parameter
Residual voltage limit: 5~60V
Load unloading delay: 0~100 cycles (some secondary loads can be removed first)
3.4 Fixed Time Transfer
When the VT fuse of the bus is blown, making it impossible to monitor the bus voltage, the system can rely on a fixed delay (30-1000 cycles) to perform the transfer, assuming that the residual voltage of the bus is low enough at this time. This method is a last resort and should be used with caution.
Locking and troubleshooting
M-4272 is designed with multiple blocking conditions to prevent accidental transfer or operation under hazardous conditions. Understanding these locking logics is the key to troubleshooting.
4.1 Common locking conditions
New source voltage exceeding limit: If the new source voltage exceeds the upper or lower limit set value (5-180V), the transfer is locked.
External locking input: activated through programmed input contacts (such as manual locking switches).
Incomplete Transfer Lockout: If the transfer is not completed within the specified time (50-3000 cycles), the system enters a locked state and needs to be manually reset.
Bus VT disconnection (60FL): If a bus VT disconnection is detected, the user can choose to lock the transfer or force a fixed time transfer.
Circuit breakers in the same state: If both circuit breakers are closed or both are open, and Auto Close or Auto Trip is not enabled, the transfer is locked.
Open circuit of tripping/closing circuit: When the TCM/CCM detects that the circuit is not connected, it locks and transfers.
If the auxiliary contacts of the same circuit breaker have conflicting states, the locking transfer will occur.
4.2 Fault handling steps
View status indicator lights and HMI menu: Use M-3931 HMI or ISScom software to check the "Lockout/Locking" status and determine the specific reason for the lockout.
Check the new source voltage: Confirm that the new source voltage is within the allowable range and check the VT wiring.
Check external lockout input: Confirm if there is a continuous external signal lockout, check wiring and logic settings.
Reset lockout: After troubleshooting, press the STOP RESET button or reset through communication.
Check the position of the circuit breaker: Confirm that the actual state of the circuit breaker is consistent with the auxiliary contacts, and adjust the contact settings if necessary (with configurations of 5a/56a).
Check the TCM/CCM circuit: Ensure that the power supply to the tripping and closing coils is normal, the circuit is not disconnected, and the input voltage level matches (24/48/125/250VDC).
4.3 Common Misconduct and Prevention
Misusing the simultaneous mode for circuit breakers with large differences in closing time may result in excessively long parallel time. It is recommended to first measure the actual closing time of the circuit breaker and set the "closing command delay".
Incorrect setting of circuit breaker closing time: affecting the accuracy of phase transfer, adaptive learning should be enabled or written through actual measurement.
Neglecting VT polarity or phase sequence: resulting in phase angle measurement errors and transfer failures. During pre operation, it is essential to check the phase sequence (ABC/ACB) and VT configuration (line to ground or line to line).

Key points for debugging and commissioning
5.1 Pre commissioning inspection
VT/CT wiring: Confirm that the three voltage lines (S1, S2, Bus) are wired in the same way (all using wire to ground or wire to wire), and that the current CT (used for circuit breaker fault detection) is installed in the correct phase.
Circuit breaker status input: Configure 5a/5b/52SP contacts to ensure that the "closed/open" LED indication is correct.
Power and grounding: Ensure that both dual power sources (non redundant) provide power and the casing is reliably grounded.
5.2 Parameter Setting Process
Connect to COM1 port through ISScom software (default 9600,8, N, 1).
Set system parameters: rated voltage, rated current, phase sequence, VT/CT ratio, VT wiring method.
Configure common settings: transfer mode (sequential/simultaneous), new source voltage limit, circuit breaker closing time and deviation, pulse length, etc.
Configure various parameters for automatic and manual transfer separately (fast, in-phase, residual voltage, fixed time).
Assign input/output contacts: such as transfer start, lockout, load unload, status indication, etc.
Enable the required functions (27B, 81, 81R, 60FL, TCM/CCM, etc.).
Save settings and write them to the device.
5.3 Oscillographic Recording and Event Analysis
By utilizing the built-in waveform recording function, the voltage, current, and switch waveforms during the transfer process can be captured. Through ISSplot software analysis, it is possible to verify whether the transfer is successful, the trend of phase angle changes, and the action time of the circuit breaker. It is recommended to conduct a simulated transfer test (such as manual triggering) before commissioning and review the recorded data to verify the correctness of the settings.
Upgrades, replacements, and compatibility
For users who are still using the early analog M-0272/M-0236B, Beckwith offers the M-5072 retrofit kit, which allows the M-4272 to be installed directly in its original chassis position without rewiring. This kit includes brackets and wiring harnesses, reproducing the original terminal layout for seamless replacement, while bringing new functions such as digital diagnosis, waveform recording, and communication.