(21)
All variables must be programmed at the same time.
(22)
They have 4 decimal place.
8.3.9.13.- Programming alarms 1 and 2 (Relays 1 and 2)
Table 96: Modbus memory map: Programming alarms 1 and 2.
Programming alarms 1 and 2
Configuration variable
Address
Valid data margin
Default
value
Relay 1 Relay 2
Maximum value 2AF8-2AF9 2B02-2B03 depending on the variable 0
Minimum value 2AFA-2AFB 2B04-2B05 depending on the variable 0
Variable code 2AFC 2B06 Table 48 and Table 49 0
Connection delay 2AFD 2B07 0 - 9999 seconds 0
Hysteresis 2AFE 2B08 0 - 99 % 0
latch 2AFF 2B09
0 : No
1: Yes
0
Disconnection delay 2B00 2B0A 0 - 9999 seconds 0
Contacts status 2B01 2B0B
0 : Normally open
1: Normally closed
0
8.3.9.14.- Programming alarms 3 and 4 (Digital outputs T1 and T2)
Table 97: Modbus memory map: Programming alarms 3 and 4.
Programming alarms 3 and 4
Configuration variable
Address
Valid data margin
Default
value
Relay 1 Relay 2
Kilowatts per impulse 2B0C-2B0D 2B16-2B17 Table 57 0
Variable code 2B10 2B1A
Table 48, Table 49 and Table
56
0
Pulse width 2B11 2B1B 30 - 400 ms 100 ms
8.3.9.15.- Digital inputs
Table 98: Modbus memory map: Configuration of digital inputs.
Configuration variable
Address
Valid data margin
Default
value
Input 1 Input 2
Operating mode
(23)
2B66 2B67
0: Tariff
1: Logic state
2: Maximum demand synchronism pulse
(24)
0
(23)
If Input 1 is configured as a tariff and Input 2 is configured as a logic state (or vice versa) we will only have
2 tariffs.
(24)
Option available on digital input 1.
We can also read the status of the digital inputs when they are in logic mode:
The Function 0x04 is implemented for this variable.
109
Instruction Manual
CVM-C11
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