Dual chamber vacuum box EZKT series

The thermal vacuum test chamber is suitable for applications in the fields of aviation, industrial and mining enterprises, home appliances, laboratories, research institutions and colleges and universities, where it can be used for high-temperature baking, low-temperature testing, high-low temperature cycling testing, temperature drying, low vacuum sealing tests, oxygen-free treatment, high-temperature stress relief, high-temperature curing, and high-temperature stage oxygen-free testing of products and materials. Technical Specifications Capacity0.5 m³ to 2.65 m³(Customizable) High Vacuum Level (mbar)5.0×10−7 No-load Vacuum Level (mbar)5.0×10−7(Room temperature) Vacuum Cube Leak Rate1×10−9std/cc/sec Pressure Regulation in  Multiple Ranges (mbar/Torr)Adjustable Temperature Range -190°C(LN2 cooling) to 150°C Temperature Uniformity±2℃ 1.Space Environment Simulation: •Replicates orbital conditions: thermal cycling, vacuum, and solar radiation (via optional xenon-arc lamps). 2.Precision Control: •PLC-based automation with real-time data logging, remote access via LabVIEW/Modbus protocols. 3.Durable Construction: •304L stainless steel chamber, multi-layer MLI (multi-layer insulation), and vibration-damping mounts. 4.Safety Systems: •Emergency venting, over-pressure relief valves, and redundant leak detection sensors. 5.Modular Design: •Expandable with solar simulation, outgassing analysis, or cryogenic shroud add-ons. Standards Supported 1.Military: •MIL-STD-810H (Method 501.7, 502.6), MIL-STD-1540E (Space Vehicle Requirements). 2.European Space: •ECSS-E-ST-10-03C (Thermal Vacuum Testing), ECSS-Q-ST-70-02C (Contamination Control). 3.Commercial: •NASA-HDBK-6022 (Materials Compatibility), ISO 14644-1 (Cleanroom Class 100–100,000). 4.Industry-Specific: •GSFC-STD-7000 (Goddard Space Flight Center), JAXA-STD-003 (Japan Aerospace). 1.Spacecraft & Satellites: •Validates payloads (e.g., sensors, thrusters) under LEO/ GEO thermal-vacuum conditions. 2.Aerospace Components: •Tests avionics, batteries, and propulsion systems for Mars rovers or lunar landers. 3.Semiconductors: •Evaluates radiation-hardened electronics for satellite communication or deep-space missions. 4.Materials Science: •Analyzes outgassing, thermal expansion, and cold welding of space-grade alloys/polymers. 5.Quantum Technologies: •Stabilizes cryogenic environments for superconducting qubits or quantum sensors.