Leveraging their high precision, high stability, and rapid response, high-precision push-pull electric cylinders can provide accurate drive for robot joints, enabling robots to perform complex tasks—such as the delicate operations of surgical robots inside the human body, and the flexible navigation and interaction of service robots in home environments. This will drive AI and robotics technology to new heights.

Through continuous technological innovation, high-precision push-pull electric cylinders are expected to achieve higher-precision motion control, meeting the rigorous demands of quantum computing experiments. They will provide solid support for the research and development of quantum computers and the improvement of their performance, helping scientists break through the technical bottlenecks of quantum computing and advancing the rapid development of quantum information science.

In the research and development of new energy batteries, they are used for the regulation of the microstructures of battery materials and performance testing; in the research of new intelligent materials, they assist in monitoring changes in the morphology and performance of materials under different external stimuli.