Textile fabrics are used in a wide variety of applications, from clothing and home furnishings to industrial and technical textiles. The quality, performance, and durability of textile fabrics are significantly influenced by environmental factors, especially temperature and humidity. To accurately assess and improve the characteristics of textile fabrics, a programmable constant temperature and humidity controlled chamber is an indispensable tool. This specialized chamber allows textile manufacturers, researchers, and quality control professionals to subject fabrics to precisely controlled environmental conditions, simulate real - world scenarios, and conduct in - depth testing and analysis.
The most distinctive feature of this chamber is its high - level programmability. Users can create highly customized temperature and humidity profiles to mimic a wide range of real - world environments that textile fabrics may encounter. The temperature can be precisely adjusted within a broad range, typically from -70°C to 150°C, while humidity levels can be set from 10% to 95% relative humidity (RH). Whether it's simulating the dry heat of a desert climate or the damp humidity of a tropical rainforest, the chamber can replicate these conditions with great accuracy. The programming options include cyclic testing, where temperature and humidity change in a repeating pattern, step - by - step testing for gradual transitions, and long - term steady - state testing to evaluate fabric performance over extended periods.
Ensuring uniform temperature and humidity distribution throughout the chamber is crucial for accurate fabric testing. The chamber is designed with advanced air circulation systems that evenly distribute the conditioned air, minimizing any hot or cold spots and ensuring consistent humidity levels. This uniform distribution is vital as it allows for reliable testing of fabric samples, eliminating any variations in test results due to uneven environmental exposure. As a result, the data collected from the tests is more representative of the fabric's true performance under specific conditions.
The chamber features a spacious interior designed to accommodate a significant amount of textile fabric samples. Whether it's a small - scale research project with a few fabric swatches or a large - scale quality control test of rolls of fabric, the chamber has sufficient space. The interior layout is flexible, with adjustable shelves and holders that can be configured to suit different fabric sizes and testing requirements. This large - capacity design enables efficient testing, allowing multiple samples to be tested simultaneously, saving both time and resources.
A comprehensive monitoring and data logging system is integrated into the chamber. Multiple sensors are strategically placed to continuously monitor temperature, humidity, and other relevant parameters such as air pressure and fabric - related measurements (if applicable). The data is logged at high frequencies, providing a detailed and continuous record of the fabric's environmental exposure during the test. The data can be accessed in real - time through a user - friendly interface, and historical data can be retrieved for in - depth analysis. This wealth of data helps in understanding how textile fabrics respond to different environmental conditions over time, facilitating the identification of trends and potential areas for improvement.
Built to withstand the rigors of continuous use in a textile testing environment, the chamber is constructed using high - quality, durable materials. The exterior is made of corrosion - resistant steel, providing excellent protection against physical damage and environmental factors. The interior is lined with materials that are resistant to heat, moisture, and chemicals, ensuring a long - lasting and stable testing environment. The components of the temperature and humidity control systems are also selected for their reliability and durability, minimizing the need for frequent maintenance and breakdowns.
Safety is a top priority in the design of the chamber. It is equipped with a range of safety features to protect both the fabric samples and the operators. Over - temperature and over - humidity protection systems are in place to prevent any abnormal increases in these parameters, which could potentially damage the fabric or the chamber itself. Fire suppression systems are installed to address any potential fire hazards, and emergency stop buttons are located conveniently throughout the chamber for immediate shutdown in case of an emergency.
Model |
THC-225 |
THC-408 |
THC-800 |
THC-1000 |
Inside dimension(W x D x H) mm |
50 x 75 x 60 |
60 x 85 x 80 |
100 x 100 x 80 |
100 x 100 x 100 |
Outside dimension(W x D x H) mm |
75 x 165 x 170 |
85 x 175 x 190 |
125 x 190 x 190 |
125 x 190 x 210 |
Internal material |
#304 Stainless Steel |
External material |
Powder coated #304 Stainless Steel |
Temperature range |
+ 150℃~ - 70 ℃ |
Humidity range |
5% ~ 98% R. H |
Temperature resolution ℃ |
0.01 |
Humidity resolution % R. H. |
0.1 |
Temperature stability ℃ |
±0.3 |
Humidity stability % R. H. |
±2 |
High temperature ℃ |
100 |
100 |
100 |
100 |
Heating time (min) |
20 |
30 |
30 |
30 |
Low temperature |
0, -40, -70 |
0, -40, -70 |
0, -40, -70 |
0, -40, -70 |
Cooling time (min) |
20, 50, 70 |
20, 50, 70 |
20, 50, 70 |
20, 50, 70 |
Air circulation system |
Mechanical convection system |
Cooling system |
Imported compressor, fin evaporator, gas condenser |
Heating system |
Sus304 Stainless steel High-speed heater |
Humidification system |
Steam Generator |
Humidification water supply |
Reservoir, Sensor-controller solenoid valve, recovery-recycle system |
Controller |
Touch panel |
Electrical power requirements |
Please contact us for requirements of specific models |
Safety device |
Circuit system load protection, compressor load protection, control system load protection, humidifier load protection, overtemperature load protection, fault warning light |
By subjecting textile fabrics to precisely controlled temperature and humidity conditions, manufacturers can identify and address potential quality issues early in the production process. This allows for the optimization of fabric manufacturing processes, such as spinning, weaving, and dyeing, to ensur