Fatigue Strength Assessment of Welded Mild Steel Joints Containing Bulk Imperfections

This work investigates the effect of gas pores, as bulk imperfections, on the fatigue strength of welded mild steel joints. Two test series containing different butt joint geometries and weld process parameters are included in order to achieve two variable types of pore sizes. Based on the √area-par...

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Bibliographic Details
Published in:Metals (Basel ) 2018-05, Vol.8 (5), p.306
Main Authors: Leitner, Martin, Murakami, Yukitaka, Farajian, Majid, Remes, Heikki, Stoschka, Michael
Format: Article
Language:English
Subjects:
Butt joints
Butt welding
Defects
fatigue assessment
Fatigue strength
Fatigue tests
gas porosity
Low carbon steels
Mathematical models
Order parameters
Process parameters
Stress concentration
Stress ratio
welded joints
Welding parameters
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Summary:This work investigates the effect of gas pores, as bulk imperfections, on the fatigue strength of welded mild steel joints. Two test series containing different butt joint geometries and weld process parameters are included in order to achieve two variable types of pore sizes. Based on the √area-parameter by Murakami, the test series can be grouped into imperfections exhibiting √area < 1000 µm and √area > 1000 µm. Fatigue tests at a load stress ratio of R = 0.1 are performed, which act as comparison for the subsequent fatigue estimation. To assess the fatigue resistance, the approaches by Murakami, De Kazinczy, and Mitchell are utilized, which highlight certain differences in the applicability depending on the imperfection size. It is found that, on one hand, Murakami’s approach is well suitable for both small and large gas pores depending on the applied model parameters. On the other hand, the fatigue concepts by De Kazinczy and Mitchell are preferably practicable for large defects with √area > 1000 µm. In addition, the method by Mitchell incorporates the stress concentration factor of the imperfection, which can be numerically computed considering the size, shape, and location of the gas pore, as presented in this paper.
ISSN:2075-4701
2075-4701
DOI:10.3390/met8050306