l Infrared Carrier Frequency: 38 kHz
l Communication Baud Rate: 1200~115200 bps, adaptive according to electric meter communication parameters
l Infrared Communication Distance: ≤10 meters
l Communication Angle: ≤15 degrees
Infrared Communication Protocol: Compliant with IEC 62056-21 (IEC 1107) and DL/T-645-1997 and 2007 standards, supports Modbus protocol.
The DAQ-GP-DTUmodbusTCP infrared meter reading terminal, developed by Shanghai Shuocai IoT Technology Co., Ltd., is a device that converts national grid electric meters such as DLT645/698 to the ModBus communication protocol. It can acquire electrical energy data, voltage, current, power factor, and other electrical parameter data from national grid meters.
Introduction to the Infrared Meter Reading Principle: The infrared photoelectric probe periodically reads parameter information from the smart meter via the infrared optical port and uploads it. The infrared meter reader features infrared signal modulation and demodulation functions, modulating binary digital signals into a 38KHz frequency pulse sequence and driving the infrared emitting diode to transmit infrared light pulses. The transceiver converts received optical pulses into electrical signals, which are then amplified and filtered before being delivered to the demodulation circuit for demodulation. The signals are restored to binary digital form, parsed into messages, and converted to the ModBus protocol, enabling reading via other host computer software.
This terminal supports meter reading scenarios for various instruments equipped with infrared communication interfaces, such as electric meters and gas meters. It is suitable for electric energy meter data acquisition, smart city data acquisition, power monitoring data acquisition, energy-saving and emission reduction data monitoring systems, energy consumption monitoring systems, photovoltaic system data acquisition, intelligent monitoring data acquisition, robotic data acquisition, smart security system data acquisition, and cloud platform system data acquisition. Electric Meter Verification and Testing Platform; particularly suitable for meter reading in photovoltaic power generation systems and for national grid electric meter main meters at power supply bureaus that are fully sealed with lead seals and cannot have any seals opened.
Our company solemnly guarantees:
You are purchasing not only a product but also meticulous and comprehensive technical support services !!! ( =^_^= )
This product requires only ordinary workers on site to connect and install the power supply! No commissioning needed!
We provide free remote guidance and remote configuration and commissioning services, transmitting data to the user-designated cloud platform.
Free consultation services for IoT solutions!
《 Q/GDW1365—2013 Technical Specification for Security Certification of Smart Electric Meter Information Exchange 》 National Grid Standard
Multifunctional Electric Energy Meter Communication Protocol DLT645-2007 State Grid Standard
Three-Phase Smart Electric Energy Meter Type Specification Q/GDW1356-2013 State Grid Standard
l Infrared Carrier Frequency: 38 kHz
l Communication Baud Rate: 1200~115200 bps, adaptive according to electric meter communication parameters
l Infrared Communication Distance: ≤10 meters
l Communication Angle: ≤15 degrees
Infrared Communication Protocol: Compliant with IEC 62056-21 (IEC 1107) and DL/T-645-1997 and 2007 standards, supports Modbus protocol.
l Power Supply Mode: 5–24 V DC power supply
l Operating Power Consumption: less than 5 W
l Temperature: -30°C to 75°C, Humidity: 0 to 95%
MODBUS Commands: 0x03: Read Data Command, 0x06: Single Register Write Command, 0x10: Multiple Register Write Command.
Configuration Parameters | ||||
Serial Number | Register Name | Register Address | Command | Remarks |
1 | Address | 0xF000 | 0x03/0x06 | Default is 1; 255 is the broadcast address |
2 | 645 Address | 0xF001 | 0x03/0x06 | 645 Address 1234 |
3 | 645 Address | 0xF002 | 0x03/0x06 | 645 Address 5678 |
4 | 645 Address | 0xF002 | 0x03/0x06 | 645 Address 9ABC |
5 | Electric Meter Communication Protocol | 0xF004 | 0x03/0x06 | 0: 645-07 Protocol; 1: 645-97 Protocol |
6 | Module Communication Mode | 0xF005 | 0x03/0x06 | 0: MODBUS Mode; 1: Transparent Transmission Mode |
7 | Module Acquisition Mode | 0xF006 | 0x03/0x06 | 0: Cyclic meter reading; 1: Real-time meter reading by single command |
8 | Module acquisition interval | 0xF007 | 0x03/0x06 | Cyclic meter reading; cyclic meter reading interval: 1S–60000S |
9 | 4851 port (MODBUS) communication baud rate | 0xF008 | 0x03/0x06 | 0:1200,1:2400,2:4800,3:9600,4:14400,5:19200,6:38400,7:56000,8:57600,9:115200 |
10 | 4851 port (MODBUS) parity mode | 0xF009 | 0x03/0x06 | 0: No parity; 1: Even parity; 3: Odd parity |
11 | 4852 port (DLT645) communication baud rate | 0xF00A | 0x03/0x06 | 0:1200,1:2400,2:4800,3:9600,4:14400,5:19200,6:38400,7:56000,8:57600,9:115200 |
12 | 4852 port (DLT645) parity mode | 0xF00B | 0x03/0x06 | 0: No parity; 1: Even parity; 3: Odd parity |
order number | Register name | Register address | order | remarks |
1 | Combine positive active power and total energy | 1000 | 0x03 | Floating point type, high address first |
2 | Combine positive active peak power | 1002 | 0x03 | Floating point type, high address first |
3 | Combine positive active peak power | 1004 | 0x03 | Floating point type, high address first |
4 | Combine positive active power with flat energy | 1006 | 0x03 | Floating point type, high address first |
5 | Combine positive active valley power | 1008 | 0x03 | Floating point type, high address first |
6 | The current is positive active total energy | 1010 | 0x03 | Floating point type, high address first |
7 | At present, active peak power is being supplied | 1012 | 0x03 | Floating point type, high address first |
8 | At present, active peak power is being generated | 1014 | 0x03 | Floating point type, high address first |
9 | At present, active power is being supplied | 1016 | 0x03 | Floating point type, high address first |
10 | At present, active power is flowing in the valley | 1018 | 0x03 | Floating point type, high address first |
11 | Current reverse active total power | 1020 | 0x03 | Floating point type, high address first |
12 | The current reverse active rate is 1 kilowatt hour | 1022 | 0x03 | Floating-point type, high address first |
13 | The current reverse active rate is 2 kilowatt-hours | 1024 | 0x03 | Floating point type, high address first |
14 | The current reverse active rate is 3 kilowatt-hours | 1026 | 0x03 | Floating point type, high address first |
15 | The current reverse active rate is 4 kilowatt-hours | 1028 | 0x03 | Floating point type, high address first |
16 | Combine reactive power to get total energy | 1030 | 0x03 | Floating point type, high address first |
17 | Combine reactive power with 1 sharp electric energy | 1032 | 0x03 | Floating point type, high address first |
18 | Combine reactive power with peak energy | 1034 | 0x03 | Floating point type, high address first |
19 | The combined reactive power is equal to the electric energy | 1036 | 0x03 | Floating point type, high address first |
20 | Combine reactive power with 1 valley power | 1038 | 0x03 | Floating point type, high address first |
21 | Combine reactive power 2 total electric energy | 1040 | 0x03 | Floating point type, high address first |
22 | Combine reactive power with 2 sharp electric energy | 1042 | 0x03 | Floating point type, high address first |
23 | Combine reactive power with peak power | 1044 | 0x03 | Floating point type, high address first |
24 | The combined reactive power is 2 flat electric energy | 1046 | 0x03 | Floating point type, high address first |
25 | Combine reactive power with valley power | 1048 | 0x03 | Floating point type, high address first |
26 | The total active energy of the portfolio on the last settlement day | 1050 | 0x03 | Floating point type, high address first |
27 | The portfolio had peak power on the last settlement day | 1052 | 0x03 | Floating point type, high address first |
28 | The portfolio has peak power on the last settlement day | 1054 | 0x03 | Floating point type, high address first |
29 | The portfolio had positive and flat power on the last settlement day | 1056 | 0x03 | Floating point type, high address first |
30 | The portfolio had active valley power on the last settlement day | 1058 | 0x03 | Floating point type, high address first |
31 | The total active power is positive on the last settlement day | 1060 | 0x03 | Floating point type, high address first |
32 | Positive active peak power was recorded on the last settlement day | 1062 | 0x03 | Floating point type, high address first |
33 | The last settlement day is positive active peak power | 1064 | 0x03 | Floating point type, high address first |
34 | The last settlement day is positive active flat power | 1066 | 0x03 | Floating point type, high address first |
35 | The previous settlement day has positive active valley power | 1068 | 0x03 | Floating point type, high address first |
36 | The total reactive power of the previous settlement day | 1070 | 0x03 | Floating point type, high address first |
37 | The reverse active rate for the last settlement day is 1 kilowatt hour | 1072 | 0x03 | Floating point type, high address first |
38 | The reverse active rate for the last settlement day is 2 kilowatt-hours of electricity | 1074 | 0x03 | Floating point type, high address first |
39 | The reverse active rate for the last settlement day is 3 kilowatt-hours | 1076 | 0x03 | Floating point type, high address first |
40 | The reverse active rate for the last settlement day is 4 kilowatt-hours | 1078 | 0x03 | Floating point type, high address first |
41 | The total energy of the reactive power in the portfolio on the last settlement day is 1 | 1080 | 0x03 | Floating point type, high address first |
42 | The previous settlement day combination of reactive power 1 spike energy | 1082 | 0x03 | Floating point type, high address first |
43 | The combined reactive power of the last settlement day is 1 peak power | 1084 | 0x03 | Floating point type, high address first |
44 | The previous settlement day combination of reactive power is 1 flat electricity | 1086 | 0x03 | Floating point type, high address first |
45 | The combined reactive power of the last settlement day is 1 valley power | 1088 | 0x03 | Floating point type, high address first |
46 | The total energy of the reactive power of the portfolio on the last settlement day | 1090 | 0x03 | Floating point type, high address first |
47 | The previous settlement day combination of reactive power 2 spike energy | 1092 | 0x03 | Floating point type, high address first |
48 | The combined reactive power of the last settlement day is 2 peak power | 1094 | 0x03 | Floating point type, high address first |
49 | The previous settlement day combination of reactive power is 2 flat electricity | 1096 | 0x03 | Floating point type, high address first |
50 | The combined reactive power of the last settlement day is 2 valley power | 1098 | 0x03 | Floating point type, high address first |
51 | A phase voltage | 1100 | 0x03 | Floating point type, high address first |
52 | B phase voltage | 1102 | 0x03 | Floating point type, high address first |
53 | C phase voltage | 1104 | 0x03 | Floating point type, high address first |
54 | A phase current | 1106 | 0x03 | Floating point type, high address first |
55 | B phase current | 1108 | 0x03 | Floating point type, high address first |
56 | C phase current | 1110 | 0x03 | Floating point type, high address first |
57 | Instantaneous active power always exists | 1112 | 0x03 | Floating point type, high address first |
58 | Instantaneous A phase active power | 1114 | 0x03 | Floating point type, high address first |
59 | Instantaneous B phase active power | 1116 | 0x03 | Floating point type, high address first |
60 | Instantaneous C phase active power | 1118 | 0x03 | Floating point type, high address first |
61 | Instantaneous total reactive power | 1120 | 0x03 | Floating point type, high address first |
62 | Instantaneous A phase reactive power | 1122 | 0x03 | Floating point type, high address first |
63 | Instantaneous B phase reactive power | 1124 | 0x03 | Floating point type, high address first |
64 | Instantaneous C phase reactive power | 1126 | 0x03 | Floating point type, high address first |
65 | Instantaneous total apparent power | 1128 | 0x03 | Floating point type, high address first |
66 | Instantaneous A phase apparent power | 1130 | 0x03 | Floating point type, high address first |
67 | Instantaneous B phase apparent power | 1132 | 0x03 | Floating point type, high address first |
68 | Instantaneous C phase apparent power | 1134 | 0x03 | Floating point type, high address first |
69 | Instantaneous total power factor | 1136 | 0x03 | Floating point type, high address first |
70 | Instantaneous A phase power factor | 1138 | 0x03 | Floating point type, high address first |
71 | Instantaneous B phase power factor | 1140 | 0x03 | Floating point type, high address first |
72 | Instantaneous C phase power factor | 1142 | 0x03 | Floating point type, high address first |
73 | Grid frequency | 1144 | 0x03 | Floating point type, high address first |
电话 : Facebook/wechat/WhatsApp:+8619936624847 LINE:daqiot
邮箱 : business@daq-iot.com
手机 : +8619936624847
地址 : Room 501-50, No.9, Lane 60, Hulan West Road, Baoshan District, Shanghai。Address : Apt. 8A, House 9, Road 105, Gulshan 2, Dhaka, Bangladesh
Copyright © 2025 DAQ-IOT All Rights Reserved. 沪ICP 2021036991号
ch
English
