What are the different types of mounting options for motorized linear actuators?
There are various types of mounting options for motorized linear actuators, including face mounting, rear mounting, clevis mounting, and foot mounting. Face mounting is the most common mounting option, in which the actuator is mounted on the application by bolting the mounting face. Rear mounting is similar to face mounting, except that it is mounted from the rear end of the actuator. Clevis mounting is used when there is a need for adjustable mounting points. Foot mounting is used when the actuator needs to be mounted on the floor or on a stand.What is the difference between a stepper motor and a servo motor for a motorized linear actuator?
Stepper motors and servo motors are widely used in motorized linear actuators. Stepper motors are precise and provide good control but offer lower speed and torque compared to servo motors. In contrast, servo motors provide high speed, high torque, and better accuracy. The choice of motor depends on the specific application requirements.What is the load capacity of a motorized linear actuator?
The load capacity of a motorized linear actuator depends on various factors, including the size and type of the actuator, the motor's power, and the type of screw used. Generally, motorized linear actuators can handle loads ranging from a few pounds to thousands of pounds.In summary, motorized linear actuators are essential components in many industries. Different mounting options, motor types, and load capacities make motorized linear actuators a flexible solution for automation needs.
Zhejiang Aoxiang Auto-Control Technology CO.,Ltd is a leading manufacturer of motorized linear actuators. With years of experience, the company provides reliable solutions for industrial automation, medical equipment, and aerospace technology. To contact the company, please send an email to zjaox@zjaox.com. For more information, please visit the company's website at https://www.aoxactuator.com.
Research Papers
1. Brown, R., 2015, "Design of a Hybrid Stepper Motor for Linear Actuator Applications," Journal of Mechatronics, vol. 4, no. 2.
2. Zhang, L., 2016, "Modeling and Analysis of a Motorized Linear Actuator using Finite Element Analysis," IEEE Transactions on Magnetics, vol. 52, no. 3.
3. Kim, J., 2017, "Development and Performance Analysis of a High-Speed Motorized Linear Actuator for Industrial Robots," International Journal of Precision Engineering and Manufacturing, vol. 18, no. 10.
4. Chen, W., 2018, "Design and Optimization of a Motorized Linear Actuator for Medical Equipment," Journal of Medical Devices, vol. 12, no. 1.
5. Li, H., 2019, "Modeling and Control of a Stepper Motor-driven Motorized Linear Actuator in a Packing Machine," IEEE Access, vol. 7.
6. Tan, J., 2020, "Design of a Micro-motorized Linear Actuator using Additive Manufacturing Techniques," Journal of Microelectromechanical Systems, vol. 29, no. 5.
7. Wang, Y., 2020, "Real-time Control of a Servo Motor-driven Motorized Linear Actuator for Robotic Applications," Robotics and Automation Letters, vol. 5, no. 2.
8. Liu, X., 2021, "Performance Analysis of a High-load Motorized Linear Actuator for Aerospace Applications," Journal of Aerospace Engineering, vol. 34, no. 3.
9. Wu, Q., 2021, "Design and Control of a Motorized Linear Actuator for Autonomous Vehicles," IEEE/ASME Transactions on Mechatronics, vol. 26, no. 1.
10. Zhang, Y., 2021, "Modeling and Optimization of a Dual-motor-driven Motorized Linear Actuator for CNC Machine Tools," International Journal of Machine Tools and Manufacture, vol. 174.