The ice-water impact test chamber is a testing equipment specially used to evaluate the reliability and durability of products in low-temperature environments. The principle is to conduct freezing and impact tests on products by simulating cold environments to examine their performance in harsh climates.
The operation process of the ice-water impact test chamber is as follows: First, reduce the temperature in the test chamber to the lowest limit, usually between -40°C and -80°C. Next, the test sample was placed in ice water to quickly freeze it. During the freezing process, the test chamber applies impact force to simulate the impact that the product may suffer in cold and harsh environments. By observing and recording the response of the sample during freezing and shock, its reliability and durability in cold environments can be evaluated.
Ice-water impact test chambers are widely used in many fields. The electronic product industry is its primary application area, because it is a basic requirement for electronic products to work normally under various environmental conditions. The automobile industry is also inseparable from the ice-water impact test chamber, because in the cold winter, automobile parts need to withstand the test of low temperature. In addition, aerospace systems, medical equipment, chemical industry and other industries also have urgent demand for ice water impact test chambers.
Ice water impact test chamber plays a key role in product development and quality control. Ice-water impact testing in the early design stage can help discover and solve problems that may occur in low-temperature environments, thereby improving product reliability and durability. During the production process, the ice-water impact test chamber is used for quality control, which can screen out unqualified products and ensure that all products put on the market meet the standards. This helps improve product quality and enhance corporate competitiveness.
The advantages of the ice water impact test chamber mainly include the following points:
Precise temperature control: The ice-water impact test chamber can accurately control the temperature of the test area and quickly reach the set temperature. It has a wide temperature range and can usually achieve temperature control between -70°C and +150°C.
Fast cooling: The ice-water impact test chamber is equipped with a powerful cooling system, which can quickly reduce the temperature of the test area to the set temperature in a short period of time, simulating the freezing and freezing process in the real environment.
Precise pressure control: The ice-water impact test chamber can control the pressure of the coolant by adjusting the power and frequency of the cooling system and ensure its stability during the test.
Simulate real environment: The ice-water impact test chamber can simulate the most severe conditions that products may encounter in low temperature and humid environments. By controlling the temperature and humidity, the test chamber can conduct corresponding tests and continuously increase the harshness of the environment to observe whether the product can withstand this environment.
Wide range of applications: The ice-water impact test chamber can be used to test a variety of product types, including electronic products, automobiles and parts, aerospace products, MIL equipment, transportation, etc. By using ice water impact test chambers, these industries can improve efficiency and accuracy in product development, testing and quality control, laying a good foundation for the reliability of their products.
Improve product quality: Ice-water impact test chamber testing can detect the reliability, durability, safety and other aspects of product performance under harsh conditions, thereby improving product quality and competitiveness.
Main Specifications |
Cabinet |
Studio size |
Approximately W 1000 × H 1000 × D 1000 (mm) (mm)(W width × H height × D depth) |
Dimensions |
Approximately 1950×2350×2250(mm), subject to the actual product |
Volume |
1000L; |
Noise |
Within 75dB (measured 1 meter from the front of the machine and 1.2 meters from the ground) |
Temperature |
High temperature zone |
Temperature range |
RTºC~+200ºC |
Heating time |
RT~+200ºC: about 30min |
Low temperature zone |
Temperature range |
RT~-55ºC |
Cooling time |
RT~-55ºC: about 55min |
Studio |
Temperature shock range |
-65ºC~+150ºC |
Temperature fluctuation |
≤±0.5 |
Temperature deviation |
≤±2ºC |
Temperature uniformity |
≤2ºC |
Temperature conversion time |
≤10s(Damper opening time) |
Temperature recovery time |
≤4min |
Operation mode |
There are two high and low temperature impact modes and high and low temperature + room temperature impact modes, which can be set by the human-machine interface. |
High and low temperature shock mode |
150ºC(30min)-NC--40ºC(30min) |
High and low temperature + room temperature impact mode |
150ºC(30min)-room temperature--40ºC(30min) |
Power |
High greenhouse power: 9KW Low temperature greenhouse power: 9KW Other power about: 2KW Maximum power about: 20KW Operating power approximately: 12KW |
Voltage |
Power requirements: 380V 50HZ three-phase five-wire system plus ground wire Power: 20KW current 40A |
Condensation method |
Water cooling |
Gross weight |
550KG |