Stress Wave Truncation Experimental Research Based on Dynamic Photoelasticity

Jia Quan Wu; Hong Yan Li; Fei Ye; Xing Yu Zhang; Kun Ma

doi:10.4028/www.scientific.net/AMR.1065-1069.2108

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1065-1069Stress Wave Truncation Experimental Research Based...

Stress Wave Truncation Experimental Research Based on Dynamic Photoelasticity

Abstract:

How to truncate stress wave is an important problem that must be considered in design of engineering structure. As an effective detection method of stress distribution, the dynamic photoelasticity has been wide used in stress analysis, such as detection of mechanical structure, civil engineering and water conservancy etc. In this paper, the stress wave isochromatic fringe at different interface structure has been obtained through vertical shooting experiment. The structural stress wave propagation rule of three kinds of case is studied by comparison fringe pattern. The experimental research results show that the stress wave propagation can be effectively guided to a fixed direction through installed connecting parts in structural connection position and the method can avoid integrity damage of structure caused by local large stress changes. Finally, the dynamic photoelasticity is an intuitive and effective way to study stress wave truncation problem.

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Periodical:

Advanced Materials Research (Volumes 1065-1069)

Pages:

2108-2112

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1065-1069.2108

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Online since:

December 2014

Authors:

Jia Quan Wu, Hong Yan Li, Fei Ye, Xing Yu Zhang, Kun Ma*

Keywords:

Dynamic Photoelasticity, Isochromatic Fringe, Stress Wave, Truncation

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References

[1] Lu Yusheng, Zhang Hongmei, Lian Zhiying. Experimental study on interaction of stress wave and interface using dynamic photoelasticity. Explosion and Shock Waves 24 ( 2004): 352-355.

Google Scholar

[2] E.A. Patterson, Digital photoelasticity: principles, practice and potential. Strain, 38 (2002): 27–39.

Google Scholar

[3] Venketesh N. Dubey, Gurtej S. Grewal. Efficacy of photoelasticity in developing whole-field imaging Sensors. Optics and Lasers in Engineering , 48 (2010) 288–294.

DOI: 10.1016/j.optlaseng.2009.11.007

Google Scholar

[4] A. Ke Sike, G. Robertson. Photoelastic stress analysis. Shanghai Science and Technology Press, (1979).

Google Scholar

[5] Jing Guanchang. Computer-aided optical measurement . Tsinghua University Press, (2007).

Google Scholar

[6] L. Roy Xu, Ares J. Rosakis. An experimental study of impact-induced failure events in homogeneous layered materials using dynamic photoelasticity and high-speed photography, 40(2003): 263-288.

DOI: 10.1016/s0143-8166(02)00093-3

Google Scholar

[7] Seyedmeysam Khaleghiana, Anahita Emami, Mehran Tehran, Nasser Soltani . Analysis of effective parameters for stress intensity factors in the contact problem between an asymmetric wedge and a half-plane using an experimental method of photoelasticity. Materials and Design, 43 (2013).

DOI: 10.1016/j.matdes.2012.07.038

Google Scholar

[8] Wu Chunping, Zhong Dongwang. Dynamic Photoelastic Method and Its Application to Blasting Research Jou of Wuhan Un. i of Sc. i & Tech. ( Natural Science Edition) 29( 2006): 55-58.

Google Scholar

[9] Resent Development of Some Issues in Dynamic Photoelastic Method. Journal of Experimental Mechanics 26 No5. (2011): 491-502.

Google Scholar