References
- V. S. Sarma and K. A. Padmanabhan: ‘Low cycle fatigue behaviour of a medium carbon microalloyed steel’, Int. J. Fatigue, 1997, 29, 135–140.
- T. Wang, D. Wang, L. Huo and Y. Zhang: ‘Discussion on fatigue design of welded joints enhanced by ultrasonic peening treatment (UPT)’, Int. J. Fatigue, 2009, 31, 644–650.
- Y. R. Luo, C. X. Huang, R. H. Tian and Q. Y. Wang: ‘Effects of strain rate on low cycle fatigue behavior of high-strength structural steel’, J. Iron Steel Res. Int., 2013, 20, 50–56.
- X. Yang: ‘Low cycle fatigue and cyclic stress ratcheting failure behavior of carbon steel 45 under uniaxial cyclic loading’, Int. J. Fatigue, 2005, 27, 1124–1132.
- D. Rozumek and Z. Marciniak: ‘Fatigue properties of notched specimens made of FeP04 steel’, Mat. Sci., 2012, 47, 462–469.
- K. H. Nip, L. Gardner, C. M. Davies and A. Y. Elghazouli: ‘Extremely low cycle fatigue tests on structural carbon steel and stainless steel’, J. Constr. Steel Res., 2010, 66, 96–110.
- K. Kanazawa, K. J. Miller and M. Brown: ‘Low cycle fatigue under out-of-phase loading conditions’, J. Eng. Mater. Technol., 1977, 99, 222–228.
- S. K. Chandra, V. Shankar, K. Mariappan, R. Sandhya and P. C. Chakraborty: ‘Effect of strain rate on the low cycle fatigue behavior of 316L(N) stainless steel weld joints’, Procedia Eng., 2013, 55, 176–780.
- M. D. Callaghan, S. R. Humphries, M. Law, M. Ho, P. Bendeich, H. Li and W. Y. Yeung: ‘Energy-based approach for the evaluation of low cycle fatigue behaviour of 2·25Cr–lMo steel at elevated temperature’, Mat. Sci. Eng., 2010, 527, 5619–5623.
- F. Ellyin and Y. Asada: ‘Time-dependent fatigue failure: the creep fatigue interaction’, Int. J. Fatigue, 1991, 13, 157–164.
- W. Fricke: ‘Fatigue analysis of welded joints: state of development’, Mar. Struct., 2003, 16, 185–200.
- E. S. Puchi-Cabrera, R. A. Saya-Gamboa, J. G. La Barbera-Sosa, M. H. Staia, J. A. Berrios-Ortiz and G. Mesmacque: ‘Fatigue life of AISI 316L stainless steel welded joints, obtained by GMAW’, Weld. Int., 2009, 23, 778–788.
- T. L. Teng and P. H. Chang: ‘Effect of residual stresses on fatigue crack initiation life for butt-welded joints’, J. Mater. Process. Tech., 2004, 145, 325–335.
- Standardization Administration of the People's Republic of China: ‘The test method for axial loading constant-amplitude low-cycle fatigue of metallic materials’, GB/T 15248–1994, Beijing, China Standards Institution, 1994.
- A. Navarro: ‘An unconditionally convergent iterative algorithm for the intersection of Neuber's and Molski–Glinka's rules with the Ramberg–Osgood stress–strain relationship’, Theor. Appl. Fract. Mec., 2014, 69, 53–62.
- V. T. Troshchenko and L. A. Khamaza: ‘Investigation of deformation diagrams of metals under static and cyclic loads in relation to their fatigue failure’, Strength Mater., 1976, 8, 1052–1056.
- L. F. Coffin: ‘A study of the effects of cyclic thermal stresses on a ductile metal’, Trans. ASME, 1954, 76, 931–950.
- S. S. Manson: ‘Behaviour of materials under conditions of thermal stress’, Report 1170, National Advisory Commission on Aeronautics, Lewis Flight Propulsion Laboratory, Cleveland, 1954.
- M. M. Alam, Z. Barsoum, P. Jonsén, A. F. H. Kaplan and H. Å. Häggblad: ‘Influence of defects on fatigue crack propagation in laser hybrid welded eccentric fillet joint’, Eng. Fract. Mech., 2011, 78, 2246–2258.
- K. A. Soadya, B. G. Mellor, J. Shackleton, A. Morris and P. A. S. Reed: ‘The effect of shot peening on notched low cycle fatigue’, Mat. Sci. Eng. A, 2011, 528, 8579–8588.
- L. Chen, L. Cai: ‘The low cycle fatigue crack growth prediction model based on material's low cyclic fatigue properties’, Eng. Mech., 2012, 29, 34–39.
- J. Morrow: ‘Cyclic plastic strain energy and fatigue of metals. Internal fraction, damping and cyclic plasticity’, ASTM STP 378, 1965, 48–84.