SBC AWD3D5WD, Assembly And Operating Instructions Manual

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R Typ Description Unit
1 R Firmware-Version Ex:11 =FW 1.1
2 R Number of supported
registers Will give 52
3 R Number of supported
flags Will give 0
4–5 R Baudrate Ex: Baudrate High = 1 Baudrate
Low = 49664
1 × 65536 + 49664 =
115’200 bps
6 R Not Used Will give 0
7 R Type / ASN function Will give «AW»
8 R Type / ASN function Will give «D3»
9 R Type / ASN function Will give «D5»
10 R Type / ASN function Will give «FW»
11 R Type / ASN function Will give «00»
12 R Type / ASN function Will give «Cx»
x : 2 = Non MID
x : 3 = Non MID
13 R Type / ASN function Will give «A0 »
14 R Type / ASN function Will give «0»
15 R HW vers. Modif. Ex: 11 =HW 1.1
16–17 R Serial number Unique 32 bit serial number low
18 R Serial number Unique 32 bit serial number high
19 R Not Used Will give 0
20 R Not Used Will give 0
21 R Not Used Will give 0
22 R Status 0 = no Problem
1 = problem with last
communication request
23 R Response timeout ms
24 R/W 1) Modbus Address Range 1–247
25 R Error register 0 : No error
1 : Error Phase 1
2 : Error Phase 2
3 : Error Phase 1+2
4 : Error Phase 3
5 : Error Phase 1+3
6 : Error Phase 2+3
7 : Error Phase 1, 2+3
26 R Current Transformer
Ratio Ex: Transformer 100 / 5 give 20
27 R Not Used Will give 0
28–29 R WT1 total High
Counter Energy Total
Tariff 1 High 10
–1
kWh (multiplier 0,1)
Ex: WT1 total High = 13
WT1 total Low = 60383
13 × 65536 + 60383 =
912351 = 91235.1 kWh
30–31 R/W WT1 partial
Counter Energy Partial
Tariff 1
10
–1
kWh (multiplier 0,1)
Ex: WT1 partial High = 13
WT1 partial Low = 60383
13 × 65536 + 60383 =
912351 = 91235.1 kWh
32 R Not Used Will give 0
Registers
For double registers (4 – 5, 16 – 17, 28 – 29, 30 – 31) the high register is sent first (big_Endian).
The Partial counter (30 – 31) can be reset by writing 0 in both registers in the same message.
R Typ Description Unit
33 R Not Used Will give 0
34 R Not Used Will give 0
35 R Not Used Will give 0
36 R URMS phase 1
Effective Voltage of
Phase 1
V
Ex: 230 = 230 V
37 R IRMS phase 1
Effective Current of
Phase 1 A / Except 5/5 = 10
–1
A
Ex: 314 = 314 A
38 R PRMS phase 1
Effective active Power
of Phase 1 10
–1
kW (multiplier 0,1)
Ex: 1545 = 154,5 kW
39 R QRMS phase 1
Effective reactive Power
of Phase 1 10 –1 kvar (multiplier 0,1)
Ex: 1545 = 154,5 kvar
40 R cos phi phase 1 10
–2
(multiplier 0,01)
Ex: 67 = 0,67
41 R URMS phase 2
Effective Voltage of
Phase 2 V
Ex: 230 = 230 V
42 R IRMS phase 2
Effective Current of
Phase 2 A / Except 5/5 = 10 –1 A
Ex: 314 = 314 A
43 R PRMS phase 2
Effective active Power
of Phase 2 10
–1
kW (multiplier 0,1)
Ex: 1545 = 154,5 kW
44 R QRMS phase 2
Effective reactive Power
of Phase 2 10
–1
kvar (multiplier 0,1)
Ex: 1545 = 154,5 kvar
45 R cos phi phase 2 10
–2
(multiplier 0,01)
Ex: 67 = 0,67
46 R URMS phase 3
Effective Voltage of
Phase 3 V
Ex: 230 = 230 V
47 R IRMS phase 3
Effective Current of
Phase 3 A / Except 5/5 = 10 –1 A
Ex: 314 = 314 A
48 R PRMS phase 3
Effective active Power
of Phase 3 10
–1
kW (multiplier 0,1)
Ex: 1545 = 154,5 kW
49 R QRMS phase 3
Effective reactive Power
of Phase 3 10
–1
kvar (multiplier 0,1)
Ex: 1545 = 154,5 kvar
50 R cos phi phase 3 10 –2 (multiplier 0,01)
Ex: 67 = 0,67
51 R PRMS total
Effective active Power of
all phases 10
–1
kW (multiplier 0,1)
Ex: 1545 = 15,45 kW
52 R QRMS total
Effective reactive power
of all phases 10
–1
kvar (multiplier 0,1)
Ex: 1545 = 15,45 kvar
1) The Modbus Address register is not writable with a broadcast message.