An Improved Design Method of High Efficiency Contactless Power Transmission in Ultrasonic Vibration System

H. Shen; Ping Fa Feng; J.F. Zhang; D.W. Yu; Z.J. Wu

doi:10.4028/www.scientific.net/KEM.693.17

Paper Titles

Preface

A FE Modelling Method for the Thermal Characteristics of High-Speed Motorized Spindle
p.3

Aerodynamic Characteristic Analysis of Flow Structure around the High-Speed Train Equipment Bay
p.11

An Improved Design Method of High Efficiency Contactless Power Transmission in Ultrasonic Vibration System
p.17

Analysis of Multi-Components Force Standard Machine Loading System Based on Stewart Structure
p.25

Analyzing Out-of-Plane Vibration of a Rotating Ring with Wave Propagation
p.31

Combining Design of Vibration Absorbing and Isolation for a Power Equipment Based on 2 Degrees of Freedom
p.37

Design and Analysis of a Power Transmission Network Model of Electric Vehicle
p.45

Design and Analysis of Conjugate Cam Beating-Up Motion Law
p.53

HomeKey Engineering MaterialsKey Engineering Materials Vol. 693An Improved Design Method of High Efficiency...

An Improved Design Method of High Efficiency Contactless Power Transmission in Ultrasonic Vibration System

Abstract:

To improve the efficiency of contactless power transmission (CPT) and the operation stability of ultrasonic vibration system, an improved design method for key parts of the contactless power transmission system was proposed and studied. By integrating both inductor model and mutual inductance model, as well as considering the fringing flux effect introduced by the air gap, this design method would be more accurate and reasonable. Considering constraint conditions, such as the operating flux density of the core, mutual inductance between primary and secondary coils, electrical signals loaded on ultrasonic vibrator, the coils and cores were designed. Simulation and experimental studies which were developed on flux density, mutual inductance and amplitude output ability of the system, verified that the key parts of CPT system could stay stable during operation and the CPT system was able to transfer ultrasonic energy efficiently.

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Periodical:

Key Engineering Materials (Volume 693)

Pages:

17-24

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.693.17

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Online since:

May 2016

Authors:

H. Shen*, Ping Fa Feng, J.F. Zhang, D.W. Yu, Z.J. Wu

Keywords:

Contactless Power Transmission, Inductor Model, Mutual Inductance Model, Transmission Efficiency, Ultrasonic Vibration System

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