A framework for computing directivities for ultrasonic sources in generally anisotropic, multi-layered media

IF 2.1 3区物理与天体物理 Q2 ACOUSTICS

Wave Motion Pub Date : 2024-02-24 DOI:10.1016/j.wavemoti.2024.103299

Xin L. Tu , Jie Zhang , Alberto M. Gambaruto , Paul D. Wilcox

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引用次数: 0

Abstract

The knowledge of the directivity of ultrasonic sources is an important element in the design of non-destructive evaluation inspection. The commonly used directivity model of piezoelectric devices is the superposition of out-of-plane force monopoles on the stress-free surface of an isotropic elastic half-space. However, this does not cover a growing range of ultrasonic generation scenarios, as new ultrasonic technologies such as laser ultrasound (LU) emerges, and the need for inspection of materials such as carbon fibre reinforced polymers (CFRPs) rises. A directivity calculation framework based on the reciprocity theorem is developed in the current paper, which accommodates various combinations of source types, material properties, and boundary conditions, for example, a localised heating under a surface layer over an anisotropic half-space. The calculation is applicable to materials with weak anisotropy or wave modes that do not have cuspoidal wavefronts, and was validated with finite element models on key representative cases. The analytical solution for LU excitation in a CFRP sample also shows a good fit to the experimentally measured directivity of the quasi-longitudinal wave mode.

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计算各向异性多层介质中超声源指向性的框架

了解超声源的指向性是设计无损评估检测的一个重要因素。压电设备常用的指向性模型是各向同性弹性半空间无应力表面上平面外力单极的叠加。然而，随着激光超声（LU）等新型超声技术的出现，以及对碳纤维增强聚合物（CFRP）等材料检测需求的增加，这一模型并不能涵盖越来越多的超声波产生情况。本文以互易定理为基础开发了一个指向性计算框架，该框架适用于声源类型、材料属性和边界条件的各种组合，例如各向异性半空间表面层下的局部加热。该计算方法适用于各向异性较弱的材料或不具有尖面波面的波模，并通过关键代表性案例的有限元模型进行了验证。CFRP 样品中 LU 激发的分析解决方案也显示出与实验测量的准纵波模式指向性的良好拟合。

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

Wave Motion 物理-力学

CiteScore

4.10

自引率

8.30%

发文量

118

审稿时长

3 months

期刊介绍： Wave Motion is devoted to the cross fertilization of ideas, and to stimulating interaction between workers in various research areas in which wave propagation phenomena play a dominant role. The description and analysis of wave propagation phenomena provides a unifying thread connecting diverse areas of engineering and the physical sciences such as acoustics, optics, geophysics, seismology, electromagnetic theory, solid and fluid mechanics. The journal publishes papers on analytical, numerical and experimental methods. Papers that address fundamentally new topics in wave phenomena or develop wave propagation methods for solving direct and inverse problems are of interest to the journal.