Qualitative analysis of a 3D multiphysics model for nonlinear ultrasonics and vibration induced heating at closed defects

IF 1 4区材料科学 Q3 MATERIALS SCIENCE, CHARACTERIZATION & TESTING

Research in Nondestructive Evaluation Pub Date : 2022-01-02 DOI:10.1080/09349847.2022.2049408

K. Truyaert, V. Aleshin, K. Van Den Abeele

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引用次数: 1

Abstract

ABSTRACT Upon exciting a material using elastic waves, the locally induced deformation at the interfaces of internally closed defects may cause nonlinear wave mechanics and dynamics in the form of clapping and friction. As a result, both phenomena instigate spectral broadening of the excitation spectrum as well as the production of heat, directly originating from the defect. To better understand and account for the physics behind the dissipation of energy by internally closed defects as a result of the wave–interface interaction, dedicated models can be developed. In this work, we propose a 3D finite element multiphysics model that is capable of simultaneously describing the generation of nonlinearities and heating at a defect’s interface experiencing clapping and friction induced by elastic wave propagation. The model consists of three different modules. The first module describes the elastic wave propagation in a virgin/bulk material, whereas the second module captures the contact physics at the defect level. The third module is implemented to calculate the diffusion of thermal energy in the specimen. The contact physics module accounts for anharmonic and hysteretic effects, describing the nonlinear behavior of the defect’s interfaces, which is echoed in both the ultrasound spectrum and in the vibration-induced heating. A qualitative analysis of the computational model, integrating the three modules, is performed to validate the approach. Examples show that nonlinear spectral components are indeed observed as a result of the friction and the clapping experienced by the faces of the defect. At the same time, a localized temperature increase due to the induced friction is noted, and its response at the outer surface of the sample is examined. The qualitative validation approves that the model is ready to be tested further quantitively, and to compare its predictions to experiments.

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闭合缺陷处非线性超声和振动致热的三维多物理场模型定性分析

当用弹性波激励材料时，内部封闭缺陷界面处的局部诱导变形会以拍击和摩擦的形式引起非线性波动力学和动力学。结果，这两种现象都引起激发谱的谱宽以及直接由缺陷引起的热的产生。为了更好地理解和解释由于波界面相互作用导致的内部闭合缺陷的能量耗散背后的物理，可以开发专用模型。在这项工作中，我们提出了一个三维有限元多物理场模型，该模型能够同时描述在经历弹性波传播引起的拍击和摩擦的缺陷界面上产生的非线性和加热。该模型由三个不同的模块组成。第一个模块描述了弹性波在原始/块状材料中的传播，而第二个模块捕获了缺陷级别的接触物理。第三个模块用于计算热能在试样中的扩散。接触物理模块考虑了非调和和滞后效应，描述了缺陷界面的非线性行为，这在超声光谱和振动诱导加热中都得到了回应。结合三个模块，对计算模型进行了定性分析，以验证该方法。实例表明，由于缺陷表面的摩擦和拍击，确实观察到非线性谱分量。同时，注意到由于摩擦引起的局部温度升高，并对其在样品外表面的响应进行了检测。定性验证表明，该模型可以进行进一步的定量测试，并将其预测与实验进行比较。

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

Research in Nondestructive Evaluation 工程技术-材料科学：表征与测试

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Research in Nondestructive Evaluation® is the archival research journal of the American Society for Nondestructive Testing, Inc. RNDE® contains the results of original research in all areas of nondestructive evaluation (NDE). The journal covers experimental and theoretical investigations dealing with the scientific and engineering bases of NDE, its measurement and methodology, and a wide range of applications to materials and structures that relate to the entire life cycle, from manufacture to use and retirement. Illustrative topics include advances in the underlying science of acoustic, thermal, electrical, magnetic, optical and ionizing radiation techniques and their applications to NDE problems. These problems include the nondestructive characterization of a wide variety of material properties and their degradation in service, nonintrusive sensors for monitoring manufacturing and materials processes, new techniques and combinations of techniques for detecting and characterizing hidden discontinuities and distributed damage in materials, standardization concepts and quantitative approaches for advanced NDE techniques, and long-term continuous monitoring of structures and assemblies. Of particular interest is research which elucidates how to evaluate the effects of imperfect material condition, as quantified by nondestructive measurement, on the functional performance.