Voltage commutation is a critical process in controlling thyristors, which are semiconductor devices commonly used in power electronics applications like motor drives, power supplies, and voltage regulation. Thyristors, including silicon-controlled rectifiers (SCRs), gate turn-off thyristors (GTOs), and insulated-gate bipolar transistors (IGBTs), are known for their ability to control the flow of electric current in high-power circuits.
In a thyristor-based circuit, such as an AC-to-DC converter or an inverter, the thyristor needs to be triggered into conduction to allow current to flow through it. Once the thyristor is triggered (turned on), it remains in the conducting state even if the control signal is removed. This characteristic is called "latching." To turn off the thyristor, the current through it must drop below a certain threshold called the holding current.
Voltage commutation is a technique used to turn off a thyristor by applying a reverse voltage across it, causing the current through it to decrease below the holding current and allowing it to turn off. This is achieved by utilizing an additional semiconductor device, such as a diode or another thyristor, in conjunction with the main thyristor.
There are two main methods of voltage commutation:
Line Commutation: In this method, the AC voltage source itself is used to turn off the thyristor. When the AC voltage reverses polarity (crosses zero), the voltage across the thyristor becomes negative, which reduces the forward bias and helps decrease the thyristor current below the holding current. The thyristor turns off once the current goes to zero. This method is simple and does not require additional components but is limited by the AC line frequency.
Forced Commutation: This method involves the use of additional components to actively turn off the thyristor. One common technique is the use of a commutation circuit that includes a capacitor and an inductor in series with the thyristor. When the thyristor needs to be turned off, the capacitor is charged. Then, when the thyristor is triggered on, the capacitor discharges through the thyristor, creating a reverse voltage across it. This reverse voltage facilitates turning off the thyristor by reducing the current below the holding current.
Voltage commutation is particularly important for high-power applications where fast and reliable switching is required. By allowing controlled turn-off of thyristors, voltage commutation enables efficient and precise control over power flow, voltage levels, and current waveforms in various electrical systems.