Vertical low temperature cold resistance testing machine

Luggage rod reciprocating testing machine for luggage rod reciprocating fatigue test. In the test, the specimen will be stretched to test the gap generated by the tie rod, loosening, connecting rod failure, deformation, etc.

Application

1. Consumer Electronics: With the widespread adoption of electronic products such as smartphones, tablets, and wearable devices, the bending performance of their screens, casings, and other components in cold environments has become a key concern for users. This testing machine allows manufacturers to evaluate product durability under extreme climatic conditions, ensuring that the user experience remains unaffected.

2. Automotive and Aerospace: In the aerospace industry, the casings, wings, and other structural components of aircraft and rockets need to withstand high-altitude low temperatures and complex aerodynamic loads; in the automotive industry, with the rise of electric and smart vehicles, the low-temperature resistance and bending strength of battery packs and body frames are equally important. The vertical low-temperature bending test machine provides strong support for material research and product design in these fields.

3. Building Materials and Piping Systems: In extremely cold regions, the thermal insulation performance of building exterior walls and the antifreeze performance of piping systems directly affect residents' quality of life and public safety. This testing machine can simulate extreme low-temperature conditions to test the crack resistance, flexibility, and overall structural stability of materials.

4. New Energy and Environmental Protection Technologies: In new energy fields such as wind and solar power, the low-temperature resistance and wind pressure bending strength of key components such as wind turbine blades and photovoltaic panels directly affect the power generation efficiency and service life of the equipment. The vertical low-temperature bending test machine provides a reliable testing method for technological innovation and product optimization in these fields.

Standards

ASTM-D1790：Standard test method for determining the brittle temperature of plastic films using the impact method.

ASTM-D1593 ：Standard Specification for Nonrigid Vinyl Chloride Plastic Film and Sheeting

ASTM-D1052 ： Standard Test Method for Measuring Rubber Deterioration Using the Ross Flexing Machine — Cut Growth

JIS-K6545 ： Method for testing the flexural resistance of leather

CNS-7705 ： Leather Flexing Resistance Test Method

ISO 20344 ： Personal protective equipment — Test methods for footwear

GB/T 20991-2007：  Personal protective equipment — Test methods for footwear

Features

1. High-precision temperature control:  Utilizing advanced refrigeration technology and a temperature feedback system, the test chamber maintains stable and uniform temperatures, providing strong assurance for the accuracy of test results.

2. Flexible and diverse testing schemes: Supports various bending modes (such as reciprocating bending and fixed-point bending), and allows for setting different speeds and angles, meeting the needs of different products and testing requirements.

3. Efficient data acquisition and analysis: Integrated with advanced sensors and data processing software, it can record and analyze various parameters during the testing process in real time, providing a scientific basis for product performance evaluation and optimization.

4. Easy operation and maintenance: The user-friendly interface and automated maintenance procedures reduce operating difficulty and maintenance costs, improving work efficiency.

Technical Parameters

Accessoriess

Refrigeration System:  Utilizing advanced refrigeration technologies such as liquid circulation, mechanical compression refrigeration, or a combination of both, the system can quickly lower the temperature inside the test chamber to the set value and maintain a stable low-temperature environment. The efficiency and stability of the refrigeration system directly affect the accuracy of the test results.

Temperature Control System:  Through high-precision temperature sensors and PID control algorithms, precise control of the temperature inside the test chamber is achieved. Users can set any temperature point according to test requirements, and the temperature control system automatically adjusts the cooling power to maintain a constant temperature inside the chamber, with an error range typically within ±1°C.

Mechanical Transmission System:  Includes a motor, reducer, transmission shaft, and bending mechanism, responsible for driving the sample to perform periodic bending movements. The design of the transmission system must consider adjustable speed, uniform force distribution, and long-term operational stability to ensure consistency and reliability during the testing process.

Sample Fixture: Designed and customized according to the shape, size, and material of the sample, used to fix the sample and maintain its correct position and posture during the bending process. The design of the fixture must consider ease of operation, secure sample fixation, and avoiding unnecessary damage to the sample.

Data Acquisition and Processing System: Equipped with high-precision sensors and data acquisition cards, it can monitor and record key parameters such as temperature, bending cycles, bending angle, and sample deformation in real time during the test. Simultaneously, the accompanying software system can process and analyze the data, generating intuitive charts and reports to facilitate user evaluation of the test results.

Test Procedures

1. Sample Pre-treatment

According to the corresponding testing standard (e.g., ASTM-D1790), place the sample to be tested (finished shoes, rubber/plastic parts, synthetic leather, etc.) in an environment of 23±2℃ and 50±5% relative humidity for at least 24 hours to ensure the sample is in a stable state.

2. Equipment Pre-check

Confirm the power supply matches (AC380V 50Hz or AC220V 50Hz), and check the condition of the compressor, refrigerant (R404), and insulation materials (rigid foam + glass wool);

Confirm that the compressor start delay is set to 5 minutes, and that the protection devices (thermal protection, leakage protection, etc.) are functioning normally.

3. Parameter and Fixture Settings

Select the temperature range through the touchscreen controller (default: room temperature to -30℃, optional: room temperature to -50℃), and confirm the control accuracy (±0.3℃) and distribution uniformity (±0.1℃);

If testing specific samples is required, install the corresponding optional fixtures (such as leather bending fixture, finished shoe bending/outsole flexing fixture);

Set the target test cycles (0-999999 cycles) through the LCD counter.

4. Sample Installation

Place the pre-treated sample into the inner chamber (600×600×550mm), and secure it firmly with the corresponding fixture, ensuring even force distribution on the sample. Then close the equipment door (confirming the double-layer vacuum window is closed).

5. Starting the Test

After confirming all settings are correct, start the equipment. The equipment will cool down from room temperature to the target low temperature at the set cooling rate. The compressor will start after a 5-minute delay, and the counter will begin recording the test cycles.

6. Process Monitoring

During the test, the sample status can be observed through the double-layer vacuum window (with a 5W P1 window light), and monitor whether the equipment protection device triggers an abnormal shutdown.

7. Test Termination and Result Recording

The equipment will automatically stop after reaching the set number of cycles; if the sample shows brittle fracture, deformation, or other failure, the test can be terminated manually;

Record the test temperature, actual test cycles, and the cold resistance performance of the sample (e.g., whether it cracked, structural integrity, etc.). 8. Concluding procedures

Turn off the device power, and after the internal chamber temperature returns to normal, remove the samples and clean the inside of the device.

Maintenance Information

Maintaining a vertical low-temperature cold resistance testing machine involves regular cleaning of the interior, lubricating door seals, checking refrigeration units for frost buildup, and annual calibration to ensure accuracy. Key maintenance includes testing electrical insulation, ensuring proper airflow, and inspecting for wear on moving components to ensure consistent, reliable cold-weather simulations.

FAQ

(1) What is this product?

A vertical low-temperature cold resistance testing machine is an industrial, lab-grade device that evaluates how materials—primarily rubber, plastics, leather, and footwear—perform under freezing conditions.

(2) What is this product used for?

A vertical low-temperature cold resistance testing machine is used to evaluate the durability, flexibility, and physical integrity of materials—such as leather, rubber, footwear, and plastics—when subjected to extreme cold environments.

(3) How does this product work?

A vertical low-temperature cold resistance testing machine evaluates material durability (rubber, leather, plastics) by subjecting specimens to bending or flexing under extreme, controlled cold conditions.

(4) Why is this product important?

A vertical low-temperature cold resistance testing machine is crucial for evaluating material performance, such as brittleness, flexibility, and strength, in extreme sub-zero temperatures.

(5) Which industries is this product suitable for?

The Vertical Low-Temperature Cold Resistance Testing Machine is specialized equipment used to evaluate the flexibility, durability, and physical properties of materials (rubber, plastics, leather) under extreme cold, typically for products like footwear, cables, seals, and automotive components, ensuring compliance with industrial cold-weather standards.