During operation, short-stroke high-precision electric cylinders are less affected by external interference and can maintain stable motion states and output forces. In optical experiments, these electric cylinders are used to adjust the positions of optical components. Even if there are slight vibrations or temperature changes in the laboratory environment, they can stably maintain the positions of optical components, ensuring the accuracy and repeatability of experimental data and providing reliable experimental conditions for researchers.

Motion parameters can be set via programming, and the user interface is user-friendly, allowing researchers to get started without complex training. In material stretching experiments, simply inputting parameters such as stretching speed and displacement on the controller interface enables the short-stroke high-precision electric cylinder to perform precise stretching operations on material samples according to the set requirements. This simplifies the experimental process and improves experimental efficiency.

Parameters such as stroke, thrust, and speed can be flexibly adjusted according to different research needs. In biomedical experiments, aiming at different experimental objects and purposes, parameters of short-stroke high-precision electric cylinders can be quickly adjusted. For example, when conducting mechanical tests on different tissue samples, the thrust and displacement can be easily modified to adapt to diverse experimental requirements.

Adopting a modular design, each functional module is standardized, facilitating integration with other equipment. When building complex scientific research testing platforms, short-stroke high-precision electric cylinders can serve as independent modules, easily integrating with data acquisition systems, control systems, etc. This shortens the system development cycle, reduces development costs, and improves the overall performance of scientific research equipment.