Improved Global-Local Method for Ultrasonic Guided Wave Scattering Predictions in Composite Waveguides and Defects

M. Capriotti, Luis Waldo Escalona Galvis, A. Spada
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Abstract

As structures increase in complexity, in the use of high-performing materials and designs, their health assessment becomes increasingly challenging. Ultrasonic guided waves (UGWs) have shown to be very promising in the inspection of large (i.e. aerospace components) attenuating (i.e. composite materials) structures and have been successfully employed for damage detection in a variety of fields. The intrinsic complex nature of UGWs, due to their dispersive behavior, combined with the structural complexity of the applications, though, makes the interpretation of UGW inspections very challenging. Numerical simulations of UGW propagation become crucial to this end and have been addressed with fully numerical, semi-analytical and hybrid approaches. The capability of predicting UGW scattering can inform experimental testing in optimizing the sensitivity of UGW inspections to specific waveguides and defects, and in interpreting the acquired data for the non-destructive identification and quantification of damages. In this work, an improved computational tool for UGW scattering predictions is presented. The approach relies on the Global-Local method and leverages the efficiency of the semi-analytical finite element (SAFE) method and the parallelized implementation of the coupled solution. 2D applications of the Global-Local approach for UGW scattering predictions in composite structures over a wide range of frequencies will be presented, together with the demonstration of the improved computational performance. The computational efficiency promises feasible and reliable UGWs predictions in multi-layered complex assemblies and different damage scenarios, and enables virtual UGWs inspections and future integration in NDE testing.
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复合波导和缺陷中超声导波散射预测的改进全局-局部方法
随着结构复杂性的增加,在高性能材料和设计的使用中,其健康评估变得越来越具有挑战性。超声导波(ugw)在大型(如航空航天部件)衰减(如复合材料)结构的检测中显示出非常有前景,并已成功地用于各种领域的损伤检测。由于其弥散性,加之应用结构的复杂性,UGW固有的复杂性使得对UGW检测的解释非常具有挑战性。UGW传播的数值模拟对这一目标至关重要,并已通过全数值、半解析和混合方法得到解决。预测UGW散射的能力可以为实验测试提供信息,以优化UGW检测对特定波导和缺陷的灵敏度,并解释获得的数据,以进行无损识别和损伤量化。在这项工作中,提出了一种改进的UGW散射预测计算工具。该方法以全局-局部法为基础,利用半解析有限元法的效率和耦合解的并行化实现。将介绍全球-局部方法在大频率范围内用于复合材料结构中UGW散射预测的二维应用,并演示改进的计算性能。计算效率保证了在多层复杂组件和不同损伤情况下可行和可靠的ugw预测,并实现了虚拟ugw检测和未来无损检测的集成。
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CiteScore
3.80
自引率
9.10%
发文量
25
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