基于PZT的超声波无接触能量传输系统的研究

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摘要给出一种基于PZT的超声波无接触能量传输系统。通过机电等效和类比的方法建立了系统的数学模型。结合声波能量传输理论和电路理论对系统模型进行了分析, 推导出控制系数的表达式及输出电压与输入电压之间的关系和负载功率表达式, 通过实验研究了负载阻抗与负载功率及传输距离与负载功率之间的关系。当换能器间发生共振时, 系统能量的传输达到最大值;当系统参数和传输距离一定时, 负载功率的大小随负载的变化而变化, 并存在一个最大值;负载功率和系统效率随传输距离的变大而减小。理论分析和实验证明, 将超声波作为媒介可以摆脱隔板电能传输的局限性, 在一定有效距离范围内进行无接触电能传输。

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	邹玉炜
	黄学良
	柏杨
	谭林林

关键词 ：无接触能量传输, 共振, 气介质换能器, 模型

Abstract：In this paper, a system of contactless ultrasonic power transmission based on PZT is presented, and mathematical model is established by mechanical equivalent and analogy method. The acoustic energy transfer theory and some analysis methods are proposed and the model of the system is analyzed, and expression of control coefficient, output voltage to the input voltage and load power are derived. Relations of load impedance to load power and transmission distance to the load power are studied by experiment. When system occurs resonance, transferred energy achieve maximum; when the system parameters and the transmission distance is fixed, the transfer efficiency changed with the load, and that there is a maximum value. Load power and system efficiency decrease with the increase of transmission distance. Theoretical analysis and experimental results show that ultrasonic can be used for contactless energy transfer and get rid of the limitations of acoustic-electric feed-throughs for power transmission and realize contactless energy transmission in a certain range of effective distance.

Key words： Contactless energy transfer resonance gas medium transducer model

收稿日期: 2011-03-02 出版日期: 2014-03-07

PACS:

TM724

基金资助:江苏省“六大人才高峰”基金资助项目(1116000088)

作者简介: 邹玉炜男, 1973年生, 博士研究生, 主要研究方向为无接触电能传输技术, 环境振动能量收集。黄学良男, 1969年生, 博士, 教授, 主要研究方向为无线电能传输, 新型能量转换装置研究, 电磁场数值分析理论及应用研究, 电力电子应用。

引用本文:

邹玉炜, 黄学良, 柏杨, 谭林林. 基于PZT的超声波无接触能量传输系统的研究[J]. 电工技术学报, 2011, 26(9): 144-150. Zou Yuwei, Huang Xueliang, Bai Yang, Tan Linlin. Research on Contactless Ultrasonic Energy Transfer System Based on PZT. Transactions of China Electrotechnical Society, 2011, 26(9): 144-150.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2011/V26/I9/144

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