Modelling and performance enhancement of the fluid coupling interface for hydraulic pressure energy harvesting by superposition of the static mean pressure and pressure fluctuations

IF 7.9 1区 工程技术 Q1 ENGINEERING, MECHANICAL Mechanical Systems and Signal Processing Pub Date : 2024-10-15 DOI:10.1016/j.ymssp.2024.112042
Huifang Xiao , Ziqi Zhu , Haotang Qie , Gang Liang , Yihu Tang , Chris Bowen , James Roscow
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Abstract

The monitoring and control of hydraulic systems in an autonomous and battery-free manner is receiving increasing attention to improve both safety and performance. In this regard, the conversion of pressure ripples within a hydraulic system into electric energy using hydraulic pressure energy harvesting (HPEH) is attractive due to the high energy intensity associated with dynamic pressure fluctuations. In this paper, a new theoretical model of the fluid to mechanical interface is established based on a central piezoelectric stack subject to a superimposed dynamic pressure fluctuation and a mean static pressure. A lumped-parameter model of the electromechanical coupling system is employed to study the overall harvesting performance of the system, and the force–deflection behavior of a circular edge-clamped plate with a lumped mass and a superimposed excitation is determined. The influence of static pressure on harvesting performance is explored in detail, where the mean static pressure introduces a softening nonlinearity to the harvester which decreases the power output and harvesting bandwidth. To reduce the negative impact of static pressure on power output, an optimized structure based on a quasi-zero stiffness (QZS) disc spring is proposed. The nonlinear restoring force of the circular plate interface on a central piezoelectric stack and disc spring is determined and the electromechanical coupling equations of the quasi-zero stiffness hydraulic pressure energy harvesting (QZS-HPEH) structure is established. Our theoretical analysis shows that the power output is improved using the novel QZS-HPEH structure, in particular at the high static loads presented in hydraulic systems. Experimental validation is performed, where good agreement is observed between model results and experimental measurements. The proposed model and experimental validation provide important new insights into the optimization of power output and application of HPEH devices in practical hydraulic systems.
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通过静态平均压力和压力波动的叠加,为用于液压能量采集的流体耦合界面建模并提高其性能
为了提高安全性和性能,以自主和无需电池的方式监测和控制液压系统正受到越来越多的关注。在这方面,利用液压能量采集 (HPEH) 将液压系统内的压力波纹转换为电能具有吸引力,因为动态压力波动具有高能量强度。本文基于受动态压力波动和平均静态压力叠加影响的中心压电叠层,建立了流体与机械界面的新理论模型。采用机电耦合系统的叠加参数模型来研究系统的整体采集性能,并确定了带有叠加质量和叠加激励的圆形边缘夹紧板的力-挠度行为。详细探讨了静压对收割性能的影响,平均静压会给收割机带来软化非线性,从而降低功率输出和收割带宽。为了减少静压对功率输出的负面影响,提出了一种基于准零刚度(QZS)碟形弹簧的优化结构。我们确定了圆板界面对中心压电叠层和碟形弹簧的非线性恢复力,并建立了准零刚度水压能量收集(QZS-HPEH)结构的机电耦合方程。我们的理论分析表明,使用新型 QZS-HPEH 结构可以提高功率输出,尤其是在液压系统中出现高静态负载时。我们还进行了实验验证,观察到模型结果与实验测量结果之间具有良好的一致性。提出的模型和实验验证为功率输出的优化和 HPEH 设备在实际液压系统中的应用提供了重要的新见解。
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来源期刊
Mechanical Systems and Signal Processing
Mechanical Systems and Signal Processing 工程技术-工程:机械
CiteScore
14.80
自引率
13.10%
发文量
1183
审稿时长
5.4 months
期刊介绍: Journal Name: Mechanical Systems and Signal Processing (MSSP) Interdisciplinary Focus: Mechanical, Aerospace, and Civil Engineering Purpose:Reporting scientific advancements of the highest quality Arising from new techniques in sensing, instrumentation, signal processing, modelling, and control of dynamic systems
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