Energy harvesting from a cantilever beam with a spring-loaded oscillating mass system and base excitation

Anwesa Mohanty, R. Behera
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引用次数: 1

Abstract

The present study deals with the mathematical modeling of a nonlinear energy harvester (EH) to analyze it's frequency bandwidth for optimal use. The exhibited unique piezoelectric energy harvester (PEH) contains a cantilever beam as resonator with a moving mass. To fulfill the mechanism, the mass needs to be connected to the fixed end of the beam with a spring that acts as a mechanical amplifier. A novel analytical approach with 1:2 internal resonance (IR) including kinematic nonlinearity is addressed for energy harvesting. The occurrence of strong nonlinear coupling is the result of constant interconnection between the beam and moving mass. A discrete electro-mechanical coupled equation is derived using Galerkin's method followed by Hamilton's energy method. To analyze the effect of input parameters on the frequency bandwidth, MATLAB code is improved by implementing the “Method of multiple scales” (MMS) for furthering the energy output of the system. Due to IR, the solution tilted to two branches in the designed EH, witnessing broader frequency bandwidth. The influence of different system parameters such as spring stiffness, mass, and velocity of moving mass changed the position of central frequency resulting in the change in symmetry of frequency response.
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具有弹簧加载振荡质量系统和基座激励的悬臂梁能量收集
本文对非线性能量采集器(EH)进行了数学建模,分析了其最优使用的频率带宽。所展示的独特的压电能量采集器(PEH)包含一个悬臂梁作为谐振腔与移动的质量。为了实现这一机制,需要用弹簧将质量连接到梁的固定端,弹簧起到机械放大器的作用。提出了一种新的含运动非线性的1:2内共振(IR)能量收集分析方法。强非线性耦合的发生是梁与运动质量之间不断相互作用的结果。采用伽辽金法和哈密顿能量法推导了离散机电耦合方程。为了分析输入参数对频宽的影响,通过实现“多尺度法”(MMS)对MATLAB代码进行改进,进一步提高系统的能量输出。由于红外效应,该方案在设计的EH中倾斜到两个支路,具有更宽的频率带宽。弹簧刚度、质量、运动质量速度等不同系统参数的影响会改变中心频率的位置,从而导致频率响应对称性的改变。
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来源期刊
CiteScore
4.10
自引率
11.10%
发文量
38
审稿时长
>12 weeks
期刊介绍: The Journal of Multi-body Dynamics is a multi-disciplinary forum covering all aspects of mechanical design and dynamic analysis of multi-body systems. It is essential reading for academic and industrial research and development departments active in the mechanical design, monitoring and dynamic analysis of multi-body systems.
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