Accelerated Life Thermal Shock Chambers: Fatigue Testing, Product DurabilityOur Accelerated Life Thermal Shock Chambers are engineered to provide a highly intensive and efficient method
for fatigue testing and rigorous evaluation of product durability. These advanced systems rapidly expose components and assemblies
to extreme and abrupt temperature changes over numerous cycles,
simulating years of thermal stress in a compressed timeframe. By
accelerating the aging process and uncovering material fatigue,
joint failures, and other degradation mechanisms, our chambers are
invaluable for validating product longevity and ensuring robust
performance throughout its intended lifespan. Key Features- Accelerated Aging Capability: Designed to induce rapid thermal fatigue, allowing for the quick
identification of long-term reliability issues.
- Precise Cycle Control: Advanced programmable controllers enable the creation and
execution of complex thermal shock profiles with exact temperature
limits, dwell times, and transition rates for accurate fatigue
testing.
- High Cycle Count Durability: Built for continuous, high-volume cycling, ensuring the chamber
itself can withstand the demands of accelerated life testing.
- Rapid Temperature Change Rates: Capable of achieving extremely fast temperature transitions
between hot and cold zones, maximizing the thermal stress on test
articles.
- Two-Zone (or Multi-Zone) Design: Utilizes physically separated hot and cold chambers with an
automated transfer mechanism for instantaneous thermal shocking.
- Comprehensive Data Logging & Analysis: Integrated systems continuously record temperature profiles,
transfer times, and cycle counts, providing critical data for
fatigue analysis and life prediction models.
- Robust & Durable Construction: Features high-grade insulation and durable components, often with
stainless steel interiors, to ensure stability and longevity under
constant thermal cycling.
- User-Friendly Interface: Intuitive touchscreen controls and software simplify test
programming, real-time monitoring, and data export for detailed
reports.
- Advanced Safety Features: Equipped with multiple interlocks, over-temperature protection,
and alarm systems to safeguard both the equipment and the valuable
test samples.
Applications- Electronic Component Lifespan Prediction: Evaluating solder joint fatigue, material delamination, and
long-term reliability of ICs, PCBs, and connectors.
- Automotive Durability Testing: Accelerating the aging of ECUs, sensors, lighting, and other
vehicle systems to predict field performance.
- Aerospace Component Qualification: Assessing the long-term resilience of critical avionics and
structural components against repeated thermal cycles.
- Material Fatigue Analysis: Studying the effects of thermal stress on the long-term properties
of metals, plastics, composites, and adhesives.
- Medical Device Longevity: Validating the durability of devices that experience significant
temperature fluctuations over their service life.
- Consumer Product End-of-Life Prediction: Simulating years of use to identify potential failure points in
appliances, gadgets, and other consumer goods.
- Product Design Validation: Proactively identifying and mitigating design flaws related to
thermal cycling fatigue.
Benefits- Predictive Reliability: Uncovers long-term fatigue issues and potential failure modes that
might take years to manifest in real-world use.
- Enhanced Product Durability: Guarantees that products will perform reliably and safely
throughout their intended service life.
- Reduced Warranty Costs: Proactive identification and correction of design flaws before
market release minimizes costly field failures and recalls.
- Accelerated Development Cycles: Significantly shortens the time required to validate product
longevity, speeding up time-to-market.
- Optimized Material Selection: Provides critical data for choosing materials and designs that are
resistant to thermal fatigue.
- Compliance & Confidence: Generates robust data for meeting industry durability standards
and boosting customer trust.
Specifications| Model | TSC-49-3 | TSC-80-3 | TSC-150-3 | TSC-216-3 | TSC-512-3 | TSC-1000-3 | | Inside dimension(W x D x H) cm | 40 x 35 x 35 | 50 x 40 x 40 | 65x 50 x 50 | 60 x 60 x 60 | 80 x 80 x 80 | 100 x 100 x 100 | | Outside dimension(W x D x H)cm | 128x 190 x 167 | 138 x 196 x 172 | 149 x 192 x 200 | 158 x 220 x 195 | 180 x 240 x 210 | 220 x 240x 220 | | Internal material | #304 Stainless Steel | | External material | Powder coated #304 Stainless Steel | | High temperature range | 60 ℃ ~ 200 ℃ | | Low temperature range | 0 ℃ ~ -70 ℃ | | Test temperature range | 60 ℃ ~ 180 ℃ / 0 ℃ ~ -70 ℃ | | Temperature recovery time | 1-5min | | Temperature stability ℃ | ±2 | | Cylinder switching time | 10s | | High temperature ℃ | 150 | 150 | 150 | 150 | 150 | 150 | | Heating time (min) | 20 | 30 | 30 | 30 | 30 | 30 | | Low temperature | -40, -50, -65 | -40, -50, -65 | -40, -50, -65 | -40, -50, -65 | -40, -50, -65 | -40, -50, -65 | | Cooling time (min) | 40, 50, 60 | 40, 50, 60 | 40, 50, 60 | 40, 50, 60 | 40, 50, 60 | 40, 50, 60 | | Air circulation system | Mechanical convection system | | Cooling system | Imported compressor, fin evaporator, gas condenser | | Heating system | Fin heating system | | Humidification system | Steam Generator | | Humidification water supply | Reservoir, Sensor-controller solenoid valve, recovery-recycle
system | | Controller | Touch panel | | Electrical power requirements | 3 phase 380V 50/60 Hz | | Safety device | Circuit system load protection, compressor load protection, control
system load protection, humidifier load protection, overtemperature
load protection, fault warning light |
Ready to accelerate your product's lifespan testing and ensure
unmatched durability? Contact our experts today to discuss your
requirements for an Accelerated Life Thermal Shock Chamber and empower your product reliability efforts. |
