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工程设计学报
Chinese Journal of Engineering Design  2010, Vol. 17 Issue (3): 215-218    DOI:
    
Research on an effective algorithm for theoretical stress concentration coefficient
 CHEN  Rong1, HUANG  Ning2
1. Yueyang Vocationaltechnical College, Yueyang 414000, China;
2. School of Mechanical and Electrical Engineering, Central South University, Changsha 410083, China
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Abstract  On the basis of finite element analysis, the maximum principal stress finite element method was presented to solve the theoretical stress concentration factor Kt, the result of which was consistent with the value of theoretical calculations and experimental measurements. Moreover, further analysis on the impact of refining the grid was done. The results showed that when the grid was refined to a certain extent, the accuracy was improved and the stress concentration factor tended to a stable value. The maximum principal stress orientation agreed with stress orientation of the fatigue life estimation, which further ensures the accuracy of the calculation of life. This approach provides an important basis for the parameters for the fatigue analysis.

Key wordsmaximum principal stress      theory stress concentration factor      finite element     
Published: 28 June 2010
CLC:  TH 11  
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Cite this article:

CHEN Rong, HUANG Ning. Research on an effective algorithm for theoretical stress concentration coefficient. Chinese Journal of Engineering Design, 2010, 17(3): 215-218.

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https://www.zjujournals.com/gcsjxb/     OR     https://www.zjujournals.com/gcsjxb/Y2010/V17/I3/215


一种理论应力集中系数的有效算法研究

在有限元分析结果的基础上,提出用最大主应力有限元法求解理论应力集中系数Kt .数值计算结果与理论计算值和实验测得的值相一致,并进一步从网格细化方面的影响作了分析.结果表明网格细化到一定程度时,计算精度提高了,应力集中系数趋于一稳定值,而且与疲劳寿命估算时的应力取向相一致,进一步保证了计算寿命的准确度,为疲劳分析提供了重要的参数依据

关键词: 最大主应力,  理论应力集中系数,  有限元 
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