MEMS based Nonlinear Monostable Electromagnetic Vibrational Energy Harvester for Wider Bandwidth

D. Mallick; A. Amann; S. Roy

doi:10.1088/1742-6596/660/1/012115

MEMS based Nonlinear Monostable Electromagnetic Vibrational Energy Harvester for Wider Bandwidth

D. Mallick
, A. Amann
, S. Roy

University College Cork

Research output: Contribution to journal › Article › peer-review

Abstract

This paper reports a wideband vibrational energy harvesting scheme using a MEMS based nonlinear electromagnetic transducer. The nonlinearity is incorporated in the proposed device through the stretching strain in addition to the bending of the fixed-guided configured beams of the designed structure. The thin spring structure is fabricated on Silicon-On-Insulator substrate with device layer thickness of 50 m. The MEMS spring structure is packaged and characterized with wire wound copper coil (NE1) and micro fabricated double layer copper coil (NE2) for comparison. Measurement results show that ∼80 Hz half power bandwidth is obtained for the fabricated devices with maximum load powers of 2.8 W (NE1) and 0.4 W (NE2) respectively at 0.5g which improves the 'power-bandwidth gain' to one of the highest among reported works.

Original language	English
Article number	012115
Journal	Journal of Physics: Conference Series
Volume	660
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/660/1/012115
Publication status	Published - 10 Dec 2015
Event	15th International Conference on Micro and Nanotechnology for Power Generation and Energy Conversion Applications, PowerMEMS 2015 - Boston, United States Duration: 1 Dec 2015 → 4 Dec 2015

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10.1088/1742-6596/660/1/012115

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title = "MEMS based Nonlinear Monostable Electromagnetic Vibrational Energy Harvester for Wider Bandwidth",

abstract = "This paper reports a wideband vibrational energy harvesting scheme using a MEMS based nonlinear electromagnetic transducer. The nonlinearity is incorporated in the proposed device through the stretching strain in addition to the bending of the fixed-guided configured beams of the designed structure. The thin spring structure is fabricated on Silicon-On-Insulator substrate with device layer thickness of 50 m. The MEMS spring structure is packaged and characterized with wire wound copper coil (NE1) and micro fabricated double layer copper coil (NE2) for comparison. Measurement results show that ∼80 Hz half power bandwidth is obtained for the fabricated devices with maximum load powers of 2.8 W (NE1) and 0.4 W (NE2) respectively at 0.5g which improves the 'power-bandwidth gain' to one of the highest among reported works.",

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AB - This paper reports a wideband vibrational energy harvesting scheme using a MEMS based nonlinear electromagnetic transducer. The nonlinearity is incorporated in the proposed device through the stretching strain in addition to the bending of the fixed-guided configured beams of the designed structure. The thin spring structure is fabricated on Silicon-On-Insulator substrate with device layer thickness of 50 m. The MEMS spring structure is packaged and characterized with wire wound copper coil (NE1) and micro fabricated double layer copper coil (NE2) for comparison. Measurement results show that ∼80 Hz half power bandwidth is obtained for the fabricated devices with maximum load powers of 2.8 W (NE1) and 0.4 W (NE2) respectively at 0.5g which improves the 'power-bandwidth gain' to one of the highest among reported works.

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T2 - 15th International Conference on Micro and Nanotechnology for Power Generation and Energy Conversion Applications, PowerMEMS 2015

Y2 - 1 December 2015 through 4 December 2015

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MEMS based Nonlinear Monostable Electromagnetic Vibrational Energy Harvester for Wider Bandwidth

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