Abstract
The flexible clamp used in linear ultrasonic motors (LUMs) not only supports the motor but also simplifies the structure and improves the vibration characteristics. However, the flexible clamp causes the mechanical drift phenomenon, leading to a reduction in positional accuracy. To solve this problem, the mechanical drift mechanism and the control methods of V-shaped LUMs are investigated in this work. First, a mechanical model of the stator of a LUM with a flexible clamp is established to analyze the reason for the mechanical drift. Then, based on the mechanical model, the rules of the appearance of mechanical drift in clamping components with different stiffnesses and shapes are studied. The results indicate that mechanical drift is obvious when the stiffnesses of the two flexible clamps are different, whereas it hardly occurs when clamping components with tremendous tangential stiffnesses are used. Finally, two new types of V-shaped LUM stators that have a flexible clamp on one side and an analogous straight-beam clamp on the other side are proposed. Experiments were conducted to validate the mechanical model analysis and the clamp drift findings, and the results demonstrate that the novel motors have little mechanical drift and stable running characteristics and can be used in precision motion platforms.
Highlights
The linear ultrasonic motor (LUM) is a new type of motor that uses the reverse piezoelectric effect of piezoelectric ceramics to actuate the ultrasonic vibration of the stator
Via the mechanical model and experimental analysis, the following two schemes can be generalized to control the mechanical drift of the LUMs
It was concluded that mechanical drift can be effectively suppressed by theoretically ensuring the same stiffness attenuation coefficients of the flexible clamps on both sides or by using clamping components with large tangential stiffnesses
Summary
With the rapid development of semiconductor lithography technology, precision measurement and processing, biological engineering, and nanotechnology, the demand for precision motion platforms is continually increasing, and the required positioning accuracy and stability of the motion platform are becoming higher.. The linear ultrasonic motor (LUM) is a new type of motor that uses the reverse piezoelectric effect of piezoelectric ceramics to actuate the ultrasonic vibration of the stator.. The linear ultrasonic motor (LUM) is a new type of motor that uses the reverse piezoelectric effect of piezoelectric ceramics to actuate the ultrasonic vibration of the stator.3 It can directly export linear motion and thrust and possesses numerous advantages, including a simple structure, high positioning accuracy, self-locking power, and resistance to electromagnetic interference.. In this paper, this phenomenon is called the mechanical drift of the LUM.
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