Research on correlation model between transducer temperature and acoustic performance parameters of ultrasonic machining system

In the process of ultrasonic vibration cutting (UVC), the acoustic performance parameters of ultrasonic machining system change because of systems heating up and cutting loads. The changes of acoustic performance parameters will affect resonant frequency, impedance, and power match of the ultrasonic...

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Published in:AIP advances 2022-11, Vol.12 (11), p.115303-115303-7
Main Authors: Ye, Hong-xian, Yang, Xu-yi, Hu, Xiao-ping, Yu, Bao-hua, Kang, Xi
Format: Article
Language:English
Subjects:
Acoustic impedance
Acoustic resonance
Acoustics
Dynamic stability
Impedance matching
Mathematical models
Noise control
Parameters
Regression analysis
Resonant frequencies
Stability analysis
Ultrasonic machining
Ultrasonic vibration
Vibration analysis
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container_title AIP advances
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creator Ye, Hong-xian
Yang, Xu-yi
Hu, Xiao-ping
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Kang, Xi
description In the process of ultrasonic vibration cutting (UVC), the acoustic performance parameters of ultrasonic machining system change because of systems heating up and cutting loads. The changes of acoustic performance parameters will affect resonant frequency, impedance, and power match of the ultrasonic machining system, and stability of the amplitude of UVC system. It is hard to monitor the acoustic performance parameters online. Based on the analysis of the correlation mechanism between transducer temperature and acoustic performance parameters, the correlation models between transducer temperature and resonance frequency, static capacitance, and dynamic resistance of ultrasonic vibration machining system are established by curve regression analysis modeling method. The acoustic performance parameters of an ultrasonic vibration machining system are determined by transducer temperature using the correlation models. The effectiveness of the model is verified by experiments. It gives the information for the stability evaluation of the ultrasonic vibration machining process, the dynamic impedance matching of the ultrasonic machining system, and the power matching adjustment of the ultrasonic power supply.
doi_str_mv 10.1063/5.0124897
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subjects Acoustic impedance
Acoustic resonance
Acoustics
Dynamic stability
Impedance matching
Mathematical models
Noise control
Parameters
Regression analysis
Resonant frequencies
Stability analysis
Ultrasonic machining
Ultrasonic vibration
Vibration analysis
title Research on correlation model between transducer temperature and acoustic performance parameters of ultrasonic machining system
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