Transient overvoltages, also known as voltage surges or spikes, can occur in three-phase circuits due to various reasons such as lightning strikes, switching operations, or faults in the system. To suppress transient overvoltages in three-phase circuits, several methods and devices can be employed. Here are some common techniques:
Surge Arresters (Metal Oxide Varistors - MOVs): Surge arresters are devices connected across the phases and ground of the circuit to divert excess voltage to ground during transient events. MOVs are the most commonly used surge arresters. They have a high resistance at normal operating voltage and a low resistance during overvoltage events, effectively shunting the excess energy to ground.
Transient Voltage Suppressors (TVS Diodes): TVS diodes provide a low-resistance path to ground during overvoltage events, similar to MOVs. They can be used to protect sensitive components like integrated circuits and electronic devices from transient overvoltages.
RC Snubber Circuits: RC snubber circuits consist of a resistor (R) and a capacitor (C) connected in series or parallel across the circuit elements. They provide a controlled path for transient currents to flow, damping the overvoltages and reducing their amplitude.
Ferrite Cores and Inductive Filtering: Ferrite cores are used to provide inductive filtering, which can attenuate high-frequency components of transient overvoltages. These cores can be added to cables or conductors to absorb and suppress surges.
Surge Protection Devices (SPDs): SPDs are devices designed to protect electrical systems from transient overvoltages. They can include a combination of different protection methods, such as MOVs, gas discharge tubes, and filtering components.
Grounding and Bonding: Proper grounding and bonding of the system can help divert and dissipate transient energy safely into the ground, reducing the impact of overvoltages.
Isolation Transformers: Isolation transformers can provide a level of protection by electrically isolating the load from the source, preventing some transient overvoltages from propagating to the load.
Shielding: Shielding cables and conductors can help reduce the coupling of external electromagnetic interference, which could contribute to transient overvoltages.
Proper Circuit Design: Implementing proper circuit layout, separation of power and signal lines, and minimizing the lengths of exposed conductors can help reduce the susceptibility of the circuit to transient overvoltages.
Lightning Protection Systems: For outdoor installations, lightning protection systems, including lightning rods and grounding systems, can be employed to safely direct lightning strikes away from critical equipment.
It's important to note that the specific method or combination of methods used to suppress transient overvoltages depends on the characteristics of the circuit, the type of equipment being protected, and the level of protection required. Consulting with electrical engineers and following industry standards and guidelines is crucial when designing and implementing protection measures for three-phase circuits.