Design of Longitudinal-Bending Coupled Horn of a Giant Magnetostriction Transducer

This article presents a design method of Longitudinal-Bending Coupled Horn (L-BCH) of a giant magnetostrictive transducer utilized in spinning ultrasonic machining. The structural parameters are initially determined by the design theory of the horn and thick disc. Then, the effect of the structural...

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Bibliographic Details
Published in:Actuators 2022-04, Vol.11 (4), p.110
Main Authors: Li, Pengyang, Chen, Yunshuai, Li, Wei, Sun, Jian, Li, Jian, Wang, Kai
Format: Article
Language:English
Subjects:
Amplitudes
Bending
Boundary conditions
Design
Diameters
Dynamic characteristics
Finite element method
Harmonic response
Horns
Influence
kinetics analysis
longitudinal-bending coupled horn
Magnetostriction
Parameter modification
Resonant frequencies
Rotation
structural design
Thickness
Ultrasonic machining
Vibration
Vibration meters
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Summary:This article presents a design method of Longitudinal-Bending Coupled Horn (L-BCH) of a giant magnetostrictive transducer utilized in spinning ultrasonic machining. The structural parameters are initially determined by the design theory of the horn and thick disc. Then, the effect of the structural parameters of the rotating wheel on the vibration characteristics of the L-BCH are explored by the model and harmonic response analysis through the finite element method. Through continuous modification of the geometrical parameters of the rotary wheel, the L-BCH meeting the requirements of a giant magnetostrictive transducer is designed. Finally, the frequency and amplitude measurements are performed on the prototype by the impedance analyzer and the laser vibrometer. The finite element analysis and experimental results show that: the large diameter, small diameter, thickness, and fillet radius of the rotating wheel have different impacts on the dynamic characteristics of the L-BCH. Among them, the thickness of the rotary wheel has the most significant influence on the natural frequency and amplitude. In addition, the rotating wheel has a pitch circle when the longitudinal-bending coupled vibration occurs, and the structure itself also has the characteristic of amplifying amplitude.
ISSN:2076-0825
2076-0825
DOI:10.3390/act11040110