Design of a New Piezoelectric Energy Harvester Based on Secondary Impact
- Authors
- Jung, Hyun Jun; Baek, Ki Hwan; Hidaka, Sinichi; Song, Daniel; Kim, Se Bin; Sung, Tae Hyun
- Issue Date
- Jan-2013
- Publisher
- Gordon and Breach Science Publishers
- Keywords
- energy harvesting; piezoelectric; secondary; impact
- Citation
- Ferroelectrics, v.449, no.1, pp 83 - 93
- Pages
- 11
- Indexed
- SCI
SCIE
SCOPUS
- Journal Title
- Ferroelectrics
- Volume
- 449
- Number
- 1
- Start Page
- 83
- End Page
- 93
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/163695
- DOI
- 10.1080/00150193.2013.822773
- ISSN
- 0015-0193
1563-5112
- Abstract
- Two models for an energy harvester imparting rotational energy to piezoelectric materials are presented, in order to compare the effects of applying identical amounts of energy to a cantilever beam by changing the total displacement per unit time, and applying a secondary impact. For a piezoelectric energy harvester given a high total impulse per unit time with low total displacement per unit time, higher power outputs were generated at lower resistive loads. Conversely, for a harvester given high total displacement per unit time with low total impulse per unit time, power output was higher at high resistive loads. At matched impedance, the secondary-impact-type piezoelectric energy harvester generated higher power output than the hitting-type piezoelectric energy harvester did at low resistive load. Optimized response of secondary-impact-type piezoelectric energy harvester was obtained at a frequency of 60Hz with a low resistive load of 1 k. The generated output power was measured as 124 mW, which corresponds to power density of 140 mW/cm(3) for the entire cantilever beam, and a power density of 342 mW/cm(3) for only the piezoelectric material volume (including sliver paste volume). For a harvester without a secondary impulse at low resistive loads (1 k), the optimizing frequency was between 20 and 30Hz, with an output power of 22 mW, which corresponds to a 25 mW/cm(3) power density for entire cantilever beam and power density of 60 mW/cm(3) for only the piezoelectric material volume(including sliver paste volume).
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