How to Test the Reliability of Explosion Proof Valve for Battery - Wuxi Sinceriend New Material Technology Co., Ltd.

Testing the reliability of explosion-proof valves for batteries is essential to ensure they perform safely and effectively under extreme conditions. Below is a structured approach to validate their functionality, durability, and compliance with industry standards:

1. Pressure Cycle Testing

Objective: Verify the valve’s ability to withstand repeated pressure fluctuations and maintain sealing integrity.

Procedure:
- Subject the valve to cyclic pressure changes within its operational range (e.g., 0 to 10 bar) using a hydraulic or pneumatic test rig.
- Use sensors to monitor pressure release thresholds and record leakage rates during each cycle.
Criteria:
- The valve must activate at the specified pressure (e.g., 5 bar) with a tolerance of ±5%.
- Leakage should remain below acceptable limits (e.g., <0.1 mL/min) in both closed and open states.

2. Thermal Endurance Testing

Objective: Evaluate performance under extreme temperatures, simulating battery thermal runaway scenarios.

Procedure:
- Place the valve in a climatic chamber and expose it to temperature ranges from -40°C to 125°C (or higher for high-risk applications).
- Apply pressure cycles at each temperature plateau and measure response time and seal integrity.
Criteria:
- No deformation, cracking, or material degradation should occur after 1,000+ thermal cycles.
- Activation pressure must remain consistent across the temperature range.

3. Chemical Resistance Testing

Objective: Ensure materials withstand exposure to battery electrolytes (e.g., lithium hexafluorophosphate in organic solvents).

Procedure:
- Immerse valve components (seals, diaphragms, springs) in electrolyte solutions for 72+ hours.
- Conduct visual inspections, hardness tests, and tensile strength measurements before and after exposure.
Criteria:
- Weight loss or dimensional change should be <2%.
- Seals must retain ≥90% of their original elasticity after chemical exposure.

4. Explosion Simulation Testing

Objective: Validate the valve’s ability to vent 爆炸性 gases (e.g., H₂, CH₄) safely without igniting surrounding environments.

Procedure:
- Use a sealed chamber to generate a controlled explosion (e.g., mixing air with 5–15% hydrogen by volume).
- Measure peak pressure, venting time, and flame propagation outside the chamber.
Criteria:
- The valve must activate within 50 ms of pressure surge.
- No external flame or sustained combustion should occur during or after venting.

5. Vibration and Mechanical Shock Testing

Objective: Assess durability in dynamic environments (e.g., automotive or aerospace applications).

Procedure:
- Mount the valve on a shaker table and apply sinusoidal or random vibration profiles (e.g., 10–2000 Hz, 3 g RMS).
- Subject it to mechanical shocks (e.g., 50 g, 11 ms half-sine wave).
Criteria:
- No loose components or structural damage should occur after 24 hours of vibration.
- Sealing performance must remain within specifications post-shock.

6. Long-Term Aging Testing

Objective: Predict service life by accelerating material degradation.

Procedure:
- Age components at elevated temperatures (e.g., 85°C, 85% RH) for 1,000 hours (equivalent to ~5 years of real-world use).
- Test pressure activation, leakage, and mechanical properties periodically.
Criteria:
- Activation pressure deviation should be <10% of the nominal value.
- Seals must pass bubble leak tests (e.g., submerged in water at 1 bar) without visible bubbles.

7. Compliance with Standards

Ensure testing aligns with international norms:

ATEX/IECEx: For explosion-proof certification in hazardous areas.
UN38.3: For lithium battery safety (applicable to valve integration in battery packs).
ISO 16750: For automotive environmental loads (vibration, temperature, etc.).