Title

The Attempt of the Low-Cycle Fatigue Life Description of Chosen Creep-Resistant Steels Under Mechanical and Thermal Interactions

Journal title

Archives of Metallurgy and Materials

Yearbook

2017

Volume

vol. 62

Issue

No 4

Authors

Okrajni, J. ; Marek, A.

Divisions of PAS

Nauki Techniczne

Publisher

Institute of Metallurgy and Materials Science of Polish Academy of Sciences ; Committee of Materials Engineering and Metallurgy of Polish Academy of Sciences

Date

2017

Identifier

DOI: 10.1515/amm-2017-0345 ; e-ISSN 2300-1909

Source

Archives of Metallurgy and Materials; 2017; vol. 62; No 4

References

Webster (2000), Structural Integrity Assessment Procedure for Europe of the SINTAP programme overview, Engineering Fracture Mechanics Science, 67. ; Manson (1966), Thermal Low Cycle New York, Stress Fatigue, 12. ; Schijve (2000), of Structures and Materials in the th Century and the State of the Art of ECF Conference Fracture Mechanics Beyond, Fatigue Proceedings, 17, 211. ; Mitchell (1991), eds in predictive techniques, Advances fatigue lifetime, 14, 122. ; RWTÜV (1983), Replicas for parts under creep according to Recommendation, null, 508. ; Miller (1988), and Background to and validation of report version Pip, null, 6, 105. ; Kocańda (1997), The basics of fatigue calculations Podstawy obliczeń zmęczeniowych in Polish, null, 13. ; Fookes (2000), Using a Strain Based Failure Assessment Diagram for Creep - Brittle Materials th International HIDA Conference Stuttgart, null. ; Huang (2006), Thermomechanical fatigue behavior and life prediction of a cast nickel - based superalloy and, Materials Science Engineering, 15, 432. ; Marek (null), Research on dependence between the fatigue life of steels under conditions of interactions of thermo - mechanical and isothermal low - cycle fatigue, Solid State Phenomena, 24, 224. ; Sehitoglu (2008), Thermal mechanical of Structural Alloys In Fracture Handbook, Fatigue Fatigue, 21, 527. ; Hähner (2008), Research and development into a European code - of - practice for strain - controlled thermo - mechanical fatigue test of, International Journal Fatigue, 20, 372. ; Okrajni (1995), Simulation of the fracture process of materials subjected to low - cycle fatigue of mechanical and thermal character of Material Processing Technology, Journal, 22, 53. ; FITNET (2001), Report European Fitness for service Network Edited by Contract No, null, 1. ; (1997), Nuclear Electric Ltd Assessment Procedure for the High Temperature Response of Structure Issue, Proc, 5. ; Manson (2006), durability of structural materials, Fatigue International, 11. ; Bressers (1996), eds under Thermal and Mechanical loading Academic Publishers, Fatigue, 19. ; (2002), null, 18, 12952. ; Webster (1994), High Temperature Component Life, Assessment, 1. ; Hernas (1999), Żarowytrzymałość stali i stopów in Polish, null. ; Okrajni (2008), Modelling of the deformation process under thermo - mechanical fatigue conditions of, International Journal Fatigue, 23, 324. ; (1976), Ostergren Damage function and associated failure equations for predicting hold time and frequency effects in elevated temperature low cycle fatigue Test, Eval, 16, 327. ; Junak (2011), Low - cycle fatigue of steels used in the power engineering industry, Arch Mater Sci Eng, 25, 19.