一种用于水质监测器件供能的压电能量采集器研究
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摘要
本文以压电材料作为核心元件,研究一种两自由度悬臂梁新型结构的压电能量采集器,通过搭建实验测试平台进行输出性能测试,为以后水环境监测无线传感网络节点供能提供基础。
By usin g piezoelectric materials as core components, the paper researches the structure of a new kind of piezoelectric energy harvester with a two-degree-of-freedom cantilever. The paper builds a test platform to carry out output performance tests, providing a basis of energy supply for the wireless sensor network node in water environment monitoring.
By usin g piezoelectric materials as core components, the paper researches the structure of a new kind of piezoelectric energy harvester with a two-degree-of-freedom cantilever. The paper builds a test platform to carry out output performance tests, providing a basis of energy supply for the wireless sensor network node in water environment monitoring.
引文
[1]顾敏明,雷岩,肖金球.面向水环境的无线实时监测系统设计[J].物联网技术,2015,(11):9-11
[2]郑慈航,唐刚,尹桂林,等.超声液体环境下压电式振动能量采集的研究[J].传感器与微系统,2011,30(03):46-49.
[3]沈修成,方华斌,王亚军,等.基于MEMS的压电微能量采集器的电路研究与测试[J].传感技术学报,2008,(04):692-694.
[4]Zheng C H,Tang G,Liu J Q,et al.Study on energy harvesting using piezoelectric cantilever generator in fluid environments from ultrasonic vibration[J].Transducer&Microsystem Technologies,2011,30(03):46-49.
[5]方华军,刘理天,任天令.硅基压电多层膜悬臂梁的偏转模型和优化设计[J].传感技术学报,2006,(05):1330-1332.
[6]孙健,李以贵,刘景全,等.微压电式振动能量采集器的研究进展[J].微纳电子技术,2009,46(11):673-677.
[7]程耀庆.基于微型压电能量采集器的无线风速监测节点[D].重庆:重庆大学,2014.
[8]徐春辉.压由式低频振动能量采集系统的研究[D].西安:西安电子科技大学,2014.
[2]郑慈航,唐刚,尹桂林,等.超声液体环境下压电式振动能量采集的研究[J].传感器与微系统,2011,30(03):46-49.
[3]沈修成,方华斌,王亚军,等.基于MEMS的压电微能量采集器的电路研究与测试[J].传感技术学报,2008,(04):692-694.
[4]Zheng C H,Tang G,Liu J Q,et al.Study on energy harvesting using piezoelectric cantilever generator in fluid environments from ultrasonic vibration[J].Transducer&Microsystem Technologies,2011,30(03):46-49.
[5]方华军,刘理天,任天令.硅基压电多层膜悬臂梁的偏转模型和优化设计[J].传感技术学报,2006,(05):1330-1332.
[6]孙健,李以贵,刘景全,等.微压电式振动能量采集器的研究进展[J].微纳电子技术,2009,46(11):673-677.
[7]程耀庆.基于微型压电能量采集器的无线风速监测节点[D].重庆:重庆大学,2014.
[8]徐春辉.压由式低频振动能量采集系统的研究[D].西安:西安电子科技大学,2014.