Nonlinear Design and Optimisation of a Vibration Energy Harvester

2018 UKACC 12th International Conference on Control (CONTROL) Pub Date : 2018-09-01 DOI:10.1109/CONTROL.2018.8516821

U. Diala, R. Gunawardena, Yunpeng Zhu, Z. Lang

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引用次数: 2

Abstract

Nonlinear behavior has been exploited over the last decade towards improving the efficiency of most engineering systems. The effect of nonlinearities on a vibration energy harvester (VEH) has been widely studied. It has been reported in literature that a cubic damping nonlinearity extends the dynamic range (power/energy level) of a VEH system. It has also been widely shown that the operational bandwidth of a VEH system can be increased using a nonlinear hardening spring. As most energy harvesters have a maximum throw limited by the physical enclosure of the device, it is imperative to improve the operational conditions of the harvester within this limitation. This paper investigates the effects of a nonlinear hardening spring with cubic damping on a VEH system while assuming no limitation to the maximum throw (Practical VEH systems are constrained to a maximum throw and this is considered in a subsequent study). A frequency-based approach known as Output Frequency Response Function (OFRF) determined using the Associated Linear Equations (ALEs) of the nonlinear system model is employed. The OFRF polynomial is a representation of the actual system model hence used for the nonlinear VEH analysis and design. Based on the OFRF, optimal parameter values are designed to achieve any desired level of energy for the VEH.

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振动能量采集器的非线性设计与优化

在过去的十年中，非线性行为已经被用于提高大多数工程系统的效率。非线性对振动能量采集器(VEH)的影响已经得到了广泛的研究。已有文献报道，三次阻尼非线性扩展了VEH系统的动态范围(功率/能级)。研究还表明，采用非线性硬化弹簧可以提高系统的工作带宽。由于大多数能量采集器的最大抛射量受到设备物理外壳的限制，因此必须在此限制范围内改善采集器的操作条件。本文研究了具有三次阻尼的非线性硬化弹簧在假设最大抛掷不受限制的情况下对VEH系统的影响(实际的VEH系统受最大抛掷约束，这将在后续研究中考虑)。采用了一种基于频率的方法，称为输出频响函数(OFRF)，该方法由非线性系统模型的关联线性方程(ALEs)确定。OFRF多项式是实际系统模型的表示，因此用于非线性VEH分析和设计。基于OFRF，设计最佳参数值以实现VEH所需的任何能量水平。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 UKACC 12th International Conference on Control (CONTROL)

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