Cable Test Thermal Shock Chamber

The cable testing thermal shock chamber is a key equipment used to evaluate the performance stability of cables under rapid extreme temperature changes. The following provides a detailed analysis from aspects such as equipment principles, technical parameters, application scenarios, selection points, and brand recommendations:

1. Equipment Principles and Functions

The thermal shock chamber simulates rapid switching of cables between high and low temperature environments to test changes in their physical and electrical properties. The equipment typically adopts a two-chamber or three-chamber structure:

Two-chamber: Samples are quickly transferred between the high-temperature and low-temperature zones via a basket or robotic arm.

Three-chamber: Samples are fixed in the test area, with rapid switching between high temperature, low temperature, and room temperature achieved through air dampers.

Main functions include:

Temperature shock testing: Simulates the usage of cables in extreme temperature environments.

Performance evaluation: Detects changes in insulation performance, mechanical strength, electrical properties, etc., of cables under thermal shock.

Reliability verification: Ensures cables can operate normally under extreme temperature conditions and meet industry standards.

2. Technical Parameters

Temperature range:

High-temperature zone: Typically up to +150°C to +200°C.

Low-temperature zone: Typically up to -60°C to -80°C.

Temperature transition time:

Two-chamber: Typically ≤15 seconds.

Three-chamber: Typically ≤5 minutes.

Temperature recovery time:

High-temperature zone: Typically ≤30 minutes.

Low-temperature zone: Typically ≤60 minutes.

Temperature uniformity:

Typically ≤±2°C.

Temperature fluctuation:

Typically ≤±0.5°C.

Sample weight:

Typically ≤3kg (depending on the equipment model).

Power supply:

Typically AC380V/50Hz.

3. Application Scenarios

Cable research and development:

Testing the performance of new cable materials under extreme temperatures.

Verifying the reliability of cable designs.

Quality control:

Detecting the stability of cable quality during production.

Ensuring cables comply with industry standards (such as GB, IEC, etc.).

Certification testing:

Meeting international or domestic certification requirements for cable products.

Providing performance basis for cables entering the market.

4. Selection Points

Temperature range and transition time:

Choose an appropriate temperature range and transition time based on cable testing requirements.

Ensure the equipment can simulate extreme temperature environments encountered in actual use.

Equipment stability and accuracy:

Select equipment with low temperature uniformity and fluctuation to ensure the accuracy of test results.

Pay attention to the long-term stability and reliability of the equipment.

Safety and protection:

The equipment should be equipped with multiple safety protection devices, such as over-temperature protection, leakage protection, etc.

Ensure the safety of operators.

Intelligence and ease of operation:

Choose equipment with programmable control functions, allowing preset test parameters and automatic test completion.

The equipment should have a user-friendly interface and data recording capabilities.

After-sales service and technical support:

Choose brands that provide comprehensive after-sales service and technical support.

Ensure timely maintenance and repair of the equipment during use.