Access the full text.
Sign up today, get DeepDyve free for 14 days.
Peng Luo, W. Yao, Piao Li (2018)
A notch critical plane approach of multiaxial fatigue life prediction for metallic notched specimensFatigue & Fracture of Engineering Materials & Structures
(1999)
Finite element modelling of fatigue crack growth of surface cracked plates: part I: the numerical technique
C. Sonsino, T. Łagoda, G. Demofonti (2004)
Damage accumulation under variable amplitude loading of welded medium- and high-strength steelsInternational Journal of Fatigue, 26
Ruijie Wang, D. Shang (2009)
Low-cycle fatigue life prediction of spot welds based on hardness distribution and finite element analysisInternational Journal of Fatigue, 31
L. Susmel, D. Taylor (2010)
An Elasto-Plastic Reformulation of the Theory of Critical Distances to Estimate Lifetime of Notched Components Failing in the Low/Medium-Cycle Fatigue RegimeJournal of Engineering Materials and Technology-transactions of The Asme, 132
Wang Qiudong, B. Ji, Chuanxi Li, Fu Zhongqiu (2020)
Fatigue evaluation of rib-deck welds: Crack-propagation-life predictive model and parametric analysisJournal of Constructional Steel Research, 173
Zhao Fang, Ai-qun Li, S. Shen, Wanrun Li (2018)
Low-cycle fatigue test and life assessment of carbon structural steel GB Q235B butt joints and cruciform jointsAdvances in Structural Engineering, 22
S. Koh (2002)
Fatigue damage evaluation of a high pressure tube steel using cyclic strain energy densityInternational Journal of Pressure Vessels and Piping, 79
(2008)
Prediction of Germination and Growth Life of Wind Induced Fatigue Crack of Earplate Connecting Guyed-Mast to Cables
Z. Barsoum, I. Barsoum (2008)
S199 Residual Stress Effects on Fatigue Life of Welded Structures Using LEFMPowder Diffraction, 23
G. Crupi, V. Crupi, E. Guglielmino, D. Taylor (2005)
Fatigue assessment of welded joints using critical distance and other methodsEngineering Failure Analysis, 12
D. Radaj, C. Sonsino, W. Fricke (2009)
Recent developments in local concepts of fatigue assessment of welded jointsInternational Journal of Fatigue, 31
N. Shamsaei, S. Mckelvey (2014)
Multiaxial life predictions in absence of any fatigue propertiesInternational Journal of Fatigue, 67
C. Sonsino, M. Kueppers (2001)
Multiaxial fatigue of welded joints under constant and variable amplitude loadingsFatigue & Fracture of Engineering Materials & Structures, 24
X. Wu, J. Carlsson (1984)
Welding residual stress intensity factors for half-elliptical surface cracks in thin and thick platesEngineering Fracture Mechanics, 19
D. Radaj, C. Sonsino, D. Flade (1998)
Prediction of service fatigue strength of a welded tubular joint on the basis of the notch strain approachInternational Journal of Fatigue, 20
Chun-sheng Wang, Yuzhu Wang, B. Cui, L. Duan, N. Ma, Jin-qiang Feng (2020)
Numerical simulation of distortion-induced fatigue crack growth using extended finite element methodStructure and Infrastructure Engineering, 16
W. Fricke, Luyao Gao, H. Paetzold (2017)
Fatigue assessment of local stresses at fillet welds around plate cornersInternational Journal of Fatigue, 101
(1998)
A crack growth approach to life assessment of spot-welded lap joints. Fatigue& Fracture of Engineering Materials & Structures 21(9):1123–1132
Zhao Fang, Ai-qun Li, You-liang Ding, Wanrun Li (2020)
Wind-induced fatigue assessment of welded connections in steel tall buildings using the theory of critical distancesEuropean Journal of Environmental and Civil Engineering, 24
A. Hobbacher (2016)
Recommendations for fatigue design of welded joints and components
A. Karolczuk (2016)
Analysis of revised fatigue life calculation algorithm under proportional and non-proportional loading with constant amplitudeInternational Journal of Fatigue, 88
Z. Barsoum, I. Barsoum (2008)
Residual stress effects on fatigue life of welded structures using LEFMEngineering Failure Analysis, 16
C. Sonsino, T. Bruder, J. Baumgartner (2010)
S-N Lines for Welded Thin Joints — Suggested Slopes and FAT Values for Applying the Notch Stress Concept with Various Reference RadiiWelding in the World, 54
Xiaoguang Yang, Jingke Wang, Jinlong Liu (2011)
High temperature LCF life prediction of notched DS Ni-based superalloy using critical distance conceptInternational Journal of Fatigue, 33
C. Sonsino, T. Łagoda (2004)
Assessment of multiaxial fatigue behaviour of welded joints under combined bending and torsion by application of a fictitious notch radiusInternational Journal of Fatigue, 26
R. Citarella, M. Perrella (2005)
Multiple surface crack propagation: numerical simulations and experimental testsFatigue & Fracture of Engineering Materials & Structures, 28
Zhao Fang, Ai-qun Li, You-liang Ding (2021)
Fatigue Test Research on Improved T-Stub Specimen of Welded Beam-to-Column ConnectionsJournal of Failure Analysis and Prevention, 21
M. Wahab, M. Alam (2004)
The significance of weld imperfections and surface peening on fatigue crack propagation life of butt-welded jointsJournal of Materials Processing Technology, 153
D. Gao, W. Yao, W. Wen, Jie Huang (2021)
A multiaxial fatigue life prediction method for metallic material under combined random vibration loading and mean stress loading in the frequency domainInternational Journal of Fatigue
W. Gerstle (1986)
Finite and boundary element modelling of crack propagation in two- and three- dimensions using interactive computer graphics
J. Schijve (2001)
Fatigue of structures and materials
Zhao Fang, Ai-qun Li, Wanrun Li, S. Shen (2017)
Wind-Induced Fatigue Analysis of High-Rise Steel Structures Using Equivalent Structural Stress MethodApplied Sciences, 7
Ja Newman, N. Dowling (1998)
A CRACK GROWTH APPROACH TO LIFE PREDICTION OF SPOT‐WELDED LAP JOINTSFatigue & Fracture of Engineering Materials & Structures, 21
W. Gerstle, L. Martha, A. Ingraffea (1987)
Finite and boundary element modeling of crack propagation in two and three dimensionsEngineering with Computers, 2
To investigate the fatigue crack growth of surface cracks in steel welded joints, a three-dimensional surface fatigue crack growth life assessment model considering both the surface crack growth period and the following through crack growth period is proposed. The fatigue crack growth life of a standard steel butt joint specimen is predicted considering the effect of welding residual stress and it is compared with fatigue test results. An example of a welded beam-to-column connection in a steel high-rise building under wind is selected to demonstrate the improvement of the model to make it applicable to stochastic loading and real engineering structures. The life results are compared with those obtained by other fatigue assessment approaches. The mesh sensitivity analysis is made and the effect of extreme welding imperfections and corrosion environment are both discussed. Guidance to select the fatigue life assessment approaches is also proposed. The results show that the growth shape of the edge crack remains a quarter of a circle while that of the center crack remains a quarter of an ellipse during the growth; When the surface crack grows through the plate thickness and becomes a through crack, the remaining fatigue crack growth life is unneglectable for real engineering components especially for the ones with a large plate width; The effect of welding residual stress on the fatigue crack growth life of real engineering component is complex and it depends on the distribution of the residual stress itself; The proposed three-dimensional surface crack engineering model can acquire accurate life results and is applicable to stochastic loading and engineering structures.
Advances in Structural Engineering – SAGE
Published: Jun 1, 2022
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.