Energy harvesting via nonlinear energy sink for whole-spacecraft 被引量：16

Energy harvesting via nonlinear energy sink for whole-spacecraft

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摘要 This paper presents nonlinear energy sink with giant magnetostrictive-piezoelectric material for energy harvesting of the wholespacecraft vibration reduction system. The whole-spacecraft vibration attenuation system can effectively reduce vibration and achieve self-tuning enhanced energy harvesting range. The open-circuit voltage generated at low frequency is affected by the magnetic field force, alternating magnetic field and relative displacement. In order to acquire a steady periodic solution of the energy harvesting system, a combination of the harmonic balance method and pseudo arc length continuation technique is used.The numerical outcomes are consistent with the analytical outcomes in a certain range, which also proves the accuracy and reliability of the results. The amplitude and voltage of the energy harvesting system are analyzed by parameters such as cubic stiffness, viscous damping, and external excitation acceleration. In addition, this paper provides a new idea for broadband energy harvesting. This paper presents nonlinear energy sink with giant magnetostrictive-piezoelectric material for energy harvesting of the wholespacecraft vibration reduction system. The whole-spacecraft vibration attenuation system can effectively reduce vibration and achieve self-tuning enhanced energy harvesting range. The open-circuit voltage generated at low frequency is affected by the magnetic field force, alternating magnetic field and relative displacement. In order to acquire a steady periodic solution of the energy harvesting system, a combination of the harmonic balance method and pseudo arc length continuation technique is used.The numerical outcomes are consistent with the analytical outcomes in a certain range, which also proves the accuracy and reliability of the results. The amplitude and voltage of the energy harvesting system are analyzed by parameters such as cubic stiffness, viscous damping, and external excitation acceleration. In addition, this paper provides a new idea for broadband energy harvesting.

作者 ZHANG YeWei LU YanNan CHEN LiQun

机构地区 Faculty of Aerospace Engineerings School of Science

出处《Science China(Technological Sciences)》 SCIE EI CAS CSCD 2019年第9期1483-1491,共9页 中国科学（技术科学英文版）

基金 supported by the National Natural Science Foundation of China(Grant Nos.11772205,11572182,51775541,11672188) the Scientific Research Fund of Liaoning Provincial Education Department(Grant Nos.L201703,L201737,L201762) the Liaoning Revitalization Talents Program(Grant No.XLYC1807172)

关键词 nonlinear ENERGY SINK giant magnetostrictive-piezoelectric material pseudo arc length CONTINUATION technique ENERGY harvesting nonlinear energy sink giant magnetostrictive-piezoelectric material pseudo arc length continuation technique energy harvesting

分类号 TH [机械工程]

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