What are the advantages of using a linear electric actuator?
Linear electric actuators offer several advantages over traditional actuators. These include: - Precise positioning and control - Smooth and quiet operation - Long service life - Energy efficiency - Minimal maintenance requirementsHow does a linear electric actuator work?
A linear electric actuator consists of an electric motor, a lead screw, and a nut. The motor turns the lead screw, which in turn moves the nut along the screw. This linear motion is used to drive the actuator's load.What factors affect the performance of a linear electric actuator?
Several factors can affect the performance of a linear electric actuator, including: - Load capacity - Speed - Precision - Duty cycle - Environmental factors such as temperature and humidityHow can you optimize the performance of a linear electric actuator?
To optimize the performance of a linear electric actuator, you can: - Choose the right actuator for your application - Ensure proper installation - Regularly maintain and lubricate the actuator - Monitor performance and make adjustments as needed - Consider using accessories such as limit switches and encoders In conclusion, linear electric actuators offer precise control, fast response times, and energy efficiency, making them ideal for a wide range of applications. To optimize their performance, it's important to choose the right actuator for your application, ensure proper installation and maintenance, and monitor performance regularly.Zhejiang Aoxiang Auto-Control Technology CO.,Ltd is a leading manufacturer of linear electric actuators. With over 20 years of experience in the industry, we offer high-quality products and excellent customer service. Contact us at zjaox@zjaox.com to learn more about our products and services.
Reference:
Jin S, Zhang H, Liu ZL, et al. Development of a new rotary-linear ultrasonic motor for precision engineering applications. Precision Engineering. 2018;54:194-202.
Chen H, Cao J, Li Q. Design and analysis of a novel electromagnetic-driven rotary-linear jolting apparatus. Journal of Mechanical Science and Technology. 2019;33(3):1233-1240.
Li H, Zhao Q, Sun Z. Research on a new type of hybrid linear actuator with large displacement and high precision. Journal of Mechanical Engineering Science. 2017;231(1):69-79.
Yang Y, Li H, Zeng B, et al. A novel intelligent linear piezoelectric actuator with stiffness adjustment based on the iterative learning control. Journal of Intelligent & Robotic Systems. 2018;91(2):1-10.
Zhao X, Zhang X, Qi X, et al. Study on an extended-range electromagnetic linear actuator using a double-sided excitation structure. IEEE Transactions on Magnetics. 2017;53(2):1-7.
Wang S, Wu X, Chen Z, et al. Design and optimization of a novel electro-hydrostatic piezoelectric linear actuator for fine positioning. Journal of Intelligent Material Systems and Structures. 2018;29(1):15-26.
Li H, Liu J, Zhang K. High-precision kinematic design of a linear ultrasonic motor based on an analytical model. IEEE Transactions on Industrial Electronics. 2017;64(1):1-10.
Hu X, Lin R, Han D, et al. Model predictive control for precision position tracking of a linear piezoactuator. Review of Scientific Instruments. 2018;89(4):1-9.
Zhao H, Tian Y, Dai J, et al. Out-of-plane vibration analysis of a Galfenol-based linear actuator on a flexible structure for energy harvesting. Journal of Physics D: Applied Physics. 2018;51(30):305302.
Wang Y, Zhang Z, Rong Y, et al. Modeling and trajectory tracking of a novel piezoelectric-cable-actuated robotic manipulator with a linear actuator. Journal of Intelligent & Robotic Systems. 2019;95(1):1-17.
Liu Y, Li H, Sun W, et al. Design and analysis of a novel low-voltage high-force piezoelectric linear actuator. Sensors and Actuators A: Physical. 2018;271:197-203.