Boosting the performance of energy harvesters subject to white Gaussian vibrations through impedance matching solutions

被引:0
作者
Song, Kailing [1 ,2 ]
Bonnin, Michele [3 ]
Traversa, Fabio L. [4 ]
Bonani, Fabrizio [3 ]
机构
[1] IUSS, Univ Sch Adv Studies, Pavia, Italy
[2] Politecn Torino, Turin, Italy
[3] Politecn Torino, Dept Elect & Telecommun, Turin, Italy
[4] MemComp Inc, San Diego, CA USA
来源
2022 IEEE INTERNATIONAL CONFERENCE ON ENVIRONMENT AND ELECTRICAL ENGINEERING AND 2022 IEEE INDUSTRIAL AND COMMERCIAL POWER SYSTEMS EUROPE (EEEIC / I&CPS EUROPE) | 2022年
关键词
Energy harvesting; piezoelectric energy harvester; nonlinear dynamical systems; equivalent circuits; load matching; power efficiency; nonlinear resonance; MICRO;
D O I
10.1109/EEEIC/ICPSEUROPE54979.2022.9854714
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
We discuss models of piezoelectric energy harvesters for scavenging energy from random mechanical vibrations, represented by a white Gaussian noise source. We show that circuit theory can be applied to design a matching network, to be interposed between the piezoelectric transducer and the load, able to increase the power transferred to the latter. The second order matching network is compared with a previously proposed solution, based on power factor correction, implemented through a single reactive element. We show that the new architecture boosts the harvested power with respect to the simple, unmatched resistive load, by a factor larger than 9, and with respect to the power factor correction solution by more than 17%.
引用
收藏
页数:6
相关论文
共 19 条
  • [1] A review of power harvesting using piezoelectric materials (2003-2006)
    Anton, Steven R.
    Sodano, Henry A.
    [J]. SMART MATERIALS AND STRUCTURES, 2007, 16 (03) : R1 - R21
  • [2] A micro electromagnetic generator for vibration energy harvesting
    Beeby, S. P.
    Torah, R. N.
    Tudor, M. J.
    Glynne-Jones, P.
    O'Donnell, T.
    Saha, C. R.
    Roy, S.
    [J]. JOURNAL OF MICROMECHANICS AND MICROENGINEERING, 2007, 17 (07) : 1257 - 1265
  • [3] Energy harvesting vibration sources for microsystems applications
    Beeby, S. P.
    Tudor, M. J.
    White, N. M.
    [J]. MEASUREMENT SCIENCE AND TECHNOLOGY, 2006, 17 (12) : R175 - R195
  • [4] On the application of circuit theory and nonlinear dynamics to the design of highly efficient energy harvesting systems
    Bonnin, Michele
    Traversa, Fabio L.
    Bonani, Fabrizio
    [J]. 2021 INTERNATIONAL CONFERENCE ON SMART ENERGY SYSTEMS AND TECHNOLOGIES (SEST), 2021,
  • [5] Leveraging circuit theory and nonlinear dynamics for the efficiency improvement of energy harvesting
    Bonnin, Michele
    Traversa, Fabio L.
    Bonani, Fabrizio
    [J]. NONLINEAR DYNAMICS, 2021, 104 (01) : 367 - 382
  • [6] Analysis of influence of nonlinearities and noise correlation time in a single-DOF energy-harvesting system via power balance description
    Bonnin, Michele
    Traversa, Fabio L.
    Bonani, Fabrizio
    [J]. NONLINEAR DYNAMICS, 2020, 100 (01) : 119 - 133
  • [7] Powering MEMS portable devices - a review of non-regenerative and regenerative power supply systems with special emphasis on piezoelectric energy harvesting systems
    Cook-Chennault, K. A.
    Thambi, N.
    Sastry, A. M.
    [J]. SMART MATERIALS AND STRUCTURES, 2008, 17 (04)
  • [8] Nonlinear dynamics and triboelectric energy harvesting from a three-degree-of-freedom vibro-impact oscillator
    Fu, Yiqiang
    Ouyang, Huajiang
    Davis, R. Benjamin
    [J]. NONLINEAR DYNAMICS, 2018, 92 (04) : 1985 - 2004
  • [9] There's plenty of energy at the bottom (micro and nano scale nonlinear noise harvesting)
    Gammaitoni, Luca
    [J]. CONTEMPORARY PHYSICS, 2012, 53 (02) : 119 - 135
  • [10] Gardiner C. W., 1985, HDB STOCHASTIC METHO
12