written 0 3 1 0

Counter 1 must be halted -99999999 899999999 1 2

Counter 2 must be

m2x3c i500c en m c manual gb

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