References
- 1. Balitskii O.I., Kostyuk I.F. (2009), Strength of welded joints of Cr-Mn steels with elevated content of nitrogen in hydrogen-containing media, Materials Science, 45, 97-107.
- 2. Benachour M., Benguediab M., Hadjoui A., Hadjoui F., Benachour N. (2008), Fatigue crack growth of a double fillet weld, Computational Materials Science, 44, 489–495.10.1016/j.commatsci.2008.04.015
- 3. Carpinteri A., Brighenti R., Huth H.J., Vantadori S. (2005) Fatigue growth of a surface crack in a welded T-joint, Int. J. Fatigue, 27, 59–69.
- 4. Duchaczek A., Mańko Z. (2012), Assessment of direct method of calculating stress intensity factor, Journal of Science of the gen. Tadeusz Kosciuszko Military Academy of Land Forces, 3 (165), 336-346 (in Polish).
- 5. Faszynka S., Lewandowski J., Rozumek D. (2016), Numerical analysis of stress and strain in specimens with rectangular cross-section subjected to torsion and bending with torsion, Acta Mechanica et Automatica, 10, 5-11.10.1515/ama-2016-0001
- 6. Ferro P., Berto F., James M.N. (2016), Asymptotic residual stresses in butt-welded joints under fatigue loading, Theoretical and Applied Fracture Mechanics, 83, 114-124.
- 7. Hobbacher A. (2008), Recommendations for fatigue design of welded joints and components, International Institute of Welding, doc. XIII-2151r4-07/XV-1254r4-07,Paris, France.
- 8. Kocańda S., Szala J., (1985), Basics of fatigue calculations, PWN, Warsaw (in Polish).
- 9. Lewandowski J., Rozumek D. (2016), Cracks growth in S355 steel under cyclic bending with fillet welded joint, Theoretical and Applied Fracture Mechanics, 86, 342–350.
- 10. Niklas K. (2014), Calculations of notch stress factor of a thin-walled spreader bracket fillet weld with the use of a local stress approach, Engineering Failure Analysis, 45, 326–338.
- 11. Pakandam F., Varvani-Farahani A. (2010), A comparative study on fatigue damage assessment of welded joints under uniaxial loading based on energy methods, Procedia Engineering, 2, 2027–2035.10.1016/j.proeng.2010.03.218
- 12. Poutiainen I., Marquis G.(2006), A fatigue assessment method based on weld stress, International Journal of Fatigue, 28, 1037–1046.10.1016/j.ijfatigue.2005.11.007
- 13. Rozumek D. (2009), Influence of the slot inclination angle in FeP04 steel on fatigue crack growth under tension, Materials & Design, 30 1859-1865.
- 14. Rozumek D., Macha E. (2009), J-integral in the description of fatigue crack growth rate induced by different ratios of torsion to bending loading in AlCu4Mg1, Mat.-wiss. u. Werkstofftech., 40 (10), 743-749.
- 15. Rozumek D., Marciniak Z. (2012), Fatigue properties of notched specimens made of FeP04 steel, Materials Science, 47, 462-469.
- 16. Rusiński E. (2002), Principles of designing load-bearing structures of automobile vehicles, Wrocław University of Science and Technology, Wrocław (in Polish).
- 17. Shang Y., Shi H., Wang Z., Zhang G. (2015), In-situ SEM study of short fatigue crack propagation behavior in a dissimilar metal welded joint of nuclear power plant, Materials & Design, 88, 598-609.
- 18. Tanaka S., Kawahara T., Okada H. (2014), Study on crack propagation simulation of surface crack in welded joint structure, Marine Structures, 39, 315-334.
- 19. www.cfg.cornell.edu/software/software.htm.
- 20. Zhi-Gang X., Tao C., Xiao-Ling Z. (2012), Fatigue strength evaluation of transverse fillet welded joints subjected to bending loads, Int. J. Fatigue, 38, 57–64.