Designed to outperform traditional two-zone models, the Three-Zone Thermal Shock Chamber redefines thermal shock testing with its innovative three-chamber structure—eliminating sample movement and minimizing thermal lag for unparalleled accuracy.
Core Design & Performance
Three Independent Zones: The high-temperature zone (up to +150℃ or customizable), low-temperature zone (down to -55℃ or lower), and central test zone work in tandem. Pre-conditioned hot/cold airflows switch seamlessly in the test zone, achieving ultra-fast temperature transitions (typically ≤15 seconds for -55℃ to +150℃) while maintaining uniform temperature distribution.
No Mechanical Transfer: Samples remain stationary in the test zone throughout testing, avoiding physical wear, position deviation, or inconsistent exposure—ensuring repeatable, reliable results.
Precise Control & Flexibility: Equipped with advanced PID temperature control, the chamber supports programmable dwell times, cycle counts, and custom temperature profiles. Intuitive touchscreen interfaces, real-time data logging, and remote monitoring capabilities simplify operation and data analysis.
Key Features & Advantages
Energy Efficiency: Insulated zones and optimized airflow design reduce energy consumption by up to 30% compared to conventional models.
Safety & Stability: Integrated over-temperature/over-pressure protection, pressure balance systems, and anti-freeze features ensure safe, continuous operation.
Customization Options: Available in various chamber sizes (from bench-top to floor-standing) to accommodate small components, large assemblies, or multi-sample testing. Optional water-cooled systems, extended temperature ranges, and specialized sealing solutions cater to unique industry needs.
Global Compliance: Meets strict international testing standards, making it suitable for global market access and cross-industry application.
Application Scenarios
Electronic components (semiconductors, circuit boards, batteries, sensors)
Aerospace parts (avionics, structural materials, engine components)
Automotive parts (connectors, modules, under-hood components)
Industrial materials (plastics, metals, composites, coatings)
Workflow Integration
Pre-Test Setup: Define parameters (voltage limits, cycle count) via intuitive touchscreen.
Test Execution: Chamber automates charge-discharge cycles while monitoring safety metrics.
Post-Test Analysis: Export Excel data for capacity fade analysis and compliance reporting.
Why Danle Thermal Shock Chamber?
Zero Sample Transfer: Samples stay stationary, reducing damage and test errors.
Ultra-Fast Transition: ≤15 seconds for -55℃ to +150℃ (customizable to -80℃~+200℃).
30% Energy Saving: Advanced VRF refrigerant control and high-density insulation.
Global Compliance: Meets IEC, MIL-STD, ASTM, and ISO standards for global market access.
Designed to outperform traditional two-zone models, the Three-Zone Thermal Shock Chamber redefines thermal shock testing with its innovative three-chamber structure—eliminating sample movement and minimizing thermal lag for unparalleled accuracy.
Core Design & Performance
Three Independent Zones: The high-temperature zone (up to +150℃ or customizable), low-temperature zone (down to -55℃ or lower), and central test zone work in tandem. Pre-conditioned hot/cold airflows switch seamlessly in the test zone, achieving ultra-fast temperature transitions (typically ≤15 seconds for -55℃ to +150℃) while maintaining uniform temperature distribution.
No Mechanical Transfer: Samples remain stationary in the test zone throughout testing, avoiding physical wear, position deviation, or inconsistent exposure—ensuring repeatable, reliable results.
Precise Control & Flexibility: Equipped with advanced PID temperature control, the chamber supports programmable dwell times, cycle counts, and custom temperature profiles. Intuitive touchscreen interfaces, real-time data logging, and remote monitoring capabilities simplify operation and data analysis.
Key Features & Advantages
Energy Efficiency: Insulated zones and optimized airflow design reduce energy consumption by up to 30% compared to conventional models.
Safety & Stability: Integrated over-temperature/over-pressure protection, pressure balance systems, and anti-freeze features ensure safe, continuous operation.
Customization Options: Available in various chamber sizes (from bench-top to floor-standing) to accommodate small components, large assemblies, or multi-sample testing. Optional water-cooled systems, extended temperature ranges, and specialized sealing solutions cater to unique industry needs.
Global Compliance: Meets strict international testing standards, making it suitable for global market access and cross-industry application.
Application Scenarios
Electronic components (semiconductors, circuit boards, batteries, sensors)
Aerospace parts (avionics, structural materials, engine components)
Automotive parts (connectors, modules, under-hood components)
Industrial materials (plastics, metals, composites, coatings)
Workflow Integration
Pre-Test Setup: Define parameters (voltage limits, cycle count) via intuitive touchscreen.
Test Execution: Chamber automates charge-discharge cycles while monitoring safety metrics.
Post-Test Analysis: Export Excel data for capacity fade analysis and compliance reporting.
Why Danle Thermal Shock Chamber?
Zero Sample Transfer: Samples stay stationary, reducing damage and test errors.
Ultra-Fast Transition: ≤15 seconds for -55℃ to +150℃ (customizable to -80℃~+200℃).
30% Energy Saving: Advanced VRF refrigerant control and high-density insulation.
Global Compliance: Meets IEC, MIL-STD, ASTM, and ISO standards for global market access.
