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AcuRev 1310 DIN-Rail Power Meter
User's Manual
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Copyright © 2020 V1.00
This manual may not be altered or reproduced in whole or in part by any means without the
expressed written consent of Accuenergy.
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www.accuenergy.com
The information contained in this document is believed to be accurate at the time of publication, however, Accuenergy assumes no responsibility for any errors which may appear here
and reserves the right to make changes without notice. Please ask the local representative for
latest product specifi ations before ordering.
Please read this manual carefully before installation, operation and maintenance of the
AcuRev 1310 series meter. The following symbols in this manual are used to provide warning
of danger or risk during the installation and operation of the meters.
Electric Shock Symbol: Carries information about procedures which must be
followed to reduce the risk of electric shock and danger to personal health.
Safety Alert Symbol: Carries information about circumstances which if not
considered may result in injury or death.
Prior to maintenance and repair, the equipment must be de-energized and grounded. All
maintenance work must be performed by qualifi d, competent accredited professionals who
have received formal training and have experience with high voltage and current devices.
Accuenergy shall not be responsible or liable for any damages or injuries caused by improper
meter installation and/or operation.
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Table of Contents
Chapter 1: Introduction ........................................................................8
1.1 Meter Overview ...................................................................................................... 8
1.2 Areas of Application ...............................................................................................9
1.3 Product Features ....................................................................................................9
Chapter 2: Installation .......................................................................... 8
2.1 Appearance and Dimensions ................................................................................ 13
2.2 Installation Methods ............................................................................................ 14
2.3 Wiring ................................................................................................................... 15
2.3.1 Terminals: ............................................................................................................. 17
2.3.2 Auxiliary Power Supply: ....................................................................................... 17
2.3.3 Voltage Input: ....................................................................................................... 18
2.3.4 Current Input: ....................................................................................................... 19
2.3.5 Relay Output Wiring Diagram ............................................................................. 26
2.3.6 Communication ................................................................................................... 27
Chapter 3: Operation and Application ................................................ 28
3.1 Display Panel and Keys .........................................................................................29
3.2 Display Mode and Key Operations ........................................................................ 30
3.2.1 Important parameter display mode: ................................................................... 30
3.2.2 All parameter display mode: ............................................................................... 30
3.3 Parameter Display and Key Operations ............................................................... 31
3.4 Settings and Operations: ......................................................................................34
3.4.1 Settings Mode ....................................................................................................... 34
3.5 Meter Conguration ............................................................................................. 37
3.5.1 Initial Setup .......................................................................................................... 37
3.6 Energy Pulse Output ............................................................................................ 38
Chapter 4 Functions and Software .....................................................42
4.1 Introduction to AcuRev 1310 Utility Software ...................................................... 42
4.2 Parameter Settings ............................................................................................... 44
4.2.1 Wiring Method & CT/PT Settings ......................................................................... 44
4.2.2 Reactive Power Calculation: ................................................................................ 45
4.2.3 Modbus Communication Options: ...................................................................... 45
4.2.4 Energy Pulse Output ............................................................................................ 46
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4.2.5 Demand ................................................................................................................ 47
4.2.6 Sealing Option ...................................................................................................... 48
4.2.7 Communication Permission ................................................................................ 49
4.2.8 Display Parameters .............................................................................................. 50
4.2.9 Energy Decimal Places & RO output mode: ........................................................ 51
4.3 Real-time Metering ............................................................................................... 51
4.4 Measurement Function ........................................................................................53
4.4.1 TOU Seasons ........................................................................................................ 55
4.4.2 Daylight Saving Time (DST) ................................................................................. 57
4.5 Event Logging ...................................................................................................... 58
4.6 Alarm Function ..................................................................................................... 60
4.6.1 Conguring the Alarm .......................................................................................... 62
4.6.2 Reading the Alarm ................................................................................................ 62
4.7 Incorrect Connection Detection ...........................................................................63
4.8 Sealing Function ..................................................................................................64
4.9 Device Information ............................................................................................... 67
Chapter 5: Communication.................................................................69
5.1 Modbus Protocol Information .............................................................................. 69
5.1.1. Transmission Mode ............................................................................................. 69
5.1.2. Frame ................................................................................................................... 69
5.2 Communication Format ......................................................................................70
5.3 Application Details ............................................................................................... 72
5.3.1 Data Types ............................................................................................................ 72
5.3.2 Relationship between Communication value and Real value ........................... 72
5.3.3 Parameter Address Table ..................................................................................... 73
5.4 BACnet Protocol Information ............................................................................. 104
5.4.1 BACnet Overview and Introduction .................................................................. 104
5.4.2 BACnet Protocol on the AcuRev 1310 Series Power ......................................... 105
5.4.3 Initializing BACnet Protocol on the AcuRev 1310 Meter ................................... 106
5.4.4 BACnet Objects ................................................................................................... 109
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Appendix .......................................................................................... 113
Appendix A – Functions List ..................................................................................... 113
Appendix B Technical Specications and Parameters ............................................. 114
Appendix C Revision History .................................................................................... 115
Appendix D Alarm Parameters Comparison Table ...................................................115
Appendix E Meter Event Flags: bit32 ........................................................................ 116
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Welcome to the AcuRev 1310!
You have purchased an advanced, versatile, multifunction power meter.
Please note the following chapter descriptions in order to utilize the power meter properly.
Chapter 1 introduces the basic AcuRev 1310 features and application areas.
Chapter 2 introduces the AcuRev 1310 installation and wiring methods in detail.
Chapter 3 walks through how to operate the AcuRev 1310 via the display panel, display
measurement data and parameter settings.
Chapter 4 introduces main functions with the included software.
Chapter 5 introduces communication related information, including communication pro-
tocol format and parameter address table.
Appendix provides AcuRev 1310 technical specications and ordering information.
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AcuRev 1310
DIN-Rail Power Meter
Chapter 1: Introduction
1.1 Meter Overview
1.2 Areas of Application
1.3 Product Features
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AcuRev 1310
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1.1 Meter Overview
The AcuRev 1310 series is a DIN rail-mounted, three phase energy meter that is small in size
with high accuracy. The meter is equipped with an easy to read liquid crystal display (LCD)
which conveys all the important data. It is ideal for building energy management systems, energy monitoring and energy metering systems.
Energy
The AcuRev 1310 series supports bi-directional active energy measurements, as well as twoway reactive power energy metering, and four quadrant reactive power energy metering. It
also supports apparent energy metering, the cumulative energy metering (Energy Import +
Energy Export), and net energy metering (input power - output power).
Measurement Function
The AcuRev 1310 series meters provides real-time RMS measurement of the instantaneous
Voltage, Current, Power, Frequency and Power Factor. All measurements can be viewed
through the meter display as well as the AcuRev 1310 Utility Software.
Demand
This product provides demand measurement of Current, Active Power, Reactive Power and
Apparent Power. It also provides demand forecasting as well as the peak demand.
DIN-Rail Power Meter
System Event Logging
The AcuRev 1310 series meter can record the time and event regarding important parameter
events.
• Run time of meter
Supports meter running time of measurements and events.
• Alarm function
Supports multiple parameter alarms, and can be congured to trigger Relay Output.
Communication
This meter supports Modbus RTU and BACnet MS/TP communication protocols, both over
serial RS485. The meter also has an infrared interface.
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1.2 Areas of Application
Chapter 1: Introduction
Large Commercial Center
School
Hotels and Buildings
Smart Building System
Industrial Environment
Rail Transport
Public Facilities
Smart Distribution Cabinet
Energy Management System
Energy Saving System
1.3 Product Features
Multifunction, high accuracy
AcuRev 1310 series meter has data collection and management for energy and multi-parameters measurement. It also features demand measurement and event logging.
The measurement accuracy of energy, power, voltage, and current is 0.5%.
Small size, convenient installation
The appearance and dimension of the AcuRev 1310 series meter is designed in accordance with the IEC 35mm DIN standard.
Clear Display
The AcuRev 1310 series features a clear display to provide visibility in all environments. All
measurement parameters can be found and easily accessed through the display. The LCD
display has backlight support that can aid users in weak lighting environments.
Safety
AcuRev 1310 series product has both an electronic and physical sealing function. It is designed is such a way that it cannot be opened without leaving signs of tampering. Users
cannot change the parameters through the display when the electronic sealing is closed,
and important parameters cannot be changed through communication, thus preventing
data or congurations from being altered.
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AcuRev 1310
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Convenient wiring
It supports both high voltage systems and low voltage systems, as well as both three-phase
three-wire systems and three-phase four-wire systems. Users can choose the appropriate
wiring conguration for the AcuRev 1310 series meter. The AcuRev 1310 series meter can be
used for single phase systems as well.
Wiring Check
The AcuRev 1310 series meter has a connection error feature that helps to reduce wiring
errors.
DIN-Rail Power Meter
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AcuRev 1310
DIN-Rail Power Meter
Chapter 2: Installation
2.1 Appearance and Dimensions
2.2 Installation Methods
2.3 Wiring
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AcuRev 1310
Before Installation
The installation must be performed by qualied, competent accredited professionals who has
received formal training and has experience with high voltage and current devices. Appropriate
safety wear (gloves, glasses, arc ush suit, etc.) is mandatory to ensure safe installation.
During normal meter operation, caution should be used when handling the following as high voltage may be present:
• Terminal Blocks
• Current/Potential Transformer leads and the related circuits
• All primary and secondary circuits may contain lethal current and voltage.
• Contact with current channels must be avoided.
The power meter and I/O modules cannot be installed on the primary side of transformers or
✓
where VA has limitations. The power meter can be only installed on the secondary side. Avoid
contact with meter terminals after the completion of installation.
Do not supply input voltage above the rated maximum limit of the power meter and devices
✓
connected to it. Before energizing the meter, please refer to the meters label and specications.
DIN-Rail Power Meter
Do not perform high voltage test or insulation experiments to output, input or communication
✓
terminals.
The use of shorting blocks and fuses are recommended. Current transformers need to be
✓
grounded (5A/1A).
Use dry cloth to wipe the meter.
✓
This chapter mainly describes the installation process of the AcuRev 1310 series meter, which is a
very important step in using the meter correctly. This chapter provides information and diagrams
about how to install the meter. Before installing the meter, please read through this section rst.
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Chapter 2: Installation
2.1 Appearance and Dimensions
Figure 2-1 AcuRev 1310 Front Display
90.0
108.0
35.5
7.0
62.5
Front View Side View
Figure 2-2 AcuRev 1310 meter Front and Side Dimensions
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Unit: mm
45.4
15.0
17.5
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AcuRev 1310
DIN-Rail Power Meter
2.2 Installation Methods
Note
Environmental
Before installation, please check the environment, temperature, and
humidity to ensure the AcuRev 1310 series meter is being placed in an
environment that are within temperature and humidity specications.
Temperature
AcuRev 1310 operating temperature is -25 ~ 75° C. Exceeding this temperature range will cause
damage to the meter and will aect the accuracy and functionality. Please note this can inuence the meters life negatively if the meter operates in extremely high or extremely low temperatures. AcuRev 1310 storage temperature range is from - 40 to 85° C.
Humidity
5% to 95% non-condensing.
Location
AcuRev 1310 series meter should be installed in a dry and dust free environment. Avoid exposing the meter to excessive heat, radiation and high electrical noise sources.
Installation Steps:
This product is DIN railed mounted and ts on a standard 35mm rail.
Temperature and humidity
of the environment must
accord with the requirement of AcuRev 1310,
Otherwise it may cause
the meter damaged.
1. To install the meter on the rail insert the top of the rail into the groove on the back of the meter. Pull the metal clips back and slide the rail across the groove of the meter.
Figure 2-3 Step A
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Chapter 2: Installation
2. Use the metal clips to tighten onto the rail to complete installation.
Figure 2-4 Step B
2.3 Wiring
The terminals of the AcuRev 1310 series can be accessed by rst removing the terminal covers
on the meter.
1. To open the terminal cover, remove the seal if applicable, and then unscrew the sealing
screws and lift the cover upwards to remove.
Figure 2-5 Removing terminal cover
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AcuRev 1310
2. To attach the bottom terminal cover back onto the meter, place the left side of the cover
down into the groove rst and then press down onto the right side, see Figure 2-6. When installed correctly, you will hear a clicking sound. To attach the top cover place the right side of
the cover down into the groove and press down onto the left side.
3. 3. After inserting the cover, tighten the sealing screws and place the seal.
DIN-Rail Power Meter
Figure 2-6 Attaching terminal cover onto meter
Figure 2-7
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Chapter 2: Installation
2.3.1 Terminals:
This manual uses V1, V2, V3 to represent three-phase conductors, which would be the same as
Va, Vb, Vc in other manuals.
ABS
R1 R2 P1 P2
Figure 2-8 AcuRev 1310 Series Terminals
• Communications Terminal: A, B, S
• Pulse Output: P1, P2
• Auxiliary Power: L, N
• Voltage Inputs: V1, V2, V3, VN
• Current Inputs: I11, I12, I21 I22, I31, I32, I41, I42
• Relay Output: R1, R2
2.3.2 Auxiliary Power Supply:
I11 I12 I21 I22 I31 I32 I41 I42
SET
L N V1 V2 V3 VN
The AcuRev 1310 series requires a power supply of 100-415 Vac at 50/60Hz or 100-300 Vdc. For
use of other power supply voltage selections please contact the manufacturer. The meter typi-
cally has small power consumption (less than 1W) so the power supply can be an independent
power supply, or can also be obtained from the circuit under test.
It is suggested that under the condition that the power voltage uctuation is large, to use a voltage stabilizer. The power supply terminals respectively are: L, N.
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AcuRev 1310
The typical auxiliary power wiring is as follows:
DIN-Rail Power Meter
1A FUSE
Power Supply
Figure 2-9 Power Supply Connections for Acurev 1310
The meter requires AWG22-16 as the wires to connect the power supply.
A fuse (typical 1A/250Vac) is suggested to be used when connecting the power supply to the meter.
Note: Check the power supply rating before wiring. Please conrm by reading the Power Supply
information on the silver sticker at the side of the meter.
L
N
AcuRev 1310
2.3.3 Voltage Input:
The maximum input voltage for the AcuRev 1310 series meter cannot exceed 400LN/690LL VAC
RMS for three phase or 400LN VAC rms for single phase. The voltage input requires a 1A fuse.
Potential Transformer (PT) must be used for high voltage systems that are greater than the meters rated voltage. The rated secondary output from the PT is typically 100-120V. Please make
sure to select an appropriate PT to maintain the measurement accuracy of the AcuRev 1310
series meter. When connecting using the WYE conguration wiring method, the PT's rated input
or primary side rated voltage should be equal to or close to the phase voltage of the system to
utilize the full range of the PT being used. When connecting using the Delta conguration wiring
method, the PT's rated input or primary side rated voltage should be equal to or close to the line
voltage of the system.
A fuse rated for 1A/600V should be used when connecting the voltage inputs to the meter.
The meter requires the wire size to be AWG22-14.
Note: Under no circumstances should the secondary of the PT be shorted. The secondary of
the PT should be grounded at one end. Please refer to the wiring diagram section for further
details.
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Chapter 2: Installation
2.3.4 Current Input:
Current Transformers (CTs) are required in most applications. The AcuRev 1310 series meter
supports four CT input types, 5A/1A, 333mV, Rogowski coil (RCT) and mA (80/100/200). CTs must
be used if the systems rated current is over 5A. The CT should be selected to maintain revenue
grade accuracy of the system. The distance between CT and the meter should be as short as
possible as the length of the CT leads will have an eect on the accuracy.
The meter requires AWG22-14 as the wire size to the current input terminals.
Note: The secondary side of the CT should not be open circuit in any circumstance when the
power is on. There should not be any fuse or switch in the CT loop. One end of the CT loop
should be connected to the ground when 5A/1A output CTs.
When using mV, RCT and mA CT's the secondary leads must not be grounded.
Vn Connection
Vn is the reference point of the AcuRev 1310 series meter voltage input. Low wire resistance
helps improve the measurement accuracy. Dierent system wiring modes require dierent Vn
connection methods. Please refer to the wiring diagram section for more details.
AcuRev 1310 series meter supports dierent wiring congurations for both three phase and single phase systems. Please read this section carefully before choosing the suitable wiring method for your power system.
In the AcuRev 1310 series meter please make sure that the wiring connection mode and the corresponding practical application in engineering are correct to ensure the measurement accuracy of meter. Here are some of the common installation methods, their respective diagrams and
meter congurations for the AcuRev 1310 series meter.
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AcuRev 1310
1) Three Phase: 4 wire-connection: (Three Phase with a neutral)
Wiring mode 3LN. Three CT's needed for this connection.
Common voltages for this connection: 120V LN/208V LL, 240V LN/415V LL
DIN-Rail Power Meter
LINE
ABCN
1A FUSE
Terminal Block
LOAD
Figure 2-10a – AcuRev 1314 3LN wiring diagram using 5A/1A CTs
Note: AcuRev 1314-RCT current input does not support neutral current measurement
LINE
ABCN
LOAD
1A FUSE
Terminal Block
I11
I12
I21
I22
I31
I32
I41
I42
I11
I12
I21
I22
I31
I32
I41
I42
VNV3 V2 V1
AcuRev 1310
VNV3 V2 V1
AcuRev 1310
Figure 2-10b – Acurev 1311, 1312, 1313 3LN wiring diagram using 5A/1A CTs
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Chapter 2: Installation
LINE
ABCN
1A FUSE
Terminal Block
1
I11
2
I12
3
I21
4
I22
5
I31
6
I32
10 9 8 7
VNV3 V2 V1
AcuRev 1310
LOAD
Figure 2-10c 3LN using 333mV, mA and Rogowski Coil CTs
2) Three Phase: 3 wire-connection (Three phase without a neutral)
The wiring mode is set to 2LL. Two CT's needed for this connection.
Note: Output of the CT is 5A/1A and mA.
With Potential Transformers (PTs) - PTs are required if the system voltage is higher than
690V LL. Instead of connecting the voltage lines directly to the meter, the voltage lines are
connected to the meter using PTs. The PTs should be connected as shown below.
Note: Only two PTs are needed for this connection
LINE
ABC
Terminal Block
LOAD
1A FUSE
I11
I12
I21
I22
I31
I32
I41
I42
VNV3 V2 V1
AcuRev 1310
Figure 2-11a 2LL wiring diagram using 5A/1A CTs and PTs
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AcuRev 1310
DIN-Rail Power Meter
LINE
ABC
1A FUSE
Figure 2-11b 2LL using 333mV, mA and Rogowski Coil CTs
Direct Connection, without PT's:
LOAD
LINE
ABC
LOAD
Terminal Block
1A FUSE
Terminal Block
I11
I12
I21
I22
I31
I32
I41
I42
I11
I12
I21
I22
I31
I32
I41
I42
VNV3 V2 V1
AcuRev 1310
VNV3 V2 V1
AcuRev 1310
Figure 2-11c – 3LN– 3 phase delta no neutral wiring diagram using 5A/1A CTs
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Chapter 2: Installation
LINE
ABC
1A FUSE
Terminal Block
1
2
3
4
5
6
10 9 8 7
I11
VNV3 V2 V1
I12
I21
I22
I31
I32
AcuRev 1310
LOAD
Figure 2-11d – 3LN– 3 phase no neutral wiring diagram using 333mV, mA and Rogowski Coil CTs.
3) Single Phase: 3 Lines (Single phase with 2 lines and a neutral)
The wiring mode is set to 1LL. Two CT's needed for this connection.
Common Voltage: 120V LN/240V LL
LINE
ANB
LOAD
1A FUSE
Terminal Block
I11
I12
I21
I22
I31
I32
I41
I42
VNV3 V2 V1
AcuRev 1310
Figure 2-12a 1LL wiring diagram using 5A/1A and CT's
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AcuRev 1310
4) Single Phase: 2 Lines (Single phase with one line and a neutral)
The wiring mode is set to 1LN. One CT needed for this connection.
Common Voltage for this connection: 120V
DIN-Rail Power Meter
LINE
ANB
LOAD
Figure2-12b 1LL Using 333mV, mA and Rogowski Coil CTs
LINE
AN
1A FUSE
1A FUSE
I11
I12
I21
I22
I31
I32
I41
I42
VNV3 V2 V1
AcuRev 1310
Terminal Block
LOAD
Figure 2-13a - AcuRev 1314 Model 1LN using 5A/1A CT
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I11
I12
I21
I22
I31
I32
I41
I42
VNV3 V2 V1
AcuRev 1310
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Chapter 2: Installation
LINE
AN
1A FUSE
Terminal Block
I11
VNV3 V2 V1
I12
I21
I22
AcuRev 1310
I31
I32
I41
I42
LOAD
Figure 2-13b – AcuRev 1311, 1312, 1313 Model 1LN using 5A/1A CT
LINE
AN
1A FUSE
Terminal Block
10 9 8 7
I11
VNV3 V2 V1
I12
I21
I22
AcuRev 1310
I31
I32
LOAD
Figure 2-13c 1LN using 333mV, mA and Rogowski Coil CT
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AcuRev 1310
2.3.5 Relay Output Wiring Diagram
DIN-Rail Power Meter
220Vac
R1
Relay
Output
R2
L
Auxiliary Power
V+
Figure 2-14 Relay Output Wiring Diagram
Supply
GN
com
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Chapter 2: Installation
2.3.6 Communication
The AcuRev 1310 supports two dierent,
Modbus-RTU and BACnet MS/TP. Modbus RTU is the factory default setting on the meter. Both
protocols utilize the built-in RS485 port, which is located under the terminal cover on the front
of the meter. The RS485 terminals are denoted as “A”, “ B,” and “S”. “A” is the positive dieren-
tial terminal, 'B' is the negative dierential terminal, and 'S' is for connecting the shield of the
shielded twisted pair cable.
The maximum distance of the cable should not exceed 1200m. This distance should be shorter if
more devices are connected to the same communication link or if using a higher baud rate.
If the master device is equipped with an RS232 port instead of an RS485 port, an RS232-toRS485 converter should be utilized.
In order to improve communication quality, note the following:
• A high-quality Shielded Twisted Pair cable is very important; AWG22 (0.6mm
recommended.
• Pay attention to "single-point earthing.” This means that there is only one side for the
shield to be connected to the ground in a communication link.
• Every A (+) should be connected to A (+) and every B (-) should be connected to B (-). Failure to make the proper connections can inuence the network or even damage the communication interface.
• “T” type connection topology should be avoided. This means no new branches except
from the starting point.
• Keep communication cables as far away as possible from sources of electrical noise.
user-selectable, communication
2
protocols:
) or lower is
• When several devices are connected in daisy chain to the same long communication line,
a resistor (typical value 120- 300 Ohm, 0.25W) should be used at the end of the circuit (the
last device of the chain).
• Only use RS232-to-RS485 or USB-to-RS485 converters with an optically isolated output
and surge protection.
Chapter 3: Operation and Application
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AcuRev 1310
DIN-Rail Power Meter
3.1 Display Panel and Keys
3.2 Display Mode and Key Operations
3.3 Parameter Display and Key Operations
3.4 Settings and Operations
3.5 Meter Conguration
3.6 Energy Pulse Output
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Chapter 3: Operation & Application
In this chapter, users will be introduced to the interface of the AcuRev 1310 meter as well as how
to interact with the meter using the key on the display to read and congure parameters.
3.1 Display Panel and Keys
The AcuRev 1310 meter consists of a built-in LCD screen and a key (SCROLL key) for users to interact with the meter. Figure 3.1.1 shows the display of the AcuRev 1310 with all characters and
number segments visible as a visual example only, they would not appear on one page. These
symbols are explained in Table 3.1.
1
2
3
9
8
4
NO. Content Description
1 Description Area
Measurement parameter display area 7
2
segments can be displayed.
3 Indicates All information mode.
4 Communication Icon
5 Load size icon
6 Four- quadrant reactive power display
7
8 Load type
9 unit Unit of the parameter being displayed.
6
5
7
Figure 3.1.1
Table 1- Display icons
To display what kind of parameter in the display
area. To distinguish the power of conjunction,
split phase, current, demand, parameter Settings, and so on.
To display the main measurement parameters:
Energy, Voltage, Current, Power, Frequency,
Demand, Settings, Time.
No icon: No communication;
One icon: Query sent;
Two icons: Query sent and response received
Displaysin the analog way according to the load
frequency
Indicates the rst to fourth quadrant reactive
power.
Import icon(right arrow): Displays the energy
consumed Export icon(left arrow) displays the
energy generated
Inductance icon: Inductive load Capacitor icon:
Capacitive load
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AcuRev 1310
3.2 Display Mode and Key Operations
The LCD display of the AcuRev 1310 meter consists of three display modes:
• Important Parameter Display
• All Parameters Display
• Settings mode.
By default, the important parameter display shows the Consumed Active Energy (kWh) parameter.
3.2.1 Important parameter display mode:
The important parameter display mode is the default display mode of the meter. It will display
the measurement parameters of the AcuRev 1310 series meter. Users only see the Consumed
Active Energy (kWh) parameter unless additional parameters are added through the settings
mode.
Users will be in this mode when they power on the meter or when they push the “SCROLL”
key after a period of inactivity. Each measurement parameter in this mode will display on the
screen for 6 seconds. When the “SCROLL” key is pressed in this display mode it will lock the current page for a minute and the backlight will remain on. Pressing the “SCROLL” key again will
turn the next page and lock the display for another minute. After one minute of inactivity the
display will continue operating normally by cycling through the enabled measurement parameters.
DIN-Rail Power Meter
3.2.2 All parameter display mode:
The all parameters display will show all the parameters that the AcuRev 1310 meter supports as
well as information about the meter. Pressing and holding the “SCROLL” key from the important parameter display mode will direct the user to the all parameter display mode. In this mode
there will be a displayed on the bottom row of the display to indicate the AcuRev 1310 is in all
parameters display mode.
Pressing the "SCROLL" key will turn to the next page in the display. Once the user has cycled
through all the parameters, pressing the "SCROLL" key again will take the user back to the rst
page.
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3.3 Parameter Display and Key Operations
The following tables show the All Parameters Display for the dierent AcuRev 1310 Series Meters.
Table 3-2 All Parameters Display for AcuRev 1311
Page Parameter
1 Voltage Wiring Check
2 Current Wiring Check
3 Meter Address
4 Hardware Version
5 Software Version
6 Date of Issue
7 Model Number
8 Imported Active Energy
9 Consumed Active Energy Phase A(kWh)
10 Consumed Active Energy Phase B(kWh)
11 Consumed Active Energy Phase C(kWh)
12 Voltage Phase A(V)
13 Voltage Phase B(V)
14 Voltage Phase C(V)
15 Current Phase A(A)
16 Current Phase B(A)
17 Current Phase C(A)
18 Total Current(A)
19 Total System Active Power
20 Active Power Phase A(kW)
21 Active Power Phase B(kW)
22 Active Power Phase C(kW)
23 Frequency(Hz)
24 Temperature
25 Meter Run Time
26 Load Run Time
--- End
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AcuRev 1310
DIN-Rail Power Meter
Table 3-3 All Parameters Display for AcuRev 1312
Page Parameter
1 Voltage Wiring Check
2 Current Wiring Check
3 Device Address
4 Baud Rate
5 Parity
6 Hardware Version
7 Software Version
8 Release Date
9 Model
10 Consumed Active Energy(kWh)
11 Consumed Active Energy Phase A(kWh)
12 Consumed Active Energy Phase B(kWh)
13 Consumed Active Energy Phase C (kWh)
14 Phase A Voltage(V)
15 Phase B Voltage(V)
16 Phase C Voltage(V)
17 Phase A Current(A)
18 Phase B Current(A)
19 Phase C Current(A)
20 Total Current(A)
21 System Active Power(kW)
22 Active Power Phase A(kW)
23 Active Power Phase B(kW)
24 Active Power Phase C(kW)
25 Frequency(Hz)
26 Temperature
27 Meter run time
28 Load run time
--- End
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Table 3-4 All Parameters Display for AcuRev 1313
Page Parameter
1 Voltage Wiring Check
2 Current Wiring Check
3 Device Address
4 Baud Rate
5 Parity
6 Hardware Version
7 Software Version
8 Release Date
9 Model
10 Consumed Active Energy(kWh)
11 Consumed Active Energy Phase A(kWh)
12 Consumed Active Energy Phase B(kWh)
13 Consumed Active Energy Phase C (kWh)
14 Phase A Voltage(V)
15 Phase B Voltage(V)
16 Phase C Voltage(V)
17 Phase A Current(A)
18 Phase B Current(A)
19 Phase C Current(A)
20 Total Current(A)
21 System Active Power(kW)
22 Active Power Phase A(kW)
23 Active Power Phase B(kW)
24 Active Power Phase C(kW)
25 Frequency(Hz)
26 Temperature
27 Meter run time
28 Load run time
--- End
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AcuRev 1310
DIN-Rail Power Meter
Table 3-5 All Parameters Display for AcuRev 1314
Page Parameter
1 Voltage Wiring Check
2 Current Wiring Check
3 Device Address
4 Baud Rate
5 Parity
6 Hardware Version
7 Software Version
8 Release Date
9 Model
10 Consumed Active Energy(kWh)
11 Consumed Active Energy Phase A(kWh)
12 Consumed Active Energy Phase B(kWh)
13 Consumed Active Energy Phase C (kWh)
14 Phase A Voltage(V)
15 Phase B Voltage(V)
16 Phase C Voltage(V)
17 Phase A Current(A)
18 Phase B Current(A)
19 Phase C Current(A)
20 Total Current(A)
21 System Active Power(kW)
22 Active Power Phase A(kW)
23 Active Power Phase B(kW)
24 Active Power Phase C(kW)
25 Frequency(Hz)
26 Temperature
27 Meter run time
28 Load run time
--- End
3.4 Settings and Operations:
3.4.1 Settings Mode
The settings mode is where the user can perform most congurations for the AcuRev 1310 meter. To enter the settings press the “SET” key which is located under the meters terminal cover.
Next the user will be prompted by a password screen.
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To input the user password, users will use the “SCROLL” key to change the value of the ashing
digit. The “SET” key is used to move between digits and to conrm the entered password when
on the last digit.
After entering the correct password, the AcuRev 1310 will direct users to the device address con-
guration of the meter.
Note: Users will be redirected back to the important parameters screen after entering the password if the physical/electronic seal is enabled.
In the setting mode there will be an “S” in the top row followed by the setting page number.
After a minute of inactivity in this mode, the meter will be redirected back to the important pa-
rameter display. If the “SCROLL” key is pressed and held, the meter will also be redirected out
of the settings mode.
Note: The default password of the meter is 0000.
Note: The ‘SET’ key is located under the meters terminal cover.
In the settings mode, the following operations apply for the keys:
The “SET” key is used to enter edit mode of the setting and to conrm the setting change.
The “SCROLL” key is used to move to the next setting page and to change the value of the set-
ting when in edit mode.
The following tables will show the Setting Display for the dierent AcuRev 1310 Series Meters.
Table 3-6 Setting Display for AcuRev 1311
Page Parameter Range
1 Device Address 1-247
2 Password 0000-9999
3 Real Time Metering Mode 1: Primary 2: Secondary
4 Voltage Wiring 3LN; 1LL; 1LN; 2LL
5A/1A(5A Current Input)
5 CT2
6 CT1 1~50,000
7 PT2 50~400
8 PT1 50~1000000
9 Pulse Constant 1~60000
10 Pulse Width 20~100ms
11 Energy Decimal Places 0-3
12 Custom Data Display: Add
80mA/100mA/200mA(mA Current Input)
333mV
RCT
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AcuRev 1310
Page Parameter Range
13 Custom Data Display: Remove
14 Wiring Check On; O
Page Parameter Range
1 Device Address 1-247
2 Baud Rate 1200;2400;4800;9600;19200;38400
3 Parity Even, Odd, None2, None1
4 Energy Pulse Output P: Real Energy; Q:Reactive Energy
5 Reactive Power Calculation 0:True; 1:Generalized
6 Password 0000-9999
7 Real-time reading mode 1: Primary; 2: Secondary
8 Wiring conguration 3LN; 1LN; 1LL;2LL
9 CT2
10 CT1 1~50,000
11 PT2 50~400
12 PT1 50~1000000
13 Pulse Constant 1~60000
14 Pulse Width 20~100ms
15 Energy Decimal places 0-3
16 Custom data display: Add
17 Custom data display: Remove
18 Wiring check enable On; O
DIN-Rail Power Meter
Table 3-7 Setting Display for AcuRev 1312
5A/1A(5A Current Input)
80mA/100mA/200mA(mA Current Input)
Table 3-8 Setting Display for AcuRev 1313
Page Parameter Range
1 Device Address 1-247
2 Baud Rate 1200;2400;4800;9600;19200;38400
3 Parity Even, Odd, None2, None1
4 Energy Pulse Output P: Real Energy; Q:Reactive Energy
5 Reactive Power Calculation 0:True; 1:Generalized
6 Password 0000-9999
7 Real-time reading mode 1: Primary; 2: Secondary
8 Wiring conguration 3LN; 1LN; 1LL;2LL
9 CT2
10 CT1 1~50,000
11 PT2 50~400
12 PT1 50~1000000
13 Pulse Constant 1~60000
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5A/1A(5A Current Input)
80mA/100mA/200mA(mA Current Input)
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Chapter 3: Operation & Application
Page Parameter Range
14 Pulse Width 20~100ms
15 Energy Decimal places 0-3
16 Custom data display: Add
17 Custom data display: Remove
18 Wiring check enable On; O
3.5 Meter Conguration
3.5.1 Initial Setup
The AcuRev 1310 series meters need to be congured correctly in order for it to measure data
accurately.
For the initial meter setup, the wiring mode, PT and CT ratios need to be congured on the meter. Here are the steps to set these up from the meter display. Users must ensure that the lower
terminal cover of the meter has been removed in order to gain access to the “SET” button.
• Once the terminal cover is removed, press the “SET” key to enter the settings mode.
• Users will then be prompted by a password screen. You can leave the password as its de-
fault value of “0000” if no password was previously congured. If a password was congured use the “SCROLL” and “SET” keys to enter in the password.
• The next screen that will appear is the “S-0-1 Addr”
• Press the “SCROLL” key until you get to the “S-08 Lt” screen(S-04 if AcuRev 1311). Select
the correct voltage wiring mode. This will be based on your voltage connection. For example if your voltage connection is a three phase 4 wire connection, the correct voltage wiring
mode would be 3LN.
• Press “SET” to enter edit mode.
• Press “SCROLL” to select the wiring mode.
• oPress “SET” to conrm the setting.
Note: Refer to Section 2.3 Wiring for more details about wiring congurations.
• Press the “SCROLL” key to move to the CT2 page. This setting should already be congured
to the secondary value of the CT. After this is conrmed, press the “SCROLL” key to move
to the next page.
• The ensuing page will be “S-10” for setting the primary rating of the CT. If no CT's are being
used, leave this as the default value and press “SCROLL” to move to the next page. If CT’s
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AcuRev 1310
are being used, enter in the primary rating of the CT here.
• Press “SET” to enter the edit mode and to move to the next digit.
• Press “SCROLL” to change the value of the digit.
• Press “SET” to conrm the setting and move to the next page.
• The next page will correspond to the PT2 setting. If no PT’s are being used, leave this set-
ting as the default and press the “SCROLL” key to go to the next page. If you are using PT’s,
enter the secondary value of the PT here.
• Press “SET” to enter the edit mode and to move to the next digit.
• Press “SCROLL” to change the value of the digit.
• Press “SET” to conrm the setting and move to the next page.
• The next page will be “S-12” for the primary rating of the PT if it is being used.
• Press the “SET” key to enter edit mode and to move to the next digit.
• Press the “SCROLL” key to change the value of the digit.
• Press the “SET” key to conrm the setting and move to the next page.
Once all of the initial meter congurations are set, the meter should now begin to read data correctly.
3.6 Energy Pulse Output
DIN-Rail Power Meter
The AcuRev 1310 series supports the transmission of energy pulses through the P1 and P2 terminals of the meter. The AcuRev 1310 series uses a two-wire pulse train to transmit test pulses
that are proportional to the accumulated energy that the meter is measuring.
The maximum output voltage and current of the pulse output circuit in the AcuRev 1310 series
is 250V and 100mA respectively.
Conguration
Ensure that the following congurations in the meter are correct to make certain the accuracy of
the meter.
• Wiring Mode
• CT2
• CT1
• PT2
• PT1
To check these settings refer to section 3.5 in the meter congurations section of the manual.
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With the above settings conrmed to ensure the meter will measure the voltage and current
accurately, the next step is to congure the meter to output the desired number of pulses
based on the required specication.
Make certain that you are in the settings mode. To get into the settings mode follow the procedure in section 3.5 of the manual.
• Once in the “Settings” mode, press the “SET” key to get to the “S-04 PULSE” page. This
conguration is to enable the meter to output pulses based on the Active Energy (P) or
the Reactive Energy (Q).
• Press the “SET” key to modify the setting; the cursor should now ash.
• Press the “SCROLL” key to select the type of energy to output.
• Press the “SET” key to conrm the selection.
• Press the “SCROLL” key to get to the “S-13 Pn” page. This conguration will represent the
number pulses (Pulse Constant) the meter will output per kWh/kvarh. This will be based
on the required specication.
• Press the “SET” key to modify; the rst digit will begin to ash.
• Press the “SET” key to move to the next ashing digit.
• Press the “SCROLL” key to change the ashing digit’s number.
• Press the “SET” key on the last digit to conrm all the changes after they have been
made.
The following calculations can be used in order to calculate the value in the meter for the DO
Pulse constant:
• First you will need to determine how many pulses are needed to represent 1 kWh or how
many kWh will represent 1 pulse.
• In this procedure, we will assume that 1 pulse = 10kWh is what is needed. Then follow
these steps:
• Multiply the PT ratio and CT ratio i.e. PT1/PT2 * CT1/CT2.
Example: PT ratio of 6600V/120V, CT ratio of 2000:5A => 6600/120 * 2000/5 = 22,000.
Note: if no PTS were used, then enter the PT ratio as the default on the meter, i.e. 400/400. If
the CT2: 333mV, RCT or 80/100/200mA, consider this as 1A for the calculation.
• Divide 10kWh by 22,000 i.e. (10/22000) kWh = (1/2200) kWh.
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AcuRev 1310
• This means that 1 pulse = (1/2200)kWh, therefore 2200 pulses = 1kWh
• Since we get 2200 pulse/kWh, enter 2200 as the pulse constant into the meter
• Press “SCROLL” to get to the “S-14 PH” page. This conguration will represent
DIN-Rail Power Meter
the pulse width of the pulse that the meter will output. Put in the pulse width
for the pulse output. The range is 20-100ms.
Pulse Output Wiring
Figure 3-2 Pulse Output Wiring Diagram
24V Supply
+
Ω
P2
P1
1k
-
-Pulse Counter
+Pulse Counter
• A 24V DC supply is required to power the circuit and should be connected to the P2 terminal of the meter.
• A 1 kilo ohm resistor is suggested to be used in series to limit the current to the P2 terminal
(refer to Figure 3-2 above).
• The P1 terminal is connected to the positive terminal of the pulse counter.
• The negative terminal of the 24V DC supply is connected to the negative of the pulse counter.
With the pulse output circuit and settings congured the pulse output can be tested. Inject the
meter with both voltage and current to ensure that the meter will accumulate energy and also
output the pulses based on the above settings.
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AcuRev 1310
DIN-Rail Power Meter
Chapter 4 Functions Functions and Software
4.1 Introduction to AcuRev 1310 Utility Software
4.2 Parameter Settings
4.3 Real Time Metering
4.4 Measurement Function
4.5 Event Logging
4.6 Alarm Function
4.7 Incorrect Connection Detection
4.8 Sealing Function
4.9 Device Information
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AcuRev 1310
This chapter will introduce you to using some important functions. Many advanced functions
cannot be performed through the meters display. Due to this we made the AcuRev 1310 Utility
software. This chapter will introduce you to some of the software’s functions.
Note: Only the AcuRev 1312, 1313 and 1314 can be connected through the AcuRev 1310 Utility
Software. The AcuRev 1311 is not supported.
4.1 Introduction to AcuRev 1310 Utility Software
The AcuRev 1310 series meters can be accessed through the AcuRev 1310 Utility Software. The software can
be downloaded from the Accuenergy website under Downloads, or using the following link: https://accuener-
gy.com/page/support/download-manuals-datasheets-software-rmware
The software can be used to read the meters measurements or to congure the meters settings. To connect to
the software a USB-RS485 converter must be used.
Note: The AcuRev 1310 Utility Software is a Windows based software.
The following details the steps to connect the meter to the computer with the USB-RS485 converter.
To connect the following two wires should be connected from the USB-RS485 converter to the meter:
1) T/R+ from the converter to “A” on the AcuRev 1310 series meter
2) T/R- from the converter to “B” on the AcuRev 1310 series meter
DIN-Rail Power Meter
The following gure shows the two wire connections.
RS485-to-USB Converter
T/R+ T/ R- RXD+ RXD-
42
Figure 4-1 Connecting USB-RS485 converter to AcuRev 1310 Series Meter.
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GND VCC
Comm Port
A
B
S
Power Meter
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Chapter 4: Functions and Software
The Communication Port (COM Port) that the meter is connected to on the computer can be
found from the “Device Manager” in Windows.
Use the following steps to get to the Device Manager on your Windows computer:
1. Open the Windows Start Menu.
2. Right Click on Computer and select Properties.
3. In the window that appears, select Device Manager from the left navigation panel.
4. In the Device Manager window, double click o Ports (COM&LPT) from the dropdown list.
5. Locate the USB Serial Port (COMx) information where the x is the port number to use.
For example COM3.
Once the COM Port is found make note of it as it is used to connect to the software.
Once the software has been opened, users will be prompted to enter the correct COM port of the
computer, baud rate, parity, the device address of the meter, and the device type (AcuRev 1312,
1313, 1314). Enter the settings and click ‘OK’ to connect the meter to the software.
Note: The baud rate, parity, and device address must be the same on the meter as well as the
AcuRev Utility Software.
The following gure shows the screen when you rst open AcuRev 1310 Utility Software.
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AcuRev 1310
4.2 Parameter Settings
The AcuRev 1310 series meters requires general settings so that the meters can work according
to the correct specication. The general settings can be found by clicking on the “Settings”
menu on the main menu toolbar and selecting “General Settings” on the top menu bar of the
software. The gure below shows the General Settings.
DIN-Rail Power Meter
Figure 4-3 General Settings in the AcuRev 1310 Utility Software
Note: To ensure that any modications in the General Settings takes place you must click on
“Update Device” on the bottom of the General Settings page.
4.2.1 Wiring Method & CT/PT Settings
Users will need to select the correct “Wiring Method” (refer to section 2.3 for details). Users will
also need to set the PT and CT ratio according to the practical use, if not set correctly this can
lead to inaccurate measurements . “CT1” is the rated input of the CT being used, and “PT1”
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and “PT2” correspond to the PT ratio of the PT used. The gure below shows these mentioned
settings in the red boxes.
Figure 4-4 the Wiring Method and CT/PT settings in the General Settings
4.2.2 Reactive Power Calculation:
Real Reactive: Q= √ (S^2+P^2+D^2 )
Generally Reactive: Q= √ (S^2+P^2 )
4.2.3 Modbus Communication Options:
At the very top of the General Settings page users can congure the meters address, baud rate
and parity for communication with the meter through Modbus. The red box in Figure 4-5 shows
how it is displayed in the AcuRev 1310 Utility Software.
Figure 4-5 Meter address, baud rate, and meter parity settings on AcuRev 1310 Utility software
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AcuRev 1310
4.2.4 Energy Pulse Output
The AcuRev 1310 series supports the transmission of the pulses through the P1 and P2 terminals
of the meter.
Active: P1, P2 terminal output pulse is based on the active energy pulse.
Reactive: the output pulse is based on the reactive power pulse.
You can see in the red box of the gure below the conguration for the Energy Pulse Output.
DIN-Rail Power Meter
Figure 4-6 the Energy Pulse Output in the General Settings
The user will also have to enter the requirements for the pulse in the “Pulse Constant” and “Pulse
Width” elds. The “Pulse Constant” is the number of pulses the user needs one pulse to represent in kWh/kvarh. The user can enter a value from 1-60000 for the pulse constant. The “Pulse
Width” of the pulse is the duration it will last for. The user can enter a value from 20-100ms in
this eld. The gure below shows this in the red box.
Figure 4-7 the Pulse Constant and Pulse Width in the General Settings
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4.2.5 Demand
Demand supports four kinds of calculation modes:
• Sliding Block Method
Set a 1-30min window time, which is the calculation time of demand. The window slides once
per minute and updates the demand value at this time.
• Fixed Block Method
Set 1-30min as a demand calculation cycle. The whole cycle calculates the demand once. This
means that the demand update time is equal to the demand calculation cycle.
• Rolling Block Method
Set 1-30min as a demand calculation cycle and 1 slip time. The demand cycle must be integer
multiples of the slip time. It calculates 1 cycle’s demand at the end of the slip time. The demand update time is equal to the slip time.
• Thermal Demand Method
Set 1-30min as a calculation cycle. In the whole cycle, the demand is calculated just once.
This means that the demand update time is equal to the demand calculation cycle.
You can see the Demand calculations in the red box of the gure below. Under the dropdown
menu in “Compute Mode” is where you can nd the four dierent methods mentioned above.
Figure 4-8 the Demand Calculation Modes in the General Settings of AcuRev1310 Utility Software
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AcuRev 1310
To View the demand parameter display click on ‘Readings’ on the main menu toolbar and then
select ‘Demand’. Figure 4-9 shows the Demand display.
4.2.6 Sealing Option
DIN-Rail Power Meter
Figure 4-9 Demand Parameters Display
• Choosing the “Device Clock + TOU related”, the corresponding content (Device Clock, TOU
parameters, Daylight saving time parameters) can be sealed.
• Choosing “Run-time and Load-time” the content of the run and load time will be sealed.
• Choosing “Communication” the content of communication time will be sealed.
Note: To change the corresponding time it must occur once the seal is open.
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The gure below shows the Sealing Options in the red box for the AcuRev 1310 Utility Software.
Figure 4-10 the Sealing Options in the General Settings
4.2.7 Communication Permission
The communication permission is divided into two settings either “low permission” or “high
permission”.
• Low Permission: The important operations disabled. These operations include clear
demand event record, programming event record, open cover event record, meter, energy
data, and initial energy data.
• High Permission: This setting supports all functions.
Note: In the low permission you can update to high permission through updating the commu
-
nication permission. After 30 minutes of updating to high permission, the meter would lower its
permission to “low permission” automatically, to keep the meters safety.
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AcuRev 1310
The gure below shows the Communication Permission in the red box.
Figure 4-11 Communication Permission in the General Settings of the AcuRev 1310 Utility Software
4.2.8 Display Parameters
The user can add more parameters through the AcuRev 1310 Utility Software. Depending on
the parameters chosen you will be able to view these parameters on the display by pressing
the “SCROLL” key.
The gure below shows the Display Scan Parameters in the red box.
DIN-Rail Power Meter
Figure 4-12 the Display Scan Parameters in the General Settings
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4.2.9 Energy Decimal Places & RO output mode:
This setting is to change the number of decimal places in which the energy is read.
The RO (Relay Output) mode can be congured to control output or alarm output. The output can be congured according to the practical application.
You can see in the following gure the setting for the energy decimal place and RO output in
the red box.
Figure 4-13 RO and Energy Decimal places in General Settings
4.3 Real-time Metering
Once connected successfully to the software, users will see the data readings appear in blue
font beside each measurement parameter as shown in gure 4-14.
All metering parameters can be found by clicking on ‘Readings’ from the main menu toolbar
and select ‘Real-Time Metering’.
Figure 4-14 Real-Time Metering in the AcuRev 1310 Software
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AcuRev 1310
Users can also access the energy consumption by clicking on the “Readings” menu and selecting “Energy1”. You can refer to Figures 4-15 and 4-16 for assistance.
DIN-Rail Power Meter
Figure 4-15 Navigating to Energy Readings
Figure 4-16 Energy Readings Page
Users will see all the energy that the meter has accumulated since the life of the meter or since
the last time the energy readings were reset or cleared.
The lower half of the Energy1 page displays the consumed active energy readings that have
been accumulated under the Time of Use (TOU) function of the meter.
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Note: The Time of Use (TOU) function is only available on the AcuRev 1312, 1313, and 1314
models.
With the Time of Use function users can select the time period of the TOU energy as the current
month, previous month or the past two months.
Users can also provide initial values for their AcuRev 1310 series models (only 1312, 1313, and
1314 applicable) to start to accumulate energy from. To do this, users must have sucient permission, which can be obtained from the General Settings page.
4.4 Measurement Function
AcuRev 1310 series provides measurement of bi-directional energy accumulation. Real time
energy can be initialized by changing the permission and sealing condition. The energy parameters supported:
Consumed Active Energy
Generated Active Energy
Total Active Energy
Net Active Energy
Consumed Apparent Energy
Generated Apparent Energy
These parameters can be located on the Energy 2 Readings page, which can be found on the
‘Readings’ menu and selecting ‘Energy 2’. Figure 4-17 show how this will look on the AcuRev
1310 Utility Software.
Figure 4-17 Energy 2 Readings Page
Four-quadrant Reactive Energy
Consumed Reactive Energy
Generated Reactive Energy
Total Reactive Energy
Net Reactive Energy
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AcuRev 1310
Note: The following settings for TOU (Time of Use) is only applicable to only certain AcuRev
1310 models which includes AcuRev 1312, 1313, and 1314 models.
TOU Settings
Users can assign up to 4 dierent taris (sharp, peak, valley and normal) to dierent time periods within the day according to the billing requirements.
The meter will calculate and accumulate energy in dierent taris according to the meters internal clock timing and TOU settings.
The following gure shows the Time of Use Setting Display Page.
DIN-Rail Power Meter
Figure 4-19 Time of Use Settings Page
TOU schedules can be congured up to 14 time segments, where each season can have its own
TOU schedule. The user can customize the TOU calendar (including its taris, seasons, schedules and segments) according to dierent applications. To make sure that the TOU calendar is
setup correctly, the meter will check the TOU settings according to the predened rules (see
below for “TOU Parameter Settings” for details). The TOU function will be disabled if the TOU
calendar is set up incorrectly. If no errors are found in the calendar and the TOU function is enabled, TOU energy accumulation will commence.
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TOU Parameter Settings:
a. Season Settings: The maximum number of Seasons is 14, where each Season can have its
own TOU schedule.
Note: The seasons should be entered as an integer from 1-14 and should also be entered in
chronological order.
b. Schedule Settings: You can have a maximum of 8 schedules, where each schedule can be di-
vided up into 14 time segments.
c. Segment Settings: You can have a maximum of 14 segments, where each segment can have
its own tari.
d. Tari setting: There is a maximum of 4 taris. The four taris are sharp, peak, valley, and
normal. They are represented by number 1-4 respectively (1: sharp, 2: peak, 3: valley, 4: nor-
mal). If the parameter is set as 2 then only the rst 2 taris (sharp and peak) will be available.
e. Weekend Settings: In this section you can set up the schedule number according to week-
ends to assign a weekend schedule. Refer to Figure 4-20.
Figure 4-20 Weekend Setting in TOU congurations page
f. Holiday Setting: You can set up to a maximum of 30 holidays
Note: If the holiday and weekend schedule number is set as 0, it means holidays are un
available. If the weekend and holidays are overlapped, the holiday overrides the weekend
settings since the holiday has a higher priority.
4.4.1 TOU Seasons
Fill in the appropriate slots in the TOU (Time of Use) Seasons based on the number in the
“Season Settings”. If the “Season Settings” is set to 2 then only the rst 2 slots of the “TOU
Seasons” must be lled in.
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AcuRev 1310
Note: If the slot is lled inappropriately then the TOU function will be disabled
• The start date into the TOU Season slot is in the following format: “MM-DD-ID”
• MM stands for month
• DD stands for date
• ID represents the TOU schedule (1-8)
Note: The dates should be organized in chronological order (The earliest date comes rst and
the later date follows). Entering the dates in the wrong order will cause the TOU function to be
disabled
Holidays
Fill in the appropriate slots under the “Holidays” setting based on the number in the “Holiday
Setting”. If the “Holiday Setting” is set as 3 then only the rst 3 slots of the “Holidays” must be
lled in otherwise the TOU function will be disabled.
• Enter the date of the Holiday in the Holiday schedule slot in the following format “MM-DD-ID”
• MM stands for month
• DD stands for date
• ID represents the TOU schedule(1-4)
Note: The dates of the Holiday schedules do not need to be organized in chronological order.
DIN-Rail Power Meter
TOU Schedules
Each TOU schedule is represented by a 24 hour cycle. Fill in the appropriate slots in the TOU
schedule based on the number in the “Schedule Settings”. If the “Schedule Setting” is set as 8
then all of the “TOU Schedules” must be lled in.
The amount of slots to ll in each TOU Schedule depends on the “Segment Setting” parameter.
If the “Segment Setting” parameter is set as 3 then the rst 3 slots in each TOU Schedule must
be set, otherwise the TOU function will be disabled.
• Enter the start time into the TOU Schedule slot in the following format “HH-MM-ID”
• HH stands for hour in 24 hour format
• MM stands for minutes
• ID represents the tari to follow (1-8)
The time should be organized in chronological order (The earliest time comes rst and the later
time follows).
Note: Entering the time in the wrong order will cause the TOU function to be disabled
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4.4.2 Daylight Saving Time (DST)
There are two types of formats that the Daylight Savings Time can be enabled as:
1. Fixed date option:
If you choose a xed date option, you set the format according to a xed date for the DST
switch, in the format of month/ day/ hour/ minute/ adjust time (in minutes).
2. Non-Fixed date option: If you choose the non-xed option, the DST will be implemented by
which day of the week, with the format as month/ which day/ which week/ hour/ minute/ adjust time (in minutes).
Setting the DST will cause the meter to automatically switch to and from daylight savings time.
When the clock starts to run on daylight saving time, the meter will automatically adjust its
clock to a time period in advance. While the clock is running to the end of daylight saving the
meter will adjust its clock back to a pervious time period.
Note: Make sure to Click “Update Device” after making any changes in order to save the set
tings. If no errors are found then the TOU energy accumulation will begin.
Figure 4-21 Daylight Saving Time Setting on AcuRev 1310 Utility Software
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AcuRev 1310
4.5 Event Logging
The AcuRev 1310 series supports event logging of important parameters and operation. The
Event logging page can be found by clicking on the ‘Readings’ menu and selecting ‘Event Log’.
Figure 4-22 shows how the Event Log will look in the AcuRev 1310 Utility Software.
DIN-Rail Power Meter
Figure 4-22 Event Log Page
The events that are logged include:
• Event of Program
This event records the programming time and programming event. When a programming
event occurs several times within 5 minutes, the meter only records the rst time.
Programming Flag Programming Event
01 Meter address programming event
02 RS485 communication programming event
03 Reserved
04 Reserved
05 Energy pulse programming event
06 Demand related programming event
07 Reactive calculation method programming event
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08 VAR/PF statue programming event
09 Change time programming event
100 Change energy base programming event
101 TOU parameter programming event
102 Daylight saving time programming event
103 Trend record programming event
• Event of Clear Demand
Figure 4-23 Event of Program in AcuRev 1310 Utility Software
The meter will record when the Demand parameters are cleared. It records up to 3 groups of
Clear Demand Events.
Figure 4-25 Event of Opening Meter Cover in AcuRev 1310 Utility Software
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• Event of Clear Meter
In the Event of Clear Meter, it shows when the meter has had any data cleared. It supports 3
groups of meter clearance events.
4.6 Alarm Function
The alarm function is used to monitor specic parameters, and when these parameters exceed a
certain preset time limit, the event alarm will be triggered and stored in the AcuRev 1310 Utility
Software. There can be a maximum of 20 records stored in the alarm log. To access the Alarm
Settings click on “Settings” from the toolbar menu and then select “Alarm Settings”.
DIN-Rail Power Meter
Figure 4-26 Event of Clear Meter 4.6 Alarm Function
To set up the alarms, users must rst select an alarming parameter, a condition, a delay time
(ms), and an alarming output. Users can set a maximum of 12 alarms. Figure 4-27 shows you
the Alarm Settings.
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Figure 4-27 Alarm Settings Page on AcuRev 1310 Utility Software
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4.6.1 Conguring the Alarm
• Enable the alarm function by checking o the “Alarm Enabled” box.
• Enable the preferred alarm channel(s) by checking o the “Alarm Enabled” box next to the
channel.
• Under the “Alarm Channel” column select the parameter from the Real-time metering.
• Choose the required setting or condition for the alarm i.e. greater than (>), equal to (=), or
less than (<).
• Enter the set point, where the set point is expressed by a percentage of the rated value.
• Enter in the desired Delay (ms) before alarm is triggered.
• Select the “Output Enabled” box if using a RO channel to be triggered when an alarm event
occurs.
Note: Make sure to click on “Update Device” after making any changes in order to save the set-
tings to the meter.
4.6.2 Reading the Alarm
To read the alarm log on the AcuRev 1310 Series Utility Software you click on the ‘Readings’
menu and select ‘Alarm Log’. The alarm log can be seen in Figure 4-28.
DIN-Rail Power Meter
Figure 4-28 Alarm Log on AcuRev 1310 Series Utility Software
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Referring to Figure 4-28, we can see that the alarm log features the time stamp which provides
the time and date the alarm was triggered. The log also identies which parameter was triggered (current, voltage, etc), and has a column for the value of Break Over which tells the user
the amount they went over/under for that particular alarm setting. The last column of the alarm
log is the status column. The alarm log can store up to 20 groups of alarm events.
4.7 Incorrect Connection Detection
The AcuRev 1310 series meter has a connection detection function. This function detects the
connections or wiring to the meter based on the wiring mode conguration.
Table 4-2 Connection Detection
Bit15 Bit14 Bit13 Bit12 Bit11 Bit10 Bit9 Bit8
Reserve Phase
Voltage A
Missing
Bit7 Bit6 Bit5 Bit4 Bit3 Bit2 Bit1 Bit0
Reserve Phase
Current
A Wrong
Direction
Phase
Voltage B
Missing
Phase
Current
B Wrong
Direction
Phase
Voltage C
Missing
Phase
Current
C Wrong
Direction
Reserve Phase Volt-
age A Wrong
Connection
Reserve Phase
Current
A Wrong
Connection
Phase Volt-
age B Wrong
Connection
Phase
Current
B Wrong
Connection
Phase Volt-
age C Wrong
Connection
Phase
Current
C Wrong
Connection
The very rst screen in the All Parameters Display (see section 3.3 for details) is the voltage wiring check. On the LCD display, it will be in the following format:
U XXXXXX, where X is either ‘1’ or ‘0
• ‘0’ represents the connection is correct
• ‘1’ represents the connection is incorrect.
On the meter display digits 1~3 (from left to right) are would represent if a phase is not connected; Phase A Voltage missing, Phase B Voltage missing, Phase C Voltage missing. Digits 4~6 represent Phase A Voltage, Phase B, Phase C voltage being connected incorrectly.
The second screen in the All Parameters Display (see section 3.3 for details) is the current wiring
check. On the meter display, it will be in the following format:
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• ‘0’ represents the connection is correct
• ‘1’ represents the connection is incorrect
On the meter display digits 1~3 (from left to right) represent Phase A CT, Phase B CT, Phase C
CT being in the reverse direction . Digits 4~6 represent Phase A CT, Phase B CT, Phase C CT being
connected incorrectly.
4.8 Sealing Function
The AcuRev 1310 series meter supports a sealing function. When the seal is open, the read write
functions are available. When the seal is closed some of the meters functions which include
parameters and optional parameters will be blocked and limited. These parameters can still be
accessed by keys communication, but cannot be modied (Write function not available when
seal is closed) when sealed status is present.
Address 209H corresponds to parameters blocked by the seal, which can be congured by users
through communication. These settings will be valid only when the seal is in sealed status.
From 101H, we can check if the sealing state is opened or closed. When the seal status is open
the address displays open sealing state. When the seal status is closed, the address displays
closed sealing state, and the corresponding content will be blocked.
DIN-Rail Power Meter
I XXXXXX, where X is either ‘1’ or ‘0’
Note: ‘X’ means that these addresses will be blocked for keys and communication, and
‘- ‘means this function is unavailable.
Seal Standard Content:
Table 4-3 Seal Standard Content
Address Parameter Description Communication Key
203H Pulse Quantity choice X X
204H Demand Calculation X 205H Demand Calculation Cycle X 206H Slip Time Demand Calculation X 207H Reactive Power Calculation Method X X
208H VAR/PF Convention X 209H Seal Optional Content X 213H Remove Electric Meter Data (Except Demand Data) X 216H Measurement Side X X
217H Wiring Mode X X
218H CT2 X X
219H CT1 X X
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Address Parameter Description Communication Key
220H PT2 X X
222H~223H PT1 X X
224H Pulse Constant X X
225H Pulse Width X X
226H Energy Decimal Places X X
Energy:
Table 4-4
Modbus Address (HEX) Parameter Description Communication Key
900H-901H Total Active Energy X 902H-903H Total Active Energy Tari 1 X -
904H-905H Total Active Energy Tari 2 X -
906H-907H Total Active Energy Tari 3 X -
908H-909H Total Active Energy Tari 4 X -
91AH-90BH Net Active Energy X 90CH-90DH Net Active Energy Tari 1 X -
90EH-90FH Net Active Energy Tari 2 X 910H-911H Net Active Energy Tari 3 X 912H-913H Net Active Energy Tari 4 X 914H-915H Import Active Energy X 916H-917H Import Active Energy Tari 1 X 918H-919H Import Active Energy Tari 2 X 91AH-91BH Import Active Energy Tari 3 X -
91CH-91DH Import Active Energy Tari 4 X -
91EH-91FH Export Active Energy X 920H-921H Export Active Energy Tari 1 X 922H-923H Export Active Energy Tari 2 X 924H-925H Export Active Energy Tari 3 X 926H-927H Export Active Energy Tari 4 X 928H-929H Total Reactive Energy X 92AH-92BH Total Reactive Energy Tari 1 X -
92CH-92DH Total Reactive Energy Tari 2 X -
92EH-92FH Total Reactive Energy Tari 3 X -
930H-931H Total Reactive Energy Tari 4 X -
932H-933H Net Reactive Energy X 934H-935H Net Reactive Energy Tari 1 X 936H-937H Net Reactive Energy Tari 2 X 938H-939H Net Reactive Energy Tari 3 X 93AH-93BH Net Reactive Energy Tari 4 X -
93CH-93DH Import Reactive Energy X -
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AcuRev 1310
Modbus Address (HEX) Parameter Description Communication Key
93EH-93FH Import Reactive Energy Tari 1 X -
940H-941H Import Reactive Energy Tari 2 X 942H-943H Import Reactive Energy Tari 3 X 944H-945H Import Reactive Energy Tari 4 X 946H-947H Export Reactive Energy X 948H-949H Export Reactive Energy Tari 1 X 94AH-94BH Export Reactive Energy Tari 2 X -
94CH-94DH Export Reactive Energy Tari 3 X -
94EH-94FH Export Reactive Energy Tari 4 X -
950H-951H Apparent Energy X -
Sealed Nonstandard Parameters
Address Parameter Communication Key
300H Clock: Year X X
301H Clock: Month X X
302H Clock: Date X X
303H Clock: Hour X X
304H Clock: Minute X X
305H Clock: Second X X
306H Clock: Week X X
DIN-Rail Power Meter
Table 4-5
Note: When the seal is closed, standard time is valid within plus or minus 5 minutes, it will be
invalid if not in this range.
Table 4-6
Address Parameter Description Communication Key
TOU Related Parameters
402H-40EH
420H-5F3H
Daylight Saving Time Related Parameters
350H-367H
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Time-Division Energy Setting
Parameter 1
Time-Division Energy Setting
Parameter 2
Daylight Saving Time Related
Parameters
X -
X -
X -
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4.9 Device Information
All the information regarding the meter can be found by clicking on the “Readings” on the main
menu toolbar and selecting “Device Information”. Figure 4-3 shows the Device Information
page.
Figure 4-29 Device Information Page
Device Information such as hardware and software version of the meter can be found on this
page. The Serial number and the seal status can also be located here. It is important to note
that when the Seal Status is set to “Closed”, the user will be unable to make any congurations
to the meter.
Users can also congure the device clock of the meter from this page to the time of the computer the meter is connected to or give it any other specic time.
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Chapter 5: Communication
5.1 Modbus Protocol Information
5.2 Communication Format
5.3 Application Details
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Chapter 5: Communication
This chapter introduces users on how to communicate with the AcuRev 1310 Series meter
through the Modbus communication protocol. Knowledge of the Modbus communication pro-
tocol would be benecial for users who read this chapter.
The chapter’s contents include the Modbus protocol, communication format, and application
of the AcuRev 1310 series meter.
5.1 Modbus Protocol Information
5.1.1. Transmission Mode
The mode of transmission denes the data structure within a frame and the rules used to transmit data.
Coding System 8 bit
Start Bit 1 bit
Data Bits 8 bit
Parity No parity/ odd parity/ even parity
Stop bit 1 bit or 2 bit
Error checking CRC
5.1.2. Frame
When the data frame reaches the AcuRev 1310 series meter (slave device), the meter removes
the data frame’s header, and reads the data. If there is no error, then the meter will implement
the data’s task. Once the task is completed, the meter will put its own data with the acquired
header and send back the frame to the master device that queried the meter. The response
data frame contains the address, function, data and CRC check. An error will cause the response to fail.
Table 5-1 Data Frame Format
Address Function Data Check
8-Bits 8-Bits N x 8-Bits 16-Bits
Address Field
The address eld is the data at the start of the frame. It is composed of 8 bits (1 byte) and corresponds to the device address. It has a decimal value ranging from 1-247.
The master device addresses the slave device by placing the slave device address in the address
eld of the message. When the slave sends its response, it places its own address in the address eld of response to let the master know which slave is responding.
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Function Field
When a query is sent from the master to a slave device, the function code led tells the slave
what kind of action to perform.
Function Code Meaning Action
03 Read Holding Register Obtain current value of 1 or more registers
16 Preset register Set value of 1 or more register
01 Reading Relay RO Status Get the current state of the relay of the RO
05 Control relay RO state Control relay RO Output state (ON/OFF)
Data Field
The data eld contains the data that the slave device needs in order to complete the request.
This data may be a numerical value, address or settings. For example, the function code tells
the slave device to read one register, however the data eld species readings from which register and how many registers to read.
Error Check Field
This eld allows for error checks to be performed by both master and slave devices. Sources of
errors such as electrical noise and other interferences can cause the data to be changed while
it is being transmitted from one device to another. The error check ensures that the master or
slave devices do not respond to the distorted data during the transmission. The error check rule
used is the bit Cyclic Redundancy Check (CRC16).
DIN-Rail Power Meter
Table 5-2 Function Code
Output (ON/OFF)
5.2 Communication Format
Table 5-3 Protocol Illustration
Addr Fun
06H 03H 00H 00H 00H 21H 84H 65H
Data start
register hi
Addr: Slave device address
Fun: Function code
Data start register hi: High byte of starting register address
Data start register lo: Low byte of starting registers address
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Data start
register lo
# of regis-
ters hi
# of regis-
ters lo
CRC16 Hi CRC16 Lo
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Chapter 5: Communication
Data # of registers hi: High byte of number of registers
Data of # of registers lo: Low byte of number of registers
1. Read Data (Function Code 03H)
This function code allows the user to obtain the measurement data from the AcuRev 1310 series
meter.
Below is an example of a query for reading three of the AcuRev 1310 series energy parameters.
The query is requesting the total active energy, tari 1 active energy and tari 2 active energy
from the meter device address of 17. The data type of the energy parameters are double words.
The data for each parameter will be in 2 registers where each register contains 2 bytes. The registers for the parameters to be polled in this example are 900H-901H, 902H-903H and 904H-905H
respectively.
Query:
Table 5-4 Query frame of Reading Energy
Addr Fun
Data start
register hi
Data start
register lo
# of regis-
ters hi
# of regis-
ters lo
CRC16 Hi CRC16 Lo
11H 03H 00H 00H 00H 21H 84H 65H
Response:
The AcuRev 1310 series responds back to the master’s query by responding with its slave device,
function code, data and CRC check.
Below is the response from the AcuRev 1310 series meter for returning the total active energy
(1.27kWh), tari 1 energy (1.00 kWh) and tari 2 energy (0.27kWh). When the values are returned
to Modbus, they need to be scaled. The relationship for the energy data between the real value
and he communication value is:
Real value = Communication value/100
Table 5-5 Response of Total Active Energy, Total Active Energy Tari 1 Total, Active Energy Tari 2
Addr Fun Byte
Count
Data 1 hiData 1
low
Data 2 hiData 2
low
Data 3 hiData 3
low
Data 4 hiData 4
low
11H 03H 0CH 00H 00H 00H 7FH 00H 00H 00H 64H
Value hi Value lo Value hi Value lo CRC16 hi CRC16 lo
00H 00H 00H 1BH 96H 8DH
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AcuRev 1310
2. Preset/Reset Multi-Registers (Function Code 10H)
Function code 10H allows the user to write the contents of meters registers such as system parameters and energy initialization.
Below is an example on writing a value to the meters total active energy (0.2kWh).
Table 5-6 Preset Energy Data
DIN-Rail Power Meter
Addr Fun Byte Count Data start
register hi
11H 10H 0CH 09H 00H 00H 00H 02H
Value hi Value lo Value hi Value lo CRC16 hi CRC16 lo
00H 00H 00H 14H CDH 30H
Data start
register lo
# of regis-
ters hi
#of regis-
ters lo
Byte Count
5.3 Application Details
5.3.1 Data Types
The data types supported by the AcuRev 1310 series meter have the following meanings:
Bit-binary value
Word-16 bit unsigned integer using one register that contains 2 bytes. The data range is
0-65535.
Int16-16 bit signed integer using one register that contains 4 bytes in total. The high bytes
follow the low bytes in this data type. The data range is 0-4294897295.
Int32- 32 bit signed integer using two registers that contains 4 bytes in total. The data range
is from 327698~32767.
Float-Single precision floating point number using two registers. The data range is2147483648~22147483647.
5.3.2 Relationship between Communication value and Real value
The measurement values from the AcuRev 1310 series meter obtained through Modbus
may not always be equal to the real value. The values may be scaled or a relationship may
need to be applied.
Note: It is very important that the user is aware of these relationships when designing programs to poll the meter, otherwise the values may not be accurate.
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Table 5-7 the relationship between communication value and real value
Parameter Relationship Unit
System Parameter settings and
Status
Real-time Clock, Timestamps
Electrical measurement parame-
ters
PT1 & PT2 Real = Communication/10 ----
Meter run time & Load time Real = Communication/10 Hours
5.3.3 Parameter Address Table
Model 2, 3, 4 represents AcuRev1312, AcuRev 1313, and AcuRev 1314 respectively.
Read only block
03H- read command
The communication value equals
the real value
The communication value equals
the real value
Electrical measurement parame-
Table 5-8 Meter Running State Display
----
----
ters unit
MODBUS Address
Hex Decimal
100H 256
101H 257 Seals Status Word R
Parameter
Description
The Result of
Wiring Check
Data
Type
Word R
Access
Property
System Parameter
System parameters decides the devices working mode.
10H- read command
03H- write command
Range Default Model
Refer to Appendix
“The Result of
Wiring Check”
0x0A: Seal sealed
Others: Seal
opened
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Register
Number
1
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DIN-Rail Power Meter
Table 5-9 System Parameters Address Table
MODBUS Address
Hex Decimal
200H 512
201H 513 Baud Rate Word R/W
202H 514 Parity Bit Setting Word R/W
203H 515
204H 516
205H 517
206H 518
207H 519
208H 520 VAR/PF Word R/W
209H 521
20AH 522
20BH 523 Password Word W
20CH 524
Parameter
Description
Meter
Address
Energy Pulse
Output Type
Demand Calculation Method
Demand Calculation Period
Demand Calculation Slipping
Time
Reactive Power
Calculation
Method
Sealed Parameters Selection
Communication
Revise Operation
Authority
New Password Word W
Data
Type
Word R/W 1-247 1 2~4 1
Word R/W
Word R/W
Word R/W 1-30 minutes 15 2~4 1
Word R/W 1-30 minutes 1 2~4 1
Word R/W
Word R/W
Word R/W
Access
Property
Range Default Model
1200; 2400; 4800; 9600; 19200;
38400
0: Even parity
1: Odd parity
2: No parity, Stop Bit 2
3: No parity, Stop Bit 1
0: Active Power
1: Reactive Power
0: Sliding Window
1: Fixed Window
2: Rolling Window
3: Thermal
0: True (sinusoidal)
1: Generalized (harmonics present)
0:IEC
1:IEEE
Bit0: TOU set is Sealed or Not
1: valid of corresponding
Selection
0: invalid of corresponding selection
0x02: Meter Reset, Event Reset,
Write Energy Data
0x04: write Data(except Energy
Data), Demand Peak reset
Note: Register Revise needs
correct Password, incorrect
password is invalid.
0000-9999
Used for revise Communication
Operation Authority, verify password when get new password
0000-9999
Note: To get new password needs
correct current password, incorrect current password in invalid.
Register
Number
19200 2~4
3
0 2~4 1
0 2~4 1
0 2~4 1
0 2~4 1
0 2~4 1
0 2~4 1
2~4 1
2~4 1
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Bit0: Reset Demand Record
Bit1: Reset Event Record
Bit2: Reset System Event Record
Bit3: Reset Meter Opening Record
Bit4: Reset Demand Event
Bit5: Reset Alarm Event
Bit6: Reset Meter Operation Time
Bit7: Reset Time of Meter Opera-
20DH 525
20EH 526
20FH 527
210H 528
211H 529 Wiring Mode Word R/W
212H 530 CT2 Value Word R/W 1; 5; 100; 200; 333
213H 531 CT1 Value Word R/W 1~50000/5~50000 5 2~4 1
214H 532 CTN Value Word R/W 1~50000/5~50000 5 4 1
215H 533 PT2 Value Word R/W
216H
-217H
218H 536
219H 537
21AH 538
21BH 539
21CH 540
Meter Data Reset Word W
Optional Display
Symbol 1
Optional Display
Symbol 2
Parameter Measurement Side
534
PT1 Value Word R/W
-535
Energy Pulse
Constant
Energy Pulse
Width
Energy Display
Decimal
Relay Operating
Mode
Connection Detection Enable
Word R/W
Word R/W
Word R/W
Word R/W 1-60000 5000 2~4 1
Word R/W 20-100 ms 80 2~4 1
Word R/W 0,1,2,3 1 2~4 1
tion with Load
Bit8: Reset Meter Record (Reset
Energy record, demand peak and
happening time record, system
event record, etc)
0:Reset
1: NO
Note: Reset not valid without
Communication Revise Operation Authority
Please see Appendix “Optional
Display Symbol Setting”
0: Primary Side
1: Secondary Side
0:3LN
1:2LL
2:1LL
3:1LN
50.0~400.0 (Communication value is 10 times of the real value)
50.0~999999.9 (Communication
Value is 10 times of the real
value)
0: Relay Control
1: Alarm Output
0: No Enable
1: Enable
2~4 1
2~4 1
2~4 1
0 2~4 1
0 2~4 1
Accord-
ing to
the order
0 2~4 1
1 2~4 1
2~4 1
220.0 2~4 1
220.0 2~4 2
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DIN-Rail Power Meter
Table 5-10 Real Time Reading Parameters
MODBUS Address
Hex Decimal
2000H-2001H 8192-8193
2002H-2003H 8194-8195 Phase A Current oat R 2
2004H-2005H 8196-8197 Phase B Current oat R 2
2006H-2007H 8198-8199 Phase C Current oat R 2
2008H-2009H 8200-8201 Phase Average Voltage oat R 2
200AH-200BH 8202-8203 Phase A Voltage oat R 2
200CH-200DH 8204-8205 Phase B Voltage oat R 2
200EH-200FH 8206-8207 Phase C Voltage oat R 2
2001H-2011H 8208-8209 Line Average Voltage oat R 2
2012H-2013H 8210-8211 Line AB Voltage oat R 2
2014H-2015H 8212-8213 Line BC Voltage oat R 2
2016H-2017H 8214-8215 Line CA Voltage oat R 2
2018H-2019H 8216-8217 Frequency oat R 2
201AH-201BH 8218-8219 Total Active Power oat R 2
201CH-201DH 8220-8221 Phase A Active Power oat R 2
201EH-201FH 8222-8223 Phase B Active Power oat R 2
2020H-2021H 8224-8225 Phase C Active Power oat R 2
2022H-2023H 8226-8227 Total Apparent Power oat R 2
2024H-2025H 8228-8229 Phase A Apparent Power oat R 2
2026H-2027H 8230-8231 Phase B Apparent Power oat R 2
2028H-2029H 8232-8233 Phase C Apparent Power oat R 2
202AH-202BH 8234-8235 Total Reactive Power oat R 2
202CH-202DH 8236-8237 Phase A Reactive Power oat R 2
202EH- 2
202FH 8238-8239 Phase B Reactive Power oat R 2
2030H-2031H 8240-8241 Phase C Reactive Power oat R 2
2032H-2033H 8242-8243 Power Factor oat R 2
2034H-2035H 8244-8245 Phase A PF oat R 2
2036H-2037H 8246-8247 Phase B PF oat R 2
2038H-2039H 8248-8249 Phase C PF oat R 2
203AH-203BH 8250-8251 Phase Angle V1/V1 oat R 2
203CH-203DH 8252-8253
203EH-203FH 8254-8255
Parameter
Total Current oat R 2
Phase Angle of V2 to V1
V1/V2
Phase Angle of V23 to
V12
V12/V23
Phase Angle of V3 to V1
V1/V3
Phase Angle of V31 to
V12 V12/V31
Data
Property Range Default
Type
oat R 2
oat R 2
registers
# of
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Chapter 5: Communication
Phase Angle of I1 to V1
2040H-2041H 8256-8257
2042H-2043H 8258-8259
2044H-2045H 8260-8261
1208H-1209H 4616-4617
120AH-120BH 4618-4619
120CH-120DH 4620-4621
120EH-120FH 4622-4623 Phase A Current Demand Float R 2
1210H-1211H 4624-4625
1212H-1213H 4626-4627
V1/I1
Phase Angle of I1 to V12
V12/I1
Phase Angle of I2 to V1
V1/I2
Phase Angle of I2 to V12
V12/I2
Phase Angle of I3 to V1
V1/I3
Phase Angle of I3 to V12
System Active Power
Demand
System Reactive Power
Demand
System Apparent Power
Demand
Phase B Current Demand
Phase C Current Demand
V: 1.0 Revised: Oct. 20
Energy: Function Code: 03H to Read; 10H to Write
Table 5-11 Real Time Energy Parameters
oat R 2
oat R 2
oat R 2
20
oat R 2
oat R 2
Float R 2
Float R 2
Float R 2
MODBUS Address
Hex Decimal
2046H-2047H 8262-8263
2048H-2049H 8264-8265
204AH-204BH 8266-8267
204CH-204DH 8268-8269
204EH-204FH 8270-8271
2050H-2051H 8272-8273
2052H-2053H 8274-8275
2054H-2055H 8276-8277
Parameter
Total Active Energy
Exported
Total Active Energy
Exported Phase A
Total Active Energy
Exported Phase B
Total Active Energy
Exported Phase C
Total Active Energy
Imported
Total Active Energy
Imported Phase A
Total Active Energy
Imported Phase B
Total Active Energy
Imported Phase C
Data
Property Range Default
Type
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
V: 1.0 Revised: Oct. 2020
# of
registers
2
2
2
2
2
2
2
2
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MODBUS Address
Hex Decimal
2056H-2057H 8278-8279
2058H-2059H 8280-8281
205AH-205BH 8282-8283
205CH-205DH 8284-8285
205EH-205FH 8286-8287
2060H-2061H 8288-8289
2062H-2063H 8290-8291
2064H-2065H 8292-8293
2066H-2067H 8294-8295
2068H-2069H 8296-8297
206AH-206BH 8298-8299
206CH-206DH 8300-8301
206EH-206FH 8302-8303
2070H-2071H 8304-8305
2072H-2073H 8306-8307
2074H-2075H 8308-8309
2076H-2077H 8310-8311
2078H-2079H 8312-8313
207AH-207BH 8314-8315
207CH-207DH 8316-8317
207EH-207FH 8318-8319
2080H-2081H 8320-8321
2082H-2083H 8322-8323
2084H-2085H 8324-8325
DIN-Rail Power Meter
Parameter
Total Apparent Power
Exported
Total Apparent Power
Exported Phase A
Total Apparent Power
Exported Phase B
Total Apparent Power
Exported Phase C
Total Apparent Power
Imported
Total Apparent Power
Imported Phase A
Total Apparent Power
Imported Phase B
Total Apparent Power
Imported Phase C
Total Reactive Imported
Q1
Total Reactive Imported
Q1 Phase A
Total Reactive Imported
Q1 Phase B
Total Reactive Imported
Q1 Phase C
Total Reactive Imported
Q2
Total Reactive Imported
Q2 Phase A
Total Reactive Imported
Q2 Phase B
Total Reactive Imported
Q2 Phase C
Total Reactive Imported
Q3
Total Reactive Imported
Q3 Phase A
Total Reactive Imported
Q3 Phase B
Total Reactive Imported
Q3 Phase C
Total Reactive Imported
Q4
Total Reactive Imported
Q4 Phase A
Total Reactive Imported
Q4 Phase B
Total Reactive Imported
Q4 Phase C
Data
Property Range Default
Type
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
Dword R/W
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
0-9999999999kWh
# of
registers
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
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Chapter 5: Communication
Table 5-12 Clock Address
MODBUS Address
Hex Decimal
Parameter
Description
Data
Type
R/W Data Range Default Model
300H 768 Clock: Year Word R/W 2000-2099 2000 2~4 1
301H 769 Clock: Month Word R/W 1-12 1 2~4 1
302H 770 Clock: Date Word R/W 1-31 1 2~4 1
303H 771 Clock: Hour Word R/W 0-23 0 2~4 1
304H 772 Clock: Minute Word R/W 0-59 0 2~4 1
0~6
305H 773 Clock: Second Word R/W
0: Sunday
1~6 Monday-Satur-
6 2~4 1
day
0-9999999999 (Com-
310H-311H 784-785 Run_time Uint32
munication value is
100 times of the real
2~4 2
value)
0-999999999 (Com-
312H-313H 786-787 Load_time Uint32
munication value is
100 times of the real
2~4 2
value)
Daylight Saving Time Setting (03H: Read 10H: Write)
Table 5-13 Daylight saving time address table
MODBUS Address
Hex Decimal
Daylight Saving Time Setting
350H 848 DST enable Word R/W
351H 849 DST format Word R/W
Format 1: Fixed Date
Parameter
Description
Data
Type
R/W Data Range Default Model
0: disable
1: enable
0 2~4 1
0: format
1 (xed date)
1: format 2 (non
0 2~4 1
xed date)
Register
Number
Register
Number
352H 850 DST Start Month Word R/W 1~12 1 2~4 1
353H 851 DST Start Day Word R/W 1~31 1 2~4 1
354H 852 DST Start Hour Word R/W 0~23 0 2~4 1
355H 853 DST Start Min Word R/W 0-59 0 2~4 1
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AcuRev 1310
356H 854
357H 854
358H 856 DST Ending Date Word R/W 1-31 1 2~4 1
359H 857 DST Ending Hour Word R/W 0-23 0 2~4 1
DIN-Rail Power Meter
DST Start Adjust
Time (Unit: Minute)
DST Ending
Month
Word R/W 1-120 60 2~4 1
Word R/W 1-12 1 2~4 1
35AH 858
35BH 859
DST Ending Minute
DST Adjust time
(Unit: Minute)
Word R/W 0-59 0 2~4 1
Word R/W 1-120 60 2~4 1
Format 2: Non Fixed Date
35CH 860 DST Start Month Word R/W 1~12 1 2~4 1
35DH 861 DST Start Day Word R/W 0~6 0 2~4 1
35EH 862 DST Start Week Word R/W 1~5 1 2~4 1
35FH 863 DST Start Hour Word R/W 0~23 0 2~4 1
360H 864 DST Start Minute Word R/W 0~59 0 2~4 1
361H 865
362H 866
363H 867 DST Ending Day Word R/W
364H 868 DST Ending Week Word R/W 1~5 1 2~4 1
DST Start Adjust
Time (Unit: Minute)
DST Ending
Month
Word R/W 1~120 60 2~4 1
Word R/W 1~12 1 2~4 1
0~6
0: Sunday
1~6 Monday-Satur-
day
0 2~4 1
365H 869 DST Ending Hour Word R/W 0~23 0 2~4 1
366H 870
367H 871
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DST Ending Minute
DST Ending
Adjust time (Unit:
minute)
Word R/W 0~59 0 2~4 1
Word R/W 1~120 60 2~4
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Chapter 5: Communication
Time of Use (TOU) Energy
Table 5-14 TOU Energy Address
MODBUS Address
Hex Decimal
TOU Parameter
400H 1024
401H 1025
402H 1026
403H 1027
404H 1028
405H 1029
406H 1030
407H 1031
408H 1032
409H 1033
40AH 1034
40BH 1035
40CH 1036
40DH 1037
40EH 1038
Parameter
Description
Wrong Parameter
Setting 1
Wrong Parameter
Setting 2
Time Zone Selecting
Schedule Setting:
number of sched-
ules to congure
Segment Setting:
number of time
segments per
schedule
Tari: number of
taris to congure
Weekend Setting
Weekend Sched-
ule
Number of Holidays
TOU auto
reset xed date:
day(default is 1)
TOU auto reset
xed date: hour
(default is 0)
TOU Enable
TOU Settings
Number
Current number
of taris to congure
TOU Settings –
reset to factory
default
Data
Type
R/W Range Default Model
Register
Number
See Appendix “Tari
Parameter Wring
2~4 1
Information 1”
See Appendix “Tari
Parameter Wrong
2~4 1
Information 1”
Word R/W 1-14 1 2~4 1
Word R/W 1-8 2 2~4 1
Word R/W 1-14 2 2~4 1
Word R/W 1-4 4 2~4 1
Bit0-Bit6
Word R/W
1: Weekdays;
0 2~4 1
0: Weekends
Word R/W 1-8 1 2~4 1
Word R/W 0-30 0 2~4 1
Word R/W 1-28 1 2~4 1
Word R/W 0-23 0 2~4 1
Word R/W
Word R/W
0: disable;
1: enable
0:System Setting
1: Communication
0 2~4 1
0 2~4 1
1-4 Only can change
Word R/W
when the TOU Tari
Number is set as 1,
1 2~4 1
Communication
Word R/W Only ‘0x0A” Valid 2~4 1
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TOU Schedule Parameters
420H-422H
423H-425H
426H-428H
429H-42BH
42CH-42EH
42FH-431H
432H-434H
435H-437H
438H-43AH
43BH-43DH
43EH-440H
441H-443H
1056-
1058
1059-
1061
1062-
1064
1065-
1067
1068-
1070
1071-
1073
1074-
1076
1077-
1079
1080-
1082
1083-
1085
1086-
1088
1089-
1091
DIN-Rail Power Meter
Time Zone 1:
starting Month,
Day, Schedule
Table number
Time Zone 2:
starting Month,
day, Schedule
Table number
Time Zone 3:
starting Month,
Day, Schedule
Table number
Tine Zone 4: starting Month, Day,
Schedule Table
number
Time Zone 5:
starting Month,
Day, Schedule
Table number
Time Zone 6:
starting Month,
Day, Schedule
Table number
Time Zone 7:
starting Month,
Day, Schedule
Table number
Time Zone 8:
starting Month,
Day, Schedule
Table number
Time Zone 9:
starting Month,
Day, Schedule,
Table number
Time Zone 10:
starting Month,
Day, Schedule
Table number
Time Zone 11:
starting Month,
Day, Schedule
Table number
Time Zone 12:
starting Month,
Day, Schedule
Table Number
R/W 02-01 01 2~4 3
R/W 06-01 02 2~4 3
R/W 10-01 03 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
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Chapter 5: Communication
444H-446H
447H-449H
44AH-44CH
44DH-44FH
450H-452H
453H-455H
456H-458H
459H-45BH
45CH-45EH
45FH- 461H
462H- 464H
465H- 467H
468H- 46AH
1092-
1094
1095-
1097
1098-
1100
1101-
1103
1104-
1106
1107-
1109
1110-
1112
1113-
1115
1116-
1118
1119-
1121
1122-
1124
1125-
1127
1128-
1130
Time Zone 13:
starting Month,
Day, Schedule
Table Number
Time Zone 14:
starting Month,
Day, Schedule
Table Number
Schedule Table
1, 1st segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 2nd segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 3rd segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 4th segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 5th segment
(Hour, Minute,
Tari Number)
Schedule Table,
6th segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 7th segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 8th segment
(Hour, Minute,
Tari Number)
Schedule 1, 9th
segment (Hour,
Minute, Tari
Number)
Schedule Table
1, 10th segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 11th segment
(Hour, Minute,
Tari Number)
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 07:12 01 2~4 3
R/W 15:22 03 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
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46BH- 46DH
46EH- 470H
471H- 473H
474H-49DH
49EH- 4C7H
4C8H- 4F1H
4F2H- 51BH
546H- 56FH
570H- 599H
59AH- 59CH
1131-
1133
1134-
1136
1137-
1139
1140-
1181
1182-
1223
1224-
1265
1308-
1349
1350-
1391
1392-
1433
1434-
1436
DIN-Rail Power Meter
Schedule Table
1, 12th segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 13th Segment
(Hour, Minute,
Tari Number)
Schedule Table
1, 14th segment
(Hour, Minute,
Tari Number)
Schedule Table 2,
1st -14th segment
(Hour, Minute,
Tari Number)
Schedule Table 3,
1st -14th segment
(Hour, Minute,
Tari Number)
Schedule Table
4, 1st – 14th
segment (Hour,
Minute, Tari
Number)
Schedule Table
6, 1st – 14th
segment (Hour,
Minute, Tari
Number)
Schedule Table
7, 1st – 14th
segment (Hour,
Minute, Tari
Number)
Schedule Table
8, 1st – 14th
segment (Hour,
Minute, Tari
Number)
The 1st special
day (Month, Day,
Schedule Table
Number)
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 3
R/W 00:00 00 2~4 42
R/W 00:00 00 2~4 42
R/W 00:00 00 2~4 42
R/W 00:00 00 2~4 42
R/W 00:00 00 2~4 42
R/W 00:00 00 2~4 42
R/W 03-12 01 2~4 3
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Chapter 5: Communication
59DH- 59FH
5A0H- 5A2H
5A3H- 5A5H
5A6H- 5A8H
5A9H- 5ABH
5ACH- 5AEH
1437-
1439
1440-
1442
1443-
1445
1446-
1448
1449-
1451
1452-
1454
The 2nd special
day (Month, Day,
Schedule Table
Number)
The 3rd special
day (Month, Day,
Schedule Table
number)
The 4th special
day (Month, Day,
Schedule Table
Number)
The 5th special
day (Month, Day,
Schedule Table
Number)
The 6th special
day (Month, Day,
Schedule Table
Number)
The 7th special
day (Month, Day,
Schedule Table
Number)
R/W 05-02 03 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
5AFH-5B1H
5B2H- 5B4H
5B5H- 5B7H
5B8H- 5F3H
1455-
1457
1458-
1460
1461-
1463
1464-
1523
The 8th special
day (Month, Day,
Schedule Table
Number)
The 9th special
day (Month, Day,
Schedule Table
Number)
The 10th special
day (Month, Day,
Schedule Table
Number)
The 11th ~30th
special day
(Month, Day,
Schedule Table
Number)
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 00-00 00 2~4 3
R/W 2~4 3
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DIN-Rail Power Meter
Table 5-15 Last/Previous Month Demand Max
MODBUS Address
Hex Decimal
1800H-1801H 6144-6145
1802H-1804H 6146-6147
1805H-1806H 6148-6149
1807H-1809H 6150-6151
180AH-180BH 6152-6153
180CH-180EH 6154-6155
180FH-1810H 6156-6157
1811H-1813H 6158-6159
1814H-1815H 6160-6161
1816H-1818H 6162-6163
1819H-181AH 6164-6165
181BH-181CH 6166-6167
181DH-181EH 6168-6169
181FH-1821H 6170-6171
1822H-1823H 6172-6173
1824H-1826H 6174-6175
Parameter
Description
Total Imported
Active Power
Demand Peak
Total Imported
Active Power Demand Peak Time
Imported Active
Power Demand 1
Peak
Imported Active
Power Demand 1
Peak Time
Imported Active
Power Demand 2
Peak
Imported Active
Power Demand 2
Peak Time
Imported Active
Power Demand 3
Peak
Imported Active
Power Demand 3
Peak Time
Imported Active
Power Demand 4
Peak
Imported Active
Power Demand 4
Peak Time
Total Exported
Active Power
Demand Peak
Total Exported
Active Power Demand Peak Time
Exported Active
Power Demand 1
Peak
Exported Active
Power Demand 1
Peak Time
Exported Active
Power Demand 2
Peak
Exported Active
Power Demand 2
Peak Time
Data
Type
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Fl1802H-
1804Hoat
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Property Range Model
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
R Xx.xxxx kw 2~4 2
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
Register
Number
86
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Page 88
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Chapter 5: Communication
1827H-1828H 6176-6177
1829H-182BH 6178-6179
182CH-182DH 6180-6181
182EH-1830H 6182-6183
1831H-1832H 6184-6185
1833H-1835H 6186-6187
1836H-1837H 6188-6189
1838H-183AH 6190-6191
183BH-183CH 6192-6193
183DH-183FH 6194-6195
1840H-1841H 6196-6197
1842H-1844H 6198-6199
1845H-1846H 6200-6201
1847H-1849H 6202-6203
184AH-184BH 6204-6205
184CH-184EH 6206-6207
184FH-1850H 6208-6209
Exported Active
Power Demand 3
Peak
Exported Active
Power Demand 3
Peak Time
Exported Active
Power Demand 4
Peak
Exported Active
Power Demand 4
Peak Time
Total Imported
Reactive Power
Demand Peak
Total Imported
Reactive Power Demand Peak Time
Imported Reactive
Power Demand 1
Peak
Imported Reactive
Power Demand 1
Peak Time
Imported Reactive
Power Demand 2
Peak
Imported Reactive
Power Demand 2
Peak Time
Imported Reactive
Power Demand 3
Peak
Imported Reactive
Power Demand 3
Peak Time
Imported Reactive
Power Demand 4
Peak
Imported Reactive
Power Demand 4
Peak Time
Total Exported
Reactive Power
Demand Peak
Total Exported
Reactive Power Demand Peak Time
Exported Reactive
Power Demand 1
Peak
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
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AcuRev 1310
DIN-Rail Power Meter
1851H-1853H 6210-6211
1854H-1855H 6212-6213
1856H-1858H 6214-6215
1859H-185AH 6216-6217
185BH-185DH 6218-6219
185FH-1860H 6220-6221
1861H-1863H 6222-6223
1864H-1865H 6224-6225
1866H-1868H 6226-6227
1869H-186AH 6228-6229
186BH-186DH 6230-6231
186EH-186FH 6232-6233
1870H-1872H 6234-6235
1873H-1874H 6236-6237
1875H-1877H 6238-6239
Exported Reactive
Power Demand 1
Peak Time
Exported Reactive
Power Demand 2
Peak
Exported Reactive
Power Demand 2
Peak Time
Exported Reactive
Power Demand 3
Peak
Exported Reactive
Power Demand 3
Peak Time
Exported Reactive
Power Demand 4
Peak
Exported Reactive
Power Demand 4
Peak H Time
Total Apparent
Power Demand
Peak
Total Apparent
Power Demand
Peak Time
Phase A Current
Demand Peak
Phase A Current
Demand Peak
Time
Phase B Current
Demand Peak
Phase B Current
Demand Peak
Time
Phase C Current
Demand Peak
Phase C Current
Demand Peak
Time
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Float R Xx.xxxx kw 2~4 2
Dword R
Dword R
Float R Xx.xxxx A 2~4 2
Dword R
Dword R
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
R Xx.xxxx A 2~4 2
YY/MM/DD/hh/mm/ss
(Second always is 0)
YY/MM/DD/hh/mm/ss
(Second always is 0)
R Xx.xxxx A 2~4 2
YY/MM/DD/hh/mm/ss
(Second always is 0)
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
2~4 3
88
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Chapter 5: Communication
Table 5-16 TOU Week Alternatives
MODBUS Address
Hex Decimal
7F00H 32512
7F01H 32513
7F02H 32514
7F03H 32515
7F04H 32516
7F05H 32517
7F06H 32518
7F07H 32519
7F08H 32520
7F09H -
7F10H
7F11H
–7F18H
7F19H
–7F20H
7F21H
–7F28H
32521-32522
32523
-32536
32537-32538
32539
-32552
Parameter
Description
Enable Weekend
Alternative
Season 1:Sign of
the Weekend
Season 1:The
schedule Table
number of Sunday
Season 1:The
schedule Table
number of Monday
Season 1:The
schedule Table
number of Tuesday
Season 1:The
schedule Table number of
Wednesday
Season 1:The
schedule Table
number of Thursday
Season 1:The
schedule Table
number of Friday
Season 1:The
schedule Table
number of Saturday
Season 2 of Weekend Alternative
Season 3 of Weekend Alternative
Season 4 of Weekend Alternative
Season 5 of Weekend Alternative
Data
Type
word R/W
word R/W
word R/W 0 2~4 1
word R/W 0 2~4 1
word R/W 0 2~4 1
word R/W
word R/W
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
Access
Property
Range Default Model
1: Enable;
0: Disable
Bit0: Sunday, 1
Enable, 0 Disable;
Bit1: Monday, 1
Enable, 0 Disable;
……
Bit6: Saturday, 1
Enable, 0 Disable;
Register
Number
0 2~4 1
0 2~4 1
2~4 1
2~4
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AcuRev 1310
DIN-Rail Power Meter
7F29H
–7F30H
7F31H
–7F38H
7F39H
–7F40H
7F41H
–7F48H
7F49H
–7F50H
7F51H
–7F58H
7F59H
–7F60H
7F61H
–7F68H
7F69H
–7F70H
32553
-32554
32555 -
32568
32569
-32570
32571 -
32584
32585 -
32586
32587 -
32600
32601-32602
32603 -
32616
32617 -
32618
Season 6 of Weekend Alternative
Season 7 of Weekend Alternative
Season 8 of Weekend Alternative
Season 9 of Weekend Alternative
Season 10 of Weekend Alternative
Season 11 of Weekend Alternative
Season 12 of Weekend Alternative
Season 13 of Weekend Alternative
Season 14 of Weekend Alternative
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
word R/W 2~4
Rate parameter error information word 1 (basic parameter)
Table 5-17 Rate parameter error information word 1
Bit7 Bit6 Bit5 Bit4 Bit3 Bit2 Bit1 Bit0
1 1 1 1 1 1 1 1
Time
segment
table 8
error
Time
segment
table 7
error
Time
segment
table 6
error
Time
segment
table 5
error
Time
segment
table 4
error
Time
segment
table 3
error
Time
segment
table 2
error
Time
segment
table 1
error
Rate parameter error information word 2 (time segment table parameter)
Table 5-18 Rate parameter error information word 2
Bit7 Bit6 Bit5 Bit4 Bit3 Bit2 Bit1 Bit0
1 1 1 1 1 1 1 1
Time
segment
table 8
error
90
Time
segment
table 7
error
V: 1.0 Revised: Oct. 2020
Time
segment
table 6
error
Time
segment
table 5
error
Time
segment
table 4
error
Time
segment
table 3
error
Time
segment
table 2
error
Time
segment
table 1
error
Page 92
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Chapter 5: Communication
Alarm Parameter Setting (Function Code: 03H to Read; 10H to Write)
Table 5-19 Alarm Parameters
MODBUS Address
Hex Decimal
700H 1792 Alarm Switch Word R/W
701H 1793 Alarm Channel Word R/W
702 1794
703 1795
704H 1796
Alarm Parameter Setting for the 1st group
705H 1797
706H 1798
Parameter
Description
Alarm Channel
Output
Alarm Output
Mode
Pulse Output
Time
Parameter Num-
ber
Comparing
Method
Data
Type
R/W Range Default Model
Word R/W
Word R/W
Word R/W
Word R/W
Word R/W
1: Enable;
0: Disable
Bit0~Bit11: Alarm
Channel 0-11
1: Enable;
0: Disable
Bit0~ Bit11: Alarm
Channel 0-11
1: Enable;
0: Disable
0: level;
1:pulse
50~3000ms (valid
with Pulse Output
Mode)
0~28 (Please see
appendix “Alarm Parameter comparison
table’)
0: larger;
1: equal;
2: less
Register
Number
0 2~4 1
0 2~4 1
0 2~4 1
0 2~4 1
1000 2~4 1
0 2~4 1
0 2~4 1
0: larger;
707H 1799 Setpoint Value Word R/W
1: equal;
0 2~4 1
2: less
708H 1800 Delay Time Word R/W 0~3000 (x10ms) 0 2~4 1
Alarm Parameter Setting for the 2nd 12th group
709H-
703BH
1801-
1851
The same as
above
Word R/W 2~4 44
91
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AcuRev 1310
DIN-Rail Power Meter
Table 5-20 SunSpec System Information Address
MODBUS Address
Hex Decimal
1000H
-1001H
1002H 4098
1003H 4099
1004H
-1013H
1014H
-1023H
1024H
-102BH
102CH
-1033H
1034H
-1043H
1044H 4164
1045H 4165
1046H 4166
1047H 4167
1048H 4168
1049H 4169
104AH 4170
104BH 4171
4096
-4097
4100-4115
4116-4131
4132-4139
4140-4147
4148-4163
Parameter
Description
Data
R/W Range Default Model
Type
Register
Number
SunSpec_ID Uint16 R 0x53756e53 1 2~4 2
ID Uint16 R 1 1 2~4 1
Length Uint16 R 65 6 2~4 1
Well known value regis-
Manufacturer String R
tered with SunSpec for
Accuenergy 2~4 16
compliance
Model String R
Options String R
Version String R
Serial Number String R
Manufacturer specic
value (32 characters)
Manufacturer specic
value (16 characters)
Manufacturer specic
value (32 characters)
Manufacturer specic
value (32 characters)
AcuRev 1310 2~4 16
AcuRev 1310 2~4 8
H: 1.10
S;1.01
2~4 8
2~4 16
Device Address Uint16 R/W Modbus device address 2~4 1
Meter (Single Phase)
single phase (AN or AB)
meter –201
Split single phase (ABN)
ID Uint16 R
meter -202 wye-connect three phase
2~4 1
(ABCN) meter –203
Delta-connect three
phase (ABC) meter
--204
Length Uint16 R 105 2~4 1
Amps (total):
SunSpec;
Total Current
Int16 R 0~9999 A 2~4 1
AcuRev 1310
Amps Phase A:
SunSpec;
Phase A Current
Int16 R 0~9999 A 2~4 1
AcuRev 1310
Amps Phase
B: SunSpec;
Phase B Current:
Int16 R 0~9999 A 2~4 1
AcuRev 1310
Amps Phase
C:SunSpec;
Phase C Current
Int16 R 0~9999 A 2~4 1
AcuRev 1310
Current scale
factor: SunSpec;
CT Ratio: AcuRev
Sunssf R
-3~+5 (used as expo-
nent of a power of 10)
2~4 1
1310
92
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Chapter 5: Communication
MODBUS Address
Hex Decimal
104CH 4172
104DH 4173
104EH 4174
104FH 4175
1050H 4176
1051H 4177
1052H 4178
1053H 4179
1054H 4180
1055H 4181 Frequency Int16 R 45Hz-65Hz 2~4 1
1056H 4182
1057H 4183
1058H 4184
1059H 4185
Parameter
Description
Voltage LN (average): SunSpec;
CT Ratio: AcuRev
1310
Phase Voltage
AN: SunSpec;
Phase Average
Voltage: AcuRev
1310
Phase Voltage
BN: SunSpec;
Phase B Voltage:
AcuRev 1310
Phase Voltage
CN: SunSpec;
Phase C Voltage:
AcuRev 1310
Voltage LL (average): SunSpec;
Line Average
Voltage: AcuRev
1310
Phase Voltage
AB: SunSpec;
Line AB Voltage:
AcuRev1310
Phase Voltage
BC: SunSpec;
Line BC Voltage
AcuRev 1310
Phase Voltage
CA: SunSpec;
Line CA Voltage:
AcuRev 1310
Voltage scale
factor: SunSpec
Frequency scale
factor
Total Real Power
SunSpec; Total
Active Power:
AcuRev 1310
Watts Phase A:
SunSpec;
Total Active Power: AcuRev 1310
Watts Phase A:
SunSpec; Phase
A Active Power:
AcuRev 1310
Data
R/W Range Default Model
Type
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Int16 R 0~9999 V 2~4 1
Sunssf R -2~2 2~4 1
Sunssf R -2 2~4 1
Int16 R 0~9999 W 2~4 1
Int16 R 0~9999 W 2~4 1
Int16 R 0~9999 W 2~4 1
Register
Number
V: 1.0 Revised: Oct. 2020
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AcuRev 1310
MODBUS Address
Hex Decimal
105AH 4186
105BH 4187
105CH 4188
105DH 4189
105EH 4190
105FH 4191
1060H 4192
1061H 4193
1062H 4194
1063H 4195
1064H 4196
DIN-Rail Power Meter
Parameter
Description
Watts Phase C:
SunSpec; Phase
C Active Power:
AcuRev 1310
Real Power scale
factor: SunSpec;
AC Apparent
Power VA: SunSpec;
Total Apparent
Power: AcuRev
1310
VA Phase A:
SunSpec;
Phase A Apparent
Power: AcuRev
1310
VA Phase B:
SunSpec;
Phase B Apparent
Power: AcuRev
1310
VA Phase C: SunSpec; Phase C
Apparent Power:
AcuRev 1310
Apparent Power
scale factor:
SunSpec;
Reactive Power
VAR: SunSpec;
Total Reactive
Power: AcuRev
1310
VAR Phase A:
SunSpec;
Phase A Reactive
Power: AcuRev
1310
VAR Phase B:
SunSpec;
Phase B Reactive
Power: AcuRev
1310
VAR Phase C:
SunSpec;
Phase C Reactive
Power: AcuRev
1310
Data
Type
Int16 R 0~9999 W 2~4 1
Sunssf R 0~4 2~4 1
Int16 R 0~9999 VA 2~4 1
Int16 R 0~9999 VA 2~4 1
Int16 R 0~9999 VA 2~4 1
Int16 R 0~9999 VA 2~4 1
Sunssf R 0~4 2~4 1
Int16 R 0~9999 VAR 2~4 1
Int16 R 0~9999 VAR 2~4 1
Int16 R 0~9999 VAR 2~4 1
Int16 R 0~9999 VAR 2~4 1
R/W Range Default Model
Register
Number
94
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Chapter 5: Communication
MODBUS Address
Hex Decimal
1065H 4197
1066H 4198 Power Factor Int16 R -1000 ~ 1000 2~4 1
1067H 4199 PF Phase A Int16 R -1000 ~ 1000 2~4 1
1068H 4200 PF Phase B Int16 R -1000 ~ 1000 2~4 1
1069H 4201 PF Phase C Int16 R -1000 ~ 1000 2~4 1
106AH 4202
106BH
-106CH
106DH
-106EH
106FH
-1070H
1071H
-1072H
1073H
-1074H
1075H
-1076H
4203-4204
4205-4206
4207-4208
4209-4210
4211-4212
4213-4214
Parameter
Description
Reactive Power
scale factor
Power Factor
scale factor
Total Real Energy
Exported: SunSpec Total Active
Energy Exported:
AcuRev 1310
Total Watt-hours
Exported in
phase A: SunSpec;
Total Active Energy Exported in
Phase A: AcuRev
1310
Total Watt-hours
Exported in
phase B: SunSpec; Total Active
Energy Exported
in Phase B:
AcuRev 1300
Total Watt-hours
Exported in
Phase C: SunSpec; Total Active
Energy Exported
in Phase C:
AcuRev 1310
Total Real Energy
Imported: SunSpec; Total Active
Energy Imported:
AcuRev 1310
Total Watt-hours
Imported Phase
A: SunSpec;
Total Active Energy Imported in
Phase A: AcuRev
1310
Data
R/W Range Default Model
Type
Sunssf R 0~4 2~4 1
Sunssf R -3 2~4 1
Acc32 R/W 0-999999999 kWh 2~4 2
Acc32 R/W 0-999999999 kWh 2~4 2
Acc32 R/W 0-999999999 kWh 2~4 2
Accc32 R/W 0-999999999 kWh 2~4 2
Acc32 R/W 0-999999999 kWh 2~4 2
Acc32 R/W 0-999999999 kWh 2~4 2
Register
Number
V: 1.0 Revised: Oct. 2020
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AcuRev 1310
MODBUS Address
Hex Decimal
1077H
-1078H
1079H
-107AH
107CH
-107DH
107EH
-17FH
1080H
-1081H
1082H
-1083H
1084H
-1085H
4215-4216
4217-4218
107B 4219
4220-4221
4222-4223
4224-4225
4226-4227
4228-4229
DIN-Rail Power Meter
Parameter
Description
Total Watt-hours
Imported Phase
B: SunSpec;
Total Active Energy Imported in
Phase B: AcuRev
1310
Total Watt-hours
Imported Phase
C: SunSpec; Total
Active Energy Imported in Phase
C: AcuRev 1310
TotWh_SF: SunSpec; CT ratio X
PT ratio: AcuRev
1310
Total VA-hours
Exported:
SunSpec; Total
Apparent Power
Exported: AcuRev
1310
Total VA-hours
Exported Phase
A: SunSpec; Total
Apparent Power
Exported in
Phase A: AcuRev
1310
Total VA-hours
Exported Phase
B: SunSpec;
Total Apparent
Power Exported
in Phase A:AcuRev 1310
Total VA-hours
Exported phase
C: SunSpec; Total
Apparent Power
Exported in
Phase C: AcuRev
1310
Total VA-hours
Imported:
SunSpec;
Total Apparent
Power Imported:
AcuRev 1310
Data
Type
Acc32 R/W 0-999999999 kWh 2~4 2
Acc32 R/W 0-999999999 kWh 2~4 2
Sunssf R -3 ~ 0 2~4 1
Acc32 R/W 0-999999999 kVAh 3~4 2
Acc32 R/W 0-999999999 kVAh 3~4 2
Acc32 R/W 0-999999999 kVAh 3~4 2
Acc32 R/W 0-999999999 kVAh 3~4 2
Acc32 R/W 0-999999999 kVAh 2~4 2
R/W Range Default Model
Register
Number
96
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Chapter 5: Communication
MODBUS Address
Hex Decimal
1086H
-1087H
1088H
-1089H
108AH
-108BH
108CH 4236
108DH
-108EH
108FH
-1090H
1091H
-1092H
1093H
-1094H
1095H
-1096H
1097H
-1098H
1099H
-109AH
109BH
-109CH
4230-4231
4232-4233
4234-4235
4237-4238
4239-4240
4241-4242
4243-4244
4245-4246
4247-4248
4249-4250
4251-4252
Parameter
Description
Total VA-hours
Imported phase
A: SunSpec; Total
Apparent Power
Imported in
Phase A: AcuRev
1310
Total VA-hours
Imported Phase
B: SunSpec; Total
Apparent Power
Imported in
Phase B: AcuRev
1310
Total VA-hours
Imported Phase
C: SunSpec; Total
Apparent Power
Imported in
Phase C: AcuRev
1310
Total VAh_SF:
SunSpec;
CT ratio X PT ratio: AcuRev 1310
Total VARhours Imported
Q1:SunSpec;
Total VAR-hours
Imported Q1
Phase 1A
Total VAR-hours
Imported Q1
Phase B
Total VAR-hors
Imported Q1
Phase C
Total VAR-hours
Imported Q2
Phase A
Total VAR-hours
Imported Q2
Phase A
Total VAR-hours
Imported Q2
Phase B
Total VAR-hours
Imported Q2
Phase C
Data
R/W Range Default Model
Type
Acc32 R/W 0-999999999 kVAh 2~4 2
Acc32 R/W 0-999999999 kVAh 2~4 2
Acc32 R/W 0-999999999 kVAh 2~4 2
Sunssf R -3 ~ 0 2~4 1
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-99k9999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Register
Number
V: 1.0 Revised: Oct. 2020
97
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AcuRev 1310
MODBUS Address
Hex Decimal
DIN-Rail Power Meter
Parameter
Description
Data
Type
R/W Range Default Model
Register
Number
109DH
-109EH
109FH
-10AH
10A1H
-10A2H
10A3H
-10A4H
10A5H
-10A6H
10A7H
-10A8H
10A9H
-10AAH
10ABH
-10ACH
10ADH 4269
4253-4254
4255-4256
4257-4258
4259-4260
4261-4262
4263-4264
4265-4266
4267-4268
Total VAR-hours
Exported Q3
Total VAR-hours
Exported Q3
Phase A
Total VAR-hours
Exported Q3
Phase B
Total VAR-hours
Exported Q3
Phase C
Total VAR-hours
Exported Q4
Total VAR-hours
Exported Q4
Phase A
Total VAR-hours
Exported Q4
Phase B
Total VAR-hours
Exported Q4
Phase C
Total VARh_SF:
SunSpec; CT
ratio X PT ratio:
AcuRev 1310
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Acc32 R/W 0-999999999 kvarh 2~4 2
Sussf R
All the energy use the
same SF
2~4 1
10AEH
-10AFH
10B0H 4272
10B1H 4273
98
V: 1.0 Revised: Oct. 2020
4270-4271
Meter EvenetFlags
SunSpec_end_
ID: SunSPec;
SunSpec_end_
length: SunSpec
Biteld32 R 0 0 2~4 2
Uint16 0xFFFF 2~4 1
Uint16 0x0000 2~4 1
Page 100
www.accuenergy.com
Chapter 5: Communication
Table 5-21 Current Maximum demand and time of occurrence address
MODBUS Address
Hex Decimal
Current maximum demand and time of occurrence data
1600H-1601H
1602H-1604H
1605H-1606H
1607H-1609H
160AH-160BH
160CH-160EH
160FH-1600H
1611H-1613H
1614H-1615H
1616H-1618H
1619H-161AH
161BH-161DH
161EH-161FH
1620H-1622H
1623H-1624H
1625H-1627H
1628H-1629H
162AH-162C
162DH-162EH
162FH-1631H
1632H-1633H
1634H-1636H
1637H-1638H
1639H-163BH
163CH-163DH
163EH-1640H
1641H-1642H
1643H-1645H
1646H-1647H
1648H-164AH
5632-5633
5634-5636
5637-5638
5639-5641
5642-5643
5644-5646
5647-5648
5649-5651
5652-5653
5654-5656
5657-5658
5659-5661
5662-5663
5664-5666
5667-5668
5669-5671
5672-5673
5674-5676
5677-5678
5679-5681
5682-5683
5684-5686
5687-5688
5689-5691
5692-5693
5694-5696
5697-5698
5699-5701
5702-5703
5704-5706
Parameter
Description
Input active power
total max demand and
occur time
Input active power
max demand 1 and
occur time
Input active power
max demand 2 and
occur time
Input active power
max demand 3 and
occur time
Input active power
max demand 4 and
occur time
Output active powers
total max demand and
occur time
Output active power
max demand 1 and
occur time
Output active power
max demand 2 and
occur time
Output active power
max demand 3 and
occur time
Output active power
max demand 4 and
occur time
Input reactive power
max demand 1 and
occur time
Input reactive power
max demand 1 and
occur time
Input reactive power
max demand 2 and
occur time
Input reactive power
max demand 3 and
occur time
Input reactive power
max demand 4 and
occur time
Data
Type
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
DWORD
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
Dword
Float
Dword
R/W Range Default Model
R xx.xxxx kW YYMMD-
Dhhmmss (Second
always be 0)
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW
YYMMDDhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kW YYMMD-
Dhhmmss
R xx.xxxx kvar YYM-
MDDhhmmss
R xx.xxxx kvar YYM-
MDDhhmmss
R xx.xxxx kvar YYM-
MDDhhmmss
R xx.xxxx kvar
YYMMDDhhmmss
R xx.xxxx kvar
YYMMDDhhmmss
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
3,4 2
Register
Number
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
V: 1.0 Revised: Oct. 2020
99
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