Design and experiment investigation of a percussive piezoelectric energy harvester scavenging on wind galloping oscillation
出版年份 2021 全文链接
标题
Design and experiment investigation of a percussive piezoelectric energy harvester scavenging on wind galloping oscillation
作者
关键词
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出版物
FERROELECTRICS
Volume 584, Issue 1, Pages 121-131
出版商
Informa UK Limited
发表日期
2021-12-09
DOI
10.1080/00150193.2021.1984769
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注意:仅列出部分参考文献,下载原文获取全部文献信息。- Exploiting the advantages of the centrifugal softening effect in rotational impact energy harvesting
- (2020) Shitong Fang et al. APPLIED PHYSICS LETTERS
- An asymmetric bending-torsional piezoelectric energy harvester at low wind speed
- (2020) Jinda Jia et al. ENERGY
- Magnet-induced monostable nonlinearity for improving the VIV-galloping-coupled wind energy harvesting using combined cross-sectioned bluff body
- (2020) Kai Yang et al. Smart Materials and Structures
- Enhancement of low-speed piezoelectric wind energy harvesting by bluff body shapes: Spindle-like and butterfly-like cross-sections
- (2020) Junlei Wang et al. AEROSPACE SCIENCE AND TECHNOLOGY
- Enhancing Performance of a Piezoelectric Energy Harvester System for Concurrent Flutter and Vortex-Induced Vibration
- (2020) Xiaobiao Shan et al. Energies
- Hybrid wind energy scavenging by coupling vortex-induced vibrations and galloping
- (2020) Junlei Wang et al. ENERGY CONVERSION AND MANAGEMENT
- A Dual-Modulator Magnetic-Geared Machine for Tidal-Power Generation
- (2020) Hang Zhao et al. IEEE TRANSACTIONS ON MAGNETICS
- Modeling and nonlinear analysis of stepped beam energy harvesting from galloping vibrations
- (2020) Jiantao Zhang et al. JOURNAL OF SOUND AND VIBRATION
- Comprehensive theoretical and experimental investigation of the rotational impact energy harvester with the centrifugal softening effect
- (2020) Shitong Fang et al. NONLINEAR DYNAMICS
- Global reduction of solar power generation efficiency due to aerosols and panel soiling
- (2020) Xiaoyuan Li et al. Nature Sustainability
- Dynamics and performance of a two degree-of-freedom galloping-based piezoelectric energy harvester
- (2019) Chunbo Lan et al. Smart Materials and Structures
- Parametrically excited nonlinear magnetic rolling pendulum for broadband energy harvesting
- (2019) Yang Kuang et al. APPLIED PHYSICS LETTERS
- Enhancing the performance of an underwater piezoelectric energy harvester based on flow-induced vibration
- (2019) Xiaobiao Shan et al. ENERGY
- Efficiency investigation on energy harvesting from airflows in HVAC system based on galloping of isosceles triangle sectioned bluff bodies
- (2019) Junlei Wang et al. ENERGY
- A curved panel energy harvester for aeroelastic vibration
- (2019) Xiaobiao Shan et al. APPLIED ENERGY
- Performance evaluation of twin piezoelectric wind energy harvesters under mutual interference
- (2019) Gang Hu et al. APPLIED PHYSICS LETTERS
- An electromagnetic galloping energy harvester with double magnet design
- (2019) Hai Dang Le et al. APPLIED PHYSICS LETTERS
- High-performance low-frequency bistable vibration energy harvesting plate with tip mass blocks
- (2019) Yi Li et al. ENERGY
- Modeling and verification of piezoelectric wind energy harvesters enhanced by interaction between vortex-induced vibration and galloping
- (2019) Xiaokang Yang et al. Smart Materials and Structures
- Theoretical modeling, wind tunnel measurements, and realistic environment testing of galloping-based electromagnetic energy harvesters
- (2019) L.B. Zhang et al. APPLIED ENERGY
- Low-frequency and broadband vibration energy harvester driven by mechanical impact based on layer-separated piezoelectric beam
- (2019) Dongxing Cao et al. APPLIED MATHEMATICS AND MECHANICS-ENGLISH EDITION
- A double-beam piezo-magneto-elastic wind energy harvester for improving the galloping-based energy harvesting
- (2019) Kai Yang et al. APPLIED PHYSICS LETTERS
- Harvest wind energy from a vibro-impact DEG embedded into a bluff body
- (2019) Z.H. Lai et al. ENERGY CONVERSION AND MANAGEMENT
- Mechanical modulations for enhancing energy harvesting: Principles, methods and applications
- (2019) Hong-Xiang Zou et al. APPLIED ENERGY
- Comparative Study of Piezoelectric Vortex-Induced Vibration-Based Energy Harvesters with Multi-Stability Characteristics
- (2019) Rashid Naseer et al. Energies
- Transonic Panel Flutter in Accelerating or Decelerating Flow Conditions
- (2018) Anastasia Shishaeva et al. AIAA JOURNAL
- Micro electrostatic energy harvester with both broad bandwidth and high normalized power density
- (2018) Yulong Zhang et al. APPLIED ENERGY
- An impact-based broadband aeroelastic energy harvester for concurrent wind and base vibration energy harvesting
- (2018) Liya Zhao et al. APPLIED ENERGY
- Enhancement of wind energy harvesting by interaction between vortex-induced vibration and galloping
- (2018) Xuefeng He et al. APPLIED PHYSICS LETTERS
- Y-type three-blade bluff body for wind energy harvesting
- (2018) Feng-Rui Liu et al. APPLIED PHYSICS LETTERS
- Nonlinear dynamic analysis of asymmetric tristable energy harvesters for enhanced energy harvesting
- (2018) Shengxi Zhou et al. Communications in Nonlinear Science and Numerical Simulation
- Dual serial vortex-induced energy harvesting system for enhanced energy harvesting
- (2018) Shengxi Zhou et al. AIP Advances
- A piezoelectric spring pendulum oscillator used for multi-directional and ultra-low frequency vibration energy harvesting
- (2018) Yipeng Wu et al. APPLIED ENERGY
- Theoretical analysis of multi-stable energy harvesters with high-order stiffness terms
- (2018) Dongmei Huang et al. Communications in Nonlinear Science and Numerical Simulation
- High-performance piezoelectric wind energy harvester with Y-shaped attachments
- (2018) Junlei Wang et al. ENERGY CONVERSION AND MANAGEMENT
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