In the power system, when two or more on load tap changers (LTC) operate in parallel, if the tap positions are not consistent, circulating current will be generated between the transformers, causing winding overheating, increased losses, and even endangering equipment safety. Therefore, a dedicated parallel balancing module must be used to achieve coordinated control of each transformer tap through the circulating current method. The M-0115A parallel balancing module launched by Beckwith Electric is the core component designed for this scenario, which can be combined with voltage regulators such as M-0067E or M-2001C/D to form a complete and stable parallel voltage regulation system. This article is based on product technical specifications and provides an in-depth analysis of the working principle, parameter settings, wiring points, and common on-site problem handling of M-0115A, providing authoritative reference for power engineers.
Product positioning and functional overview
M-0115A is an independent parallel balancing module that integrates all the additional components required for the parallel operation of on load tap changers. It uses the Circulating Current Method to automatically balance the tap positions of each transformer. This scheme complies with the requirements of ANSI C57.12.10-1988 Section 10.2 and has been adopted by numerous transformer manufacturers.
The core functions include:
Circulating current detection: Using a 0.2A rated CT input, detect the amplitude and phase of circulating current between transformers.
Sensitivity adjustment: 9-level sensitivity selection (from 2 times normal to 0.5 times normal) to prevent system oscillation (over sensitivity) or excessive tap deviation (under sensitivity).
Parallel/Independent Mode Switching: The panel switch allows the controller to operate in parallel or independent mode.
Transient protection: meets the requirements of ANSI/IEEE C37.90.1-1989 for oscillation wave and fast transient immunity, with input and output isolated from ground and withstand voltage of 1500Vac.
This module is designed to be compatible with voltage regulators with 0.2A load/circulating current input (such as Beckwith M-0067E, M-2001C/D) and can be installed on new transformers or retrofitted to existing equipment.
Working principle: Parallel control using circulation method
The basic principle of the circulating current method is that when the tap voltages of two parallel transformers are not consistent, a circulating current will be generated on the secondary side, and its size and direction reflect the deviation of the tap position. M-0115A detects the circulating current and generates a correction signal (usually proportional to the circulating current, with a phase lag of about 90 °) to be sent to the voltage regulating controllers of each transformer, causing the controllers to adjust the tap to reduce the circulating current.
Specific process:
The load current and circulating current of each transformer are superimposed by CT and sent to the current input terminal of M-0115A.
M-0115A internal processing circuit extracts circulating current components (through load current balancing and vector synthesis).
According to the sensitivity setting, output the corresponding amplitude DC or AC correction signal to the circulating current input port of the voltage regulator controller.
The voltage regulator controller combines the correction signal with the local voltage deviation to determine the boost or buck command.
The ultimate goal is to make the tap positions of each transformer the same and minimize the circulating current, which can usually be controlled within 5% of the rated current.

Key parameters and setting methods
3.1 Rated current input value
Rated current: 0.2A (continuous), corresponding to 1PU (per unit).
Short term overload capacity: 0.4A continuous; 2.9A lasts for 5 seconds; 3.3A lasts for 4 seconds; 4.0A lasts for 3 seconds; 5.0A lasts for 2 seconds.
The turns ratio design ensures that the iron core is not saturated under a 12VA load.
If the CT secondary is 5A on site, auxiliary CT (such as Beckwith M-0169A, variable ratio 5A: 0.2A) conversion must be used. If using phase to phase voltage (such as some wiring of M-0067E), it is important to note that it should be led out from terminal 5 of M-0169A instead of terminal 1 (only applicable to non-M-2001C/D controllers, as the latter have phase angle correction function).
3.2 Sensitivity switch (43S)
There are 9 levels of sensitivity adjustment, with level 1 being the highest sensitivity (2 times normal) and level 9 being the lowest (0.5 times normal). Proper setup is crucial:
Excessive sensitivity: The system reacts excessively to the circulation, causing frequent movements of the tap and resulting in hunting.
Low sensitivity: The circulating current cannot be effectively suppressed, and the tap deviation may reach several levels, increasing winding stress.
It is recommended to set the initial setting to the middle gear (about 5 or 6), and adjust it to the minimum circulation and smooth operation by observing the circulation (CT secondary can be measured with a clamp gauge) and tap action frequency on site.