A transformer tap changer control scheme is a mechanism used to adjust the turns ratio of a transformer by changing the position of its tap changer. The primary purpose of tap changers is to regulate the voltage ratio of the transformer to accommodate variations in the incoming voltage or load conditions, ensuring that the output voltage remains within acceptable limits. This is especially important for distribution transformers that serve various loads with different voltage requirements.
Here's how a transformer tap changer control scheme typically functions:
Tap Changer Mechanism: A transformer tap changer is a mechanical device that allows for the adjustment of the winding turns ratio. It usually consists of a set of taps or connections on the transformer winding that can be switched between different positions. These taps are connected to a selector switch or a diverter switch.
Controller and Sensors: The tap changer control scheme incorporates a controller that receives input from sensors and other monitoring equipment. Sensors might include voltage sensors, current sensors, load sensors, and sometimes even temperature sensors. These sensors provide real-time information about the transformer's operating conditions.
Set-Point Reference: The controller compares the actual output voltage (measured by the voltage sensor) with a desired or set-point voltage. The set-point voltage is often predetermined based on the desired output voltage level.
Feedback Loop: The difference between the actual output voltage and the set-point voltage creates an error signal. This error signal is used as input to the control algorithm.
Control Algorithm: The control algorithm, often implemented in software, processes the error signal and determines whether tap changing is required. It considers the magnitude and direction of the voltage deviation from the set point and calculates the necessary tap change adjustment.
Tap Change Decision: Based on the control algorithm's calculations, the controller decides whether to change the tap position. If the output voltage is lower than the set point, the controller might initiate a tap increase to raise the output voltage. Conversely, if the output voltage is higher than the set point, a tap decrease could be initiated.
Tap Change Execution: Once the controller decides to change the tap position, it sends signals to the tap changer mechanism. The tap changer mechanism then physically switches the tap connections on the winding, adjusting the turns ratio.
Monitoring and Safety: During tap changing, the control scheme continuously monitors the transformer's parameters, including voltage, current, and temperature. It ensures that tap changing occurs smoothly without causing voltage spikes or other disruptions that could damage equipment. Safety features are also incorporated to prevent rapid tap changes that could harm the transformer or the connected system.
Feedback and Iteration: After a tap change is executed, the control scheme continues to monitor the output voltage and other parameters. If necessary, it will make additional adjustments to the tap position to maintain the desired voltage level.
In summary, a transformer tap changer control scheme functions as an automated system that continuously monitors the transformer's output voltage and other relevant parameters, calculates the required tap change adjustments, and executes those adjustments through a mechanical tap changer mechanism. This process helps to ensure stable and consistent output voltage despite variations in incoming voltage or load conditions.