A varistor, short for "variable resistor," is an electrical component that plays a crucial role in protecting electronic devices and circuits from overvoltage conditions. It is also commonly known as a Voltage Dependent Resistor (VDR) or a surge suppressor. The working principle of a varistor involves its nonlinear voltage-current characteristics, which make it an effective device for clamping and absorbing excessive voltages.
Here's how a varistor works and its role in overvoltage protection:
Working Principle:
A varistor is typically made from a ceramic material that contains zinc oxide grains. These grains are carefully formulated to have a high resistance under normal operating conditions but exhibit a significant decrease in resistance when subjected to high voltage spikes or surges. This nonlinearity in its current-voltage curve is what makes the varistor suitable for surge protection.
In a normal operating state, where the voltage across the varistor is below a certain threshold (its rated voltage), the varistor presents a high resistance and allows only a negligible current to flow through it. However, when the voltage across the varistor exceeds its threshold, its resistance drops dramatically, allowing a large amount of current to flow through it.
Role in Overvoltage Protection:
The primary function of a varistor is to protect sensitive electronic components and circuits from overvoltage events, such as lightning strikes, power surges, or transient voltage spikes. These events can occur due to various factors like lightning strikes, switching operations in the power grid, or faults in electrical equipment.
When an overvoltage event occurs, the voltage across the varistor rises above its threshold. At this point, the varistor's resistance drops significantly, effectively providing a low-resistance path for the excessive current to flow through. This has the following protective effects:
Voltage Clamping: The varistor "clamps" the voltage at its threshold level, preventing it from rising further and protecting downstream components from exposure to dangerously high voltages.
Energy Absorption: By allowing the excessive current to flow through it, the varistor dissipates the energy associated with the transient voltage spike. This prevents the energy from reaching and damaging sensitive components.
Diversion of Current: The varistor directs the excessive current away from the sensitive circuitry, reducing the likelihood of damage to the protected devices.
Once the overvoltage event subsides and the voltage returns to normal levels, the varistor's resistance increases again, effectively cutting off the excess current flow and returning the protection circuit to its standby state.
In summary, varistors serve as crucial components in overvoltage protection schemes by quickly responding to transient voltage spikes and surges, clamping the voltage to safe levels, and diverting excess energy away from sensitive components. This helps prevent damage to electronic devices and ensures the overall reliability and longevity of electrical systems.