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谐振式压电叠堆的高效换能结构研究 被引量:6

Efficient energy conversion structure of a piezoelectric stack oscillator
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摘要 压电叠堆具有纵向机电耦合系数高、耐疲劳性强的特点,但在低频振动条件下,压电叠堆的机电转换效率低,从而限制了其在结构振动能量收集方面的应用。通过将谐振频率接近结构振动频率的谐振器附加在压电叠堆表面形成谐振式压电换能系统,可以有效提高谐振频率附近的机电能量转换效率。对谐振式压电换能结构进行参数建模,以压电叠堆所受纵向力与结构激励力的比值衡量谐振式压电叠堆的换能效率,确定系统有效换能频带的宽度与系统的结构设计参数的关系,从而给出谐振式压电换能系统参数优化设计方法。谐振式压电换能结构的实验表明谐振器能有效增加较低振动频率下的机电能量转换效率,提高输出的开路电压。 Piezoelectric stack has the advantages of high longitudinal electro-mechanical coupling coefficient and strong fatigue-resistance, but its electro-mechanical conversion efficiency is not high under lower frequency vibration, it limits its applications in vibration energy gathering. A novel oscillator piezoelectric energy conversion system (OPECS) was presented to enhance its conversion efficiency nearby resonant frequency through attaching an oscillator onto the surface of the piezoelectric stack. The parametric model of an OPECS was built at first. According to the model, its electro-mechanical conversion efficiency was evaluated using a ratio of the longitudinal force of the stack to the exciting force. Then the relationship between the effective conversion bandwidth and the structural parameters were determined, thus the optimal design principles of the structural parameters were obtained. Experimental results showed that OPESC can effectively increase the electro-mechanical conversion efficiency in lower frequency vibration and raise the output voltage of the piezoelectric stack.
作者 王兆强 刘海利 徐天柱 陈加浪 黄震宇
机构地区 上海交通大学电子信息与电气工程学院仪器系
出处 《振动与冲击》 EI CSCD 北大核心 2011年第12期125-128,共4页 Journal of Vibration and Shock
基金 国家"863"计划项目资助(2009AA043000-2009AA043001)
关键词 振动能量收集 压电叠堆 谐振器 机电转换效率 频带宽度 vibration energy gathering piezoelectric stack oscillator electro-mechanical conversion efficiency bandwidth
分类号 TH113.1 [机械工程—机械设计及理论] TN384 [电子电信—物理电子学]
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参考文献7

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共引文献41

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振动与冲击
2011年 第12期

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