câmara de teste de temperatura ambiente

• Customization Process of Walk-in Environmental Test Chambers: A Professional Guide from Requirement to Delivery

  Dec 03, 2025

      As core equipment for industrial testing, the customization level of walk-in environmental test chambers directly determines testing accuracy and efficiency. This article breaks down the entire process from requirement communication to final delivery, helping enterprises clearly grasp the key nodes of customization. 1. Accurate Requirement Communication: Clarify Core Parameters The first step in customization is to define core technical parameters, which lay the foundation for subsequent design. Size Range: Covering small test spaces of 4m³ to large walk-in test chambers of 260m³, the size should be determined based on the volume, quantity of test samples and operational space requirements. Temperature & Humidity Range: It can generally achieve temperature control of -70℃~+180℃ and humidity control of 30%R.H~98%R.H. For special scenarios, the range can be further expanded to -73℃~+177℃ (integral type). Control Method: Multiple options are available, from basic microchip LED displays to PLC programmable logic controller touch screens, and can also be upgraded to remote centralized control systems to meet different operation and management needs. Structure Type: Selection should be based on application scenarios, with parameters of three mainstream types as follows: Test Type Temperature Range Humidity Range Temperature Change Rate Integral Type -73℃~+177℃ 30%~95%RH 4~5℃/min, or faster Assembled Type -68℃~+85℃ 30%~95%RH 1~2℃/min Steady-state Type -20℃~+50℃ 30%~95%RH N/A 2. Scheme Design & Confirmation: Balance Professionalism and Practicality After clarifying requirements, the technical team will issue a customization scheme, which mainly includes three parts: Structural Design: Based on size and type, plan the layout of the test chamber's door, observation window and sample rack to ensure operational convenience and airtightness.  System Matching: Equip with corresponding refrigeration, heating, humidification and dehumidification systems to ensure temperature and humidity control accuracy, and configure hardware and software according to the control method. Compliance Verification: The scheme must conform to relevant industry standards (such as GB/T, IEC, etc.), and confirm with the customer whether it needs to meet specific industry testing specifications. After scheme confirmation, detailed drawings and technical agreements will be generated to clarify the rights, obligations and delivery standards of both parties. 3. Production & Manufacturing: Strictly Control Process and Quality Entering the production stage, the process will be controlled around the two cores of "accuracy" and "stability": Core Component Procurement: Select high-reliability compressors, sensors, controllers and other core components to ensure long-term operational stability of the equipment. Modular Production: Assembled equipment adopts modular manufacturing to reduce on-site installation errors; integral equipment undergoes integrated assembly and preliminary debugging. Factory Inspection: Each piece of equipment must undergo no-load temperature and humidity calibration and operational stability testing. Only after confirming that the parameters meet the design requirements can shipment be arranged. 4. Installation, Commissioning & Delivery: Ensure On-site Application After the equipment arrives at the site, the professional team will provide full-process services: On-site Installation: Carry out equipment positioning, pipeline connection and circuit debugging according to site conditions; for assembled equipment, ensure airtight connection of each module. Accuracy Calibration: Combine the customer's testing needs, use professional instruments to perform on-site calibration of temperature and humidity uniformity and fluctuation to ensure compliance with test requirements. Training & Delivery: Provide equipment operation and maintenance training for the operation team, and deliver technical materials such as operation manuals and calibration reports to complete the final acceptance.     Would you like me to supplement an English Version of Walk-in Environmental Test Chamber Customization Requirement Confirmation Form? It will list key parameter check items and common questions to facilitate quick alignment of requirements between you and your customers.

  TAGS QUENTES : fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Walk-in Environmental Test Chambers Testing Equipment Environmental Chamber

  LEIA MAIS
• Operation Notes for Rapid Temperature Change Test Chambers: Don't Overlook These Key Points

  Dec 02, 2025

      As a core device for environmental reliability testing, the rapid temperature change test chamber is widely used in electronics, automotive, and other industries due to its ability to achieve drastic temperature variations. Its high/low temperature performance and rapid temperature change capability directly affect test data accuracy, operational safety, and equipment service life. Below are the core operational precautions: I. Pre-Startup: Conduct Basic Inspections Comprehensive pre-startup checks are critical for preventing malfunctions, focusing on "medium, status, and connections": Medium & Pipeline Inspection: Verify that the cooling system's liquid level and pressure meet standards, with no pipeline leakage or blockage. Check the refrigerant system pressure to avoid cooling failure or compressor damage due to insufficient medium. Equipment Status Confirmation: Ensure the chamber door seal is intact (poor sealing reduces temperature change rate and increases energy consumption). Keep the chamber interior clean and free of debris, and ensure sensor surfaces are free of oil and dust to avoid temperature measurement interference. Electrical Connection Check: Confirm power and control cables are securely connected, and the grounding resistance complies with specifications (≤4Ω) to prevent electric leakage or electromagnetic interference. II. Sample Placement: Prioritize Scientific Standards Proper sample placement ensures test authenticity, adhering to the principles of "no interference, no overrun, easy monitoring": Weight & Volume Control: Total sample weight must not exceed the rated load. Single sample volume ≤ 1/3 of the working chamber. Maintain a distance of ≥5cm from the chamber walls and sensors to avoid uneven local temperature caused by airflow blockage. Sample Compatibility: Never place flammable, explosive, corrosive, or toxic samples. For heat-generating samples, specify power in advance to ensure compatibility with the equipment's heat dissipation capacity and prevent overload. Fixing & Wiring Specifications: Secure samples with dedicated brackets to prevent displacement during temperature changes. Use high-temperature resistant insulated wires for energized tests to avoid short circuits and aging. III. Operation Process: Precise Monitoring & Adjustment Dynamic monitoring during operation guarantees test reliability, focusing on "parameters, status, and abnormalities": Parameter Setting & Verification: Set temperature range, change rate, and other parameters per standards and re-verify. Adjust only after the equipment stabilizes to avoid system fluctuations. Operation Status Monitoring: Real-time monitor temperature curves and indicator lights to ensure the deviation between actual and set temperatures ≤ ±1℃. Listen for abnormal noises from components like the compressor and shut down immediately if detected. Abnormal Handling: If the equipment triggers over-temperature, overload, or other protections, do not force reset. First troubleshoot the cause (e.g., abnormal sample heating, unstable voltage) before restarting. IV. Post-Test: Standardized Shutdown & Maintenance Proper post-test procedures extend equipment life, following three steps: "cooling, cleaning, and recording": Gradual Cooling to Prevent Damage: After testing, open the door only when the chamber temperature drops to room temperature (20-25℃) and the temperature difference with the outside ≤10℃, avoiding sample condensation or chamber wall damage. Cleaning & Maintenance: Wipe the chamber interior and door seal with a dry cloth. Use dedicated cleaners for leaked substances. Remove dust from the equipment exterior to ensure unobstructed heat dissipation. Data & Status Recording: Document test parameters, curves, and abnormalities. After turning off the power, cut off the cooling medium supply and organize wires and brackets. V. Long-Term Maintenance: Extend Equipment Lifespan Regular maintenance prolongs service life: Monthly: Check the door seal elasticity and replace if aged. Quarterly: Clean the condenser and evaporator. Annually: Arrange professional inspection and maintenance of the compressor and refrigeration system. The core of test chamber operation is "safety first, standardized operation, and precise monitoring." Strict adherence to the above precautions ensures safety, reliable test data, and extended equipment life, providing strong support for product reliability verification.

  TAGS QUENTES : câmaras de teste de mudança rápida de temperatura câmara de temperatura fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Testing Equipment

  LEIA MAIS
• How to Achieve Precise Temperature Control in High-Low Temperature Test Chambers? The Q8 Series Controller Has the Answer

  Nov 29, 2025

  As the "control core" of high-low temperature test chambers, the Q8 Series Controller delivers stable support for environmental reliability testing with full-scenario adaptability, ultra-high precision, and multiple safety designs. Whether for extreme testing of electronic components or weather resistance verification of new materials, its rich functions and user-friendly design meet the rigorous requirements of scientific research, industrial production, and other fields. I. Intuitive Touch Interaction: Doubling Operational Efficiency Adopting full-touch interaction, the Q8 Controller features a high-definition touchscreen with sensitive response, enabling parameter setting, program startup, and other operations with simple finger taps—no professional training required for new users. The customizable interface allows pinning frequently used functions, significantly reducing configuration time for complex tests and adapting to high-frequency, multi-batch testing scenarios. II.  0.01-Class Precision: Core Guarantee for Accurate Data Equipped with a high-precision data acquisition module and intelligent PID algorithm, the Q8 achieves 0.01-class temperature control precision, capturing real-time temperature fluctuations inside the chamber and adjusting rapidly. Within the wide temperature range of -80℃~150℃, the fluctuation is stabilized at ±0.01℃, avoiding temperature deviations in sensitive tests such as semiconductor and aerospace component testing, and providing authoritative data for product reliability evaluation. III. Versatile Adaptability: Meeting Multi-Scenario Needs Compatible with PT100, thermocouples, and other sensors, the Q8 supports flexible switching to reduce equipment upgrade costs. Its cooling output function precisely controls the refrigeration system to minimize energy waste, while the transmission output converts temperature data into standard electrical signals, seamlessly connecting to data acquisition systems for automatic upload and traceability of test data. IV.  Massive Storage: Intelligent Manager for Complex Processes Catering to multi-stage testing needs (e.g., automotive parts), the Q8 supports storage of 100 process programs, each with up to 50 steps. Operators can preset parameters such as temperature and holding time to simulate working conditions like day-night cycles and extreme temperature shocks. Programs can be activated with one click for continuous operation, enhancing the standardization and efficiency of batch testing. V.  EVT Function: Early Warning Barrier for Test Safety The Q8’s EVT (Event Verification Test) function monitors temperature abnormalities, sensor failures, and other issues in real time. When thresholds are triggered, it activates audio-visual alarms and records fault information. Supporting hierarchical fault handling, it automatically adjusts parameters to resume testing for minor anomalies and shuts down urgently for severe faults, safeguarding unattended long-duration tests. Conclusion: Empowering Test Reliability with Strong Capabilities Integrating intuitive touch operation, 0.01-class precision, versatile adaptability, and comprehensive safety guarantees, the Q8 Controller fully meets the core requirements of high-low temperature testing. Whether for precise scientific research or production quality control, its stable performance and intelligent design serve as the core competitiveness of test chambers, helping industries improve product quality.

  TAGS QUENTES : Câmara de teste de umidade de alta e baixa temperatura fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Environmental Chamber High-Low Temperature Test Chambers

  LEIA MAIS
• Core Faults and Troubleshooting of Thermal Shock Chambers

  Nov 27, 2025

  I. Temperature-related Issues Failure to reach set temperature: Check operation of heater/compressor, replace if damaged; calibrate sensor, replenish refrigerant if leaking; replace aging sealing strips. Slow shock rate: Clean air duct filter/condenser dust; inspect fan and switching valve, lubricate or replace if stuck.  Large temperature fluctuation: Calibrate thermostat PID parameters; reduce sample load (≤30% of chamber volume), place evenly without blocking air ducts. II. Refrigeration-related Issues Slow cooling in low-temperature zone: Clean condenser fins; detect leaks and replenish refrigerant; activate defrost program or replace expansion valve. Frequent compressor on/off: Stabilize power supply voltage, improve equipment room ventilation; replenish refrigerant or replace refrigeration oil. High-pressure alarm: Clean condenser and inspect cooling fan. III. Mechanical-related Issues Poor door sealing: Adjust door latch, replace aging sealing strips; calibrate chamber levelness. Stuck transfer mechanism: Clean guide rail debris and lubricate; calibrate position sensor. Abnormal noise (fan/valve): Add lubricating grease, replace worn bearings; clean valve impurities. IV. Electrical-related Issues Failure to start: Reset emergency stop button, inspect power supply/air switch; rewire if grounding is poor. Abnormal display: Reconnect cable, test power module; restore factory settings after backing up parameters. Alarm code triggered: Troubleshoot per code prompt (e.g., E1 overheating: check heater/sensor); contact manufacturer for repeated alarms. V. Key Notes Power off before troubleshooting; refrigeration system maintenance requires professional operation. Clean filter weekly, inspect seals monthly, and calibrate sensor annually.

  TAGS QUENTES : fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de choque de temperatura câmara de teste de temperatura ambiente Environmental Chamber Thermal Shock Chambers

  LEIA MAIS
• What should we pay attention to when using a thermal shock test chamber (water-cooled)?

  Nov 22, 2025

  I. Before Operation Use deionized water or distilled water as cooling water (to prevent scale formation); control temperature at 15-30℃, pressure at 0.15-0.3MPa, flow rate ≥5L/min. Clean the Y-type filter element in advance to ensure unobstructed water flow. Inspect water supply/drainage pipelines for secure connections, no leakage or kinking; keep drainage ports unobstructed with a height difference ≥10cm. Ensure the environment is ventilated and dry, grounding resistance ≤4Ω, and power supply (AC380V±10%) stable. Keep the inner chamber and shelves clean. Sample volume ≤1/3 of effective capacity, with weight evenly distributed on shelves. Seal moisture-sensitive parts of non-hermetic samples to avoid condensation affecting test accuracy. II. During Operation Real-time monitor cooling water pressure, flow rate and temperature. Immediately shut down for troubleshooting (pipeline blockage, leakage or chiller failure) if pressure drops sharply, flow is insufficient or temperature exceeds 35℃. Set high/low temperature parameters per GB/T, IEC and other standards (not exceeding rated range); control heating/cooling rate ≤5℃/min. Prohibit instantaneous switching between extreme temperatures. Do not open the door arbitrarily during operation (to prevent scalding/frostbite from hot/cold air). Use protective gloves for emergency sample handling. Shut down immediately for maintenance upon alarm (overtemperature, water shortage, etc.); prohibit forced operation. III. After Test Turn off power and cooling water inlet/outlet valves; drain residual water in pipelines. Clean the water tank and replace water monthly; add special water stabilizer to extend pipeline service life. Wipe the inner chamber and shelves after temperature returns to room temperature. Clean the air filter (1-2 times monthly); inspect pipeline seals and replace aging/leaking ones promptly. For long-term non-use: Power on and run for 30 minutes monthly (including water cooling system circulation), inject anti-rust protection fluid into pipelines, and cover the equipment with a dust cover in a dry, ventilated place. IV. Prohibitions Prohibit using unqualified water (tap water, well water, etc.) or blocking filters/drainage ports (to avoid affecting heat dissipation). Prohibit overloading samples or unauthorized disassembly/modification of water cooling pipelines/core components. Repairs must be performed by professionals. Prohibit frequent start-stop (wait ≥5 minutes after shutdown before restarting). Prohibit placing flammable, explosive or corrosive substances.

  TAGS QUENTES : Câmara de teste de alta e baixa temperatura Câmara de teste de choque térmico fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de choque de temperatura câmara de teste de temperatura ambiente

  LEIA MAIS
• Maintenance Methods for Industrial Precision Oven

  Nov 20, 2025

  As core industrial equipment for precise temperature control, drying and curing, precision ovens’ operational stability directly impacts product quality and production efficiency. Scientific maintenance extends service life and ensures process parameter accuracy. Below are key methods divided into daily basic maintenance and regular in-depth maintenance. I. Daily Basic Maintenance: Safeguard Fundamental Operation Daily maintenance, the first line of stable operation defense, is performed before startup, during operation and after shutdown—simple yet critical. 1. Comprehensive Cleaning: Eliminate Impurities Wipe the oven cavity, shelves and door seal daily to remove debris, dust, cured stains or oil. Use neutral detergent and a clean cloth to avoid cavity corrosion. Regularly clean the exterior and heat dissipation holes for unobstructed heat dissipation. 2. Parameter & Safety Checks: Ensure Accuracy and Safety Verify that temperature controller, timer and other parameters match process requirements before startup, and check for stable display without drift. Inspect door interlock sensitivity, power cords, heating tube terminals and cooling fan for abnormalities. Confirm emergency stop buttons and over-temperature protection devices function properly to eliminate hidden dangers. 3. Standardized Operation: Reduce Human-induced Wear Avoid overloading workpieces and ensure proper spacing for hot air circulation to prevent local overheating. Follow the manual for temperature rise/drop—no sudden startup/shutdown or drastic adjustments to avoid furnace cracking. Turn off main power only when temperature drops below 50℃ to extend heating element life. II. Regular In-depth Maintenance: Enhance Core Performance Recommended monthly or quarterly, regular maintenance focuses on core components and requires professional technicians. 1. Heating & Circulation System Overhaul: Ensure Efficiency Inspect heating tubes for oxide layers, scale or abnormal resistance (replace if needed), and clean/fasten junction box terminals with insulating grease. Disassemble fan impellers to remove dust and oil, lubricate bearings, replace damaged seals and adjust air duct baffles for uniform hot air circulation. 2. Temperature Control Calibration: Improve Accuracy Calibrate temperature sensors with a standard thermometer—adjust parameters or replace sensors if deviation is excessive. Inspect signal transmission lines for interference or poor contact. Verify multi-stage heating curve accuracy for programmable ovens. 3. Furnace Structure Maintenance: Extend Service Life Check insulation layers for damage and refill insulation material if heat dissipation is abnormal. Replace aged or deformed door seals. Repair the cavity’s high-temperature resistant coating to prevent rusting.

  TAGS QUENTES : Forno Industrial Forno de secagem fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Test Equipment

  LEIA MAIS
• Common Faults and Practical Solutions for High-Low Temperature Humidity Test Chambers

  Nov 19, 2025

  High and low temperature humidity test chambers are key reliability testing equipment, widely used in electronics, automotive and biomedicine. Their stability directly affects test accuracy. This article summarizes common faults and solutions for efficient troubleshooting. I. Temperature-related Faults: Core Impact on Test Accuracy 1. Failure to Reach Set Temperature Fault Performance: Fails to reach target temperature when heating; slow or no cooling.Possible Causes: Abnormal power voltage, burned heater, compressor failure, fan stop, air duct blockage.Solutions: Verify power matches rated specs (220V/380V); check fan operation and clean duct debris; contact professionals to replace faulty parts if heater/compressor fails. 2. Large Temperature Fluctuation and Poor Uniformity Fault Performance: Excessive temperature difference in the chamber or frequent fluctuations near set value.Possible Causes: Abnormal fan speed, damaged air duct seals, over-dense samples blocking airflow.Solutions: Arrange samples for ventilation; check fan stability and replace damaged seals promptly. 3. Severe Temperature Overshoot Fault Performance: Temperature overshoots set value significantly before dropping.Possible Causes: Improper controller settings, energy regulation system failure.Solutions: Restart to reset parameters; if unresolved, have technicians calibrate controller or overhaul regulation modules. II. Humidity-related Faults: Directly Linked to Test Environment Stability 1. Failure to Reach Set Humidity Fault Performance: Slow or no humidification.Possible Causes: Empty humidification tank, faulty water level sensor, burned humidifier tube, blocked solenoid valve.Solutions: Replenish water; clean valve filter; replace tube or repair sensor if humidifier fails to heat. 2. High Humidity That Cannot Be Reduced Fault Performance: Humidity remains above set value; dehumidification fails.Possible Causes: Faulty dehumidification system, poor chamber sealing, high ambient humidity.Solutions: Check door seals and reduce ambient humidity; report for repair if dehumidification module fails. 3. Abnormal Humidity Display Fault Performance: Humidity reading jumps, disappears or deviates greatly from reality.Possible Causes: Aging humidity sensor, contaminated probe.Solutions: Wipe probe with clean cloth; calibrate or replace sensor if inaccuracy persists. III. Operation and Circulation Faults: Ensure Basic Equipment Operation 1. Fan Not Rotating or Making Abnormal Noise Possible Causes: Motor damage, foreign objects in fan blades, worn bearings.Solutions: Clean debris after power-off; replace motor or bearings if fault persists. 2. Compressor Abnormality Fault Performance: Compressor fails to start or stops frequently after starting.Possible Causes: Power phase loss, overload protection trigger, refrigerant leakage.Solutions: Check three-phase wiring; retry after overload reset; report for refrigerant and compressor inspection if fault recurs. 3. Equipment Alarm Fault Performance: Alarms like "phase loss" or "overload" activate.Possible Causes: Triggered protection from wrong phase sequence, unstable voltage or overheated components.Solutions: Troubleshoot per alarm; restart after 30-minute cooldown for overload; report if ineffective. IV. Core Notes 1. Always power off before troubleshooting to avoid shock or component damage.2. Contact professionals for complex repairs (compressors, refrigerants, circuit boards); do not disassemble yourself.3. Regularly clean air ducts, filters and sensors to reduce over 80% of common faults.

  TAGS QUENTES : Câmara de teste de umidade de alta e baixa temperatura Câmara de teste de umidade fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Test Equipment

  LEIA MAIS
• Walk-in Environmental Test Chambers: The Hidden Tech Gem in Industrial Testing

  Nov 18, 2025

  In industrial manufacturing's "quality defense line", walk-in environmental test chambers are low-key yet critical. As "environmental simulation masters", they replicate extreme conditions from polar cold to tropical heat, testing large equipment and batch products. Their hidden technical strengths merit in-depth exploration. I. Spacious Interior for Flexible Adaptation to Diverse Testing Needs The "walk-in" design is a core breakthrough. With  several to dozens of cubic meters of space, it accommodates large products (automotive parts, electronic devices) and enables batch testing of small/medium items. New energy vehicle battery packs and rail transit systems can be tested integrally without disassembly. Flexible racks and zoning fit various sample shapes, solving traditional equipment's "unfit and unstable" issues. II. Precise Temperature Control for Highly Simulating Diverse Extreme Environments Precise temperature control is its core advantage, with a temperature range of -70℃ to 250℃ and humidity of 20%RH to 98%RH, replicating high-altitude, desert and coastal environments. Using PID algorithms and multi-point sensing, temperature/humidity fluctuations are controlled within ±0.5℃ and ±2%RH, ensuring reliable data. It simulates high-altitude conditions for aerospace and verifies consumer electronics' performance in extremes to support product iteration. III. Energy Conservation and Environmental Protection for Long-term Operating Cost Optimization To address high energy consumption, it adopts variable frequency compressors and low-power heating modules for intelligent power adjustment. Double-layer vacuum insulation reduces heat exchange, and high-end models feature waste heat recovery. Energy consumption is cut by over 30% vs. traditional equipment, saving tens of thousands in annual electricity costs. Stable operation lowers maintenance needs and extends service life, reducing long-term costs. IV. Structural Selection and Customization Services Lab Companion's walk-in chambers have two main structures: integral welded and assembled, with diverse specifications compatible with multiple refrigerants. Assembled models use independent panels fixed by interlocks and reinforcing bolts, simplifying transportation and installation. Integral welded models offer better performance, with wider temperature/humidity ranges and faster temperature change rates. In addition, you can choose a suitable model based on your needs. Lab Companion provides customized services if existing specifications are insufficient . V. Conclusion: The "Core Driving Force" for Industrial Quality Upgrading With large space, precise control, energy efficiency and durability, these chambers are industrial testing's "quality stewards". Critical for improving product reliability in manufacturing transformation, they will upgrade to more precise and intelligent versions to empower industrial high-quality development.

  TAGS QUENTES : câmara de temperatura fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Test Equipment Walk-in Environmental Test Chambers

  LEIA MAIS
• Sample Restrictions for All Models of Test Chambers

  Nov 17, 2025

      As core equipment in industrial production and scientific research that accurately simulates complex environmental conditions such as high and low temperatures, and humidity, the safe and stable operation of test chambers not only directly affects the test process, but is also closely related to the characteristics of test samples. To maximize the protection of the performance of the equipment's core components, avoid safety risks during operation, and ensure the accuracy and reliability of the final test data, all models of test chambers have established clear and strict restriction standards for sample selection. Testing and storage of the following models of samples are strictly prohibited. The specific prohibited scope includes: • Flammable substances such as gasoline and ethanol, explosive substances such as gunpowder and acetylene, and volatile substances such as methanol and ether; • Corrosive substances such as strong acids, strong alkalis and various corrosive solvents that may damage the equipment cavity; • Biological samples such as microorganisms, cell tissues and living organisms that may cause pollution or safety hazards; • Samples that are strong electromagnetic emission sources such as high-frequency emission modules, which may interfere with the equipment's control system; • Radioactive substances with radiation hazards such as uranium and cobalt; • Highly toxic substances that pose serious hazards to humans and the environment, such as cyanides and highly toxic pesticides; • All models of samples that may generate flammable, explosive, volatile, highly toxic, corrosive, or radioactive substances due to changes in temperature and humidity during the testing or storage process.     Before starting the test chamber, operators must confirm the specific properties of the samples through professional testing methods or authoritative materials, and strictly abide by the above restriction requirements. If there is any doubt in judging the applicability of the samples, they should consult the technical personnel of the equipment manufacturer or experts in related fields immediately, and must not operate blindly based on experience. This is to avoid equipment cavity damage, control system failure, safety accidents, or serious deviations in test data caused by illegal use.

  TAGS QUENTES : Câmara de teste fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente Test Equipment High and Low Temperature

  LEIA MAIS
• Have You Completed These Critical Checks Before Delivering a High-Low Temperature Humidity Test Chamber?

  Nov 15, 2025

  1. Preparation for Load-bearing and Dimensional Adaptation • The load-bearing capacity of the site floor shall strictly meet the core requirement of ≥500kg/m², which is a key prerequisite for ensuring the long-term stable operation of the equipment and avoiding equipment deformation or safety hazards caused by insufficient load-bearing capacity. • It is necessary to accurately confirm the external dimensions of the test chamber specified in the technical specification in advance. Combined with the on-site actual survey of the transportation and installation path, ensure that the equipment can smoothly pass through all key passage nodes such as elevators, laboratory doors and corridors, so as to avoid delay in delivery and installation due to inconsistent dimensions. 2. Preparation for Installation Site Conditions • The floor of the installation site shall be flat without protrusions and depressions, and the ventilation conditions shall meet the basic standards for equipment operation. At the same time, there shall be no flammable, explosive, corrosive gases or dust in the environment, as such substances will seriously affect the service life of equipment components and the accuracy of test data. • Strong electromagnetic radiation sources such as high-voltage lines and large motors should be actively avoided near the equipment installation location, as strong electromagnetic interference may cause disorder of the equipment control system, thereby affecting the temperature and humidity control accuracy of the test chamber. • A floor drain that meets the drainage standards must be provided within 2 meters of the equipment's refrigeration unit. This requirement is to timely discharge the condensed water generated during the operation of the refrigeration system, so as to avoid water accumulation soaking the equipment or polluting the site environment. • Sufficient maintenance and operation space shall be reserved around the equipment in accordance with specifications. The specific requirements strictly follow the following standards: Area A ≥80cm, Area B ≥60cm, Area C ≥110cm, Area D ≥110cm. Sufficient space is a necessary guarantee for later equipment maintenance, calibration and component replacement.

  TAGS QUENTES : Câmara de teste de umidade fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente High and Low Temperature (Humidity) Test Chamber Test Equipment

  LEIA MAIS
• High-Low Temperature and Humidity Test Chamber: Comprehensive Safety Protection

  Nov 14, 2025

  Widely used in electronics, automotive, aerospace, etc. It tests product reliability by simulating extreme environments and is key equipment for product quality and safety. 1. Refrigeration system safety protection Compressor overpressure protection: Activates pressure relief when overpressure, preventing explosion and ensuring safety. Compressor overheating protection: Monitors temperature in real time, cuts power when exceeding threshold to avoid burnout and extend life. Compressor over-current protection: Monitors current, cuts power when exceeding rated value to prevent overload or motor damage. 2. Test area safety protection Adjustable over-temperature protection: Flexible threshold setting, automatically controls temperature (reduces power, starts cooling) when exceeding, protecting samples and equipment. First-layer high/low temperature over-temperature protection: Sets high/low temperature protection values for operating temperature, stops heating/cooling when exceeding range. Second-layer high-temperature over-temperature protection: Electronic device with high-precision detection, cuts heating power when exceeding first-layer range. Third-layer high-temperature over-temperature protection: Last barrier, cuts all heating power and alarms when first two layers fail. Fault protection: Cuts control power when faulty, indicates cause and outputs alarm for easy troubleshooting. 3. Other safety protections Total power phase sequence and open-phase protection: Monitors phase sequence and open-phase, cuts power when abnormal to prevent damage. Short-circuit protection: Quickly cuts circuit (fuse blowing, breaker tripping) during short circuit to avoid fire, etc. Leakage/surge protection: ELB prevents electric shock, fuse protects circuit, RC device suppresses surges. Water-cut and dry-burning protection: Cuts power for humidity-related equipment and electric heating when water is cut off to prevent dry burning. 4. Summary     The safety protection system of the high-low temperature and humidity test chamber covers core working units and key auxiliary links, forming a comprehensive and multi-level protection closed loop. Through accurate monitoring, rapid response and effective intervention, each protection device not only ensures the long-term stable operation of the equipment and extends its service life, but also safeguards the safety of test samples and personnel operation. It serves as the core support for reliable test processes and accurate results, building a solid safety barrier for product quality verification.

  TAGS QUENTES : Câmara de teste de umidade fabricantes de câmaras de teste ambientais câmara de simulação ambiental câmara de teste de temperatura ambiente High-Low Temperature Test Chamber High-Low Temperature and Humidity Test Chamber

  LEIA MAIS
• Differences between High and Low Temperature Test Chamber and Constant Temperature Test Chamber

  Nov 13, 2025

      In environmental reliability testing, high-low temperature humidity test chambers and constant temperature and humidity test chambers are easily confused due to similar names, but they differ significantly in testing capabilities, applications and technical characteristics. Accurate distinction and selection are key to ensuring valid test data. This blog will analyze the core differences and provide selection suggestions. I. Core Definition: Essential Distinction of Functional Boundaries     The core difference between the two starts with functional positioning, which directly determines the applicable scenarios.     The core of the constant temperature and humidity test chamber is "maintaining stability". It can accurately control and maintain the set temperature and humidity for a long time, and is used to simulate the long-term performance of products in specific environments, such as electronic component stability testing and textile temperature-humidity sensitivity testing. Its core requirement is "steady-state environmental performance verification".     The high-low temperature humidity test chamber focuses on "dynamic simulation". In addition to precise temperature and humidity control, it has a wide-range fluctuation capability, which can simulate environments such as high-low temperature cycles and alternating humidity and heat, such as extreme temperature differences during product transportation and diurnal temperature-humidity changes of outdoor equipment. Its core requirement is "dynamic environmental reliability verification". II. Key Differences: Multi-dimensional Analysis from Technology to Application 1. Temperature and Humidity Range and Fluctuation Capacity     The constant temperature and humidity chamber has a mild temperature and humidity range (temperature 0℃-100℃, humidity 30%-95%RH) and high control precision (temperature fluctuation ±0.5℃, humidity ±2%RH), but no extreme temperature-humidity impact capability.     The high-low temperature humidity chamber has a wider temperature and humidity coverage (temperature -70℃~200℃, humidity 10%-98%RH) and rapid change capability (heating rate 3℃/min-15℃/min, cooling rate 1℃/min-10℃/min), which can realize rapid cycle switching between "high temperature and high humidity - low temperature and low humidity"—a feature unavailable in the former. 2. Differences in Core Technical Architecture     The constant temperature and humidity chamber adopts single-stage compression refrigeration, conventional resistance heating, and steam or ultrasonic humidification. Its system design focuses on "energy saving and stability", with simple structure and low operating cost.     To meet extreme needs, the high-low temperature humidity chamber uses cascade refrigeration, rapid-heating tubes, and its humidity system includes a fast-response dehumidification module, with a thicker insulation layer on the chamber wall. Its technical complexity and manufacturing cost are much higher than the former. 3. Applicable Scenarios and Testing Purposes     The constant temperature and humidity chamber is used for steady-state environmental adaptability testing, such as electronic component aging and pharmaceutical storage simulation, to verify the performance consistency and durability of products in a fixed environment.     The high-low temperature humidity chamber focuses on dynamic reliability testing, such as high-low temperature cycling of auto parts and extreme environment simulation of aerospace products, to expose product defects (material aging, structural deformation, etc.) under drastic environmental changes.     In summary, the constant temperature and humidity chamber guards the steady-state environment, while the high-low temperature humidity chamber challenges the dynamic environment. There is no absolute advantage or disadvantage between the two. Only by matching needs, clarifying scenarios and budgets can the test truly guarantee product quality.

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