Journal of Jilin University(Engineering and Technology Edition) ›› 2024, Vol. 54 ›› Issue (12): 3478-3485.doi: 10.13229/j.cnki.jdxbgxb.20230172

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Hot spot stress concentration factor for welded skewed-T joints

Xing WEI1(),Yong-qi ZHANG2,Jun-ming ZHAO1,Hui-jun WANG1,Lin XIAO1()   

  1. 1.School of Civil Engineering,Southwest Jiaotong University,Chengdu 610031,China
    2.China Railway First Survey and Design Institute Group Ltd. ,Xi'an 710043,China
  • Received:2023-02-27 Online:2024-12-01 Published:2025-01-24
  • Contact: Lin XIAO E-mail:we_star@swjtu.edu.cn;xiaolin@swjtu.edu.cn

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Abstract:

Using Abaqus finite element software, 150 finite element models of oblique T-shaped welded joints with different angles, plate thickness ratios, and length-to-thickness ratios were established to analyze and obtain the maximum hot spot stress concentration factors (HSCFs) at critical points. Based on the Levenberg-Marquardt algorithm combined with a general global optimization method, the data were fitted to derive simplified and refined formulas for the maximum HSCF. The results indicate that the HSCF at the toe of the obtuse angle side is always greater than that at the acute angle side, and as the angle difference decreases, the difference in HSCFs between the two sides correspondingly diminishes. The HSCF at the toe of the oblique T-shaped joint shows a positive correlation with the angle, plate thickness ratio, and length-to-thickness ratio, reaching its maximum when the angle is 80°, the plate thickness ratio is 2, and the length-to-thickness ratio is 18. The proposed formulas for calculating the maximum HSCF show good agreement with the finite element numerical results, with the correlation coefficient R2 of the refined formula reaching 99.97%.

Key words: bridge engineering, hot spot stress, fatigue, stress concentration factor, oblique T-shaped welded joints

CLC Number: 

  • U441.4

Fig.1

Skewed-T joint in the Split steel box girder"

Fig.2

CJP skewed-T joint geometry and weld construction"

Table 1

Partial design parameters"

接头编号Ta/mmTb/mmLb/mmφ/(°)R/mmΨ/(°)τθ/(°)γ
ST-0.5-30-108161606011500.53010
ST-0.75-40-1212161926011400.754012
ST-1.0-50-14161622460113015014
ST-1.5-60-1624162566011201.56016
ST-2.0-70-18321628860111027018

Fig.3

Details of the finite element model"

Fig.4

Mises stress distribution subjected to axial tension (unit:MPa)"

Fig.5

SCF value for 30°"

Fig.6

SCF value for 80°"

Fig.7

Variation of SCF value with angle at obtuse angle when γ=10"

Fig.8

Variation of SCF value with angle at obtuse angle when γ=18"

Fig.9

Variation of SCF value with angle at acute angle when γ=10"

Fig.10

Variation of SCF value with angle at acute angle when γ=18"

Fig.11

Error comparison between the real and predicted SCF values at obtuse angle of the simplified formula"

Fig.12

Error comparison between the real and predicted SCF values at acute angle of the simplified formula"

Fig.13

Error comparison between the real and predicted SCF values at obtuse angle of the refined formula"

Fig.14

Error comparison between the real and predicted SCF values at acute angle of the refined formula"

Table 2

Comparison of SCF value of weld toes at obtuse angle"

模型有限元计算简化公式精细化公式
ST-0.6-37-134.023.954.03
ST-0.6-45-155.265.155.28
ST-0.6-53-176.586.496.60
ST-1.2-37-137.216.987.09
ST-1.2-45-159.679.189.61
ST-1.2-53-1712.2611.6512.28
ST-1.8-37-139.709.829.63
ST-1.8-45-1513.4412.9613.34
ST-1.8-53-1717.3016.4717.30

Table 3

Comparison of SCF value of weld toes at acute angle"

模型有限元计算简化公式精细化公式
ST-0.6-37-131.791.531.79
ST-0.6-45-153.152.843.12
ST-0.6-53-174.674.484.64
ST-1.2-37-133.093.273.11
ST-1.2-45-155.735.465.71
ST-1.2-53-178.698.198.69
ST-1.8-37-134.064.784.12
ST-1.8-45-157.907.757.93
ST-1.8-53-1712.2311.4412.29
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