PM130 PLUS. Коммуникационный протокол Modbus. Справочное руководство (англ.)
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Series PM130 PLUS Powermeters
Modbus Communications Protocol
Reference Guide
BG0427 Rev. A1
Every effort has been made to ensure that the material herein is complete and accurate.
However, the manufacturer is not responsible for any mistakes in printing or faulty instructions contained in this book. Notification of any errors or misprints will be received with appreciation.
For further information regarding a particular installation, operation or maintenance of equipment, contact the manufacturer or your local representative or distributor.
Modbus is a trademark of Schneider Electric.
2
Table of Contents
2 MODBUS PROTOCOL IMPLEMENTATION......................................................8
..............................................................................................9
...............................................................................................11
..................................................................................................13
...............................16
3
Summary Energy Accumulated Demands
....................................................................................... 23
Summary Energy Sliding Window Demands
.................................................................................... 24
TOU Maximum Demand Register #1
............................................................................................... 24
TOU Maximum Demand Register #3
............................................................................................... 24
............................................26
Fundamental (H01) Phase Values
Summary Energy Accumulated Demands
....................................................................................... 34
Summary Energy Sliding Window Demands
.................................................................................... 34
TOU Maximum Demand Register #1
............................................................................................... 34
4
TOU Maximum Demand Register #4
............................................................................................... 34
......................................................................................37
TOU Maximum Demand Register #2
............................................................................................... 39
TOU Maximum Demand Register #4
............................................................................................... 40
............................................................................41
.............................................................................51
5
6
1 General
This document specifies a subset of the Modbus serial communications protocol used to transfer data between a master computer station and the PM130. The document provides the complete information necessary to develop third-party communications software capable of communication with the Series
PM130 instruments. Additional information concerning operating the device, configuring the communication parameters, and communication connections may be found in the "Series PM130
PLUS Powermeters, Installation and Operation Manual".
The document is applicable to the PM130P and PM130EH devices.
IMPORTANT
1. In 3-wire connection schemes, the unbalanced current and phase readings for power factor, active power, and reactive power will be zeros, because they have no meaning. Only the total three-phase power values are provided.
2. Most of the advanced features are configured using multiple setup parameters that can be accessed in a number of contiguous registers. When writing the setup registers, it is recommended to write all the registers at once using a single request, or to clear (zero) the setup before writing into separate registers.
Designations used in the guide:
EH - available in the PM130EH
7
2 Modbus Protocol Implementation
For detailed information about Modbus protocol, Modbus message framing and error checking, refer to the "Modicon Modbus Protocol Reference Guide". It can be downloaded from the www.modbus.org
Website. The following paragraphs outline some issues concerning the implementation of the Modbus protocol in the PM130.
2.1 Transmission Modes
The PM130 can be set up to communicate on a Modbus network using RTU transmission mode. Refer to the "Series PM130 PLUS Powermeters, Installation and Operation Manual" on how to select the transmission mode in your meter.
2.2 Address Field
The address field contains a user assigned address of the instrument (1-247) on a Modbus network.
Broadcast mode using address 0 is not supported.
2.3 Function Field
The Modbus functions implemented in the PM130 are shown in Table 2-1. Function 04 can be used in the same context as function 03.
Table 2-2 Modbus Function Codes
Code (decimal)
03
04
06
16
08
1
Meaning in Modbus
Read holding registers
Read input registers
Preset single register
Preset multiple registers
Loop-back test
Action
Read multiple registers
Read multiple registers
Write single register
Write multiple registers
Communications test
1
The PM130 supports only diagnostic code 0 - return query data.
2.4 Exception Responses
The instrument sends an exception response when an error is detected in the received message. To indicate that the response is notification of an error, the high order bit of the function code is set to 1.
Implemented exception response codes:
01 - Illegal function
02 - Illegal data address
03 - Illegal data value
04 - Device failure
When the character framing, parity, or redundancy check detects a communication error, processing of the master's request stops. The instrument will not act on or respond to the message.
2.5 Transaction Timing
The PM130 response time to master requests is indicated in Table 2-2.
Table 2-2 Response Time
Baud Rate, bps Response Time, ms
9600 13 15 13
19200 11 12 11
57600 9 10 9
115200 9 10 9
8
2.6 Modbus Register Addresses
The PM130 Modbus registers are numbered in the range of 0 to 65535. From the Modbus applications, the PM130 Modbus registers can be accessed by simulating holding registers of the
Modicon 584, 884 or 984 Programmable Controller, using a 5-digit “4XXXX” or 6-digit “4XXXXX” addressing scheme. To map the PM130 register address to the range of the Modbus holding registers, add a value of 40001 to the PM130 register address. When a register address exceeds 9999, use a 6-digit addressing scheme by adding 400001 to the PM130 register address.
2.7 Data Formats
The PM130 uses four data formats to pass data between a master application and the instrument: 16bit short integer, 32-bit long integer, 32-bit floating point and 32-bit modulo-10000 formats. Binary values and counters are always transmitted in 32-bit registers, while analog values can be read both in
32-bit and in 16-bit scaled registers.
32-bit analog and energy registers and counters can be read either in long integer or in single precision floating point format. The register type can be selected in the meter separately for analog registers, binary counters and energy registers via Modbus register 246 (see Section 3.1, Modbus Setup
Registers). Refer to the "PM130 PLUS Powermeters, Installation and Operation Manual, Device
Options Setup" for information on how to setup the type of 32-bit registers in your meter.
Analog registers 256 through 308 and 6656 through 10935 contain scaled 16-bit data.
2.7.1 16-bit Scaled Integer Format
16-bit scaled analog data is transmitted in a single 16-bit Modbus register being scaled to the range of 0 to 9999. To get a true reading, a reverse conversion should be done using the following formula:
Y =
X × ( HI − LO )
9999
+ LO where:
Y - True reading in engineering units
X - Raw input data in the range of 0 to 9999
LO and HI - Data low and high scales in engineering units
The engineering scales are indicated for every scaled 16-bit register. Refer to Section 4 “Data Scales and Units” for applicable data scales and measurement units. The default voltage scale in the device is
144V (120V+20%). It can be changed through register 242 (see Section 3.1, Device Data Scales), or via the supplemental PAS software. The recommended voltage scale is 120V+20% = 144V for using with external PT’s, and 690V+20% = 828V for a direct connection to power line.
CONVERSION EXAMPLES
1. Voltage readings
a) Assume device settings (direct wiring): PT ratio = 1; Voltage scale = 828V (690V + 20%).
Voltage engineering scales (see Section 4):
HI_ENG = Vmax = 828.0 × PT ratio = 828.0 × 1 = 828.0V
LO_ENG = 0V
If the raw data reading is 1449 then the voltage reading in engineering units will be as follows:
Volts reading = 1449
× (828.0 - 0)/(9999 - 0) + 0 = 120.0V b) Assume device settings (wiring via PT): PT ratio = 14,400V : 120V = 120; Voltage scale = 144V.
Voltage engineering scales (see Section 4):
HI_ENG = Vmax = 144.0 × PT ratio = 144 × 120 = 17,280V
LO_ENG = 0V
If the raw data reading is 8314 then the voltage reading in engineering units will be as follows:
9
Volts reading = 8314 × (17,280 - 0)/9999 + 0 = 14,368V
2. Current readings
Assume device settings: CT primary current = 200A.
Current engineering scales (see Section 4):
HI_ENG = Imax = CT primary current × 2 = 200.00 × 2 = 400.00A
LO_ENG = 0A
If the raw data reading is 250 then the current reading in engineering units will be as follows:
Amps reading = 250 × (400.00 - 0)/(9999 - 0) + 0 = 10.00A
3. Power readings
a) Assume device settings (direct wiring): Wiring 4LL3; PT = 1; CT primary current = 200A; Voltage scale = 828V.
Active Power engineering scales (see Section 4):
HI_ENG = Pmax = Vmax × Imax × 2 = (828.0 × 1) × (200.00 × 2) × 2 = 662,400W = 662.400kW
LO_ENG = -Pmax = -662.400kW
If the raw data reading is 5500 then the power reading in engineering units will be as follows:
Watts reading = 5500
× (662.400 - (-662.400))/(9999 - 0) + (-662.400) = 66.313kW
If the raw data reading is 500 then the power reading in engineering units will be as follows:
Watts reading = 500 × (662.400 - (-662.400))/(9999 - 0) + (-662.400) = -596.153kW b) Assume device settings (wiring via PT): Wiring 4LN3; PT = 120; CT primary current = 200A.
Active Power engineering scales (see Section 4):
HI_ENG = Pmax = Vmax × Imax × 3 = (828 × 120) × (200.00 × 2) × 3/1000 = 119,232kW
LO_ENG = -Pmax = -119,232kW
If the raw data reading is 5500 then the power reading in engineering units will be as follows:
Watts reading = 5500
× (119,232 - (-119,232))/(9999 - 0) + (-119,232) = 11,936kW
If the raw data reading is 500 then the power reading in engineering units will be as follows:
Watts reading = 500 × (119,232 - (-119,232))/(9999 - 0) + (-119,232) = -107,307kW
4. Power Factor readings
Power factor engineering scales (see Section 3.3):
HI_ENG = 1.000.
LO_ENG = -1.000.
If the raw data reading is 8900 then the power factor in engineering units will be as follows:
Power factor reading = 8900 × (1.000 - (-1.000))/(9999 - 0) + (-1.000) = 0.78
2.7.2 32-bit Long Integer Format
32-bit long integer data is transmitted in two adjacent 16-bit Modbus registers as unsigned (UINT32) or signed (INT32) whole numbers. The first register contains the low-order word (lower 16 bits) and the second register contains the high order word (higher 16 bits). The low-order word always starts at an even Modbus address. The value range for unsigned data is 0 to 4,294,967,295; for signed data the range is -2,147,483,648 to 2,147,483,647.
If your Modbus driver does not support a 32-bit long integer format, you can read the two 16-bit registers separately, and then convert them into a 32-bit value as follows (using C notation):
32-bit value = (signed short)high_order_register × 65536L + (unsigned short)low_order_register
10
Examples
1. Unsigned 32-bit Values
If you read unsigned Voltage V1 of 69,000V from registers 13952-13953, then the register readings will be as follows:
(13952) = 3464
(13953) = 1
The 32-bit value is (1 x 65536 + 3464) = 69000V.
2. Signed 32-bit Values
If you read signed kW of -789kW from registers 14336-14337, then the register readings will be:
(14336) = 64747 (unsigned)
(14337) = 65535 (unsigned) or -1(signed value).
To take the high order register as a signed value, compare it with 32767. If the value is less or equal to 32767, use it as is.
If it is greater than 32767, then this is a negative number in a two's complement code (like in our example) - just subtract it from 65536 to get the original negative value.
The 32-bit reading is (-1 x 65536 + 64747) = -789kW.
Fractional 32-bit data is transmitted using a decimal pre-multiplier to pass fractional numbers in an integer format. Fractional numbers are pre-multiplied by 10 to the power N, where N is the number of digits in the fractional part. For example, the frequency reading of 50.01 Hz is transmitted as 5001, having been pre-multiplied by 100. Whenever a data register contains a fractional number, the register measurement unit is given with a multiplier ×0.1, ×0.01 or ×0.001, showing the weight of the least significant decimal digit. To get an actual fractional number with specified precision, multiply the register value by the given multiplier. To write a fractional number into the register, divide the number by the given multiplier.
2.7.3 32-bit Floating Point Format
32-bit analog registers, energy registers and binary counters, and 32-bit Min/Max registers (see Sections
3.3-3.5) can be read in IEEE single precision floating point format in two adjacent 16-bit Modbus registers, the low order register first.
The low-order register always starts at an even Modbus address.
2.7.4 32-bit Modulo-10000 Format
Energy counters 287-294 and 301-302 are read in two contiguous 16-bit registers in a modulo-10000 format. The first (low order) register contains the value mod 10000, and the second (high order) register contains the value/10000. To get the true energy reading, the high order register value should be multiplied by 10,000 and added to the low order register.
2.8 User Assignable Registers
The PM130 provides 120 user assignable registers in the address range of 0 to 119. You can re-map any register available in the meter to any assignable register so that Modbus registers that reside at different locations may be simply accessed using a single request by re-mapping them to adjacent addresses. Refer to Configuring Modbus in the PM130 PLUS Installation and Operation Manual for information on how to configure the assignable registers via PAS.
The actual addresses of the assignable registers, which are accessed via addresses 0 through 119, are specified in the register map (registers 120 through 239), where register 120 contains the actual address of the register accessed via register 0, register 121 contains the actual address of the register accessed via register 1, and so on. The assignable registers and the map registers themselves may not be remapped.
Initially these registers are reserved and none of them points to an actual register address. To build your own register map, write to map registers 120 to 239 the actual addresses you want to read from or write to via the assignable area (registers 0 to 119). 32-bit long registers should always be aligned at
11
even addresses. For example, if you want to read registers 7136 (1-second V1 voltage, scaled short integer) and 14720-14721 (kWh Import, long integer) via registers 0-2, do the following:
- write 14720 to register 120
- write 14721 to register 121
- write 7136 to register 122
Reading from registers 0-2 will return the kWh reading in registers 0 (low 16 bits) and 1 (high 16 bits), and the voltage reading in register 2.
2.9 Password Protection
The PM130 has a password protection option allowing you to protect your setups, cumulative registers and logs from being changed or cleared through communications. You can disable or enable password protection through communications or via the front display. For details, refer to your instrument
Installation and Operation Manual. When password protection is enabled, the user password you set in your instrument should be written into the device authorization register (2575) before another write request is issued. If the correct password is not supplied while password protection is enabled, the instrument will respond to all write requests with the exception code 01 (illegal operation). It is recommended to clear the password register after you have completed your changes in order to activate password protection.
12
3 Modbus Register Map
3.1 Modbus Setup Registers
Assignable Modbus Registers
0-119
+0
Register 0 contents
+1
Register 1 contents
+119
...
Register 119 contents
Assignable Registers Map
120-239
+0
Mapped register 0 address
+1
Mapped register 1 address
+119
Mapped register 119 address
Modbus Conversion Scales
240
Low raw scale
241
High raw scale
Device Data Scales
242
243
Voltage scale, secondary volts
Current scale, secondary amps
244-245
Reserved
32-bit Register Type
246
Type of 32-bit registers
Options/Range Units Notes
10-100
Bits 0-1 - analog values:
0 = 32-bit integer
1 = 32-bit floating point
Bits 2-3 - binary counters:
0 = 32-bit integer
1 = 32-bit floating point
Bit 4-5 - energy counters:
0 = 32-bit integer
1 = 32-bit floating point
×0.1A UINT16 R/W ×CT secondary
R/W 0
13
3.2 16-bit Scaled Analog Registers and Energy Counters - Basic Register Set
256-308
+8 0x1108
+15 0x110F
+16 0x1110
+17 0x1111 kW L3
Power factor L1
Power factor L2
Power factor L3
+22 0x1501 In (neutral) Current
+23 0x1502 Frequency
+24 0x3709
+25 0x160F
Maximum kW import sliding window demand kW import accumulated demand
+26 0x370B
+27 0x1611
+28 0x3703
+29 0x3704
Maximum kVA sliding window demand kVA accumulated demand
I1 Maximum ampere demand
I2 Maximum ampere demand
+30 0x3705
+31
+32
+33
+34
+35
+36
+37
I3 Maximum ampere demand kWh import (low) kWh import (high) kWh export (low) kWh export (high)
+kvarh net (low)
+kvarh net (high)
-kvarh net (low)
Low and High Scales
2
Units
2
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-1.000-1.000
-1.000-1.000
-1.000-1.000
-1.000-1.000
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
U1
U1
U1
U2
U2
U2
U3
U3
U3
U3
U3
U3
U3
U3
U3
0.001
0.001
UINT16 R
1
UINT16 R
UINT16 R
1
1
UINT16 R
UINT16 R
UINT16 R
INT16 R
INT16 R
INT16 R
INT16
INT16
INT16
R
R
R
UINT16 R
UINT16 R
UINT16 R
INT16
INT16
R
R
0.001 INT16 R
0.001 INT16 R
U3
U3
U3
INT16
INT16
R
R
UINT16 R
0-Imax
45.00-65.00
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
0-Imax
0-Imax
U2 UINT16 R
0.01Hz UINT16 R
U3
U3
U3
U3
U2
U2
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
0-Imax
0-9999
0-9999
0-9999
0-9999
0-9999
0-9999
0-9999
U2
1kWh
UINT16
UINT16
R
R 5
×10MWh UINT16 R 5
1kWh UINT16 R
5
×10MWh UINT16 R 5
1kvarh UINT16 R 3, 5
×10Mvarh UINT16 R 3, 5
1kvarh UINT16 R 4, 5
14
+38
+39 0x1112
+40 0x1113
+41 0x1114
+42 0x1115
+43 0x1116
-kvarh net (high)
V1/V12 Voltage THD
V2/V23 Voltage THD
V3/V31 Voltage THD
I1 Current THD
I2 Current THD
+44 0x1117
+45
+46
+47 0x1609
+48 0x160B
I3 Current THD kVAh (low) kVAh (high)
Present kW import sliding window demand
Present kVA sliding window demand
+49 0x1615
+50 0x111B
PF (import) at Max. kVA sliding window demand
I1 Current TDD
+51 0x111C I2 Current TDD
+52 0x111D I3 Current TDD
Low and High Scales
2
Units
2
0-9999
0-999.9
×10Mvarh UINT16 R 4, 5
0.1% UINT16 R 1 3-sec value
0-999.9
0-999.9
0-999.9
0-999.9
0-999.9
0-9999
0-9999
-Pmax-Pmax
-Pmax-Pmax
0-1.000
0-100.0
0-100.0
0-100.0
0.1%
0.1%
0.1%
0.1%
0.1%
1kVAh
10MVAh
U3
U3
0.001
0.1%
0.1%
0.1%
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
R
R
R
R
R
R
R
1 3-sec value
1 3-sec value
3-sec value
3-sec value
3-sec value
5
5
3-sec value
3-sec value
3-sec value
NOTES:
Energy, power demand and total harmonics readings are only available in the PM130EH meters.
1
Voltage and Voltage Harmonics Readings:
When the 4LN3, 3LN3 or 3BLN3 wiring mode is selected, the voltages will be line-to-neutral; for any other wiring mode, they will be line-to-line voltages.
2 All analog registers except of harmonics are 1-second average values. For volts, amps and power scales and units, refer to Section 4 ”Data Scales and Units”. For analog data scaling formulas and examples, see Section 2.7.1, “16-bit Scaled Integer Format”.
3 Positive readings of kvarh net
4 Negative readings of kvarh net
5 If you use these energy registers instead of 32-bit registers, limit the energy roll value to 8 digits to avoid overflow (see Device Options Setup).
15
3.3 16-bit Scaled Analog Registers, Binary Registers and Counters
Low and High Scales
2
Units
2, 4
Notes
6656 0x0000
6697 0x0101
None
Special Inputs
Phase rotation order 0=error, 1=positive (ABC),
2=negative (CBA)
6896 0x0600
6976 0x0800
7056-7063
Digital Inputs (bitmap)
Relay Outputs (bitmap)
Counters
7136-7168
+8 0x0C08
1-Cycle Phase Values
kW L3
+15 0x0C0F Power factor L1
+16 0x0C10 Power factor L2
+17 0x0C11 Power factor L3
+18 0x0C12 V1/V12 Voltage THD
+19 0x0C13 V2/V23 Voltage THD
+20 0x0C14 V3/V31 Voltage THD
+21 0x0C15 I1 Current THD
+22 0x0C16
+23 0x0C17
I2 Current THD
I3 Current THD
+24 0x0C18 I1 K-Factor
+25 0x0C19 I2 K-Factor
+26 0x0C1A I3 K-Factor
0-99,999
0-99,999
0-99,999
0-99,999
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-Pmax
0-Pmax
-1.000-1.000
-1.000-1.000
-1.000-1.000
0-999.9
0-999.9
0-999.9
0-999.9
0-999.9
0-999.9
1.0-999.9
1.0-999.9
1.0-999.9
0.1%
0.1%
0.1%
0.1%
0.1%
0.1%
0.1
0.1
0.1
U3
U3
U3
U3
U3
U3
0.001
0.001
0.001
U1
U1
U1
U2
U2
U2
U3
U3
U3
UINT32 R/W
UINT32 R/W
UINT32 R/W
UINT32 R/W
UINT16 R 1
UINT16 R 1
UINT16 R 1
UINT16 R
UINT16 R
UINT16 R
INT16 R
INT16 R
INT16 R
INT16 R
INT16 R
INT16 R
UINT16 R
UINT16 R
UINT16 R
INT16 R
INT16
INT16
R
R
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
R
R
R
1 2-cycle value
1 2-cycle value
1 2-cycle value
2-cycle value
2-cycle value
2-cycle value
2-cycle value
2-cycle value
2-cycle value
16
+27 0x0C1B I1 Current TDD
+28 0x0C1C I2 Current TDD
+29 0x0C1D I3 Current TDD
Low and High Scales
2
Units
2, 4
Notes
0-100.0
0-100.0
0-100.0
0.1%
0.1%
0.1%
UINT16
UINT16
UINT16
R
R
R
2-cycle value
2-cycle value
2-cycle value
7256-7359
1-Cycle Total Values
Total PF lag
Total PF lead
Total kW import
Total kW export
Total kvar import
0-Vmax
0-Vmax
0-Vmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
-1.000-1.000
0-1.000
U1
U1
U1
UINT16 R
UINT16 R
UINT16 R
U3
U3
INT16 R
INT16 R
U3 UINT16 R
0.001 INT16 R
0.001 UINT16 R +4 0x0F04
+5 0x0F05
+5 0x0F06
+7 0x0F07
+8 0x0F08
0-1.000
0-Pmax
0-Pmax
0-Pmax
0.001
U3
U3
U3
UINT16
UINT32
UINT32
UINT32
R
R
R
R
+9 0x0F09
+10 0x0F0A
+11 0x0F0B
+12 0x0F0C
7296-7300
+1 0x1001
Total kvar export
3-phase average L-N/L-L voltage
0-Pmax
0-Vmax
U3
U1
UINT32
UINT32
R
R 1
3-phase average current 0-Imax U2
1-Cycle Auxiliary Values
In (neutral) Current
+2 0x1002 Frequency
0-Imax
0-Fmax
U2
UINT16 R
UINT16 R
0.01Hz UINT16 R
7316-7331
+0 0x1080
+1 0x1081
+2 0x1082
Phasor
V1/V12 Voltage magnitude
V2/V23 Voltage magnitude
V3/V31 Voltage magnitude
0-300
0-300
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
%
%
U1
U1
U1
U2
U2
UINT16 R
UINT16 R
UINT16
UINT16
R
R
1
1
UINT16 R 1
UINT16 R
UINT16
UINT16
R
R
+4 0x1084
+5 0x1085
+5 0x1086
+8 0x1088
+9 0x1089
I1 Current magnitude
I2 Current magnitude
I3 Current magnitude
V1/V12 Voltage angle
V2/V23 Voltage angle
0-Imax
-180.0-180.0
-180.0-180.0
U2
0.1º
0.1º
UINT16 R
UINT16 R
INT16
INT16
R
R
1
1
+10 0x108A V3/V31 Voltage angle -180.0-180.0 0.1º INT16 R 1
INT16 R
+12 0x108C
+13 0x108D I2 Current angle -180.0-180.0
+14 0x108E
INT16 R
17
7336-7368
1-Second Phase Values
+8 0x1108 kW L3
+15 0x110F
+16 0x1110
+17 0x1111
+18 0x1112
+19 0x1113
+20 0x1114
+21 0x1115
+22 0x1116
Power factor L1
Power factor L2
Power factor L3
V1/V12 Voltage THD
V2/V23 Voltage THD
V3/V31 Voltage THD
I1 Current THD
I2 Current THD
+23 0x1117
+24 0x1118
+25 0x1119
+26 0x111A
+27 0x111B
I3 Current THD
I1 K-Factor
I2 K-Factor
I3 K-Factor
I1 Current TDD
+28 0x111C I2 Current TDD
+29 0x111D I3 Current TDD
7456-7459
1-Second Total Values
+4 0x1404
+5 0x1405
+5 0x1406
+7 0x1407
Total PF lag
Total PF lead
Total kW import
Total kW export
Low and High Scales
2
Units
2, 4
Notes
0-Vmax
0-Vmax
U1
U1
UINT16 R
UINT16 R
1
1
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
U1
U2
U2
U2
U3
U3
U3
U3
U3
UINT16 R
INT16
INT16
INT16
INT16
INT16
R
1
UINT16 R
UINT16 R
UINT16 R
R
R
R
R
-Pmax-Pmax
0-Pmax
0-Pmax
0-Pmax
-1.000-1.000
-1.000-1.000
-1.000-1.000
0-999.9
0-999.9
0-999.9
0-999.9
0-999.9
0-999.9
1.0-999.9
1.0-999.9
1.0-999.9
0-100.0
0-100.0
0-100.0
0-Vmax
0-Vmax
0-Vmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
-1.000-1.000
0-1.000
0-1.000
0-Pmax
0-Pmax
U3
U3
U3
U3
0.001
0.001
0.001
0.1%
0.1%
0.1%
0.1%
0.1%
0.1%
0.1
0.1
0.1
0.1%
INT16 R
UINT16 R
UINT16 R
UINT16 R
INT16
INT16
INT16
UINT16
R
R
R
R 1 3-sec value
0.1%
0.1%
U1
U1
U1
U3
U3
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
R
R
R
R
R
1
1
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
3-sec value
UINT16 R
UINT16 R
UINT16 R
INT16 R
INT16 R
U3 UINT16 R
0.001 INT16 R
0.001
0.001
U3
UINT16
UINT16
UINT32
R
R
R
U3 UINT32 R
18
+8 0x1408
+9 0x1409
+10 0x140A
+11 0x140B
+12 0x140C
7496-7500
Total kvar import
Total kvar export
3-phase average L-N/L-L voltage
3-phase average L-L voltage
3-phase average current
1-Second Auxiliary Values
+1 0x1501 In (neutral) Current
+2 0x1502 Frequency
7536-7565
+0 0x1600
+1 0x1601
+2 0x1602
+3 0x1603
+4 0x1604
+5 0x1605
+6 0x1606
+7 0x1607
+8 0x1608
+9 0x1609
+10 0x160A
+11 0x160B
Present Volt, Ampere and Power Demands
V1/V12 Volt demand
V2/V23 Volt demand
V3/V31 Volt demand
I1 Ampere demand
I2 Ampere demand
I3 Ampere demand kW import block demand kvar import block demand kVA block demand kW import sliding window demand kvar import sliding window demand kVA sliding window demand
+15 0x160F
+16 0x1610
+17 0x1611
+18 0x1612
+19 0x1613
+20 0x1614 kW import accumulated demand kvar import accumulated demand kVA accumulated demand kW import predicted sliding window demand kvar import predicted sliding window demand kVA predicted sliding window demand
+21 0x1615
+22 0x1616
+23 0x1617
+24 0x1618
PF (import) at Max. kVA sliding window demand kW export block demand kvar export block demand kW export sliding window demand
+25 0x1619
+26 0x161A kvar export sliding window demand kW export accumulated demand
+27 0x161B kvar export accumulated demand
+28 0x161C kW export predicted sliding window demand
+29 0x161D kvar export predicted sliding window demand
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-1.000
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
Low and High Scales
2
Units
2, 4
Notes
0-Pmax
0-Pmax
0-Vmax
U3
U3
U1
UINT32
UINT32
UINT32
R
R
R 1
0-Vmax
0-Imax
0-Imax
0-Fmax
0-300
0-300
U1
U2
U2
%
%
UINT32
UINT32
UINT16
R
R
R
UINT16 R
0.01Hz UINT16 R
UINT16 R
UINT16 R
U1
U1
U1
U2
U2
U2
U3
U3
U3
U3
U3
U3
U3
U3
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
R
R
R
R
R
R
R
1
1
1
UINT16 R
UINT16 R
UINT16 R
UINT16 R
U3
U3
U3
U3
U3
U3
U3
U3
U3
0.001
U3
U3
U3
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
R
R
UINT16
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
UINT16 R
19
+34 0x1622
7576-7611
+0,1 0x1700
+2,3 0x1701
In Ampere demand
Total Energies EH
kWh import kWh export
7616-7633
+0,1 0x1800
+2,3 0x1801
+4,5 0x1802
+6,7 0x1803
+8,9 0x1804
+10,11 0x1805
+12,13 0x1806
Phase Energies EH
kWh import L1 kWh import L2 kWh import L3 kvarh import L1 kvarh import L2 kvarh import L3 kVAh total L1
+14,15 0x1807
+16,17 0x1808 kVAh total L2 kVAh total L3
7656-7695
+0 0x1900
V1/V12 Harmonic Distortion
H01 Harmonic distortion
+1 0x1901
H02 Harmonic distortion
...
+39 0x1927
7696-7735
+0 0x1A00
H40 Harmonic distortion
H01 Harmonic distortion
EH
V2/V23 Harmonic Distortion EH
+1 0x1A01
H02 Harmonic distortion
...
+39 0x1A27
H40 Harmonic distortion
7736-7775
V3/V31 Harmonic Distortion EH
+0 0x1B00
H01 Harmonic distortion
+1 0x1B01
H02 Harmonic distortion
...
+39 0x1B27
H40 Harmonic distortion
7776-7815
+0 0x1C00
I1 Harmonic Distortion
H01 Harmonic distortion
EH
Low and High Scales
2
Units
2, 4
Notes
UINT16 R
UINT16 R
UINT16 R
0-Imax
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
U2
1 kWh
1 kWh
1 kvarh
1 kvarh
UINT16
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
1 kVAh
1 kWh
1 kWh
1 kWh
1 kvarh
1 kvarh
1 kvarh
1 kVAh
1 kVAh
1 kVAh
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
R
R
R
R
1
1
1
20
+1 0x1C01
+0 0x1E00
+1 0x1E01
H02 Harmonic distortion
...
+39 0x1E27
8296-8313
H02 Harmonic distortion
...
+39 0x1C27
H40 Harmonic distortion
7816-7855
I2 Harmonic Distortion EH
+0 0x1D00
H01 Harmonic distortion
+1 0x1D01
H02 Harmonic distortion
...
+39 0x1D27
H40 Harmonic distortion
7856-7895
I3 Harmonic Distortion
H01 Harmonic distortion
H40 Harmonic distortion
EH
Fundamental Phase Values EH
+8 0x2908 kW L3
+15 0x290F
+16 0x2910
+17 0x2911
8336-8343
+0 0x2A00
+1 0x2A01
+2 0x2A02
+3 0x2A03
8416-8445
Power factor L1
Power factor L2
Power factor L3
Fundamental Total Values EH
Total fundamental kW
Total fundamental kvar
Total fundamental kVA
Total fundamental PF
Minimum 1-Cycle Phase Values
Low and High Scales
2
Units
2, 4
Notes
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-Pmax
0-Pmax
-1.000-1.000
-1.000-1.000
-1.000-1.000
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
-1.000-1.000
0-Vmax
0-Vmax
0-Vmax
0-Imax
U3
U3
U3
0.001
U1
U1
U1
U2
U1
U1
U1
U2
U2
U2
U3
U3
U3
U3
U3
U3
U3
U3
U3
0.001
0.001
0.001
UINT16 R 1
UINT16 R 1
UINT16 R 1
UINT16 R
UINT16 R
UINT16 R
INT16 R
INT16 R
INT16 R
INT16 R
INT16 R
INT16 R
UINT16 R
UINT16 R
UINT16 R
INT16
INT16
INT16
R
R
R
INT16
INT16
UINT16
INT16
R
R
R
R
UINT16 R 1
UINT16 R 1
UINT16 R 1
UINT16 R
21
8456-8459
+3 0x2D03
8496-8498
+2 0x2E02 Frequency
8736-8765
8776-8779
+3 0x3503
881608818
+0 0x3700
+1 0x3701
+2 0x3702
+3 0x3703
+4 0x3704
+5 0x3705
Minimum 1-Cycle Total Values
Total PF
Minimum 1-Cycle Auxiliary Values
Maximum 1-Cycle Phase Values
Maximum 1-Cycle Total Values
Total PF
Maximum 1-Cycle Auxiliary Values
+2 0x3602 Frequency
8856-8872
Maximum Demands
V1/V12 Maximum volt demand
V2/V23 Maximum volt demand
V3/V31 Maximum volt demand
I1 Maximum ampere demand
I2 Maximum ampere demand
I3 Maximum ampere demand
+9 0x3709
+10 0x370A
+11 0x370B
Maximum kW import sliding window demand
Maximum kvar import sliding window demand
Maximum kVA sliding window demand
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
0-Pmax
0-Pmax
0-Pmax
Low and High Scales
2
Units
2, 4
Notes
0-Imax
0-Imax
U2
U2
UINT16 R
UINT16 R
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-1.000
0-Imax
0-Fmax
U3
U3
U3
0.001
U2
U2
INT16
INT16
UINT16 R
UINT16
R
R
R Absolute value
UINT16 R
UINT16 R
0.01Hz UINT16 R
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-1.000
0-Imax
0-Fmax
0-Vmax
U1
U1
U1
U2
U2
U2
U3
U3
U3
0.001
U2
U2
UINT16 R 1
UINT16 R 1
UINT16 R 1
UINT16 R
UINT16 R
UINT16 R
UINT16 R
INT16 R
INT16 R
UINT16 R
Absolute value
UINT16 R
UINT16 R
0.01Hz UINT16 R
U1 UINT16 R
1
U3
U3
U3
U1
U1
U2
U2
U2
UINT16
UINT16
UINT16
UINT16
R
R
R
R
1
1
UINT16 R
UINT16 R
UINT16 R
UINT16 R
UINT16
UINT16
R
R
UINT16 R
UINT16 R
UINT16 R
UINT16 R
22
+15 0x370F
+16 0x3710
+21 0x3715
9056-9057
+1 0x3C01
Maximum kW export sliding window demand
Maximum kvar export sliding window demand
In Maximum ampere demand
TOU Parameters EH
Active profile
9076-9079
+0 0x3C80
+1 0x3C81
+2 0x3C82
+3 0x3C83
9096-9103
Scaled Analog Outputs
Analog output AO1
Analog output AO2
Analog output AO3
Analog output AO4
TOU Energy Register #1 EH
+0,1 0x3D00
Tariff #1 register
+2,3 0x3D01
Tariff #2 register
+4,5 0x3D02
Tariff #3 register
+6,7 0x3D03
Tariff #4 register
9136-9143
+0,1 0x3E00
+2,3 0x3E01
TOU Energy Register #2 EH
Tariff #1 register
Tariff #2 register
+4,5 0x3E02
+6,7 0x3E03
Tariff #3 register
Tariff #4 register
9176-9183
+0,1 0x3F00
TOU Energy Register #3 EH
Tariff #1 register
+2,3 0x3F01
+4,5 0x3F02
Tariff #2 register
Tariff #3 register
+6,7 0x3F03
9216-9223
+0,1 0x4000
+2,3 0x4001
Tariff #4 register
TOU Energy Register #4 EH
Tariff #1 register
Tariff #2 register
+4,5 0x4002
+6,7 0x4003
9416-9419
+0 0x4500
Tariff #3 register
Tariff #4 register
Summary Energy Accumulated Demands EH
Summary register #1 demand
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
Low and High Scales
2
Units
2, 4
Notes
0-Pmax
0-Pmax
U3
U3
UINT16
UINT16
R
R
UINT16 R
0-Imax
0-7
0-15:
0-3 = Season 1 Profile #1-4,
4-7 = Season 2 Profile #1-4,
8-11 = Season 3 Profile #1-4,
12-15 = Season 4 Profile #1-4
0-4095
0-4095
0-4095
0-4095
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
U2
1 kWh
1 kWh
1 kWh
1 kWh
UINT16 R
UINT16 R
UINT16 R
UINT16
UINT16
UINT16
UINT16
UINT16
UINT32
UINT32
UINT32
UINT32
R
R/W
R/W
R/W
R/W
R
R
R
R
UINT16 R/W
1 kWh
1 kWh
UINT32
UINT32
R
R
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
R
R
R
R
23
+1 0x4501
+2 0x4502
+3 0x4503
9436-9439
+0 0x4580
+1 0x4581
+2 0x4582
+3 0x4583
9456-9459
+0 0x4600
+1 0x4601
+2 0x4602
+3 0x4603
9516-9519
+0 0x4780
+1 0x4781
+2 0x4782
+3 0x4783
9536-9539
+0 0x4800
+1 0x4801
+2 0x4802
+3 0x4803
9576-9579
+0 0x4900
+1 0x4901
+2 0x4902
+3 0x4903
9616-9619
+0 0x4A00
+1 0x4A01
+2 0x4A02
+3 0x4A03
9556-9559
+0 0x4880
+1 0x4881
+2 0x4882
+3 0x4883
10656-10695
+0 0x6400
Summary register #2 demand
Summary register #3 demand
Summary register #4 demand
Summary Energy Block Demands EH
Summary register #1 demand
Summary register #2 demand
Summary register #3 demand
Summary register #4 demand
Summary Energy Sliding Window Demands EH
Summary register #1 demand
Summary register #2 demand
Summary register #3 demand
Summary register #4 demand
Summary Energy Maximum Demands EH
Low and High Scales
2
Units
2, 4
Notes
Summary register #1 maximum demand
Summary register #2 maximum demand
Summary register #3 maximum demand
Summary register #4 maximum demand
TOU Maximum Demand Register #1 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
TOU Maximum Demand Register #2 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
TOU Maximum Demand Register #3 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
TOU Maximum Demand Register #4 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
V1/V12 Harmonic Angles EH
H01 Harmonic angle
1, 3
24
Low and High Scales
2
Units
2, 4
Notes
+1 0x6400
H02 Harmonic angle
...
+39 0x6427
H40 Harmonic angle
10696-10735
+0 0x6500
V2/V23 Harmonic Angles EH
H01 Harmonic angle
+1 0x6500
H02 Harmonic angle
...
+39 0x6527
10736-10775
H40 Harmonic angle
V1/V31 Harmonic Angles EH
+0 0x6600
+1 0x6600
H02 Harmonic angle
...
+39 0x6627
10816-10855
+0 0x6700
H01 Harmonic angle
H40 Harmonic angle
I1 Harmonic Angles EH
H01 Harmonic angle
+1 0x6700
H02 Harmonic angle
...
+39 0x6727
H40 Harmonic angle
10856-10895
+0 0x6800
I2 Harmonic Angles
H01 Harmonic angle
EH
+1 0x6800
H02 Harmonic angle
...
+39 0x6827
10896-10935
H40 Harmonic angle
I3 Harmonic Angles EH
+0 0x6900
H01 Harmonic angle
+1 0x6900
H02 Harmonic angle
...
+39 0x6927
H40 Harmonic angle
11616 0x7C00
Setpoint Status (bitmap)
NOTES:
Energy, power demand and harmonics readings are only available in the PM130EH meters.
1, 3
1, 3
3
3
3
1
Voltage and voltage harmonics readings:
When the 4LN3, 3LN3 or 3BLN3 wiring mode is selected, the voltages will be line-to-neutral; for any other wiring mode, they will be line-to-line voltages.
2 For volts, amps, power and frequency scales and units refer to Section 4 ”Data Scales and Units”. For analog data scaling formulas and examples, see Section 2.7.1, “16-bit Scaled Integer
Format”.
3
4
Harmonic angles are referenced to the fundamental voltage harmonic H01 on phase L1.
The binary counters and energy registers can be read either as 32-bit integer, or 32-bit floating-point values. Refer to Section 2.7 for details.
25
3.4 32-bit Analog Registers, Binary Registers and Counters
Options/Range
2
Units
2, 4
Type
2
11776-11777 0x0000
11904-11905 0x0101
None
Special Inputs
Phase rotation order 0=error, 1=positive (ABC),
2=negative (CBA)
12544-12545 0x0600
12800-12801 0x0800
13056-13063
Digital Inputs DI1-DI4 (bitmap)
Relay Outputs RO1-RO2 (bitmap)
Counters
13312-13377
+16,17 0x0C08
+30,31 0x0C0F
+32,33 0x0C10
+34,35 0x0C11
+36,37 0x0C12
+38,39 0x0C13
+40,41 0x0C14
+42,43 0x0C15
+44,45 0x0C16
+46,47 0x0C17
1-Cycle Phase Values
kW L3
Power factor L1
Power factor L2
Power factor L3
V1/V12 Voltage THD
V2/V23 Voltage THD
V3/V31 Voltage THD
I1 Current THD
I2 Current THD
I3 Current THD
0-99,999
0-99,999
0-99,999
0-99,999
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-Pmax
0-Pmax
-1000-1000
-1000-1000
-1000-1000
0-9999
0-9999
0-9999
0-9999
0-9999
0-9999
10-9999
10-9999
10-9999
U1
U1
U1
U2
U2
U2
U3
U3
U3
U3
U3
U3
U3
U3
U3
×0.001
×0.001
×0.001
×0.1%
×0.1%
×0.1%
×0.1%
×0.1%
×0.1%
×0.1
×0.1
×0.1
R/W Notes
UINT32 R/W
UINT32 R/W
UINT32 R/W
UINT32 R/W
UINT32 R 1
UINT32 R 1
UINT32 R 1
UINT32 R
UINT32 R
UINT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
UINT32 R
UINT32 R
UINT32 R
INT32 R
INT32 R
INT32 R
UINT32 R 1 2-cycle value
UINT32 R 1 2-cycle value
UINT32 R 1 2-cycle value
26
+54,55 0x0C1B I1 Current TDD
+56,57 0x0C1C I2 Current TDD
+58,59 0x0C1D I3 Current TDD
13696-13721
1-Cycle Total Values
+8,9 0x0F04
+10,11 0x0F05
+12,13 0x0F06
+14,15 0x0F07
+16,17 0x0F08
+18,19 0x0F09
+20,21 0x0F0A
+22,23 0x0F0B
+24,25 0x0F0C
13824-13833
Total PF lag
Total PF lead
Total kW import
Total kW export
Total kvar import
Total kvar export
3-phase average L-N/L-L voltage
3-phase average L-L voltage
3-phase average current
1-Cycle Auxiliary Values
+2,3 0x1001 In (neutral) Current
+4,5 0x1002 Frequency
13864-13895
+0,1 0x1080
+2,3 0x1081
+4,5 0x1082
+8,9 0x1084
+10,11 0x1085
+12,13 0x1086
Phasor
V1/V12 Voltage magnitude
V2/V23 Voltage magnitude
V3/V31 Voltage magnitude
I1 Current magnitude
I2 Current magnitude
I3 Current magnitude
+16,17 0x1088
+18,19 0x1089
+20,21 0x108A
V1/V12 Voltage angle
V2/V23 Voltage angle
V3/V31 Voltage angle
+24,25 0x108C I1 Current angle
+26,27 0x108D I2 Current angle
+28,29 0x108E I3 Current angle
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-1800-1800
-1800-1800
-1800-1800
-1800-1800
-1800-1800
-1800-1800
Options/Range
2
Units
2, 4
Type
2
0-1000
0-1000
0-1000
0-Vmax
0-Vmax
×0.1%
×0.1%
×0.1%
U1
U1
R/W Notes
UINT32 R
UINT32 R
0-Vmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
-1000-1000
0-1000
0-1000
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Fmax
0-300
0-300
U1
U3
U3
U3
×0.001
×0.001
×0.001
U3
U3
U3
U3
U1
U1
U2
U2
UINT32 R
INT32 R
INT32 R
UINT32 R
INT32 R
UINT16 R
UINT16 R
UINT32 R
UINT32 R
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
1
UINT32 R
UINT32 R
×0.01Hz UINT32 R
% UINT32 R
% UINT32 R
U1
U1
U1
U2
U2
U2
×0.1º
×0.1º
×0.1º
×0.1º
×0.1º
×0.1º
UINT32
UINT32
UINT32
R
R
R
1
1
1
UINT32 R
UINT32
UINT32
R
R
UINT32 R
UINT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
27
13952-14017
1-Second Phase Values
+16,17 0x1108 kW L3
+30,31 0x110F
+32,33 0x1110
+34,35 0x1111
+36,37 0x1112
+38,39 0x1113
+40,41 0x1114
+42,43 0x1115
+44,45 0x1116
+46,47 0x1117
Power factor L1
Power factor L2
Power factor L3
V1/V12 Voltage THD
V2/V23 Voltage THD
V3/V31 Voltage THD
I1 Current THD
I2 Current THD
I3 Current THD
+54,55 0x111B
+56,57 0x111C
I1 Current TDD
I2 Current TDD
+58,59 0x111D I3 Current TDD
14336-14361
1-Second Total Values
+8,9 0x1404
+10,11 0x1405
+12,13 0x1406
+14,15 0x1407
Total PF lag
Total PF lead
Total kW import
Total kW export
Options/Range
2
Units
2, 4
Type
2
0-Vmax
0-Vmax
U1
U1
R/W Notes
UINT32 R 1
UINT32 R 1
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
U1
U2
U2
U2
U3
U3
U3
U3
U3
UINT32 R
INT32
INT32
INT32
INT32
INT32
R
1
UINT32 R
UINT32 R
UINT32 R
R
R
R
R
-Pmax-Pmax
0-Pmax
0-Pmax
0-Pmax
-1000-1000
-1000-1000
-1000-1000
0-9999
0-9999
0-9999
0-9999
0-9999
0-9999
10-9999
10-9999
10-9999
0-1000
0-1000
0-1000
0-Vmax
0-Vmax
0-Vmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
-1000-1000
0-1000
0-1000
0-Pmax
0-Pmax
U3
U3
U3
U3
U1
U1
U3
U3
U3
×0.001
×0.001
×0.001
U3
U3
×0.001
×0.001
×0.001
×0.1%
×0.1%
×0.1%
×0.1%
×0.1%
×0.1%
×0.1
×0.1
×0.1
×0.1%
×0.1%
×0.1%
U1
INT32 R
UINT32 R
UINT32 R
UINT32 R
INT32 R
INT32 R
INT32 R
UINT32 R 1 3-sec value
UINT32 R 1 3-sec value
UINT32 R 1 3-sec value
UINT32 R
UINT32 R
UINT32 R
INT32 R
INT32 R
UINT32 R
INT32 R
UINT16 R
UINT16 R
UINT32 R
UINT32 R
28
+16,17 0x1408
+18,19 0x1409
+20,21 0x140A
+22,23 0x140B
+24,25 0x140C
14464-14473
Total kvar import
Total kvar export
3-phase average L-N/L-L voltage
3-phase average L-L voltage
3-phase average current
1-Second Auxiliary Values
+2,3 0x1501 In (neutral) Current
+4,5 0x1502 Frequency
14592-14651
+0,1 0x1600
+2,3 0x1601
+4,5 0x1602
+6,7 0x1603
+8,9 0x1604
+10,11 0x1605
+12,13 0x1606
+14,15 0x1607
+16,17 0x1608
+18,19 0x1609
+20,21 0x160A
+22,23 0x160B
Present Volt, Ampere and Power Demands
V1/V12 Volt demand
V2/V23 Volt demand
V3/V31 Volt demand
I1 Ampere demand
I2 Ampere demand
I3 Ampere demand kW import block demand kvar import block demand kVA block demand kW import sliding window demand kvar import sliding window demand kVA sliding window demand
+30,31 0x160F
+32,33 0x1610
+34,35 0x1611
+36,37 0x1612
+38,39 0x1613
+40,41 0x1614
+42,43 0x1615
+44,45 0x1616
+46,47 0x1617
+48,49 0x1618
+50,51 0x1619
+52,53 0x161A kW import accumulated demand kvar import accumulated demand kVA accumulated demand kW import predicted sliding window demand kvar import predicted sliding window demand kVA predicted sliding window demand
PF (import) at Max. kVA sliding window demand kW export block demand kvar export block demand kW export sliding window demand kvar export sliding window demand kW export accumulated demand
+54,55 0x161B
+56,57 0x161C kvar export accumulated demand kW export predicted sliding window demand
+58,59 0x161D kvar export predicted sliding window demand
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-1000
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
0-Pmax
Options/Range
2
Units
2, 4
Type
2
0-Pmax
0-Pmax
0-Vmax
U3
U3
U1
UINT32
UINT32
UINT32
0-Vmax
0-Imax
0-Imax
0-Fmax
0-300
0-300
R/W Notes
R
R
R 1
U1
U2
UINT32
UINT32
R
R
UINT32 R
U2 UINT32 R
×0.01Hz UINT32 R
% UINT32 R
% UINT32 R
U1
U1
U1
U2
U2
U2
U3
U3
U3
U3
U3
U3
U3
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
R
R
R
R
R
R
R
1
1
1
UINT32 R
UINT32 R
UINT32 R
UINT32
U3
U3
U3
U3
U3
U3
U3
U3
U3
U3
U3
U3
×0.001
U3
UINT32
UINT32
UINT32
UINT32
R
R
R
R
UINT32 R
UINT32 R
UINT32 R
UINT32
UINT32
UINT32
UINT32
R
R
R
R
UINT32
UINT32
R
R
UINT32 R
UINT32 R
29
+68,69 0x1622
14720-14755
+0,1 0x1700
+2,3 0x1701
In Ampere demand
Total Energies EH
kWh import kWh export
+10,11 0x1705 kvarh export
+16,17 0x1708
14760-14767
+0,1 0x1780
+2,3 0x1781
+4,5 0x1782
+6,7 0x1783
14848-14865
+0,1 0x1800
+2,3 0x1801
+4,5 0x1802
+6,7 0x1803
+8,9 0x1804 kVAh total
Summary Energy Registers EH
Summary energy register #1
Summary energy register #2
Summary energy register #3
Summary energy register #4
Phase Energies EH
kWh import L1 kWh import L2 kWh import L3 kvarh import L1 kvarh import L2
+10,11 0x1805
+12,13 0x1806
+14,15 0x1807
+16,17 0x1808 kvarh import L3 kVAh total L1 kVAh total L2 kVAh total L3
14976-15055
+0,1 0x1900
V1/V12 Harmonic Distortions EH
H01 Harmonic distortion
+2,3 0x1901
H02 Harmonic distortion
...
+78,79 0x1927
15104-15183
H40 Harmonic distortion
V2/V23 Harmonic Distortions EH
+0,1 0x1A00
+78,79 0x1A27
15232-15311
H01 Harmonic distortion
+2,3 0x1A01
H02 Harmonic distortion
...
H40 Harmonic distortion
V3/V31 Harmonic Distortions EH
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
Options/Range
2
Units
2, 4
Type
2
R/W Notes
UINT32 R
UINT32 R
UINT32 R
0-Imax
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
U2
1 kWh
1 kWh
1 kvarh
1 kvarh
UINT32
UINT32
UINT32
INT32
UINT32
UINT32
R
R
R
R
UINT32 R
R
R
1 kVAh
INT32 R
UINT32 R
UINT32 R
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kvarh
1 kvarh
1 kvarh
1 kVAh
1 kVAh
1 kVAh
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
R
R
R
R
R
R
R
1
1
1
30
+0,1 0x1B00
H01 Harmonic distortion
+2,3 0x1B01
H02 Harmonic distortion
...
+78,79 0x1B27
15360-15439
15616-15695
+0,1 0x1E00
H40 Harmonic distortion
I1 Harmonic Distortions EH
+0,1 0x1C00
H01 Harmonic distortion
+2,3 0x1C01
H02 Harmonic distortion
...
+78,79 0x1C27
15488-15567
H40 Harmonic distortion
I2 Harmonic Distortions
+0,1 0x1D00
H01 Harmonic distortion
EH
+2,3 0x1D01
H02 Harmonic distortion
...
+78,79 0x1D27
H40 Harmonic distortion
I3 Harmonic Distortions
H01 Harmonic distortion
EH
+2,3 0x1E01
H02 Harmonic distortion
...
+78,79 0x1E27
17024-17059
H40 Harmonic distortion
Fundamental (H01) Phase Values EH
+30,31 0x290F
+32,33 0x2910
+34,35 0x2911
17152-17164
+0,1 0x2A00
+2,3 0x2A01
+4,5 0x2A02
Power factor L1
Power factor L2
Power factor L3
Harmonic Total Values EH
Total fundamental kW
Total fundamental kvar
Total fundamental kVA
+16,17 0x2908 kW L3
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-Pmax
0-Pmax
-1000-1000
-1000-1000
-1000-1000
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
Options/Range
2
Units
2, 4
Type
2
R/W Notes
U3
U3
U3
U3
U3
U3
×0.001
×0.001
×0.001
U1
U1
U1
U2
U2
U2
U3
U3
U3
U3
U3
U3
UINT32 R 1
UINT32 R 1
UINT32 R 1
UINT32 R
UINT32 R
UINT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
INT32 R
UINT32 R
UINT32 R
UINT32 R
INT32 R
INT32 R
INT32 R
INT32
INT32
UINT32
R
R
R
31
+6,7 0x2A03
17408-17467
17536-17543
17664-17669
Total fundamental PF
Minimum 1-Cycle Phase Values
Minimum 1-Cycle Total Values
Minimum 1-Cycle Auxiliary Values
+4,5 0x2E02 Frequency
18432-18491
Maximum 1-Cycle Phase Values
18560-18567
Maximum 1-Cycle Total Values
18688-18693
Maximum 1-Cycle Auxiliary Values
+4,5 0x3602 Frequency
18816-18849
+0,1 0x3700
+2,3 0x3701
+4,5 0x3702
Maximum Demands
V1/V12 Maximum volt demand
V2/V23 Maximum volt demand
V3/V31 Maximum volt demand
+6,7 0x3703
+8,9 0x3704
+10,11 0x3705
I1 Maximum ampere demand
I2 Maximum ampere demand
I3 Maximum ampere demand
Options/Range
2
Units
2, 4
Type
2
-1000-1000 ×0.001
R/W Notes
INT32 R
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
-Pmax-Pmax
0-Pmax
0-1000
0-Imax
0-Fmax
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
-Pmax-Pmax
U1
U1
U1
U2
U2
U2
U3
U3
U3
×0.001
UINT32 R
UINT32 R
UINT32 R
INT32
INT32
1
1
1
UINT32 R
UINT32 R
UINT32 R
R
R
UINT32 R
U2
UINT32 R
UINT32 R
×0.01Hz UINT32 R
U1
U1
U1
U2
UINT32 R
UINT32 R
UINT32 R
1
1
1
UINT32 R
U2
U2
U3
UINT32 R
UINT32 R
INT32 R
-Pmax-Pmax
0-Pmax
0-1000
0-Imax
0-Fmax
0-Vmax
0-Vmax
0-Vmax
0-Imax
0-Imax
0-Imax
U3
U3
INT32 R
UINT32 R
×0.001
U2
UINT32 R
UINT32 R
×0.01Hz UINT32 R
U1
U1
U1
U2
U2
U2
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
1
1
1
UINT32 R
UINT32 R
UINT32 R
32
19496-19503
+0,1 0x3C80
+2,3 0x3C81
+4,5 0x3C82
Scaled Analog Outputs
Analog output AO1
Analog output AO2
Analog output AO3
+6,7 0x3C83
19584-19591
Analog output AO4
TOU Energy Register #1 EH
+0,1 0x3D00
Tariff #1 register
+2,3 0x3D01
Tariff #2 register
+4,5 0x3D02
Tariff #3 register
+6,7 0x3D03
Tariff #4 register
19712-19719
+0,1 0x3E00
TOU Energy Register #2 EH
Tariff #1 register
+2,3 0x3E01
Tariff #2 register
+4,5 0x3E02
+6,7 0x3E03
19840-19847
+0,1 0x3F00
Tariff #3 register
Tariff #4 register
TOU Energy Register #3 EH
Tariff #1 register
+2,3 0x3F01
+4,5 0x3F02
Tariff #2 register
Tariff #3 register
+6,7 0x3F03
19968-19975
+0,1 0x4000
Tariff #4 register
TOU Energy Register #4
Tariff #1 register
EH
+18,19 0x3709
+20,21 0x370A
+22,23 0x370B
Maximum kW import sliding window demand
Maximum kvar import sliding window demand
Maximum kVA sliding window demand
+30,31 0x370F
+32,33 0x3710
+42,43 0x3715
19456-19459
+2,3 0x3C01
Maximum kW export sliding window demand
Maximum kvar export sliding window demand
In Maximum ampere demand
TOU Parameters EH
Active profile
0-4095
0-4095
0-4095
0-4095
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
0-10
9
-1
Options/Range
2
Units
2, 4
Type
2
0-Pmax
0-Pmax
0-Pmax
0-Pmax
U3
U3
U3
U3
UINT32
UINT32
UINT32
R/W Notes
R
R
R
UINT32 R
UINT32 R
UINT32 R
UINT32 R
0-Pmax
0-Imax
0-7
0-15:
1-3 = Season 1 Profile #1-4,
4-7 = Season 2 Profile #1-4,
8-11 = Season 3 Profile #1-4,
12-15 = Season 4 Profile #1-4
U3
U2
UINT32
UINT32
R
R
UINT32 R
UINT32 R
UINT32 R
UINT32 R
UINT32 R
1 kWh
UINT32
UINT32
UINT32
UINT32
UINT32
R/W
R/W
R/W
R/W
R
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
1 kWh
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
R
R
R
R
R
R
33
+2,3 0x4001
+4,5 0x4002
+6,7 0x4003
20608-20615
+0,1 0x4500
+2,3 0x4501
+4,5 0x4502
+6,7 0x4503
20648-20655
+0,1 0x4580
+2,3 0x4581
+4,5 0x4582
+6,7 0x4583
20736-20743
+0,1 0x4600
+2,3 0x4601
+4,5 0x4602
+6,7 0x4603
20904-20911
+0,1 0x4780
+2,3 0x4781
+4,5 0x4782
+6,7 0x4783
20992-20999
+0,1 0x4800
+2,3 0x4801
+4,5 0x4802
+6,7 0x4803
21120-21127
+0,1 0x4900
+2,3 0x4901
+4,5 0x4902
+6,7 0x4903
21248-21255
+0,1 0x4A00
+2,3 0x4A01
+4,5 0x4A02
+6,7 0x4A03
21032-21039
+0,1 0x4880
Tariff #2 register
Tariff #3 register
Tariff #4 register
Summary Energy Accumulated Demands EH
Summary register #1 demand
Summary register #2 demand
Summary register #3 demand
Summary register #4 demand
Summary Energy Block Demands EH
Summary register #1 demand
Summary register #2 demand
Summary register #3 demand
Summary register #4 demand
Summary Energy Sliding Window Demands EH
Options/Range
2
Units
2, 4
Type
2
0-10
9
-1
1 kWh UINT32
0-10
9
-1
0-10
9
-1
1 kWh
1 kWh
UINT32
UINT32
Summary register #1 demand
Summary register #2 demand
Summary register #3 demand
Summary register #4 demand
Summary Energy Maximum Demands EH
Summary register #1 maximum demand
Summary register #2 maximum demand
Summary register #3 maximum demand
Summary register #4 maximum demand
TOU Maximum Demand Register #1 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
TOU Maximum Demand Register #2 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
TOU Maximum Demand Register #3 EH
Tariff #1 maximum demand
Tariff #2 maximum demand
Tariff #3 maximum demand
Tariff #4 maximum demand
TOU Maximum Demand Register #4 EH
Tariff #1 maximum demand
R/W Notes
R
R
R
34
Options/Range
2
Units
2, 4
Type
2
R/W Notes
+2,3 0x4881
Tariff #2 maximum demand
+4,5 0x4882
Tariff #3 maximum demand
+6,7 0x4883
24576-24655
+0,1 0x6400
Tariff #4 maximum demand
V1/V12 Harmonic Angles
H01 Harmonic angle
+2,3 0x6400
H02 Harmonic angle
...
+78,79 0x6427
24704-24783
+0,1 0x6500
H40 Harmonic angle
H01 Harmonic angle
EH
V2/V23 Harmonic Angles EH
+2,3 0x6500
H02 Harmonic angle
...
+78,79 0x6527
H40 Harmonic angle
24832-24911
V1/V31 Harmonic Angles EH
+0,1 0x6600
+2,3 0x6600
H02 Harmonic angle
...
+78,79 0x6627
25088-25167
+0,1 0x6700
H01 Harmonic angle
H40 Harmonic angle
I1 Harmonic Angles EH
H01 Harmonic angle
+2,3 0x6700
H02 Harmonic angle
...
+78,79 0x6727
25216-25295
+0,1 0x6800
H40 Harmonic angle
I2 Harmonic Angles EH
H01 Harmonic angle
+2,3 0x6800
H02 Harmonic angle
...
+78,79 0x6827
H40 Harmonic angle
25344-25423
I3 Harmonic Angles EH
+0,1 0x6900
+78,79 0x6927
27648-27649 0x7C00
H01 Harmonic angle
+2,3 0x6900
H02 Harmonic angle
...
H40 Harmonic angle
Setpoint Status SP1-SP16 (bitmap)
-1800-1800
-1800-1800
×0.1º
×0.1º
1, 3
INT32 R
INT32 R
-1800-1800
-1800-1800
-1800-1800
-1800-1800
-1800-1800
-1800-1800
×0.1º
×0.1º
×0.1º
×0.1º
×0.1º
×0.1º
INT32 R
1, 3
INT32 R
INT32 R
INT32 R
1, 3
INT32 R
INT32 R
-1800-1800
-1800-1800
-1800-1800
×0.1º
×0.1º
×0.1º
INT32 R
3
INT32 R
INT32 R
-1800-1800
-1800-1800
-1800-1800
×0.1º
×0.1º
×0.1º
INT32 R
3
INT32 R
INT32 R
-1800-1800
-1800-1800
-1800-1800
×0.1º
×0.1º
×0.1º
INT32 R
3
INT32 R
INT32 R
-1800-1800 ×0.1º INT32 R
0x00000000-0x0000FFFF UINT32 R
NOTES:
Energy, power demand and harmonics readings are only available in the PM130EH meters.
1
Voltage and voltage harmonics readings:
When the 4LN3, 3LN3 or 3BLN3 wiring mode is selected, the voltages will be line-to-neutral; for any other wiring mode, they will be line-to-line voltages.
35
2
3
4
For volts, amps, power and frequency scales and units, refer to Section 4 ”Data Scales and Units”.
Harmonic angles are referenced to the fundamental voltage harmonic H01 on phase L1.
The registers can be read as 32-bit integer or 32-bit floating-point values. Refer to Section 2.7 for details.
36
3.5 Minimum/Maximum Log Registers
Description
35840-35959
+0,1 0x2C00
+2,3
+4,5 0x2C01
+6,7
+8,9
+10,11
0x2C02
Minimum Phase Values
Min. V1/V12 Voltage
Timestamp
Min. V2/V23 Voltage
Timestamp
Min. V3/V31 Voltage
Timestamp
+12,13
+14,15
+16,17
+18,19
0x2C03
0x2C04
Min. I1 Current
Timestamp
Min. I2 Current
Timestamp
+20,21
+22,23
0x2C05 Min. I3 Current
Timestamp
36096-36111
+0,1
Minimum Total Values
0x2D00 Min. Total kW
+2,3
+4,5
+6,7
Timestamp
0x2D01 Min. Total kvar
Timestamp
+8,9
+10,11
+12,13
+14,15
36352-36362
+0,1
0x2D02 Min. Total kVA
Timestamp
0x2D03 Min. Total PF
Timestamp
Minimum Auxiliary Values
+2,3
+4,5
+6,7
+8,9
+10,11
0x2E01
0x2E02
Min. In Current
Timestamp
Min. Frequency
Timestamp
36864-36983
+0,1 0x3400
+2,3
+4,5
+6,7
0x3401
+8,9
+10,11
+12,13
+14,15
+16,17
+18,19
0x3402
0x3403
0x3404
Maximum Phase Values
Max. V1/V12 Voltage
Timestamp
Max. V2/V23 Voltage
Timestamp
Max. V3/V31 Voltage
Timestamp
Max. I1 Current
Timestamp
Max. I2 Current
Timestamp
Options/Range/Format
2
Units
2, 3
0-Vmax
F1
0-Vmax
F1
0-Vmax
F1
U1 sec
U1 sec
U1 sec
0-Imax
F1
U2 sec
Type R/W
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
UINT32
R
R
R
R
R
R
R
R
1
1
1 sec UINT32 R sec UINT32 R
-1000-1000 sec UINT32 R sec
INT32
UINT32
R
R sec
×0.001 sec
UINT32
INT32
UINT32
UINT32
UINT32
R
R
R
R
R
0-Fmax
0-Vmax sec
×0.01Hz sec
U1
UINT32
UINT32
UINT32
UINT32 R sec UINT32 R sec
UINT32
UINT32
R
R
R
R
R sec UINT32 R sec UINT32 R sec
UINT32
UINT32
R
R
1
1
1
Notes
37
Description
+20,21
+22,23
0x3405
37120-37135
+0,1
+2,3
0x3500
+4,5
+6,7
+8,9
+10,11
+12,13
+14,15
0x3501
0x3502
0x3503
37376-37387
+0,1
+2,3
+4,5
+6,7
+8,9
+10,11
37504-37535
+0,1
+2,3
+4,5
+6,7
+12,13
+14,15
0x3601
0x3602
0x4780
Max. In Current
Timestamp
Max. Frequency
Timestamp
Summary Energy Maximum Demands EH
Summary register #1 Maximum Demand
Timestamp
Summary register #2 Maximum Demand 0x4781
Timestamp
…
0x4783 Summary register #4 Maximum Demand
37632-37695
+0,1
+2,3
0x3700
0x3701 +4,5
+6,7
+8,9
+10,11
+12,13
+14,15
+16,17
+18,19
0x3702
0x3703
0x3704
Max. I3 Current
Timestamp
Maximum Total Values
Max. Total kW
Timestamp
Max. Total kvar
Timestamp
Max. Total kVA
Timestamp
Max. Total PF
Timestamp
Maximum Auxiliary Values
Timestamp
Maximum Demands
V1/V12 Maximum volt demand
Timestamp
V2/V23 Maximum volt demand
Timestamp
V3/V31 Maximum volt demand
Timestamp
I1 Maximum ampere demand
Timestamp
I2 Maximum ampere demand
Timestamp
+20,21
+22,23
+24,25
+26,27
+28,29
+30,31
0x3705
0x3706
0x3707
I3 Maximum ampere demand
Timestamp
Not used
Timestamp
Not used
Timestamp
Options/Range/Format
2
Units
2, 3
Type R/W
sec
UINT32
UINT32
R
R sec
INT32
UINT32
R
R sec
INT32
UINT32
R
R
-1000-1000
0-Fmax sec
×0.001 sec
UINT32
INT32
UINT32
UINT32 R
UINT32 R sec
UINT32
UINT32
R
R
R
R
R
×0.01Hz sec
UINT32
UINT32
R
R
Notes
sec
UINT32
UINT32
R
R
0-Vmax U1 sec
UINT32
UINT32
1 sec UINT32
R
R
R
1
1 sec UINT32 R sec
UINT32
UINT32
R
R sec
UINT32
UINT32
R
R
UINT32 R
UINT32
UINT32
R
R
38
Description
+32,33
+34,35
+36,37
+38,39
+40,41
+42,43
+44,45
+46,47
+48,49
+50,51
+52,53
+54,55
+56,57
+58,59
+60,61
+62,63
0x3708 Not used
Timestamp
0x3709
0x370A
0x370B
0x3737
Maximum kW import sliding window demand
Timestamp
Maximum kvar import sliding window demand
Timestamp
Maximum kVA sliding window demand
Timestamp
Not used
Timestamp
0x370D Not used
Timestamp
0x370E Not used
Timestamp
0x370F Maximum kW export sliding window demand
Timestamp
+64,65
+66,67
+68,69
+70,71
+71,73
+74,75
+76,77
+78,79
0x3710
0x3711
0x3712
0x3713
+80,81
+82,83
+84,85
+86,87
0x3714
0x3715
38144-38159
+0,1 0x4800
+2,3
+4,5
+6,7
0x4801
Maximum kvar export sliding window demand
Timestamp
Not used
Timestamp
Not used
Timestamp
Not used
Timestamp
Not used
Timestamp
In Maximum ampere demand
Timestamp
TOU Maximum Demand Register #1
Tariff #1 maximum demand
EH
Timestamp
Tariff #2 maximum demand
Timestamp
+12,13
+14,15
38400-38415
+0,1
+2,3
…
0x4803 Tariff #4 maximum demand
0x4900
Timestamp
TOU Maximum Demand Register #2 EH
Tariff #1 maximum demand
Timestamp
+4,5
+6,7
0x4901 Tariff #2 maximum demand
Timestamp
…
+12,13 0x4903 Tariff #4 maximum demand
Options/Range/Format
2
Units
2, 3
Type R/W Notes
UINT32
UINT32
R
R sec
UINT32
UINT32
R
R sec UINT32 R sec UINT32 R
UINT32
UINT32
R
R
UINT32 R
UINT32 R sec
UINT32
UINT32
R
R sec
UINT32
UINT32
R
R
UINT32 R
0-Pmax
UINT32 R
UINT32
UINT32
R
R sec
UINT32
UINT32
R
R
UINT32 R sec UINT32 R sec UINT32 R
R sec
UINT32
UINT32
R
R sec UINT32 R sec
UINT32
UINT32
R
R
R
U3 UINT32 R
39
Description
+14,15
38656-38671
+0,1
+2,3
0x4A00
+4,5
+6,7
+12,13
+14,15
38272-38287
+0,1
+2,3
+4,5
+6,7
Timestamp
TOU Maximum Demand Register #3
Tariff #1 maximum demand
0x4A01
Timestamp
Tariff #2 maximum demand
Timestamp
…
0x4A03 Tariff #4 maximum demand
0x4880
0x4881
Timestamp
Tariff #2 maximum demand
Timestamp
…
EH
Timestamp
TOU Maximum Demand Register #4 EH
Tariff #1 maximum demand
+12,13
+14,15
0x4883 Tariff #4 maximum demand
Timestamp
Options/Range/Format
2
Units
2, 3 sec sec
Type R/W
UINT32
UINT32
UINT32
UINT32
R
R sec UINT32 R
R sec
UINT32
UINT32
R
R sec UINT32 R
R sec
UINT32
UINT32
R
R
R
R
NOTES:
Power demand readings are only available in the PM130EH meters.
1
Voltage and Voltage Harmonics readings:
2
3
When the 4LN3, 3LN3 or 3BLN3 wiring mode is selected, the voltages will be line-to-neutral; for any other wiring mode, they will be line-to-line voltages.
For volts, amps, power and frequency scales and units, refer to Section 4 ”Data Scales and Units”.
The Min/Max register values can be read as 32-bit integer or 32-bit floating-point values. Refer to Section 2.7 for details.
Notes
40
3.6 Device Control and Status Registers
Options/Range Units Notes
Device Restart Register
2560 Warm restart of the device 0 when read,
0xFFFF when written = restart the device
Device Authorization Registers
2575 When write: 4-digit password. When read: 0 = access
44378-44379 permitted, -1 = authorization required.
When write: 8-digit password. When read: 0 = access permitted, -1 = authorization required.
Remote Relay Control
3244-3245
+0 Remote relay command
0-9999 (write)
0/-1 (read)
0 - 99999999 (write)
0/-1 (read)
0 = remove a remote command
1 = operate relay
2 = remove a remote command and release a locally latched relay
3244
3245
RO1 Control
RO2 Control
Device Reset/Clear Registers
3404
3405
Clear total energy registers
Clear total maximum demand registers
0
0 = Clear all maximum demands
1 = Clear power demands
EH
2 = Clear volt, ampere and harmonic demands
3406
3407
3408
Clear TOU energy registers
EH
0
Clear TOU maximum demand registers
EH
0
Clear pulse counters 0 = Clear all counters
1-4 = Clear counter #1-#4
0 3409
Device Identification
Clear Min/Max log
2561-2562 Reserved
2563 Firmware build number
2564 Reserved
2565 Firmware version number
0
1-99
0
1100-1199
UINT16 W
UINT16
UINT16
UINT16
UINT16
W
R
R Two higher decimal digits = major version number, two lower decimal digits = minor version number
3484
Device Status Registers
3452
Current serial port number
Relay status RO1-RO2 (bitmap)
F28
0=COM1, 1=COM2
0x0000-0x0003
UINT16
UINT16
R
R Bits set to 1 indicate closed relay contacts.
41
3453 Reserved
3454
3455
Digital (status) inputs DI1-DI4
Present setpoint status SP1-SP16 (bitmap)
Self-check alarm status (device diagnostics).
Nonvolatile register that keeps the status of the internal device diagnostics.
Options/Range Units Notes
0
0x0000-0x000F
0x0000-0xFFFF
UINT16
UINT16
R
R
Bits set to 1 indicate closed input contacts.
Bits set to 1 indicate operated
(activated) setpoints.
Alarm Notification Registers
3474 Setpoint alarm status SP1-SP16 (bitmap). Nonvolatile register that keeps the status of the operated setpoints.
0x0000-0xFFFF
3475 F23
UINT16
UINT16
R/W When read: Bits set to 1 indicate that the designated setpoint have been operated at least once since the alarm bits were reset.
When written: Bits preset to 0 clear corresponding alarms, Bits set to 1 have no effect.
R/W When read: Bits set to 1 indicate that the designated diagnostics failed at least once since the alarm bits were reset.
When written: Bits preset to 0 clear corresponding alarms; bits set to 1 have no effect.
42
3.7 Device Setup Registers
Device Identification
46080-46111
+0,1
+2,3
Device serial number
Device model ID
+4-11
+12-13
Device model name
Device options (bitmap)
+14-19 Reserved
+20 Device firmware version number
+21 Device firmware build number
+22,23 Reserved
+24 Boot loader version number
Options/Range Units Notes
0-999999
13010=PM130P, 13030=PM130EH
“PM130P”, “PM130EH”
0
1100-1199 (PM130P/EH)
1-99
0101-0199
UINT32
UINT32
CHAR16
UINT32
UINT16
UINT16
UINT16
UINT16
R
R
R
R
R
R
R
R
Null-terminated string
Two higher decimal digits = major version number, two lower decimal digits = minor version number
Two higher decimal digits = major version number, two lower decimal digits = minor version number
+25 Boot loader build number
+26-31 Reserved
Factory Device Settings
46112-46178
+0
+1
V1-V3 input range
V1-V3 input overload
+2,3 Reserved
+4 I1-I3 input range
+5 I1-I3 input overload
+6-13 Reserved
+14-63 Unused
+64 Ethernet MAC address 0-1
+65
+66
Basic Setup
Ethernet MAC address 2-3
Ethernet MAC address 4-5
2304-2324
+1
+2
+3
1-99
690, 120 (option U)
120
1, 5
200
0x0500
0x00F0
0x0000-0xFFFF
PT ratio
F2
10 to 65000
CT primary current 1 to 50,000
Power block demand period
EH
1,2,3,5,10,15,20,30,60 min,
255 = external synchronization
V
%
A
%
UINT16
UINT16
UINT16
UINT16
R
R
R
R
Does not limit the 690V input range
UINT16
UINT16 R
UINT16
UINT16
R
R
×0.1
A min
UINT16 R/W
UINT16
UINT16
R/W
R/W If the external synchronization is selected, the DI1 input is considered a pulse or KYZ input.
The pulse edge restarts the power demand block accumulation interval. E
43
+4
+5-7
+8
+9,10
+11
+12
Volt/ampere demand period
Reserved
Number of blocks in a sliding window
EH
Reserved
Nominal line frequency
Maximum demand load current
+13-19
+20
Reserved
PT ratio multiplication factor
Communication Ports Setup
2344-2359
+0 Communication protocol
+1 Interface
+2 Device address
+3 Baud rate
+4
+5
+6
Data format
Flow control
RTS mode
+7
2344-2351
2352-2359
Device Options Setup
2376-2386
+0
ASCII compatibility mode
COM1 Setup
COM2 Setup
Power calculation mode
Options/Range Units Notes
0 to 1800 sec UINT16 R/W
1 to 15
25, 50, 60, 400 Hz
0 to 50,000 (0=CT primary current) A
×1, ×10
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R/W
R/W
R/W
R/W
R/W
R/W
Read as 65535
E
Read as 65535
Read as 65535
COM1: 0=SATEC ASCII, 1=Modbus
RTU, 2=DNP3.0
COM2: 0=SATEC ASCII, 1=Modbus
RTU, 2=DNP3.0, 5=Profibus DP
COM2: 0=RS-232, 1=RS-422,
2=RS-485, 6=Ethernet, 7=Profibus
SATEC ASCII: 0-99
Modbus RTU: 1-247
DNP3.0: 0–65532
Profibus DP: 0-126
1=300 bps, 2=600 bps, 3=1200 bps, 4=2400 bps, 5=4800 bps,
6=9600 bps, 7=19200 bps,
8=38400 bps, 9=57600 bps,
10=115200 bps
0=7 bits/even parity,
1=8 bits/no parity,
2=8 bits/even parity
0=no flow control
1=software (XON/XOFF)
2=hardware (CTS)
0=not used,
1=RTS is permanently asserted
2=RTS is asserted during the transmission
0=disabled, 1=enabled
UINT16
UINT16
UINT16
R/W
R/W
R/W
N/A for COM1 (read as 65535)
N/A for COM1 (read as 65535)
0=using reactive power: S=f(P,Q),
1=using non-active power:
Q=f(S,P)
44
+1
+2
+3-9
+10
+11
+12-13
+14
Local Settings
4320-4330
+0
+1
+2
+3
+4
+5
+6
+7
Energy roll value
EH
Phase energy calculation mode
Reserved
Energy LED test mode
EH
EH
Options/Range Units Notes
0=1 ×10 4
3=1 ×10
7
, 1=1 ×10 5
, 4=1 ×10
8
, 2=1 ×10 6
, 5=1 ×10
9
,
0=disabled,
0=disabled, 1=Wh test, 2=varh test
UINT16
UINT16
R/W ×10 8
R/W Read as 65535
R/W LED pulse rate is 10,000 pulses/kWh
Starting voltage, percent of FS voltage
Reserved
Device resolution (see Section 4 for details)
15-50
0 = Low resolution, 1 = High resolution
×0.1%
UINT16 R/W Read as 65535
R/W 0
Daylight savings time (DST) option
DST start month
DST start week of the month
DST start weekday
DST end month
DST end week of the month
DST end weekday
Clock synchronization source
+8
+9
Country code
DST start hour
+10 DST end hour
Clock Indication and Setup
4352-4358
+0 Seconds
+1 Minutes
+2 Hour
+3 Day of month
+4 Month
+5
+6
Year (calendar year minus 2000)
Weekday
Alarm/Event Setpoints Setup
2576-2703
+0 Trigger parameter ID
+1 Action
0 = DST disabled (standard time only), 1 = DST enabled
1-12
1-4 = 1st, 2nd, 3rd and 4th week,
5=the last week of the month
1-7 (1=Sun, 7=Sat)
1-12
1-4=1st, 2nd, 3 rd
and 4th week,
5=the last week of the month
1-7 (1=Sun, 7=Sat)
1-4 = DI1-DI4, 32767 = meter clock
ITU calling number
1-6
1-6
0-59
0-59
0-23
1-31
1-12
0-99
1-7 (1=Sun, 7=Sat)
F12
F14
0-9999
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R/W
R/W
R/W
R/W
R/W A DI input is considered a pulse or
KYZ input. The pulse edge adjusts the clock at the nearest whole minute.
R/W
R/W
R/W
R/W
R/W
R/W Ignored when written
UINT16 R/W
×0.1 sec UINT16 R/W
45
+4,5
+6,7
2576-2583
2584-2591
2592-2599
2600-2607
2608-2615
2616-2623
2624-2631
2632-2639
2640-2647
2648-2655
2656-2663
2664-2671
2672-2679
2680-2687
2688-2695
2696-2703
Pulse Counters Setup
2940-2947
+0
Operate limit
Release limit
Setpoint #1
Setpoint #2
Setpoint #3
Setpoint #4
Setpoint #5
Setpoint #6
Setpoint #7
Setpoint #8
Setpoint #9
Setpoint #10
Setpoint #11
Setpoint #12
Setpoint #13
Setpoint #14
Setpoint #15
Setpoint #16
Source digital input ID
+1 Multiplier
2940-2941
Counter #1 Setup
2942-2943
2944-2945
2946-2947
Analog Outputs Setup
Counter #2 Setup
Counter #3 Setup
Counter #4 Setup
3148-3153
+0
+1
+2
3148-3150
3151-3153
Digital Inputs Setup
3292-3296
Output parameter ID
Zero scale value (0/4 mA)
Full scale value (1/20 mA)
AO1 Setup
AO2 Setup
+0
+1
+3
+4
Status inputs (bitmap)
Pulse inputs (bitmap)
External demand synchronization input (bitmap)
Time synchronization input (bitmap)
Options/Range Units Notes
0-9999 ×0.1 sec UINT16 R/W
See Section 3.3 UINT32 R/W Scaled value
0=not assigned, 1=DI1, 2=DI2,
3=DI3, 4=DI4
0-9999
F18
See Section 3.3
See Section 3.3
UINT16
UINT16
UINT16
R/W
R/W
R/W
Scaled value
Scaled value
0x0003
0x0003
0
0x0001=DI1
UINT16
UINT16
UINT16
Obsolete registers. Refer to Digital
Inputs setup registers 61728-61735
R/W Ignored when written
R/W Ignored when written
R/W Ignored when written
46
Network Setup
46576-46703
+0,1
+2,3
+4,5
+6,7
+8,9
Network subnet mask
Use DHCP
TCP service port
+10-127 Reserved
Password Setup
46704-46707
+0,1 Communications password (4 digits)
+2 Password protection enabled
+3 Reserved
Expert Power Service Setup
46768-46783
+0,1
+2,3
+4,5
Expert Power server IP Address
Expert Power server TCP service port
Expert Power client enabled
+6,7
+8,9
Time to next session
Time to next session
+10-15 Reserved
Internet Service Provider (ISP) accounts
46784-46879
+0-15 ISP telephone number
46784-46831
46832-46879
DNP Options Setup
51158-51183
Account No.1
Account No.2
+0 Binary Input Static Objects
+1 Reserved
+2 Binary Counter Objects
+3-5 Reserved
+6 Analog Input Objects
+7-10 Reserved
+11 16-bit BC Scaling
+12 16-bit AI Scaling
Options/Range Units Notes
0x0004=DI3, 0x0008=DI4
0 = NO, 1 = YES
502 = Modbus/TCP,
20000 = DNP3.0/TCP
0-9999
0 = disabled, 1 = enabled
0-65535
0 = client disabled, 1 = client enabled
1-99999
1-99999
F24 (default 0)
F24 (default 3)
F24 (default 3)
0= ×1 (default), 1=×10, 2=×100,
3= ×1000
0 – scaling OFF, 1-scaling ON min min
UINT32
UINT16
UINT16
UINT16
R/W
R/W
R/W
R/W
R/W
UINT32
UINT16
R/W
R/W
Read as 0
UINT32
UINT32
UINT32
CHAR32
UINT16
R/W
R/W
R
R/W
R/W
Default = 5001
Same as previous
47
+13-5 Reserved
+16
+17
+18-21
+22,23
Select/Operate Timeout
Multi Fragment Interval
Reserved
Time Sync Period
+24
+25
51184-51189 Reserved
DNP Class 0 Point Assignments
51702-51797
+0
+1
+2
51702-51704
Voltage scale, secondary volts
Current scale, secondary amps
DNP object and variation
DNP point number
Number of points
DNP Class 0 Points Range 1
51705-51707
DNP Class 0 Points Range 2
…
51795-51797
DNP Class 0 Points Range 32
51798-51893 Reserved
TOU Daily Profile Setup EH
55574-55701
+0 1
+1 2 st nd
tariff change
tariff change
+2 3 rd
tariff change
+3 4 th tariff change
+4 5
+5 6
+6 7 th th th
tariff change
tariff change
tariff change
+7 8 th tariff change
55574-55581
55582-55589
55590-55597
55598-55605
55606-55613
55614-55621
55622-55629
55630-55637
55638-55645
55646-55653
55654-55661
55662-55669
55670-55677
Daily profile #1: Season 1, Day type 1
Daily profile #2: Season 1, Day type 2
Daily profile #3: Season 1, Day type 3
Daily profile #4: Season 1, Day type 4
Daily profile #5: Season 2, Day type 1
Daily profile #6: Season 2, Day type 2
Daily profile #7: Season 2, Day type 3
Daily profile #8: Season 2, Day type 4
Daily profile #9: Season 3, Day type 1
Daily profile #10: Season 3, Day type 2
Daily profile #11: Season 3, Day type 3
Daily profile #12: Season 3, Day type 4
Daily profile #13: Season 4, Day type 1
F10
F10
F10
F10
F10
F10
F10
F10
Options/Range Units Notes
2 to 30 seconds (default 10 sec)
50 to 500 ms (default 50 ms)
Read as 65535
0 to 86400 seconds (default 86400 sec)
60-828
10-100
V
×0.1A
UINT16
UINT16
UINT16
UINT16
R/W
R/W
R/W
R/W
UINT16 R/W
F25
Point number for the selected object
0-128
UINT16
UINT16
UINT16
R/W
R/W
R/W
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
48
55678-55685
55686-55693
55694-55701
55702-55711
TOU Calendar Setup EH
55712-56031
+0-9
+0
Daily profile #14: Season 4, Day type 2
Daily profile #15: Season 4, Day type 3
Daily profile #16: Season 4, Day type 4
Reserved
Calendar entry record
Daily profile
+1 Week of month
+2
+3
+4
+5
+6
+7
Weekday
Till Weekday
Month
Day of month
Till Month
Till Day of month
+8-9 Reserved
55712-55721
Calendar entry #1
55722-55731
55732-55741
Calendar entry #2
Calendar entry #3
…
56022-56031
Calendar entry #32
56032-56191 Reserved
Summary Energy/TOU Registers Setup EH
56672-56703
+1 Units of measurement
+2 Flags (bitmap)
56672-56675
56676-56679
Register #1 Setup
Register #2 Setup
56680-56683
56684-56687
Register #3 Setup
Register #4 Setup
Summary Energy/TOU Registers Source Setup EH
56928-57183
+0
+1
Energy source ID
Target summary register number
+2,3 Multiplier
Options/Range Units Notes
R/W
0-3 = Season 1, Day types 0-3
4-7 = Season 2, Day types 0-3
8-11 = Season 3, Day types 0-3
12-15 = Season 4, Day types 0-3
0=all, 1=1st, 2=2nd, 3=3 rd
5=last week of the month
, 4=4th,
0=all, 1-7 (Sun=1, Sat=7)
0=all, 1-7 (Sun=1, Sat=7)
0=all, 1-12=January - December
0=all, 1-31=day 1-31
0=all, 1-12=January - December
0=all, 1-31=day 1-31
0=none, 1=kWh, 2=kvarh, 3=kVAh,
4=m
3
, 5=CF (cubic feet), 6=CCF
(hundred cubic feet)
Bit 0=1 - TOU enabled
0
F11
0-7 = register #1-#8
0-1000000 ×0.001
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
R/W
R/W
R/W
R/W
R/W
R/W
R/W
UINT16
UINT16
R/W
R/W
INT32 R/W
49
56928-56931
56932-56935
56936-56939
56940-56943
Digital Inputs Setup
61728-61743
+0
+1
+2
Energy Source #1
Energy Source #2
Energy Source #3
Energy Source #4
Pulse mode
Polarity
De-bounce time, ms
Options/Range Units Notes
0 = pulse, 1 = KYZ
0 = normal, 1 = inverting
1-100
+3 Reserved
61728-61731
DI1 Setup
61732-61735
DI2 Setup
61736-61739
61740-61743
Relay Outputs Setup
DI3 Setup
DI4 Setup
61984-61995
+0
+1
+2
+3
+4
Operation Mode
Polarity
Pulse width, ms
0=unlatched, 1=latched,
2=pulse, 3=KYZ
Bit 0 – Polarity:
0=normal, 1=inverting
1-1000
Pulse source ID
EH
F17
Units per pulse 1-10000 x0.1
+5 Reserved
61984-61989
RO1 Setup
61990-61995
Analog Outputs Setup
RO2 Setup
62560-62571
+0 Output parameter ID
+2,3
+4,5
62560-62565
62566-62571
Zero scale value (0/4 mA)
Full scale value (20/1 mA)
AO1 Setup
AO2 Setup
F18
0
See Section 3.4
See Section 3.4
UINT16
UINT16
UINT16
UINT16
UINT16
UINT16
INT32
INT32
R/W
R/W
R/W Debounce time will be the same for both inputs
R/W
R/W
R/W
R/W
R/W
50
3.8 Analog and Digital I/O Configuration
I/O Slots Configuration Info
63008-63055
+1
+2
+3
63008-63011
63012-63015
Number of I/Os on the slot
First I/O number on the slot
Last I/O number on the slot
DI Slot Configuration
RO Slot Configuration
63016-63019
AI/AO Slot Configuration
63020-63055 Reserved
I/O Type Info
63056-63119
+0
+1
+2
Number of I/O slots of this type
Total number of I/O's of this type
Number of I/O's on the slot
63056-63059
DI Type Info
63060-63063
63064-63067
RO Type Info
AI Type Info
63068-63071
AO Type Info
63076-63119 Reserved
Options/Range Units Notes
F29
0-4
0
0-4
UINT16
UINT16
UINT16
R
R
R
0-1
0-4
0-4
0
UINT16
UINT16
UINT16
R
R
R
51
4 Data Scales and Units
Code Condition
Data Scales
Value/Range
Vmax
Imax
Pmax
Voltage scale × PT Ratio, V
Current scale × CT Ratio, A
Wiring 4LN3, 3LN3, 3BLN3
Vmax
× Imax × 3, W
Wiring 4LL3, 3LL3, 3BLL3,
3OP2, 3OP3, 3DIR2
Vmax × Imax × 2, W
Fmax Nominal frequency 25, 50 or 60 Hz
100 Hz
Nominal frequency 400Hz 500 Hz
Data Units – Low Resolution Option
U1
U2
U3
Data Units – High Resolution Option
U1 PT Ratio = 1
PT Ratio > 1
U2
U3 PT Ratio = 1
PT Ratio > 1
1V
1A
1kW/kvar/kVA
0.1V
1V
0.01A
1W/Var/VA
1kW/kvar/kVA
Notes
2
1, 3
4
See Device Options Setup for information on selecting the device resolution option.
1
CT Ratio = CT primary current/CT secondary current
2
The default Voltage scale is 144V (120V +20%). You can change it via the Device Data Scale setup (see Section 3.1) or via the Device Options setup in PAS.
3
The default Current scale is 2 × CT secondary current (2.0A with 1A secondaries, 10.A with 5A secondaries). You can change it via the Device Data Scale setup (see Section 3.1) or via the Device Options setup in PAS.
4
Pmax is rounded to whole kilowatts. With PT=1.0, if Pmax is greater than 9,999,000 W, it is truncated to 9,999,000 W.
52
5 Data Formats
Format Code
0x1701
Value
Timestamp
F1 Local time in a UNIX-style format. Represents the number of seconds since midnight (00:00:00), January 1, 1970.
The time is valid after January 1, 2000.
Wiring Mode
F2 0
1
2
3
4
5
6
8
3OP2 - 3-wire open delta using 2 CTs (2 element)
4LN3 - 4-wire WYE using 3 PTs (3 element), line-toneutral voltage readings
3DIR2 - 3-wire direct connection using 2 CTs (2 element)
4LL3 - 4-wire WYE using 3 PTs (3 element), line-to-line voltage readings
3OP3 - 3-wire open delta using 3 CTs (2 1/2 element)
3LN3 - 4-wire WYE using 2 PTs (2 1/2 element), line-toneutral voltage readings
3LL3 - 4-wire WYE using 2 PTs (2 1/2 element), line-toline voltage readings
3BLN3 - 3-wire broken delta using 2 PTs (2 1/2 element), line-to-neutral voltage readings
9 3BLL3 - 3-wire broken delta using 2 PTs (2 1/2 element), line-to-line voltage readings
TOU Tariff Change Time
F10 Bits 8:15 = 0-3
Bits 2:7 = 0-23
Tariff number #1-#4
Tariff start hour
Bits 0:1 = 0-3 Tariff start quarter of an hour
Summary/TOU Energy Register Source ID
F11 0x0000 None
0x0700-0x0703
0x1700
Pulse input DI1-DI4 kWh import
0x1705
0x1708
Setpoint Trigger Parameters ID
F12 0x0000
0x0600
0x0601
0x0602
0x0603
0x8600
0x8601
0x8602
0x8603
0x0800
0x0801
0x8800
0x8801
0x8901
0x8902 kWh export kvarh export kVAh total
Description
None (condition is not active)
Status Inputs
Status input #1 ON
Status input #2 ON
Status input #3 ON
Status input #4 ON
Status input #1 OFF
Status input #2 OFF
Status input #3 OFF
Status input #4 OFF
Relays
Relay #1 ON
Relay #2 ON
Relay #1 OFF
Relay #2 OFF
Phase Reversal
Positive phase rotation reversal
Negative phase rotation reversal
1-Cycle Values on any Phase
2
Notes
2-cycle response
2-cycle response
0x0E07
0x0E08
0x0E0A
0x1002
0x9002
0x1003
High voltage THD
EH
2-cycle
High current THD
EH
2-cycle
K-Factor
EH
2-cycle
High current TDD
EH
2-cycle
1-Cycle Auxiliary Values
High frequency
Low frequency
High voltage unbalance
53
Format Code
0x1004
0x1103
0x1104
0x1105
0x9103
0x9104
0x9105
Value
High current balance
1-Sec Phase Values
High I1 current
High I2 current
High I3 current
Low I1 current
Description
Low I2 current
Low I3 current
1-Sec Values on any Phase
0x1406
0x1407
0x1408
0x1409
0x1402
0x9404
0x9405
0x1501
0x1502
0x9502
0x1600
0x1601
0x1602
0x1603
0x1604
0x1605
0x1606
0x1608
0x1609
0x160B
1-Sec Total Values
High total kW import
High total kW export
High total kvar import
High total kvar export
High total kVA
Low total PF Lag
Low total PF Lead
1-Sec Auxiliary Values
High neutral current
High frequency
Low frequency
Present Demands
High V1/V12 Volt demand
High V2/V23 Volt demand
High V3/V31 Volt demand
High I1 Ampere demand
High I2 Ampere demand
High I3 Ampere demand
High block kW import demand
EH
High block kVA demand
EH
High sliding window kW import demand
EH
High sliding window kVA demand
EH
0x160F
0x1611
0x1612
0x1614
Setpoint Action ID
F14
Action type Target
High accumulated kW import demand
EH
High accumulated kVA demand
EH
High predicted kW import demand
EH
High predicted kVA demand
EH
0x30
0x30
0x31
0x31
0x40
0x00
0x01
0x00
0x01
0x00
Operate Relay #1
Operate Relay #2
Release latched Relay #1
Release latched Relay #2
Increment counter #1
0x40
0x40
0x40
0x44
0x44
0x01
0x02
0x03
0x00
0x01
Increment counter #2
Increment counter #3
Increment counter #4
Count operating time using counter #1
Count operating time using counter #2
0x44
0x44
0x02
0x03
Count operating time using counter #3
Count operating time using counter #4
Counter Source ID
F16 0x0000 None
0x0001-0x0004
Relay Output Pulse Source ID
F17
Pulse input DI1-DI4
0x0000 None
0x0400
0x0401
0x0403
0x0404 kWh import pulse
EH kWh export pulse
EH kvarh import pulse
EH kvarh export pulse
EH
0x0405 kvarh total pulse
EH pulse
EH
Notes
54
Format Code
AO Parameters ID
F18 0x0000
Value Description
None (output disabled)
1-Cycle Phase Values
1-Cycle Total Values
0x0F04
0x0F05
Total PF Lag
Total PF Lead
1-Cycle Auxiliary Values
0x1002 Frequency
1-Sec Phase Values
0x1100 V1/V12 Voltage
0x1101
0x1102
V2/V23 Voltage
V3/V31 Voltage
1-Sec Total Values
0x1404
0x1405
Total PF Lag
Total PF Lead
1-Sec Auxiliary Values
0x1502 Frequency
0x160F
0x1610
0x1611
0x161A
0x161B
Device Diagnostics
F23 Bit 0
Bit 1
Bit 2 = 1
Bit 3 = 1
Bit 4 = 1
Bit 5 = 1
Bit 6
Bit 7 = 1
Bit 8 = 1
Bit 9 = 1
Bit 10 = 1
Bit 11 = 1
Bit 12
Bit 13
Bit 14
Bit 15 = 1
DNP Object Types
F24
Demands
EH
Accumulated kW import demand
Accumulated kvar import demand
Accumulated kVA demand
Accumulated kW export demand
Accumulated kvar export demand
Reserved
Reserved
RAM/Data error
CPU watchdog reset
Sampling fault
CPU exception
Reserved
Software watchdog reset
Power down
Device reset
Configuration reset
RTC fault
Reserved
Reserved
Reserved
EEPROM fault
Static Binary Input Objects
Notes
2
55
Format Code
0
1
0
1
2
3
0
1
2
3
DNP Class 0 Objects
F25 0x1E01
0x1E02
0x1E03
0x1E04
0x2801
0x2802
0x0101
0x0102
0x0A01
0x0A02
0x1401
0x1402
0x1405
0x1406
Instrument Options
F28 Bit 0=1
Bit 1=1
Bits 2-5
Value
Bit 6=1
Bit 7=1
Bit 8=1
Bit 9=1
Bit 10=1
Bit 11=1
Bit 12=1
Bits 13-15
Bits 16-18
Bits 19-22
Bits 23-24
Bits 25-31
I/O Slot Types
F29
Single-Bit Binary Input
Binary Input With Status
Static Binary Counters
32-bit Binary Counter
32-bit Binary Counter Without Flag
16-bit Binary Counter
16-bit Binary Counter Without Flag
Static Analog Input Objects
32-bit Analog Input
32-bit Analog Input Without Flag
16-bit Analog Input
16-bit Analog Input Without Flag
Analog Input 30:01
Analog Input 30:02
Analog Input 30:03
Analog Input 30:04
Analog Output 40:01
Analog Output 40:02
Binary Input 01:01
Binary Input 01:02
Binary Output 10:01
DI DRY 00000000B
RO 00100000B
AI ±1 01010000B
Description
Binary Output Status 10:02
Binary Counter 20:01
Binary Counter 20:02
Binary Counter 20:05
Binary Counter 20:06
120V Option
690V Option
Reserved
Analog output 0/4 or 4/20mA
Analog output 0-1mA
Analog output ±1mA
RO option
DI option
Reserved
Setup is secured by a password (authorization required)
Reserved
Number of RO - 1
Number of DI – 1
Number of AO - 1
Reserved
AI 0-1 01010011B
11111111B
Notes
Empty slot
NOTES:
1
Analog Outputs
1) For bi-directional analog output ( ±1 mA), the zero scale setup corresponds to the center (0 mA) of the scale range, and the direction of the current matches the sign of the output parameter. Unsigned parameters are output within the current range 0 to +1 mA and can be scaled as in the case of single-ended analog output (0-1 mA).
For signed values, such as powers and signed power factor, the scale is always symmetrical with regard to 0 mA, and the full scale corresponds to +1 mA output for positive readings and to -1 mA output for negative readings. The zero scale (0 mA output) is permanently set in the instrument to zero for all parameters except the signed power factor for which it is set to
1.000 (see Note 2). In write requests, the zero scale is ignored.
56
2) Except for the signed power factor, the setup scale is continuous within the entire value range. For signed power factor, the setup scale is broken at +1.000 in order to provide continuous output current when the power factor changes close to ±1.000.
The setup scale is symmetrical in the range of -0 to +0 with a center at 1.000 (-1.000 is assumed to be equal to +1.000).
Negative power factor is output as -1.000 minus measured value, and non-negative power factor is output as +1.000 minus measured value. To set the entire range for power factor from-0 to +0, the scales would be specified as -0 to 0. Because of the fact that negative zero may not be transmitted through communications, the value of -0.001 is used to specify the scale of -0, and both +0.001 and 0.000 are used to specify the scale of +0.
2
Phase Reversal Trigger
The setpoint is operated when the actual phase sequence does not match the designated phase rotation order.
57
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