Limit hypersurface state-of-the-art damage assessment approach for a galloping energy harvester, accounting for memory effects

IF 2.3 3区 工程技术 Q2 ACOUSTICS
Oleg Gaidai, Zirui Liu, Yu Cao, Fuxi Zhang, Yan Zhu, Jinlu Sheng
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引用次数: 0

Abstract

Energy harvesters (i.e., EH) constituting nowadays an essential part of renewable energy engineering; hence, apart from numerical modeling, experimental studies are necessary, constituting reliable input for durable design and structural safety assessments. In the current study, galloping EH’s performance was analyzed, utilizing extensive laboratory wind-tunnel tests, conducted under realistic windspeed conditions. The novel structural multivariate risks assessment methodology, presented in the current study is particularly feasible for multi-dimensional nonlinear EH dynamic systems, that have been either directly Monte Carlo (i.e., MC) numerically simulated or physically measured over a representative temporal lapse, providing piecewise ergodic time series. As shown in this analysis, the suggested multivariate methodology accurately enables accurate predictions of the EH dynamic system’s failure/hazard or damage risks, based on laboratory-measured EH system’s dynamics. Furthermore, nonlinear inter-correlations between various systems’ critical components are not always easily handled by classic risk assessment techniques, when dealing with a high-dimensional system’s raw time series. The primary goal of this study was validation and benchmarking the novel risk assessment methodology, which can extract pertinent information, contained within the EH system’s dynamics, based on lab-recorded time histories. In conclusion, the novel hypersurface methodology presented in this study is generic, providing additional capability to accurately, yet efficiently predict damage/failure risks for a variety of nonlinear EH multidimensional systems. Relatively narrow confidence bands have been reported for the forecasted damage and failure levels, indicating both the robustness of the experimental setup, as well as practical design virtues of the advocated Gaidai hypersurface risks assessment methodology. Note that the presented methodology being mathematically exact does not rely on pre-assumptions and yet it is of general purpose.
考虑记忆效应的驰骋式能量收集器极限超表面最先进损伤评估方法
能量收集器(即 EH)是当今可再生能源工程的重要组成部分;因此,除了数值建模外,还需要进行实验研究,为持久设计和结构安全评估提供可靠信息。在当前的研究中,利用大量的实验室风洞试验,在实际风速条件下对疾驰式 EH 的性能进行了分析。本研究中提出的新型结构多变量风险评估方法特别适用于多维非线性 EH 动态系统,这些系统已经过直接蒙特卡罗(即 MC)数值模拟,或在有代表性的时间间隔内进行了物理测量,提供了片断遍历时间序列。如本分析所示,建议的多元方法可根据实验室测量的 EH 系统动态准确预测 EH 动态系统的故障/危险或损坏风险。此外,在处理高维系统的原始时间序列时,传统的风险评估技术很难处理系统各关键组件之间的非线性相互关系。本研究的主要目标是验证和基准测试新型风险评估方法,该方法可根据实验室记录的时间历程,提取 EH 系统动态中包含的相关信息。总之,本研究中提出的新型超表面方法是通用的,可为各种非线性 EH 多维系统提供额外的能力,以准确、高效地预测损坏/故障风险。据报告,预测损害和失效水平的置信区间相对较窄,这既表明了实验装置的稳健性,也表明了所倡导的 Gaidai 超表面风险评估方法的实用设计优点。需要注意的是,所提出的方法在数学上是精确的,并不依赖于预先假设,但却具有通用性。
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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来源期刊
Journal of Vibration and Control
Journal of Vibration and Control 工程技术-工程:机械
CiteScore
5.20
自引率
17.90%
发文量
336
审稿时长
6 months
期刊介绍: The Journal of Vibration and Control is a peer-reviewed journal of analytical, computational and experimental studies of vibration phenomena and their control. The scope encompasses all linear and nonlinear vibration phenomena and covers topics such as: vibration and control of structures and machinery, signal analysis, aeroelasticity, neural networks, structural control and acoustics, noise and noise control, waves in solids and fluids and shock waves.
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