A Gas Discharge Tube (GDT) is a device used to protect electrical and electronic equipment from transient overvoltage events, such as lightning strikes and voltage surges. It operates based on the principle of gas ionization and provides a reliable means of diverting high-energy transient currents away from sensitive equipment, preventing damage or destruction.
Here's how a Gas Discharge Tube works and how it protects against surges:
Gas-Filled Enclosure: A GDT consists of a small glass or ceramic tube that is filled with a specific gas mixture, usually containing inert gases like neon or argon, along with a small amount of another gas. The gases are chosen to have a relatively high ionization potential, meaning they require a significant amount of energy to become ionized and allow electric current to flow.
Two Electrodes: Inside the tube, there are two electrodes separated by a small gap. These electrodes are typically made of metal and are designed in such a way that they promote an electric field across the gap.
Normal Operating Condition: Under normal operating conditions, when the voltage across the GDT is below a certain threshold (known as the breakdown voltage or striking voltage), the gas within the tube remains in a non-conductive state. In this state, the GDT has a very high impedance and does not conduct electric current.
Surge or Transient Event: When a transient overvoltage event, such as a lightning strike or voltage surge, occurs on the power line or signal line connected to the GDT, the voltage across the GDT rapidly increases. Once the voltage exceeds the breakdown voltage, the electric field across the gap becomes strong enough to ionize the gas.
Ionization and Conduction: Ionization of the gas creates a conductive plasma path between the two electrodes. This allows the GDT to rapidly divert the excess energy of the transient event away from the protected equipment. The GDT effectively "short circuits" the surge current and provides a low-resistance path for it to dissipate safely to ground.
Current Diversion: As the surge current is diverted through the ionized gas path, the voltage across the GDT drops significantly. Once the transient event subsides and the voltage returns to normal levels, the gas within the tube de-ionizes, and the GDT returns to its non-conductive state.
Gas Discharge Tubes are widely used in various applications, including power distribution systems, telecommunications networks, data centers, and electronic equipment, to protect against voltage spikes and surges. They offer fast response times and high energy-handling capabilities, making them effective and reliable surge protection devices.