An experimentally validated electromagnetic energy harvester

被引:138
|
作者
Elvin, Niell G. [1 ]
Elvin, Alex A. [2 ]
机构
[1] CUNY City Coll, Dept Mech Engn, New York, NY 10031 USA
[2] Univ Witwatersrand, Sch Civil & Environm Engn, Johannesburg, South Africa
来源
JOURNAL OF SOUND AND VIBRATION | 2011年 / 330卷 / 10期
关键词
VIBRATION; GENERATOR;
D O I
10.1016/j.jsv.2010.11.024
中图分类号
O42 [声学];
学科分类号
070206 ; 082403 ;
摘要
A relatively simple method for determining the electromechanical parameters of electromagnetic energy harvesters are presented in this paper. The optimal power generated through a load resistor at both off-resonance and resonance is derived analytically. The experimentally measured performance of a rudimentary electromechanical energy harvester using a rare-earth magnet shows good agreement with the results from the model. The parasitic generator coil resistance can have a profound effect on the overall performance of an electromagnetic generator by essentially acting to degrade the effective coupling coefficient. Data from the setup electromagnetic generator shows normalized power densities of 1.7 mu W/[(m/s(2))(2) cm(3)] operating at a resonance frequency of 112.25 Hz. This power density is comparable with other electromagnetic devices of the same volume operating at these frequencies. The power output of the presented electromagnetic generator is comparable to equivalent piezoelectric generators. (C) 2010 Elsevier Ltd. All rights reserved.
引用
收藏
页码:2314 / 2324
页数:11
相关论文
共 50 条
  • [31] A simply tunable electromagnetic pendulum energy harvester
    Davide Castagnetti
    Meccanica, 2019, 54 : 749 - 760
  • [32] Asynchronous phase shifted electromagnetic energy harvester
    Park, Jinkyoo
    Kwon, Soonduck
    Law, Kincho H.
    SENSORS AND SMART STRUCTURES TECHNOLOGIES FOR CIVIL, MECHANICAL, AND AEROSPACE SYSTEMS 2013, 2013, 8692
  • [33] Electromagnetic micro energy harvester for human locomotion
    Patel, Pratik
    Khamesee, Mir Behrad
    MICROSYSTEM TECHNOLOGIES-MICRO-AND NANOSYSTEMS-INFORMATION STORAGE AND PROCESSING SYSTEMS, 2013, 19 (9-10): : 1357 - 1363
  • [34] A simply tunable electromagnetic pendulum energy harvester
    Castagnetti, Davide
    MECCANICA, 2019, 54 (06) : 749 - 760
  • [35] ELECTROMAGNETIC ENERGY HARVESTER BY USING BURIED NDFEB
    Miki, S.
    Fujita, T.
    Kotoge, T.
    Jiang, Y. G.
    Uehara, M.
    Kanda, K.
    Higuchi, K.
    Maenaka, K.
    2012 IEEE 25TH INTERNATIONAL CONFERENCE ON MICRO ELECTRO MECHANICAL SYSTEMS (MEMS), 2012,
  • [36] EXPERIMENTALLY VERIFIED MODEL OF ELECTROSTATIC ENERGY HARVESTER WITH INTERNAL IMPACTS
    Binh Duc Truong
    Cuong Phu Le
    Halvorsen, Einar
    2015 28TH IEEE INTERNATIONAL CONFERENCE ON MICRO ELECTRO MECHANICAL SYSTEMS (MEMS 2015), 2015, : 1125 - 1128
  • [37] Experimentally Modelling a Piezoelectric Glued Laminated Plate Energy of Harvester
    Meng, Ying
    Wei, Sha
    Yuan, Tianchen
    Ding, Hu
    Chen, Liqun
    JOURNAL OF VIBRATION ENGINEERING & TECHNOLOGIES, 2024, 12 (SUPPL 1) : 907 - 919
  • [38] Scavenging vibrational energy with a novel bistable electromagnetic energy harvester
    Yan, Bo
    Yu, Ning
    Zhang, Lu
    Ma, Hongye
    Wu, Chuanyu
    Wang, Ke
    Zhou, Shengxi
    SMART MATERIALS AND STRUCTURES, 2020, 29 (02)
  • [39] Modelling of Electromagnetic Coupling in Micro-scale Electromagnetic Energy Harvester
    Sokolov, Andrii
    Mallick, Dhiman
    Roy, Saibal
    Kennedy, Michael Peter
    Blokhina, Elena
    SYMPOSIUM ON DESIGN, TEST, INTEGRATION & PACKAGING OF MEMS AND MOEMS (DTIP 2019), 2019,
  • [40] Electromagnetic Energy Harvester Interface Design for Wearable Applications
    Wang, Shih-Wei
    Ke, Yi-Wen
    Huang, Po-Chiun
    Hsieh, Ping-Hsuan
    IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS II-EXPRESS BRIEFS, 2018, 65 (05) : 667 - 671
12345