Aircraft and satellite components operate in some of the most
extreme and demanding environments known to man. From the frigid
temperatures of high - altitude flight to the intense heat and
variable humidity in space, these components must be able to
withstand a wide range of conditions to ensure the safety and
success of their missions. Our high - precision temperature
humidity test chamber is specifically designed to meet the rigorous
testing requirements of aircraft and satellite component
manufacturers. This advanced chamber provides a controlled
environment where components can be tested under precisely
simulated conditions, allowing for the evaluation of their
performance, reliability, and durability.
The core strength of this test chamber lies in its ability to
achieve ultra - high precision in temperature and humidity control.
The temperature can be adjusted within an extensive range,
typically from - 70°C to 150°C, with an astonishing precision of
±0.1°C. Humidity levels can be precisely regulated from 5% to 98%
relative humidity (RH), with a precision of ±2% RH. This level of
accuracy is crucial for mimicking the exact environmental
conditions that aircraft and satellite components will encounter
during their operational lifetimes. Whether it's the extreme cold
of space or the high - humidity conditions during a tropical
flight, the chamber can replicate these scenarios with unparalleled
precision.
To accommodate the diverse testing needs of aircraft and satellite
components, the chamber offers a wide variety of customizable test
profiles. Users can create complex, multi - stage test sequences
that simulate the actual environmental changes a component will
experience during its mission. For example, a test profile could
include rapid temperature changes to mimic the transition from a
hot launch environment to the cold of space, or cyclic humidity
variations to simulate the effects of different atmospheric
conditions. These custom - programmed test scenarios allow for a
more comprehensive evaluation of component performance under
realistic conditions.
In addition to temperature and humidity control, the test chamber
is equipped with advanced vacuum and pressure control systems. This
feature is essential for simulating the low - pressure and vacuum
conditions that satellite components encounter in space. The
chamber can achieve extremely low pressures, down to [X] Pascal,
allowing for the testing of components' ability to function in a
near - vacuum environment. Similarly, it can also simulate high -
pressure conditions, such as those experienced during aircraft
takeoff and landing, to ensure the components' structural integrity
and performance under stress.
Aircraft and satellite components often experience rapid changes in
temperature and humidity during their operation. To accurately test
their ability to adapt to these changes, the test chamber is
capable of achieving high - speed temperature and humidity
transitions. The temperature can change at a rate of up to [X] °C
per minute, and the humidity can be adjusted equally quickly. This
feature enables the testing of components' transient response,
ensuring that they can withstand sudden environmental changes
without compromising their performance.
A sophisticated monitoring and data logging system is integrated
into the test chamber. Multiple sensors are strategically placed
throughout the chamber to continuously monitor temperature,
humidity, pressure, and other relevant parameters. The data is
logged at high frequencies, providing a detailed and continuous
record of the component's performance during the test. This data
can be analyzed in real - time or retrieved later for in - depth
post - test analysis. The comprehensive data logging capabilities
allow for the identification of potential weaknesses in the
component's design and performance, enabling manufacturers to make
informed improvements.
Given the critical nature of aircraft and satellite components, the
test chamber is built with durability and cleanliness in mind. The
chamber's exterior is constructed from high - quality, corrosion -
resistant materials that can withstand the rigors of continuous
use. The interior is designed to be clean and free from
contaminants that could potentially affect the components being
tested. Specialized air filtration and purification systems are
installed to maintain a clean environment within the chamber,
ensuring that the test results are not influenced by external
pollutants.
Safety is of utmost importance in the testing of aircraft and
satellite components. The test chamber is equipped with a
comprehensive set of safety features, including over - temperature
and over - humidity protection, fire suppression systems, and
emergency stop buttons. In case of any abnormal conditions, such as
a sudden increase in temperature or pressure, the safety systems
will automatically activate to protect the components, the testing
equipment, and the personnel. These safety features ensure a secure
testing environment for all involved.
| 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 components to precisely controlled temperature and
humidity conditions, along with realistic pressure variations,
manufacturers can identify and address potential performance issues
early in the design and development process. This allows for the
optimization of component design, materials selection, and
manufacturing processes to ensure maximum performance under all
operational conditions. The ability to simulate real - world
scenarios with high precision helps in improving the reliability
and functionality of the components, resulting in safer and more
efficient aircraft and satellites.
Testing components in a controlled environment that replicates the
extreme conditions of space and flight helps manufacturers evaluate
their durability. The chamber's ability to subject components to
repeated cycles of temperature, humidity, and pressure changes
allows for the identification of parts that may be prone to
fatigue, corrosion, or failure over time. By addressing these
issues before production, manufacturers can improve the long - term
durability of their components, reducing the need for frequent
replacements and maintenance during the mission.
The aerospace industry is subject to strict international and
national regulations regarding the performance and safety of
aircraft and satellite components. Our high - precision test
chamber enables manufacturers to conduct the necessary tests to
ensure compliance with these regulations. By providing accurate and
reliable test data, manufacturers can obtain the required
certifications and approvals, facilitating the integration of their
components into aircraft and satellite systems.
Early detection of potential problems through comprehensive testing
in the test chamber can save manufacturers significant costs. By
identifying and fixing issues before mass production, manufacturers
can avoid costly product recalls, warranty claims, and mission
failures. The ability to optimize component design based on test
results also leads to cost savings in terms of materials,
manufacturing processes, and launch costs. Additionally, the long -
term durability of the components reduces the overall cost of
ownership for aircraft and satellite operators.
For research and development teams in the aerospace industry, the
test chamber provides a valuable tool for exploring new
technologies and materials. The ability to precisely control the
environmental conditions allows for in - depth studies of how
different materials and designs perform under extreme conditions.
This can lead to the development of innovative solutions and the
improvement of existing technologies, giving manufacturers a
competitive edge in the global aerospace market.
During the design and development of new aircraft and satellite
components, manufacturers use the test chamber to evaluate the
performance of prototypes. By subjecting the components to various
temperature, humidity, and pressure conditions, engineers can
assess their functionality, durability, and reliability. The test
results are used to make design improvements and ensure that the
final product meets the stringent requirements of the aerospace
industry.
In the manufacturing process, the test chamber is used for quality
control purposes. A sample of components from each production batch
is tested in the chamber to ensure that they meet the specified
quality standards. The precise control of environmental conditions
allows for accurate evaluation of the components' performance, and
any issues can be identified and addressed before the components
are shipped for integration.
To ensure the long - term reliability of aircraft and satellite
components, manufacturers conduct reliability testing in the test
chamber. This involves subjecting the components to extended
periods of simulated operational conditions, including cyclic
temperature, humidity, and pressure changes. The data collected
during these tests helps in predicting the components' lifespan and
failure rates, enabling manufacturers to implement appropriate
maintenance and replacement strategies.
Research institutions and aerospace companies use the test chamber
to conduct research on new technologies and materials for aircraft
and satellite components. For example, they can study the
performance of new composite materials under extreme environmental
conditions or the behavior of advanced electronic components in a
vacuum. The test chamber provides a controlled environment for
these experiments, facilitating the development of innovative
solutions for the aerospace industry.
Our high - precision temperature humidity test chamber for aircraft
and satellite components is an indispensable tool for the aerospace
industry. With its ultra - high precision control, customizable
test profiles, vacuum and pressure control capabilities, high -
speed transitions, comprehensive monitoring and data logging,
durable construction, and safety features, it provides a
comprehensive and reliable platform for testing, evaluating, and
improving aircraft and satellite components. Whether it's for
component design and development, quality control, reliability
testing, or new technology research, this test chamber is essential
for ensuring the safety, performance, and competitiveness of the
aerospace industry. Contact us today to learn more about how our
product can meet your specific testing needs.
