Internal resonance is explored as a possible mechanism to enhance vibration-based energy harvesting. An electromagnetic device with snap-through nonlinearity is proposed as an archetype of an internal resonance energy harvester. Based on the equations governing the vibration measured from a stable equilibrium position, the method of multiple scales is applied to derive the amplitude–frequency response relationships of the displacement and the power in the first primary resonances with the two-to-one internal resonance. The amplitude–frequency response curves have two peaks bending to the left and the right, respectively. The numerical simulations support the analytical results. Then the averaged power is calculated under the Gaussian white noise, the narrow-band noise, the colored noise defined by a second-order filter, and the exponentially correlated noise. The results demonstrate numerically that the internal resonance design produces more power than other designs under the Gaussian white noise and the exponentially correlated noise. Besides, the internal resonance energy harvester can outperform the linear energy harvesters with the same natural frequencies and in the same size under Gaussian white noise.
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March 2015
Research-Article
Internal Resonance Energy Harvesting
Li-Qun Chen,
Li-Qun Chen
1
Department of Mechanics,
Shanghai University
,Shanghai 200444
, China
Shanghai Institute of Applied
Mathematics and Mechanics,
Mathematics and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory of Mechanics
in Energy Engineering,
e-mail: lqchen@staff.shu.edu.cn
in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
e-mail: lqchen@staff.shu.edu.cn
1Corresponding author.
Search for other works by this author on:
Wen-An Jiang
Wen-An Jiang
Shanghai Institute of Applied
Mathematics and Mechanics,
e-mail: anan0397@163.com
Mathematics and Mechanics,
Shanghai University
,Shanghai 200072
, China
e-mail: anan0397@163.com
Search for other works by this author on:
Li-Qun Chen
Department of Mechanics,
Shanghai University
,Shanghai 200444
, China
Shanghai Institute of Applied
Mathematics and Mechanics,
Mathematics and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory of Mechanics
in Energy Engineering,
e-mail: lqchen@staff.shu.edu.cn
in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
e-mail: lqchen@staff.shu.edu.cn
Wen-An Jiang
Shanghai Institute of Applied
Mathematics and Mechanics,
e-mail: anan0397@163.com
Mathematics and Mechanics,
Shanghai University
,Shanghai 200072
, China
e-mail: anan0397@163.com
1Corresponding author.
Manuscript received August 16, 2014; final manuscript received January 12, 2015; published online January 29, 2015. Assoc. Editor: Alexander F. Vakakis.
J. Appl. Mech. Mar 2015, 82(3): 031004 (11 pages)
Published Online: March 1, 2015
Article history
Received:
August 16, 2014
Revision Received:
January 12, 2015
Online:
January 29, 2015
Citation
Chen, L., and Jiang, W. (March 1, 2015). "Internal Resonance Energy Harvesting." ASME. J. Appl. Mech. March 2015; 82(3): 031004. https://doi.org/10.1115/1.4029606
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