Standard Dataset Common Registers
Circuit Breaker Status Register
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Bit |
Description |
---|---|---|---|---|---|---|---|---|---|---|
0x7CFF |
32000 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
Quality of each bit of register 32001:
|
0x7D00 |
32001 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
Circuit breaker status register |
A/E |
A/E/P/H |
X |
0 |
OF status indication contact
|
||||||
A/E |
A/E/P/H |
X |
1 |
SD trip indication contact
Bit always equal to 0 for MasterPact and ComPact NS circuit breakers with motor mechanism. |
||||||
A/E |
A/E/P/H |
X |
2 |
SDE fault trip indication contact
|
||||||
– |
A/E/P/H |
X |
3 |
CH spring charged contact (only with MasterPact)
Bit always equal to 0 for MasterPact and ComPact NS circuit breakers with motor mechanism. |
||||||
– |
– |
– |
4 |
Reserved |
||||||
– |
A/E/P/H |
X |
5 |
PF ready to close contact (only with MasterPact)
Bit always equal to 0 for MasterPact and ComPact NS circuit breakers with motor mechanism. |
||||||
– |
– |
– |
6–14 |
Reserved |
||||||
A/E |
A/E/P/H |
– |
15 |
Data availability If this bit is set at 1, all other bits of the register are not significant. |
IO Status Registers
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Bit |
Description |
---|---|---|---|---|---|---|---|---|---|---|
0x7D01 |
32002 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
Quality of each bit of register 32003:
|
0x7D02 |
32003 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
IO1 module and M2C status |
A/E |
A/E/P/H |
X |
0 |
Digital input 1 status:
|
||||||
A/E |
A/E/P/H |
X |
1 |
Digital input 2 status:
|
||||||
A/E |
A/E/P/H |
X |
2 |
Digital input 3 status:
|
||||||
A/E |
A/E/P/H |
X |
3 |
Digital input 4 status:
|
||||||
A/E |
A/E/P/H |
X |
4 |
Digital input 5 status:
|
||||||
A/E |
A/E/P/H |
X |
5 |
Digital input 6 status:
|
||||||
A/E |
A/E/P/H |
X |
6 |
Digital output 1 status:
|
||||||
A/E |
A/E/P/H |
X |
7 |
Digital output 2 status:
|
||||||
A/E |
A/E/P/H |
X |
8 |
Digital output 3 status:
|
||||||
– |
– |
X |
9 |
Digital M2C output 1 status:
|
||||||
– |
– |
X |
10 |
Digital M2C output 2 status:
|
||||||
– |
– |
– |
11–14 |
Reserved |
||||||
A/E |
A/E/P/H |
– |
15 |
Data availability If this bit is set at 1, all other bits of the register are not significant. |
||||||
0x7D03 |
32004 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
Quality of each bit of register 32005:
|
0x7D04 |
32005 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
IO2 module status |
0 |
Digital input 1 status:
|
|||||||||
1 |
Digital input 2 status:
|
|||||||||
2 |
Digital input 3 status:
|
|||||||||
3 |
Digital input 4 status:
|
|||||||||
4 |
Digital input 5 status:
|
|||||||||
5 |
Digital input 6 status:
|
|||||||||
6 |
Digital output 1 status:
|
|||||||||
7 |
Digital output 2 status:
|
|||||||||
8 |
Digital output 3 status:
|
|||||||||
– |
9–14 |
Reserved |
||||||||
– |
15 |
Data availability If this bit is set at 1, all other bits of the register are not significant. |
Tripping Cause
The tripping cause register provides information about the cause of the trip for the standard protection functions. When a tripping cause bit is at 1 in the tripping cause register, it indicates that a trip has occurred and has not been reset.
-
For MicroLogic A/E trip units for ComPact NSX circuit breakers, the tripping cause bit is reset by pressing the key OK (keypad of the MicroLogic A/E trip unit) twice (validation and confirmation).
-
For MicroLogic A/E/P/H trip units for MasterPact NT/NW and ComPact NS circuit breakers, the tripping cause bit is reset as soon as the circuit breaker is closed again.
-
For MicroLogic X control units for MasterPact MTZ circuit breakers, the tripping cause bit is reset by pressing the test/reset button (located beside the trip cause LEDs on the MicroLogic X control unit). Press and hold the button for 3 to 15 seconds to reset all the trip causes.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Bit |
Description |
---|---|---|---|---|---|---|---|---|---|---|
0x7D05 |
32006 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
– |
– |
Quality of each bit of register 32007:
|
0x7D06 |
32007 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
Tripping cause for the standard protection functions |
|
A/E |
A/E/P/H |
X |
0 |
Long-time protection Ir |
||||||
A/E |
A/E/P/H |
X |
1 |
Short-time protection Isd |
||||||
A/E |
A/E/P/H |
X |
2 |
Instantaneous protection Ii |
||||||
A/E |
A/E/P/H |
X |
3 |
Ground-fault protection Ig |
||||||
E |
A/P/H |
X |
4 |
Earth-leakage protection IΔn |
||||||
A/E |
A/E/P/H |
X |
5 |
Integrated instantaneous protection (SELLIM and DIN/DINF) |
||||||
A/E |
– |
X |
6 |
Internal failure (STOP) |
||||||
– |
A/E |
– |
Other protections |
|||||||
– |
P/H |
– |
Internal failure (temperature) |
|||||||
– |
A/E/P/H |
– |
7 |
Internal failure (overvoltage) |
||||||
– |
P/H |
X |
8 |
Other protection (see register 32009) |
||||||
– |
– |
– |
9 |
Reserved |
||||||
E |
– |
– |
10 |
Unbalance motor protection |
||||||
E |
– |
– |
11 |
Jam motor protection |
||||||
E |
– |
– |
12 |
Underload motor protection |
||||||
E |
– |
– |
13 |
Long-start motor protection |
||||||
A/E |
– |
– |
14 |
Reflex tripping protection |
||||||
A/E |
A/E/P/H |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
||||||
0x7D07 |
32008 |
R |
– |
INT16U |
– |
– |
P/H |
– |
Quality of each bit of register 32009:
|
|
0x7D08 |
32009 |
R |
– |
INT16U |
– |
– |
P/H |
– |
– |
Tripping causes for the advanced protection functions |
– |
P/H |
– |
0 |
Current unbalance |
||||||
– |
P/H |
– |
1 |
Overcurrent on phase 1 |
||||||
– |
P/H |
– |
2 |
Overcurrent on phase 2 |
||||||
– |
P/H |
– |
3 |
Overcurrent on phase 3 |
||||||
– |
P/H |
– |
4 |
Overcurrent on Neutral |
||||||
– |
P/H |
X |
5 |
Undervoltage |
||||||
– |
P/H |
X |
6 |
Overvoltage |
||||||
– |
P/H |
– |
7 |
Voltage unbalance |
||||||
– |
P/H |
– |
8 |
Overpower |
||||||
– |
P/H |
X |
9 |
Reverse power |
||||||
– |
P/H |
X |
10 |
Underfrequency |
||||||
– |
P/H |
X |
11 |
Overfrequency |
||||||
– |
P/H |
– |
12 |
Phase rotation |
||||||
– |
P/H |
– |
13 |
Load shedding based on current |
||||||
– |
P/H |
– |
14 |
Load shedding based on power |
||||||
– |
P/H |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
||||||
0x7D09– 0x7D0C |
32010– 32013 |
– |
– |
– |
– |
– |
– |
– |
– |
Reserved |
Note for UL project team (CEP, 11/03/2013 “Question for next release”): how registers related to “Vigi module” are settled: should they be “Reserved” for UL?
Overrun of the Protection Setpoints
The alarm setpoint registers provide information about overrun of the standard and advanced protection setpoints. A bit is at 1 once a setpoint overrun has occurred, even if the time delay has not expired.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Bit |
Description |
---|---|---|---|---|---|---|---|---|---|---|
0x7D0D |
32014 |
R |
– |
INT16U |
– |
A/E |
P/H |
– |
– |
Quality of each bit of register 32015:
|
0x7D0E |
32015 |
R |
– |
INT16U |
– |
A/E |
P/H |
– |
– |
Overrun of the standard protection setpoints |
A/E |
P/H |
– |
0 |
Long-time protection pick-up |
||||||
– |
– |
– |
1–14 |
Reserved |
||||||
A/E |
P/H |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
||||||
0x7D0F |
32016 |
R |
– |
INT16U |
– |
A/E |
P/H |
– |
– |
Quality of each bit of register 32017:
|
0x7D10 |
32017 |
R |
– |
INT16U |
– |
A/E |
P/H |
– |
– |
Overrun of the advanced protection setpoints |
– |
P/H |
– |
0 |
Current unbalance |
||||||
– |
P/H |
– |
1 |
Maximum current on phase 1 |
||||||
– |
P/H |
– |
2 |
Maximum current on phase 2 |
||||||
– |
P/H |
– |
3 |
Maximum current on phase 3 |
||||||
– |
P/H |
– |
4 |
Maximum current on the neutral |
||||||
– |
P/H |
– |
5 |
Minimum voltage |
||||||
– |
P/H |
– |
6 |
Maximum voltage |
||||||
– |
P/H |
– |
7 |
Voltage unbalance |
||||||
– |
P/H |
– |
8 |
Maximum power |
||||||
– |
P/H |
– |
9 |
Reverse power |
||||||
– |
P/H |
– |
10 |
Minimum frequency |
||||||
– |
P/H |
– |
11 |
Maximum frequency |
||||||
– |
P/H |
– |
12 |
Phase rotation |
||||||
– |
P/H |
– |
13 |
Load shedding based on the current |
||||||
– |
P/H |
– |
14 |
Load shedding based on the power |
||||||
– |
P/H |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
||||||
0x7D11 |
32018 |
R |
– |
INT16U |
– |
– |
P/H |
– |
– |
Quality of each bit of register 32019:
|
0x7D12 |
32019 |
R |
– |
INT16U |
– |
– |
P/H |
– |
– |
Advanced protection settings extended |
– |
P/H |
– |
0 |
Ground-fault alarm |
||||||
E |
P/H |
– |
1 |
Earth-leakage alarm |
||||||
– |
– |
– |
2–14 |
Reserved |
||||||
– |
P/H |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
Alarms
The alarm register provides information about the pre-alarms and the user-defined alarms. A bit is set to 1 once an alarm is active.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Bit |
Description |
---|---|---|---|---|---|---|---|---|---|---|
0x7D13 |
32020 |
R |
– |
INT16U |
– |
A/E |
– |
– |
– |
Quality of each bit of register 32021:
|
0x7D14 |
32021 |
R |
– |
INT16U |
– |
A/E |
– |
– |
– |
Pre-alarm extended register |
A/E |
– |
X |
0 |
Long-time protection time pre-alarm (PAL Ir) |
||||||
E |
– |
– |
1 |
Earth-leakage protection pre-alarm (PAL IΔn) |
||||||
– |
– |
X |
Earth-leakage alarm(1) |
|||||||
A/E |
– |
– |
2 |
Ground-fault protection pre-alarm (PAL Ig) |
||||||
– |
– |
X |
Ground-fault alarm(2) |
|||||||
– |
– |
– |
3–14 |
Reserved |
||||||
A/E |
– |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
||||||
0x7D15 |
32022 |
R |
– |
INT16U |
– |
A/E |
– |
– |
– |
Quality of each bit of register 32023:
|
0x7D16 |
32023 |
R |
– |
INT16U |
– |
A/E |
– |
– |
– |
Register of user-defined alarms |
A/E |
– |
– |
0 |
User-defined alarm 201 |
||||||
A/E |
– |
– |
1 |
User-defined alarm 202 |
||||||
A/E |
– |
– |
2 |
User-defined alarm 203 |
||||||
A/E |
– |
– |
3 |
User-defined alarm 204 |
||||||
A/E |
– |
– |
4 |
User-defined alarm 205 |
||||||
A/E |
– |
– |
5 |
User-defined alarm 206 |
||||||
A/E |
– |
– |
6 |
User-defined alarm 207 |
||||||
A/E |
– |
– |
7 |
User-defined alarm 208 |
||||||
A/E |
– |
– |
8 |
User-defined alarm 209 |
||||||
A/E |
– |
– |
9 |
User-defined alarm 210 |
||||||
– |
– |
– |
10–14 |
Reserved |
||||||
A/E |
– |
– |
15 |
If this bit is at 1, bits 0 to 14 are not valid. |
||||||
0x7D17–0x7D1A |
32024–32027 |
– |
– |
– |
– |
– |
– |
– |
– |
Reserved |
(1) Value available on MicroLogic 7.0 X control unit only when the Digital Module ANSI 51N/51G Ground-fault alarm is installed. (2) Value available on MicroLogic 2.0 X, 3.0 X, 5.0 X, and 6.0 X control units only when the Digital Module ANSI 51N/51G Ground-fault alarm is installed. |
Current
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D1B–0x7D1C |
32028–32029 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
RMS current on phase 1 |
0x7D1D–0x7D1E |
32030–32031 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
RMS current on phase 2 |
0x7D1F–0x7D20 |
32032–32033 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
RMS current on phase 3 |
0x7D21–0x7D22 |
32034–32035 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
RMS current on the neutral(1) |
0x7D23–0x7D24 |
32036–32037 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
Maximum of RMS current of phases 1, 2, 3 and N (most loaded phase) (3) |
0x7D25–0x7D26 |
32038–32039 |
R |
– |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
Current ratio on ground (Ig setting ratio) |
0x7D27–0x7D28 |
32040–32041 |
R |
– |
FLOAT32 |
– |
E |
A/P/H |
X |
Current ratio on earth-leakage (IΔn setting ratio) (2) |
(1) Value available when system type register returns 30 or 41. (2) Value available with MicroLogic 7.0 X. (3) Value reset with the reset minimum/maximum command. |
Maximum Current Values
Maximum current values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D29–0x7D2A |
32042–32043 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
Maximum RMS current on phase 1 |
0x7D2B–0x7D2C |
32044–32045 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
Maximum RMS current on phase 2 |
0x7D2D–0x7D2E |
32046–32047 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
Maximum RMS current on phase 3 |
0x7D2F–0x7D30 |
32048–32049 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
Maximum RMS current on the neutral(1) |
0x7D31–0x7D32 |
32050–32051 |
R |
A |
FLOAT32 |
– |
A/E |
A/E/P/H |
X |
This is the highest (i.e. maximum) maximum current value since this measurement was last reset. The measurement looks at all 3 currents, MaxI1, MaxI2, MaxI3 and MaxIN and keeps track of the highest value of any of them over time. |
0x7D33–0x7D36 |
32052–32055 |
– |
– |
– |
– |
– |
– |
– |
Reserved |
(1) Value available when system type register returns 30 or 41. |
Voltage
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D37–0x7D38 |
32056–32057 |
R |
V |
FLOAT32 |
41.6–2250 |
E |
E/P/H |
X |
RMS phase-to-phase voltage V12 |
0x7D39–0x7D3A |
32058–32059 |
R |
V |
FLOAT32 |
41.6–2250 |
E |
E/P/H |
X |
RMS phase-to-phase voltage V23 |
0x7D3B–0x7D3C |
32060–32061 |
R |
V |
FLOAT32 |
41.6–2250 |
E |
E/P/H |
X |
RMS phase-to-phase voltage V31 |
0x7D3D–0x7D3E |
32062–32063 |
R |
V |
FLOAT32 |
24-1500 |
E |
E/P/H |
X |
RMS phase-to-neutral voltage V1N(1) |
0x7D3F–0x7D40 |
32064–32065 |
R |
V |
FLOAT32 |
24-1500 |
E |
E/P/H |
X |
RMS phase-to-neutral voltage V2N(1) |
0x7D41–0x7D42 |
32066–32067 |
R |
V |
FLOAT32 |
24-1500 |
E |
E/P/H |
X |
RMS phase-to-neutral voltage V3N(1) |
(1) Value available when system type register returns 40 or 41. |
Frequency
When the MicroLogic trip unit cannot calculate the frequency, it returns Not applicable = 0xFFC00000.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D43–0x7D44 |
32068–32069 |
R |
Hz |
FLOAT32 |
40.0–70.0 |
E |
P/H |
X |
Frequency |
0x7D45–0x7D46 |
32070–32071 |
R |
Hz |
FLOAT32 |
40.0–70.0 |
E |
P/H |
X |
Maximum frequency (1) |
(1) This value can be reset with the reset minimum/maximum command. |
Power
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D47–0x7D48 |
32072–32073 |
R |
W |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Active power on phase 1(1) (2) |
0x7D49–0x7D4A |
32074–32075 |
R |
W |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Active power on phase 2(1) (2) |
0x7D4B–0x7D4C |
32076–32077 |
R |
W |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Active power on phase 3 (1) (2) |
0x7D4D–0x7D4E |
32078–32079 |
R |
W |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Total active power(2) |
0x7D4F–0x7D50 |
32080–32081 |
R |
VAr |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Reactive power on phase 1(1) (2) |
0x7D51–0x7D52 |
32082–32083 |
R |
VAr |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Reactive power on phase 2(1) (2) |
0x7D53–0x7D54 |
32084–32085 |
R |
VAr |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Reactive power on phase 3(1) (2) |
0x7D55–0x7D56 |
32086–32087 |
R |
VAr |
FLOAT32 |
-16000000–16000000 |
E |
E/P/H |
X |
Total reactive power(2) |
0x7D57–0x7D58 |
32088–32089 |
R |
VA |
FLOAT32 |
0–16000000 |
E |
E/P/H |
X |
Apparent power on phase 1(1) |
0x7D59–0x7D5A |
32090–32091 |
R |
VA |
FLOAT32 |
0–16000000 |
E |
E/P/H |
X |
Apparent power on phase 2(1) |
0x7D5B–0x7D5C |
32092–32093 |
R |
VA |
FLOAT32 |
0–16000000 |
E |
E/P/H |
X |
Apparent power on phase 3(1) |
0x7D5D–0x7D5E |
32094–32095 |
R |
VA |
FLOAT32 |
0–16000000 |
E |
E/P/H |
X |
Total apparent power |
(1) Value available when system type register returns 40 or 41. (2) The sign for the active and reactive power depends on the configuration of:
|
Energy
Energy is stored in big-endian format: the most significant register is transmitted first.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D5F–0x7D62 |
32096–32099 |
R |
Wh |
INT64 |
– |
E |
E/P/H |
X |
Total active energy(2) |
0x7D63–0x7D66 |
32100–32103 |
R |
VARh |
INT64 |
– |
E |
E/P/H(1) |
X |
Total reactive energy(2) |
0x7D67–0x7D6A |
32104–32107 |
R |
Wh |
INT64U |
– |
E |
P/H |
X |
Total active energy delivered (into the load, counted positively)(2) |
0x7D6B–0x7D6E |
32108–32111 |
R |
Wh |
INT64U |
– |
E |
P/H |
X |
Total active energy received (out of the load, counted negatively)(2) |
0x7D6F–0x7D72 |
32112–32115 |
R |
VARh |
INT64U |
– |
E |
P/H |
X |
Total reactive energy delivered (into the load, counted positively)(2) |
0x7D73–0x7D76 |
32116–32119 |
R |
VARh |
INT64U |
– |
E |
P/H |
X |
Total reactive energy received (out of the load, counted negatively)(2) |
0x7D77–0x7D7A |
32120–32123 |
R |
VAh |
INT64U |
– |
E |
– |
X |
Total apparent energy(2) |
0x7D7B–0x7D7E |
32124–32127 |
R |
Wh |
INT64U |
– |
E |
– |
X |
Total cumulative active energy delivered (into the load, counted positively, not resettable) |
0x7D7F–0x7D82 |
32128–32131 |
R |
Wh |
INT64U |
– |
E |
– |
X |
Total cumulative active energy received (out of the load, counted negatively, not resettable) |
(1) This value is always positive with MasterPact MicroLogic E trip unit. (2) Value reset with the reset energies command. |
Average Values
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D83–0x7D84 |
32132–32133 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Average of 3-phase RMS currents |
0x7D85–0x7D86 |
32134–32135 |
R |
V |
FLOAT32 |
– |
– |
– |
X |
Average of 3 RMS phase-to-phase voltages: (V12+V23+V31)/3 |
0x7D87–0x7D88 |
32136–32137 |
R |
V |
FLOAT32 |
– |
– |
– |
X |
Average of 3 RMS phase-to-neutral voltages: (V1N+V2N+V3N)/3(1) |
(1) Value available when system type register returns 40 or 41. |
Maximum Power Values
Maximum power values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D89–0x7D8A |
32138–32139 |
R |
W |
FLOAT32 |
– |
– |
– |
X |
Maximum total active power |
0x7D8B–0x7D8C |
32140–32141 |
R |
VAr |
FLOAT32 |
– |
– |
– |
X |
Maximum total reactive power |
0x7D8D–0x7D8E |
32142–32143 |
R |
VA |
FLOAT32 |
– |
– |
– |
X |
Maximum total apparent power |
Maximum Average Values
Maximum average values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D8F–0x7D90 |
32144–32145 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Maximum of average of 3-phase RMS currents |
0x7D91–0x7D92 |
32146–32147 |
R |
V |
FLOAT32 |
– |
– |
– |
X |
Maximum of average of 3 RMS phase-to-phase voltages |
0x7D93–0x7D94 |
32148–32149 |
R |
V |
FLOAT32 |
– |
– |
– |
X |
Maximum of average of 3 RMS phase-to-neutral voltages |
Ground and Earth-Leakage Current
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D95–0x7D96 |
32150–32151 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Ground-fault current |
0x7D97–0x7D98 |
32152–32153 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Earth-leakage current(1) |
0x7D99–0x7D9A |
32154–32155 |
– |
– |
– |
– |
– |
– |
– |
Reserved |
(1) Value available with MicroLogic 7 |
Current Demand Values
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7D9B–0x7D9C |
32156–32157 |
R |
A |
FLOAT32 |
– |
E |
E/P/H |
X |
Current demand value on phase 1: I1 Dmd |
0x7D9D–0x7D9E |
32158–32159 |
R |
A |
FLOAT32 |
– |
E |
E/P/H |
X |
Current demand value on phase 2: I2 Dmd |
0x7D9F–0x7DA0 |
32160–32161 |
R |
A |
FLOAT32 |
– |
E |
E/P/H |
X |
Current demand value on phase 3: I3 Dmd |
0x7DA1–0x7DA2 |
32162–32163 |
R |
A |
FLOAT32 |
– |
E |
E/P/H |
X |
Current demand value on the neutral: IN Dmd(1) |
(1) Value available when system type register returns 30 or 41. |
Power Demand Values
-
For the block window, the demand value is updated at the end of the window.
-
For the sliding window,
-
If window duration is configured for less or equal to 15 minutes, the demand value is updated every 15 seconds
-
If window duration is configured for more than 15 minutes, the demand value is updated every 1 minute.
-
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DA3–0x7DA4 |
32164–32165 |
R |
W |
FLOAT32 |
– |
E |
E/P/H |
X |
Total active power demand: P Dmd |
0x7DA5–0x7DA6 |
32166–32167 |
R |
VAR |
FLOAT32 |
– |
E |
P/H |
X |
Total reactive power demand: Q Dmd |
0x7DA7–0x7DA8 |
32168–32169 |
R |
VA |
FLOAT32 |
– |
E |
P/H |
X |
Total apparent power demand: S Dmd |
Current Peak Demand Values
Current peak demand values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DA9–0x7DAA |
32170–32171 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Current peak demand value on phase 1: I1 dmd max |
0x7DAB–0x7DAC |
32172–32173 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Current peak demand value on phase 2: I2 dmd max |
0x7DAD–0x7DAE |
32174–32175 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Current peak demand value on phase 3: I3 dmd max |
0x7DAF–0x7DB0 |
32176–32177 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Current peak demand value on the neutral: IN dmd max(1) |
(1) Value available when system type register returns 30 or 41. |
Power Peak Demand Values
Power peak demand values are updated every 15 seconds. Power peak demand values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DB1–0x7DB2 |
32178–32179 |
R |
W |
FLOAT32 |
– |
– |
– |
X |
Total active power peak demand: P dmd max |
0x7DB3–0x7DB4 |
32180–32181 |
R |
VAR |
FLOAT32 |
– |
– |
– |
X |
Total reactive power peak demand: Q dmd max |
0x7DB5–0x7DB6 |
32182–32183 |
R |
VA |
FLOAT32 |
– |
– |
– |
X |
Total apparent power peak demand: S dmd max |
Maximum Ground and Earth-Leakage Current Values
Maximum ground and earth-leakage current values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DB7–0x7DB8 |
32184–32185 |
R |
A |
FLOAT32 |
– |
– |
– |
X |
Maximum ground-fault current |
0x7DB9–0x7DBA |
32186–32187 |
R |
V |
FLOAT32 |
– |
E |
– |
X |
Maximum earth-leakage current(1) |
0x7DBB–0x7DC0 |
32188–32193 |
– |
– |
– |
– |
– |
– |
– |
Reserved |
(1) Value available with MicroLogic 7. |
Maximum Voltage Values
Maximum voltage values can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DC1–0x7DC2 |
32194–32195 |
R |
V |
FLOAT32 |
41.6–2250 |
E |
E/P/H |
X |
Maximum RMS phase-to-phase voltage V12 |
0x7DC3–0x7DC4 |
32196–32197 |
R |
V |
FLOAT32 |
41.6–2250 |
E |
E/P/H |
X |
Maximum RMS phase-to-phase voltage V23 |
0x7DC5–0x7DC6 |
32198–32199 |
R |
V |
FLOAT32 |
41.6–2250 |
E |
E/P/H |
X |
Maximum RMS phase-to-phase voltage V31 |
0x7DC7–0x7DC8 |
32200–32201 |
R |
V |
FLOAT32 |
24–1500 |
E |
E/P/H |
X |
Maximum RMS phase-to-neutral voltage V1N(1) |
0x7DC9–0x7DCA |
32202–32203 |
R |
V |
FLOAT32 |
24–1500 |
E |
E/P/H |
X |
Maximum RMS phase-to-neutral voltage V2N(1) |
0x7DCB–0x7DCC |
32204–32205 |
R |
V |
FLOAT32 |
24–1500 |
E |
E/P/H |
X |
Maximum RMS phase-to-neutral voltage V3N(1) |
(1) Value available when system type register returns 40 or 41. |
Power Factor
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DCD–0x7DCE |
32206–32207 |
R |
– |
FLOAT32 |
– |
E |
E/P/H |
X |
Power factor on phase 1(1) |
0x7DCF–0x7DD0 |
32208–32209 |
R |
– |
FLOAT32 |
– |
E |
E/P/H |
X |
Power factor on phase 2(1) |
0x7DD1–0x7DD2 |
32210–32211 |
R |
– |
FLOAT32 |
– |
E |
E/P/H |
X |
Power factor on phase 3(1) |
0x7DD3–0x7DD4 |
32212–32213 |
R |
– |
FLOAT32 |
– |
E |
E/P/H |
X |
Total power factor |
0x7DD5–0x7DD6 |
32214–32215 |
R |
– |
FLOAT32 |
– |
E |
H |
X |
Fundamental power factor on phase 1 (cosϕ1)(1)(2) |
0x7DD7–0x7DD8 |
32216–32217 |
R |
– |
FLOAT32 |
– |
E |
H |
X |
Fundamental power factor on phase 2 (cosϕ2)(1)(2) |
0x7DD9–0x7DDA |
32218–32219 |
R |
– |
FLOAT32 |
– |
E |
H |
X |
Fundamental power factor on phase 3 (cosϕ3)(1)(2) |
0x7DDB–0x7DDC |
32220–32221 |
R |
– |
FLOAT32 |
– |
E |
H |
X |
Total fundamental power factor(2) |
(1) Value available when system type register returns 40 or 41. (2) The sign for the fundamental power factor (cosϕ) depends on the configuration:
|
Total Harmonic Distortion (THD)
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DDD–0x7DDE |
32222–32223 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of phase-to phase voltage V12 compared to the fundamental |
0x7DDF–0x7DE0 |
32224–32225 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of phase-to phase voltage V23 compared to the fundamental |
0x7DE1–0x7DE2 |
32226–32227 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of phase-to phase voltage V31 compared to the fundamental |
0x7DE3–0x7DE4 |
32228–32229 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of phase-to-neutral voltage V1N compared to the fundamental (1) |
0x7DE5–0x7DE6 |
32230–32231 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of phase-to-neutral voltage V2N compared to the fundamental (1) |
0x7DE7–0x7DE8 |
32232–32233 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of phase-to-neutral voltage V3N compared to the fundamental (1) |
0x7DE9– 0x7DEA |
32234–32235 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of current on phase 1 compared to the fundamental |
0x7DEB–0x7DEC |
32236–32237 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of current on phase 2 compared to the fundamental |
0x7DED–0x7DEE |
32238–32239 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Total harmonic distortion (THD) of current on phase 3 compared to the fundamental |
0x7DEF– 0x7DF0 |
32240–32241 |
R |
– |
FLOAT32 |
0–2 |
E |
H |
X |
Average of 3-phase current Total harmonic distortions (THD) compared to the fundamental |
(1) Value available when system type register returns 40 or 41. |
Maximum Power Factor
Maximum power factor can be reset with the reset minimum/maximum command.
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Description |
---|---|---|---|---|---|---|---|---|---|
0x7DF1–0x7DF2 |
32242–32243 |
R |
– |
FLOAT32 |
– |
– |
– |
X |
Maximum total power factor |
0x7DF3–0x7E52 |
32244–32339 |
– |
– |
– |
– |
– |
– |
– |
Reserved |
Inhibit Close Order
Address |
Register |
RW |
Unit |
Type |
Range |
A/E |
A/E/P/H |
X |
Bit |
Description |
---|---|---|---|---|---|---|---|---|---|---|
0x7E53 |
32340 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
Quality of each bit of register 32341:
|
0x7E54 |
32341 |
R |
– |
INT16U |
– |
A/E |
A/E/P/H |
X |
– |
Inhibit close order status |
0 |
Close breaker inhibited by IO module
|
|||||||||
1 |
Close breaker inhibited by communication
|
|||||||||
– |
– |
– |
2–15 |
Reserved |
Note for UL Mkt and project team (March 5 2014): “Bit always equal to 0 for Compact NS circuit breaker” in IEC guide is adapated to “Bit always equal to 0 for PowerPact circuit breaker”. Please validate it’s correct for all bits concerned in reg. 32001, 12001, and 661.