Efficient layerwise multiphysics spectral element model for delaminated composite strips with PWAS transducers

IF 4.4 2区 工程技术 Q1 MECHANICS
Mayank Jain, Santosh Kapuria
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引用次数: 0

Abstract

Efficient structural element-based models are essential for fast simulations of wave propagation in composite structures for model-based and physics-informed data-driven structural health monitoring. This article introduces the first efficient multiphysics time-domain spectral structural element for wave propagation analysis of beam and panel-type composite structures with piezoelectric transducers (patch or full layers) containing delaminations. A general framework is presented to model multiple delaminations and transducer patches located arbitrarily. The intact host and patch transducer-bonded laminates and sub-laminates between delaminations are modelled separately using an electromechanically coupled efficient layerwise zigzag theory (ZIGT) for kinematics and a piecewise quadratic variation for the electric potential across piezoelectric layers. The high-order spectral element (SE) features a virtual electric node to model equipotential surfaces of piezoelectric transducers apart from the usual physical nodes having mechanical and internal electric degrees of freedom. A hybrid point-least squares continuity approach is employed to maintain continuity at the intersections of delaminated sub-laminates or the patch-bonded laminate with the host laminate. The model’s performance in capturing electroelastic waves’ interaction with delamination is examined with reference to the conventional finite element (FE) solution based on the ZIGT, continuum-based FE solutions, and the SE solution based on a non-layerwise version of the laminate theory. Finally, the model is used to examine the impact of interfacial location and size of delaminations on wave propagation behaviour.
带 PWAS 传感器的分层复合材料带材高效多物理场谱元模型
基于模型和物理信息数据驱动的结构健康监测中,高效的结构元素模型对于复合材料结构中波传播的快速模拟至关重要。本文介绍了第一种高效的多物理场时域频谱结构元素,用于分析带有压电传感器(贴片或全层)、含有分层的梁式和板式复合材料结构的波传播。本文提出了一个通用框架,用于模拟多个分层和任意位置的传感器贴片。采用机电耦合的高效分层之字形理论 (ZIGT) 分别对完整的主机和贴片换能器结合层以及分层之间的子层板进行运动学建模,并采用片式二次变化对跨压电层的电动势进行建模。高阶谱元(SE)除了具有机械和内部电动自由度的常规物理节点外,还具有一个虚拟电动节点,用于模拟压电传感器的等电位表面。该模型采用混合点最小二乘法连续性方法,以保持分层子层压板或贴片粘合层压板与主层压板交汇处的连续性。参照基于 ZIGT 的传统有限元 (FE) 解法、基于连续体的 FE 解法和基于层压板理论非分层版本的 SE 解法,检验了该模型在捕捉电弹性波与分层相互作用方面的性能。最后,利用该模型研究了分层的界面位置和大小对波传播行为的影响。
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
CiteScore
7.00
自引率
7.30%
发文量
275
审稿时长
48 days
期刊介绍: The European Journal of Mechanics endash; A/Solids continues to publish articles in English in all areas of Solid Mechanics from the physical and mathematical basis to materials engineering, technological applications and methods of modern computational mechanics, both pure and applied research.
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