Gas Discharge Tube Arresters (GDT)

Part Number	Description / PDF	Quantity
2049-13-BT1LF J.W. Miller / Bourns	GDT 130V 15KA 2 POLE TH	0
B88069X3030C253 TDK EPCOS	GDT 72V 10KA 3 POLE	0
SL1021A600C Wickmann / Littelfuse	GDT 600V 10KA 3 POLE	0
B88069X5641T902 TDK EPCOS	GDT 1200V 1KA 2 POLE SMD	0
2026-35-C2FLF J.W. Miller / Bourns	GDT 350V 20KA 3 POLE TH	611
2038-47-SM J.W. Miller / Bourns	GDT 470V 5KA 3 POLE SMD	0
2798530 Phoenix Contact	GDT 500V 10KA 2 POLE	0
2055-60-SM-RPLF J.W. Miller / Bourns	GDT 600V 2.5KA 2 POLE SMD	0
B88069X1673T602 TDK EPCOS	GDT 90V 20KA 2 POLE	0
2036-07-ALF J.W. Miller / Bourns	GDT 75V 10KA 3 POLE	0
SL1011A090C Wickmann / Littelfuse	GDT 90V 5KA 2 POLE	0
B88069X0680T502 TDK EPCOS	GDT 255V THROUGH HOLE	313
2056-60-B2FLF J.W. Miller / Bourns	GDT 600V 5KA 3 POLE THROUGH HOLE	0
CG2230SN Wickmann / Littelfuse	GDT 230V 20KA 2 POLE	0
2035-20-A J.W. Miller / Bourns	GDT 200V 5KA 2 POLE	0
2030-23T-SM-RPLF J.W. Miller / Bourns	GDT 185V 4KA 3 POLE SMD	157
SL1411A470SM Wickmann / Littelfuse	GDT 470V 10KA 2 POLE SMD	0
SG600 Wickmann / Littelfuse	GDT 600V 1KA 2 POLE SMD	0
2036-09-SM-RPLF-H J.W. Miller / Bourns	GDT 90V 10KA 3 POLE SMD	24
SL1411A350C Wickmann / Littelfuse	GDT 350V 10KA 2 POLE	0

Gas Discharge Tube Arresters (GDT)

1. Overview

Gas Discharge Tube Arresters (GDT) are voltage-dependent overvoltage protection devices that utilize ionization of gas to divert high-voltage transients to ground. They act as switches that remain non-conductive under normal operating conditions but rapidly transition to a low-impedance state when voltage exceeds a specific threshold. GDTs play a critical role in safeguarding electronic systems from lightning strikes, electrostatic discharge (ESD), and other transient voltage events in telecommunications, power distribution, and industrial automation systems.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Single-Electrode GDT	Compact design with one gas chamber, suitable for low-energy transients	Consumer electronics, IoT devices
Multi-Electrode GDT	Stacked electrodes for higher energy absorption and multi-stage protection	Telecom infrastructure, 5G base stations
Inert Gas GDT	Uses argon/neon for stable performance in harsh environments	Industrial control systems, aerospace
Metal Vapor GDT	Mercury/xenon vapor for ultra-fast response times	High-speed data lines, medical imaging equipment

3. Structure and Components

Typical GDT construction includes:

Ceramic or glass cylindrical body with hermetic sealing
Tungsten/copper alloy electrodes with precision spacing
Inert gas (e.g., argon, neon) or metal vapor filling
External insulation coating (epoxy/silicone rubber)
Threaded/metallic base for grounding connection

4. Key Technical Specifications

Parameter	Typical Range	Importance
DC Spark-over Voltage	70V 5kV	Determines trigger threshold
Impulse Spark-over Voltage	100V 10kV	Response under fast transients
Max Discharge Current	10kA 100kA	Overload handling capability
Response Time	0.1 s 1 s	Critical for ESD protection
Dielectric Strength	1kV 20kV/mm	Post-event insulation recovery

5. Application Fields

Major industry applications include:

Telecommunications: DSL modems, fiber optic transceivers, antenna protection
Industrial Automation: PLC systems, motor drives, sensor networks
Renewable Energy: Solar inverter DC inputs, wind turbine control cabinets
Railway Systems: Signaling equipment, traction converter protection
Case Study: 5G Base Station Implementation

Multi-electrode GDTs protect RF front-end modules from lightning surges
Combined with TVS diodes for multi-level protection architecture
Reduces maintenance costs by 40% in coastal deployments

6. Leading Manufacturers and Products

Manufacturer	Product Series	Key Features
Littelfuse	SPA-GDT Series	Hybrid gas-silicon integration, 10kA rating
Bourns	2021 Series	Surface-mount design, 500V breakdown
Eaton	Pulsar GDT	100kA max current, UL94 certified
Murata	MA48 Series	Nano-coated ceramic body, -55 C~125 C operation

7. Selection Guidelines

Key considerations for GDT selection:

Match breakdown voltage to system operating voltage (min. 1.2x nominal)
Verify discharge current rating exceeds maximum expected surge (IEC 61643-11 compliance)
Consider environmental factors (temperature, humidity, vibration)
Assess mounting requirements (through-hole vs surface-mount)
Coordinate with downstream protection devices for coordinated clamping
Check certification standards (UL, CSA, RoHS)

8. Industry Trends

Future development directions:

Miniaturization for high-density PCB applications (sub-5mm diameters)
Advanced nanogap technologies for sub-nanosecond response times
Integration with AI-based predictive maintenance systems
Development of eco-friendly alternative gases to replace SF6
Wide bandgap semiconductor hybrid protection devices
Increased adoption in EV charging infrastructure (DC fast chargers)