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一种用于形状传感和结构健康监测的高精度逆有限元方法。

A High-Precision Inverse Finite Element Method for Shape Sensing and Structural Health Monitoring.

作者信息

Yan Hongsheng, Tang Jiangpin

机构信息

School of Civil Engineering, Tianjin University, Tianjin 300350, China.

出版信息

Sensors (Basel). 2024 Sep 30;24(19):6338. doi: 10.3390/s24196338.

DOI:10.3390/s24196338
PMID:39409378
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11478794/
Abstract

In the contemporary era, the further exploitation of deep-sea resources has led to a significant expansion of the role of ships in numerous domains, such as in oil and gas extraction. However, the harsh marine environments to which ships are frequently subjected can result in structural failures. In order to ensure the safety of the crew and the ship, and to reduce the costs associated with such failures, it is imperative to utilise a structural health monitoring (SHM) system to monitor the ship in real time. Displacement reconstruction is one of the main objectives of SHM, and the inverse finite element method (iFEM) is a powerful SHM method for the full-field displacement reconstruction of plate and shell structures. However, existing inverse shell elements applied to curved shell structures with irregular geometry or large curvature may result in element distortion. This paper proposes a high-precision iFEM for curved shell structures that does not alter the displacement mode of the element or increase the mesh and node quantities. In reality, it just modifies the methods of calculation. This method is based on the establishment of a local coordinate system on the Gaussian integration point and the subsequent alteration of the stiffness integration. The results of numerical examples demonstrate that the high-precision iFEM is capable of effectively reducing the displacement difference resulting from inverse finite element method reconstruction. Furthermore, it performs well in practical engineering applications.

摘要

在当代,深海资源的进一步开发使得船舶在众多领域(如石油和天然气开采)中的作用显著扩大。然而,船舶经常面临的恶劣海洋环境可能导致结构失效。为了确保船员和船舶的安全,并降低此类失效带来的成本,利用结构健康监测(SHM)系统对船舶进行实时监测势在必行。位移重构是结构健康监测的主要目标之一,逆有限元法(iFEM)是一种用于板壳结构全场位移重构的强大结构健康监测方法。然而,现有的应用于几何形状不规则或曲率较大的曲壳结构的逆壳单元可能会导致单元畸变。本文提出了一种适用于曲壳结构的高精度逆有限元法,该方法不会改变单元的位移模式,也不会增加网格和节点数量。实际上,它只是修改了计算方法。该方法基于在高斯积分点建立局部坐标系并随后改变刚度积分。数值算例结果表明,高精度逆有限元法能够有效减小逆有限元法重构引起的位移差异。此外,它在实际工程应用中表现良好。

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