The article is provided by Jinan Sanquan Zhongshi Experimental Instrument***.
In the field of materials science and engineering, the diaphragm electronic tensile testing machine is an important test equipment used to evaluate the mechanical properties of materials, such as tensile strength, tear strength, and deformation rate. This kind of testing equipment is widely used in the performance testing of plastics, rubber, textiles, paper and other materials.
1.Test principle.
The diaphragm electronic tensile testing machine works by clamping the specimen between two chucks, which move relative to each other. With the help of a force sensor located on the moving chuck and a displacement sensor built into the machine, we can collect the force value and displacement changes during the test. This data is used to calculate performance indicators such as tensile, tear and deformation rates of the specimen.
2.Precise measurements.
The precise measurement capability of the diaphragm electronic tensile testing machine is mainly due to its high-precision force and displacement sensors. These sensors are able to measure changes in force with extreme accuracy and resolution, providing us with detailed information about the performance of the specimen.
3.Practical application.
This test method has a wide range of applications in several fields, such as materials science, packaging industry, automotive manufacturing, etc. In materials science, this kind of testing can help researchers understand the mechanical properties of materials in order to develop more durable and effective materials. In the packaging industry, this test can help designers evaluate the strength and durability of packaging materials to ensure the safe transportation of products. In automotive manufacturing, this type of testing can help engineers evaluate the durability and safety of vehicle components.
4.Summary. In summary, the diaphragm electronic tensile testing machine is an accurate material performance testing equipment, which can calculate the tensile and tear rate and deformation rate of the specimen by collecting changes in force and displacement. With the advancement of science and technology and the expansion of application fields, we have reason to believe that this test method will play a greater role in future research and development.