Effect of increased yield strength, R-ratio, and plate thickness on the fatigue resistance of high-frequency mechanical impact (HFMI)–treated steel joints

Leitner, Martin; Barsoum, Zuheir

doi:10.1007/s40194-020-00914-2

Cited by 18 publications

(9 citation statements)

References 25 publications

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“…Fatigue strength improvement by HFMI treatment is known to depend on the stress ratio of fatigue loading, meaning that the fatigue strength benefits from HFMI treatment decrease as the stress ratio increases [3][4][5][6][7][8][9][10][11]. The IIW recommendations for HFMI treatment take this effect into account as an additional reduction in the number of FAT classes [2].…”

Section: Introductionmentioning

confidence: 99%

Effect of static load during HFMI treatment on fatigue strength and residual stress field of longitudinal atachment welded joints

et al. 2021

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In this study, the effect of the stress state of a welded joint during application of high-frequency mechanical impact (HFMI) treatment on the resulting fatigue strength was investigated through fatigue tests and finite element analysis. A high-frequency impact treatment tool was used as the HFMI device. Longitudinal attachment welded joints were treated under a state in which a static load was applied and subsequently tested under a constant stress amplitude with stress ratios of 0 or 0.5. In addition, residual stress measurements and finite element analysis simulating welding and treatment processes were performed. The results indicate that the HFMI treatment is beneficial even when applied under a static tensile load, as the resulting compressive residual stresses are similar regardless of the stress state in the joint during treatment, meaning that the HFMI is applicable to existing structures.

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Section: Introductionmentioning

confidence: 99%

Effect of static load during HFMI treatment on fatigue strength and residual stress field of longitudinal atachment welded joints

et al. 2021

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“…For welded joints, fatigue strength improvement can be achieved by using postweld treatment in which the aim is to modify the weld toe regions to avoid fatigue crack development. Among others, high-frequency mechanical impact (HFMI) treatment has received much attention in the last two decades [1][2][3][4][5][6][7][8][9][10][11]. The application of the HFMI treatment introduces compressive residual stress in the weld toe and material hardening in the surface layer, simultaneously improves the local weld geometry, and removes typical weld imperfections.…”

Section: Introductionmentioning

confidence: 99%

“…The application of the HFMI treatment introduces compressive residual stress in the weld toe and material hardening in the surface layer, simultaneously improves the local weld geometry, and removes typical weld imperfections. The degree of the fatigue strength improvement of HFMI has been related with the material yield strength (f y ), namely, it increases together with the steel grade [9][10][11]. Therefore, the use of HFMI treatment for high-strength steel welded joints may lead to a superior fatigue performance [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

“…The degree of the fatigue strength improvement of HFMI has been related with the material yield strength (f y ), namely, it increases together with the steel grade [9][10][11]. Therefore, the use of HFMI treatment for high-strength steel welded joints may lead to a superior fatigue performance [9][10][11]. The primary reason for this is the extended fatigue crack initiation and propagation periods within short crack lengths [12].…”

Section: Introductionmentioning

confidence: 99%

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Damage-Based Assessment of the Fatigue Crack Initiation Site in High-Strength Steel Welded Joints Treated by HFMI

Ono

Yıldırım

Kinoshita

et al. 2022

Metals

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This study aimed to identify the fatigue crack initiation site of high-frequency mechanical impact (HFMI)-treated high-strength steel welded joints subjected to high peak stresses; the impact of HFMI treatment residual stress relaxation being of particular interest. First, the compressive residual stresses induced by HFMI treatment and their changes due to applied high peak stresses were quantified using advanced measurement techniques. Then, several features of crack initiation sites according to levels of applied peak stresses were identified through fracture surface observation of failed specimens. The relaxation behavior was simulated with finite element (FE) analyses incorporating the experimentally characterized residual stress field, load cycles including high peak load, improved weld geometry and non-linear material behavior. With local strain and local mean stress after relaxation, fatigue damage assessments along the surface of the HFMI groove were performed using the Smith–Watson–Topper (SWT) parameter to identify the critical location and compared with actual crack initiation sites. The obtained results demonstrate the shift of the crack initiation most prone position along the surface of the HFMI groove, resulting from a combination of stress concentration and residual stress relaxation effect.

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“…Concerning the latter one, methods mostly influencing the residual stress condition [6] are considered, like shot peening [7], hammer/needle peening [8], HFMI treatment [9] as well as further non-mechanical techniques, such as post-weld heat treatment [10]. Especially in case of the methods based on an improvement of the local residual stress condition, special attention must be laid on increased stress ratios [11][12][13] or variable amplitude loads [14][15][16] mostly due to a possible relaxation of the compressive residual stress condition [17,18].…”

Section: Introductionmentioning

confidence: 99%

Fatigue strength assessment of TIG-dressed high-strength steel cruciform joints by nominal and local approaches

et al. 2022

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According to the IIW recommendation, the fatigue strength of welded steel joints is defined as independent of the base material in case of the as-welded condition. However, post-treatment techniques can improve the fatigue performance of welded structures, especially for increased base material strengths. Therefore, this paper investigates the effect of TIG dressing, as common post-weld treatment method, on the fatigue strength of high-strength steel S700 cruciform joints. The statistically evaluated fatigue test results reveal a significant increase of the nominal fatigue strength from FAT 90 for the as-welded up to 182 MPa for the TIG-dressed state. The experiments are further compared to recommended and suggested design curves applying both nominal as well as local stress approaches. Focusing on the TIG-dressed state, the suggested increase in nominal stresses is well validated leading to a conservative assessment. In addition, the proposed slope in the finite life region with a value of m1 = 4 shows a sound fit to the statistically evaluated value of m1 = 4.7 for the test results. The local fatigue strength estimation is performed based on a recent proposal using the theory of critical distances. Therefore, linear elastic numerical analysis of the investigated specimens is performed. Again, the resulting S-N curves agree well to the experiments validating the proposed local design approach.

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Effect of increased yield strength, R-ratio, and plate thickness on the fatigue resistance of high-frequency mechanical impact (HFMI)–treated steel joints

Cited by 18 publications

References 25 publications

Effect of static load during HFMI treatment on fatigue strength and residual stress field of longitudinal atachment welded joints

Effect of static load during HFMI treatment on fatigue strength and residual stress field of longitudinal atachment welded joints

Damage-Based Assessment of the Fatigue Crack Initiation Site in High-Strength Steel Welded Joints Treated by HFMI

Fatigue strength assessment of TIG-dressed high-strength steel cruciform joints by nominal and local approaches

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