Comprehensive Analysis of Surge Protection Tester for Lightning Surge Immunity Testing: Focus on the LISUN SG61000-5 Surge Generator
Introduction
Surge protection testing is a crucial aspect of ensuring the reliability and safety of electrical and electronic devices, especially in environments prone to lightning strikes and power surges. The surge protection tester plays a pivotal role in evaluating the immunity of equipment to these sudden voltage spikes. In this article, we will provide a detailed analysis of surge immunity testing, specifically focusing on the LISUN SG61000-5 Surge Generator, a leading surge protection tester designed to meet international standards such as IEC 61000-4-5.
Overview of Surge Immunity Testing
Lightning strikes and switching transients are major sources of high-energy surges, which can cause severe damage to electrical and electronic systems. To mitigate these risks, surge protection devices (SPDs) are employed, and their effectiveness is validated through surge protection testers. These tests simulate real-world surge conditions to evaluate how well the equipment can withstand such stress without malfunctioning or being permanently damaged.
Key Standards for Surge Immunity Testing
The primary standard for surge immunity testing is IEC 61000-4-5, which specifies the test setup, parameters, and testing procedures for assessing the robustness of electronic equipment against high-energy surges. The LISUN SG61000-5 Surge Generator is compliant with this standard, making it suitable for testing a wide range of devices, including power supplies, communication equipment, and industrial control systems.
The Role of Surge Protection Testers
A surge protection tester, such as the LISUN SG61000-5, is designed to generate controlled surge pulses to simulate various surge scenarios. These testers can generate high-voltage and high-current pulses to mimic the conditions during a lightning strike or a switching transient. The main parameters of interest during surge testing include:
• Peak voltage: The maximum voltage generated during the surge event.
• Peak current: The maximum current that flows through the system during the surge.
• Pulse waveform: The shape and duration of the surge pulse, which typically follows a combination wave (1.2/50 μs voltage and 8/20 μs current).
The surge protection tester applies these pulses to the equipment under test (EUT) to assess its ability to withstand and recover from such conditions.
Key Features of the LISUN SG61000-5 Surge Generator
The LISUN SG61000-5 Surge Generator is a state-of-the-art surge protection tester designed for comprehensive surge immunity testing. Some of its key features include:
• Wide voltage and current range: The SG61000-5 can generate surge voltages up to 10 kV and surge currents up to 20 kA, making it suitable for testing high-performance SPDs and industrial equipment.
• User-friendly interface: The device is equipped with an intuitive touch-screen interface, allowing users to easily configure test parameters and monitor real-time test results.
• Compliant with IEC 61000-4-5: The surge generator meets all the requirements specified by the IEC standard, ensuring that the test results are valid and recognized globally.
• Multiple test modes: The SG61000-5 supports both single-phase and three-phase surge testing, enabling users to test a wide range of devices under realistic surge conditions.
• Automatic report generation: After the test, the system generates detailed reports that include test parameters, results, and pass/fail status, simplifying the documentation process.
SG61000-5_Surge Generator
Surge Testing Procedure Using the LISUN SG61000-5 Surge Generator
Step 1: Equipment Setup
The first step in surge immunity testing is setting up the equipment under test (EUT) and the surge protection tester. The EUT is connected to the surge generator according to the IEC 61000-4-5 standard, ensuring that all test conditions are met.
Step 2: Test Parameter Configuration
Using the touch-screen interface of the LISUN SG61000-5 Surge Generator, the test parameters such as surge voltage, surge current, and pulse duration are configured. For example, to simulate a lightning-induced surge, a voltage of 6 kV and a current of 3 kA can be selected.
Step 3: Conducting the Test
Once the test parameters are set, the surge generator applies the surge pulses to the EUT. The tester monitors the performance of the equipment, recording any failures or malfunctions.
Step 4: Analyzing the Results
After the test, the system generates a detailed report, which includes critical information such as the peak voltage and current during the test, the response of the EUT, and the final pass/fail status.
Data and Test Results
To illustrate the testing process, let’s consider a sample test using the LISUN SG61000-5 Surge Generator to evaluate the surge immunity of a power supply unit (PSU). The test parameters are configured as follows:

Test Parameter
Value

Surge Voltage
6 kV

Surge Current
3 kA

Pulse Waveform
1.2/50 μs & 8/20 μs

Number of Pulses
10

Test Duration
30 minutes

Test Results

Pulse No.
Peak Voltage (kV)
Peak Current (kA)
EUT Response
Pass/Fail

1
6
3.1
No malfunction
Pass

2
6.1
3
No malfunction
Pass

3
5.9
3.2
No malfunction
Pass

4
6
3
Temporary voltage drop
Pass

5
6.2
3.1
No malfunction
Pass

6
6
3
No malfunction
Pass

7
6.1
3.2
No malfunction
Pass

8
6
3
No malfunction
Pass

9
6.2
3.1
No malfunction
Pass

10
6
3
No malfunction
Pass

As seen from the test results, the power supply unit successfully withstood all 10 surge pulses, with only a minor temporary voltage drop during the fourth pulse. This demonstrates the high surge immunity of the PSU and the reliability of the LISUN SG61000-5 Surge Generator as a surge protection tester.
Applications of Surge Protection Testing
Surge protection testing is critical in several industries, including:
• Power systems: Surge immunity testing ensures that power supplies and transformers can withstand lightning-induced surges, preventing large-scale power outages.
• Telecommunication: Communication equipment, such as routers and modems, must be surge-protected to maintain network reliability during thunderstorms.
• Industrial control systems: Surge testing is vital for protecting programmable logic controllers (PLCs) and other control equipment from transient voltage events.
• Consumer electronics: Devices like televisions, refrigerators, and computers need surge protection to ensure they are safe for everyday use, particularly in regions with unstable power grids.
Conclusion
The LISUN SG61000-5 Surge Generator is a highly effective surge protection tester, designed to perform comprehensive surge immunity testing in compliance with international standards. Its ability to generate a wide range of surge pulses, coupled with its user-friendly interface and automatic report generation, makes it an essential tool for manufacturers and testing laboratories. Through rigorous testing, such as that demonstrated in this article, the robustness of electrical and electronic equipment against surges can be validated, ensuring the safety and reliability of these systems in real-world environments.
This analysis highlights the importance of surge immunity testing and the critical role that surge protection testers, like the LISUN SG61000-5, play in maintaining the integrity of various electrical systems. https://www.lisungroup.com/news/technology-news/comprehensive-analysis-of-surge-protection-tester-for-lightning-surge-immunity-testing-focus-on-the-lisun-sg61000-5-surge-generator.html

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