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Mechanical Engineering and Design

Mechanical Engineering and Design is an international comprehensive professional academic journal of Ivy Publisher, concerning the development of mechanical engineering theory and technology application, on the combination of mechanical theory and modern industrial technology. The main focus of the journal is the academic papers and comments of latest mechanical engineering design theory research improvement in the fields of nature science, engin... [More] Mechanical Engineering and Design is an international comprehensive professional academic journal of Ivy Publisher, concerning the development of mechanical engineering theory and technology application, on the combination of mechanical theory and modern industrial technology. The main focus of the journal is the academic papers and comments of latest mechanical engineering design theory research improvement in the fields of nature science, engineering technology, economy and science, report of latest research result, aiming at providing a good communication platform to transfer, share and discuss the theoretical and technical development of mechanical engineering technology theory for professionals, scholars and researchers in this field, reflecting the academic front level, promote academic change and foster the rapid expansion of mechanical manufacture, mechanical technology theory and technology research.

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ISSN Print:2327-0543

ISSN Online:2327-0624

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Paper Infomation

The Effect of Creep on Stress and Strain Fields nearby Crack Tip

Full Text(PDF, 645KB)

Author: Fuqiang Yang, He Xue

Abstract: Stress and strain nearby crack tip are key factors in quantitatively predicting the growth rate of stress corrosion cracking (SCC). Metals will creep in high temperature water environments, which will lead to the variation of stress and strain distribution nearby crack tip and affect the SCC growth rate. The effects of creep on the stress and strain fields nearby crack tip are studied with one inch compact tension (1T-CT) specimen by finite element method in this paper. The results indicate that the stress nearby crack tip reduces dramatically because of the action of creep, but the variation of strain and plastic zone nearby the crack tip are insignificant.

Keywords: Creep; Crack Tip; Stress; Strain; Finite Element Method

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