Creep Damage and Creep-Fatigue Damage

Chapter
Part of the Solid Mechanics and Its Applications book series (SMIA, volume 185)

Abstract

A time-dependent deformation occurring in a material subject to load for a prolonged period of time is called creep. In a narrower sense, creep means a time-dependent deformation caused by a constant stress or a constant load. Materials undergoing creep for long time are often accompanied by time dependent internal deterioration. This deterioration is called creep damage. When metals and alloys are subject to a variable load at elevated temperature, the materials are deteriorated by combined damage of creep and fatigue. This damage is called creep-fatigue damage. Creep damage and creep-fatigue damage, therefore, give essential failure modes of high temperature components.

Keywords

Creep Rate Creep Strain Fatigue Damage Damage Variable Creep Damage 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

References

  1. Benallal A, Siad L (1997) Stress and strain fields in cracked damaged solids. Technische Mechanik17:295–304Google Scholar
  2. Benallal A, Siad L (2001) Strain, stress and damage fields in damaged and cracked solids. In: Murakami S, Ohno N (eds) IUTAM symposium on creep in structures. Kluwer, Dordrecht, pp 151–163Google Scholar
  3. Boyle JT, Spence J (1983) Stress analysis for creep. Butterworths, LondonGoogle Scholar
  4. Cadek J (1988) Creep in metallic materials. Elsevier, AmsterdamGoogle Scholar
  5. Cailletaud G, Levaillant C (1984) Creep-fatigue life prediction: What about initiation? Nucl Eng Des 83:279–292CrossRefGoogle Scholar
  6. Chaboche JL (1982) The concept of effective stress applied to elasticity and to viscoplasticity in the presence of anisotropic damage. In: Boehler JP (ed) Mechanical behavior of anisotropic solids (Proceedings of Euromech Colloquium 115, Grenoble 1979). Martinus Nijhoff, The Hague, pp 737–760Google Scholar
  7. Chaboche JL (1984) Anisotropic creep damage in the framework of continuum damage mechanics. Nucl Eng Technol 79:309–319Google Scholar
  8. Chaboche JL, Rousselier G (1983) On the plastic and viscoplastic constitutive equations, part I: rules developed with internal variable concept; part II: application of internal variable concepts to the 316 stainless steel. J Press Vessel Technol Trans ASME 105:153–164CrossRefGoogle Scholar
  9. Cocks ACF, Leckie FA (1987) Creep constitutive equations for damaged materials. In: Wu TY, Hutchinson JW (eds) Advances in applied mechanics, vol 25. Academic, New York, pp 239–294Google Scholar
  10. Dunne FPE, Hayhurst DR (1992a) Continuum damage based constitutive equations for copper under high temperature creep and cyclic plasticity. Proc R Soc London A 437:545–566CrossRefGoogle Scholar
  11. Dyson BF, Hayhurst DR, Lin J (1996) The ridged uniaxial testpiece: creep and fracture predictions using large-displacement finite-element analyses. Proc R Soc London A 452:655–676CrossRefGoogle Scholar
  12. Evans HE (1984) Mechanisms of creep fracture. Elsevier, LondonGoogle Scholar
  13. Goodall IW, Hales R, Walters DJ (1981) On constitutive relations and failure criteria of an austenitic steel under cyclic loading at elevated temperature, In: Ponter ARS, Hayhurst DR (eds) Creep in structures. Springer, Berlin, pp 103–127CrossRefGoogle Scholar
  14. Hayhurst DR (1972) Creep rupture under multi-axial states of stress. J Mech Phys Solids 20:381–390CrossRefGoogle Scholar
  15. Hayhurst DR (2001) Computational continuum damage mechanics: its use in the prediction of creep in structures- past, present and future. In: Murakami S, Ohno N (eds) IUTAM symposium on creep in structures. Kluwer, Dordrecht, pp 175–188Google Scholar
  16. Hayhurst DR, Brown PR, Morrison CJ (1984) The role of continuum damage in creep crack growth. Philos Trans R Soc London A 311:131–158CrossRefGoogle Scholar
  17. Kowalewski ZL, Hayhurst DR, Dyson BF (1994) Mechanisms-based creep constitutive equations for an aluminum alloy. J Strain Anal 29:309–316CrossRefGoogle Scholar
  18. Kraus H (1980) Creep analysis. Wiley, New YorkGoogle Scholar
  19. Lemaitre J (1992) A course on damage mechanics. Springer, Berlin; 2nd Edition (1996)MATHGoogle Scholar
  20. Murakami S, Hirano T (2000) Effects of damage on the asymptotic fields of a mode III creep crack in steady-state growth. In: Benallal A (ed) Continuous damage and fracture. Elesevier, Paris, pp 65–70Google Scholar
  21. Murakami S, Imaizumi T (1982) Mechanical description of creep damage state and its experimental verification. Journal de Mécanique Théorique et Appliquée 1:743–761MATHGoogle Scholar
  22. Murakami S, Ohno N (1981) A continuum theory of creep and creep damage. In: Ponter ARS, Hayhurst DR (eds) Creep in structures, proceedings of 3rd IUTAM symposium, Leicester, 1980. Springer, Berlin, pp 422–444Google Scholar
  23. Murakami S, Hirano T, Liu Y (2001) Effects of damage on the asymptotic fields of a mode I creep crack in steady-stress growth. In: Murakami S, Ohno N (eds) IUTAM symposium on creep in structures. Kluwer, Dordrecht, pp 165–174Google Scholar
  24. Othman AM, Hayhurst DR, Dyson BF (1993) Skeletal point stresses in circumferentially notched tension bars undergoing tertiary creep modelled with physically based constitutive equations. Proc R Soc London A 441:343–358CrossRefGoogle Scholar
  25. Perrin IJ, Hayhurst DR (1999) Continuum damage mechanics analyses of type IV creep failure in ferritic steel crossweld specimens. Int J Press Vessels Piping 76:599–617CrossRefGoogle Scholar
  26. Saanouni K, Forster C, Ben Hatira F (1994) On the anelastic flow with damage. Int J Damage Mech 3:140–169CrossRefGoogle Scholar
  27. Sermage JP, Lemaitre J, Desmorat R (2000) Multiaxial creep-fatigue under anisothermal conditions. Fatigue Fract Eng Mater Struct 23:241–252CrossRefGoogle Scholar
  28. Viswanathan R (1989) Damage mechanisms and life assessment of high-temperature components. ASM International, Metals Park, OHGoogle Scholar
  29. Kachanov LM (1958) On rupture time under condition of creep, Izvestia Akademi Nauk SSSR, Otd. Tekhn. Nauk, No.8, 1958, 26–31 (in Russian)Google Scholar
  30. Odqvist FKG und Hult J (1962) Kriechfestigkeit Metallis c her Werkstoffe. Springer, BerlinGoogle Scholar
  31. Rabotnov Yu N (1969) Creep problems in structural members. North-Holland, AmsterdamGoogle Scholar
  32. Needham NG, Wheatley JE, Greenwood GW (1975) The creep fracture of copper and magnesium. Acta Metall 23:23–27CrossRefGoogle Scholar
  33. Matera R, Rustichelli F (1979) The evaluation of creep damage. In: Bernasconi G, Piatti G (eds) Creep of engineering materials and structures. Applied Science Publishers, London, pp 389–412Google Scholar
  34. Chaboche JL (1988) Continuum damage mechanics, part I general concepts; part II damage growth, crack initiation, and crack growth. J Appl Mech Trans ASME 55:59–72CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media B.V. 2012

Authors and Affiliations

  1. 1.Nagoya UniversityNagoyaJapan

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