Lightweight Design with Welded High-Frequency Mechanical Impact (HFMI) Treated High-Strength Steel Joints from S700 under Constant and Variable Amplitude Loadings

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@article{972ec5c3e65f4ca5bdf952e5de59400f,
title = "Lightweight Design with Welded High-Frequency Mechanical Impact (HFMI) Treated High-Strength Steel Joints from S700 under Constant and Variable Amplitude Loadings",
abstract = "In cases where lightweight designs are particularly in focus, effective fatigue strength improvement techniques like high-frequency mechanical impact (HFMI) treatment can be successfully implemented. Proper HFMI treatment helps overcome the strength limits resulting from local deterioration of themicrostructure and local stress concentrators, as well as tensile residual stresses which occur due to the welding process. Investigations carried out under fully-reversed, constant amplitude loading with longitudinal stiffeners of the steel grade S700 show impressive fatigue strength improvement far superiorto those observed using other mechanical treatments such as hammering or shot peening. Considerable potential for lightweight design is observed when implementing HFMI; especially in cases which can be characterised by constant amplitude loading. Under fully-reversed, variable amplitude loading with astraight-line spectrum, the fatigue strength could be improved by HFMI. However, the degree of improvement was lower when compared to constant amplitude loading due to local plasticity which occurs during larger load levels and consequently reduces the beneficial compressive residual stresses. Apart from the HFMI-treatment, the exceedance of constant amplitude loading (Woehler-lines) by variable amplitude loading (Gassner-lines) offers further lightweight potential, despite the lower degree of improvement by HFMI under spectrum loading. During design, other failure modes and restrictions must berespected if lightweight designs by HFMI-treatment are to be realised. Professional execution of the treatment and good quality control, as well as accessibility of all fatigue-critical areas to the treatment is needed. Regarding cumulative damage calculations IIW recommendations can be applied atisfyingly.The current state of knowledge suggests that more data is required about the influence of weld geometry, spectrum shape, loading mode and residual stress state are needed before general rules for HFMI treated welded joints subject to variable amplitude loading can be made. This is due to the fact that the interaction of these parameters determines the degree of improvement with respect to the aswelded state.",
keywords = "Longitudinal stiffeners, High-strength steel",
author = "Halid Yildirim and Gary Marquis and C.M. Sonsino",
year = "2016",
month = "10",
doi = "10.1016/j.ijfatigue.2015.11.009",
language = "English",
volume = "91",
pages = "466--474",
journal = "INTERNATIONAL JOURNAL OF FATIGUE",
issn = "0142-1123",

}

RIS - Lataa

TY - JOUR

T1 - Lightweight Design with Welded High-Frequency Mechanical Impact (HFMI) Treated High-Strength Steel Joints from S700 under Constant and Variable Amplitude Loadings

AU - Yildirim, Halid

AU - Marquis, Gary

AU - Sonsino, C.M.

PY - 2016/10

Y1 - 2016/10

N2 - In cases where lightweight designs are particularly in focus, effective fatigue strength improvement techniques like high-frequency mechanical impact (HFMI) treatment can be successfully implemented. Proper HFMI treatment helps overcome the strength limits resulting from local deterioration of themicrostructure and local stress concentrators, as well as tensile residual stresses which occur due to the welding process. Investigations carried out under fully-reversed, constant amplitude loading with longitudinal stiffeners of the steel grade S700 show impressive fatigue strength improvement far superiorto those observed using other mechanical treatments such as hammering or shot peening. Considerable potential for lightweight design is observed when implementing HFMI; especially in cases which can be characterised by constant amplitude loading. Under fully-reversed, variable amplitude loading with astraight-line spectrum, the fatigue strength could be improved by HFMI. However, the degree of improvement was lower when compared to constant amplitude loading due to local plasticity which occurs during larger load levels and consequently reduces the beneficial compressive residual stresses. Apart from the HFMI-treatment, the exceedance of constant amplitude loading (Woehler-lines) by variable amplitude loading (Gassner-lines) offers further lightweight potential, despite the lower degree of improvement by HFMI under spectrum loading. During design, other failure modes and restrictions must berespected if lightweight designs by HFMI-treatment are to be realised. Professional execution of the treatment and good quality control, as well as accessibility of all fatigue-critical areas to the treatment is needed. Regarding cumulative damage calculations IIW recommendations can be applied atisfyingly.The current state of knowledge suggests that more data is required about the influence of weld geometry, spectrum shape, loading mode and residual stress state are needed before general rules for HFMI treated welded joints subject to variable amplitude loading can be made. This is due to the fact that the interaction of these parameters determines the degree of improvement with respect to the aswelded state.

AB - In cases where lightweight designs are particularly in focus, effective fatigue strength improvement techniques like high-frequency mechanical impact (HFMI) treatment can be successfully implemented. Proper HFMI treatment helps overcome the strength limits resulting from local deterioration of themicrostructure and local stress concentrators, as well as tensile residual stresses which occur due to the welding process. Investigations carried out under fully-reversed, constant amplitude loading with longitudinal stiffeners of the steel grade S700 show impressive fatigue strength improvement far superiorto those observed using other mechanical treatments such as hammering or shot peening. Considerable potential for lightweight design is observed when implementing HFMI; especially in cases which can be characterised by constant amplitude loading. Under fully-reversed, variable amplitude loading with astraight-line spectrum, the fatigue strength could be improved by HFMI. However, the degree of improvement was lower when compared to constant amplitude loading due to local plasticity which occurs during larger load levels and consequently reduces the beneficial compressive residual stresses. Apart from the HFMI-treatment, the exceedance of constant amplitude loading (Woehler-lines) by variable amplitude loading (Gassner-lines) offers further lightweight potential, despite the lower degree of improvement by HFMI under spectrum loading. During design, other failure modes and restrictions must berespected if lightweight designs by HFMI-treatment are to be realised. Professional execution of the treatment and good quality control, as well as accessibility of all fatigue-critical areas to the treatment is needed. Regarding cumulative damage calculations IIW recommendations can be applied atisfyingly.The current state of knowledge suggests that more data is required about the influence of weld geometry, spectrum shape, loading mode and residual stress state are needed before general rules for HFMI treated welded joints subject to variable amplitude loading can be made. This is due to the fact that the interaction of these parameters determines the degree of improvement with respect to the aswelded state.

KW - Longitudinal stiffeners

KW - High-strength steel

U2 - 10.1016/j.ijfatigue.2015.11.009

DO - 10.1016/j.ijfatigue.2015.11.009

M3 - Article

VL - 91

SP - 466

EP - 474

JO - INTERNATIONAL JOURNAL OF FATIGUE

JF - INTERNATIONAL JOURNAL OF FATIGUE

SN - 0142-1123

ER -

ID: 9476362