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用于能量自主型仪器化全髋关节置换的压电能量收集系统性能:实验与数值评估

Performance of a Piezoelectric Energy Harvesting System for an Energy-Autonomous Instrumented Total Hip Replacement: Experimental and Numerical Evaluation.

作者信息

Lange Hans-E, Arbeiter Nils, Bader Rainer, Kluess Daniel

机构信息

Department of Orthopaedics, Rostock University Medical Center, 18057 Rostock, Germany.

Institute of General Electrical Engineering, University of Rostock, 18059 Rostock, Germany.

出版信息

Materials (Basel). 2021 Sep 8;14(18):5151. doi: 10.3390/ma14185151.

DOI:10.3390/ma14185151
PMID:34576375
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8470322/
Abstract

Instrumented implants can improve the clinical outcome of total hip replacements (THRs). To overcome the drawbacks of external energy supply and batteries, energy harvesting is a promising approach to power energy-autonomous implants. Therefore, we recently presented a new piezoelectric-based energy harvesting concept for THRs. In this study, the performance of the proposed energy harvesting system was numerically and experimentally investigated. First, we numerically reproduced our previous results for the physiologically based loading situation in a simplified setup. Thereafter, this configuration was experimentally realised by the implantation of a functional model of the energy harvesting concept into an artificial bone segment. Additionally, the piezoelectric element alone was investigated to analyse the predictive power of the numerical model. We measured the generated voltage for a load profile for walking and calculated the power output. The maximum power for the directly loaded piezoelectric element and the functional model were 28.6 and 10.2 µW, respectively. Numerically, 72.7 µW was calculated. The curve progressions were qualitatively in good accordance with the numerical data. The deviations were explained by sensitivity analysis and model simplifications, e.g., material data or lower acting force levels by malalignment and differences between virtual and experimental implantation. The findings verify the feasibility of the proposed energy harvesting concept and form the basis for design optimisations with increased power output.

摘要

带仪器的植入物可以改善全髋关节置换术(THR)的临床效果。为了克服外部能量供应和电池的缺点,能量收集是为能量自主植入物供电的一种有前景的方法。因此,我们最近提出了一种用于全髋关节置换术的基于压电的新型能量收集概念。在本研究中,对所提出的能量收集系统的性能进行了数值和实验研究。首先,我们在简化设置中通过数值再现了我们之前关于基于生理负荷情况的结果。此后,通过将能量收集概念的功能模型植入人工骨段来实验实现这种配置。此外,对单独的压电元件进行了研究,以分析数值模型的预测能力。我们测量了步行负荷曲线下产生的电压,并计算了功率输出。直接加载的压电元件和功能模型的最大功率分别为28.6和10.2微瓦。在数值上,计算得出为72.7微瓦。曲线进展在质量上与数值数据高度一致。偏差通过敏感性分析和模型简化来解释,例如材料数据、因错位导致的较低作用力水平以及虚拟植入和实验植入之间的差异。这些发现验证了所提出的能量收集概念的可行性,并为提高功率输出的设计优化奠定了基础。

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3
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4
Correction: Lange et al. Performance of a Piezoelectric Energy Harvesting System for an Energy-Autonomous Instrumented Total Hip Replacement: Experimental and Numerical Evaluation. 2021, , 5151.更正:兰格等人。用于能量自主型仪器化全髋关节置换的压电能量收集系统的性能:实验与数值评估。2021年,,5151。
Materials (Basel). 2021 Dec 13;14(24):7693. doi: 10.3390/ma14247693.
一种使用摩擦电能量收集器的智能膝关节植入物。
Smart Mater Struct. 2019 Feb;28(2). doi: 10.1088/1361-665X/aaf3f1. Epub 2019 Jan 25.
4
A round-robin finite element analysis of human femur mechanics between seven participating laboratories with experimental validation.七个参与实验室之间对人类股骨力学进行的循环有限元分析及实验验证。
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5
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6
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7
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8
Smart implants in orthopedic surgery, improving patient outcomes: a review.骨科手术中的智能植入物,改善患者预后:综述
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9
Projections of hip arthroplasty in OECD countries up to 2050.经合组织国家截至2050年的髋关节置换术预测。
Hip Int. 2018 Sep;28(5):498-506. doi: 10.1177/1120700018757940. Epub 2018 May 21.
10
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