Transformation of body force generated by non-contact sources of ultrasound in an isotropic solid of complex shape into equivalent surface stresses

Non-contact techniques in ultrasonic nondestructive evaluation use external non-mechanical excitation (electromagnetic, heat) which interacts with the mechanical part to be tested. The part itself becomes the source of ultrasounds by transforming the non-mechanical energy into a mechanical one. This...

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Bibliographic Details
Published in:Wave motion 2016-01, Vol.60, p.135-148
Main Authors: Clausse, Bastien, Lhémery, Alain
Format: Article
Language:English
Subjects:
Differential and tensorial analyses
Dynamics
Elastic wave radiation
Equivalence
Equivalent surface stress
Excitation
Mathematical models
Non-contact sources
Physics
Stress concentration
Transformations
Ultrasonic NDE
Ultrasonic testing
Ultrasound
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Summary:Non-contact techniques in ultrasonic nondestructive evaluation use external non-mechanical excitation (electromagnetic, heat) which interacts with the mechanical part to be tested. The part itself becomes the source of ultrasounds by transforming the non-mechanical energy into a mechanical one. This process involves the generation of dynamic body forces or of an eigenstrain that can be modeled as equivalent body forces, these forces being confined in the vicinity of the part surface. Many models developed for predicting ultrasonic field radiation in solids assume source terms given as surface distributions of stress. In order to predict ultrasonic fields radiated by non-contact sources by means of these radiation models, we developed a method to transform dynamic body forces into equivalent surface stress distributions, irrespective of the nature of the excitation. The approximate transformation relies on a second order expansion of Green’s integral formulation of the elastic wave equation. To make this transformation applicable broadly, the geometry of the surface considered herein is of complex shape, implying thorough differential and tensorial analyses to achieve our aim. Some assumptions, notably isotropic elasticity, are made in deriving the transformation method, which are discussed in detail to clearly define its applicability. Numerical examples of radiated fields are given for illustration and validation. •We develop a method to simulate dynamic body forces as equivalent surface stresses.•Body forces are assumed to be confined at depths smaller than elastic wavelengths.•The method handles arbitrary shaped surface through surface differential operators.•Explicit formula of equivalent stress includes first and second order force moments.•Formulas provide inputs to wave radiation models for non-contact ultrasonic sources.
ISSN:0165-2125
1878-433X
DOI:10.1016/j.wavemoti.2015.09.007