Stress evaluation of metallic material under steady state based on nonlinear critically refracted longitudinal wave

•The nonlinear property of LCR wave is applied to evaluate the stress of metallic components under steady state.•The stress detection model based on combined ultrasonic nonlinear parameter is constructed to predict the stress.•The magnitude and direction of stress can be predicted. This paper presen...

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Bibliographic Details
Published in:Results in physics 2018-06, Vol.9, p.665-672
Main Authors: Mao, Hanling, Zhang, Yuhua, Mao, Hanying, Li, Xinxin, Huang, Zhenfeng
Format: Article
Language:English
Subjects:
Combined ultrasonic nonlinear parameter
Critically refracted longitudinal wave
Nonlinear ultrasonic
Stress evaluation
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Summary:•The nonlinear property of LCR wave is applied to evaluate the stress of metallic components under steady state.•The stress detection model based on combined ultrasonic nonlinear parameter is constructed to predict the stress.•The magnitude and direction of stress can be predicted. This paper presents the study of applying the nonlinear ultrasonic wave to evaluate the stress state of metallic materials under steady state. The pre-stress loading method is applied to guarantee components with steady stress. Three kinds of nonlinear ultrasonic experiments based on critically refracted longitudinal wave are conducted on components which the critically refracted longitudinal wave propagates along x, x1 and x2 direction. Experimental results indicate the second and third order relative nonlinear coefficients monotonically increase with stress, and the normalized relationship is consistent with simplified dislocation models, which indicates the experimental result is logical. The combined ultrasonic nonlinear parameter is proposed, and three stress evaluation models at x direction are established based on three ultrasonic nonlinear parameters, which the estimation error is below 5%. Then two stress detection models at x1 and x2 direction are built based on combined ultrasonic nonlinear parameter, the stress synthesis method is applied to calculate the magnitude and direction of principal stress. The results show the prediction error is within 5% and the angle deviation is within 1.5°. Therefore the nonlinear ultrasonic technique based on LCR wave could be applied to nondestructively evaluate the stress of metallic materials under steady state which the magnitude and direction are included.
ISSN:2211-3797
2211-3797
DOI:10.1016/j.rinp.2018.03.029