5.03 - Thermal-Mechanical Fatigue (Including Thermal Shock)

Comprehensive Structural Integrity

Volumn 5, Issue , 2007, Pages 113-199

  Remy L ^a  

^a PSL RESEARCH UNIVERSITY   (France)

Author keywords

[No Author keywords available]

Indexed keywords

THERMAL MECHANICAL FATIGUE;

THERMAL FATIGUE;

EID: 84903409315     PISSN: None     EISSN: None     Source Type: Book    
DOI: 10.1016/B0-08-043749-4/05021-7     Document Type: Chapter

References (304)

1. Achter M.R., Danek G.J., Smith H.H. Effect on fatigue of gaseous environments under varying temperature and pressure. Trans. Met. Soc. AIME 1963, 227:1296-1301.
2. Ainsworth R.A., Budden P.J. Assessment of defects at high temperatures: the r5 procedures. Behaviour of Defects at High Temperatures, ESIS 15 1993, 453-465. Mechanical Engineering Publications, London. R.A. Ainsworth, R.P. Skelton (Eds.).
3. Andrieu E., Molins R., Ghonem H., Pineau A. Intergranular crack tip oxidation mechanism in a nickel-based superalloy. Mater. Sci. Eng. A 1992, 154:21-28.
4. Angarita L., Pitz G., Lang K.-H., Löhe D. Realization of complex thermal-mechanical fatigue by a two-specimen testing system. Thermo-mechanical Fatigue Behaviour of Materials: 3rd Volume, ASTM STP 1371 2000, 304-318. American Society for Testing and Materials, West Conshohocken, PA. H. Sehitoglu, H.J. Maier (Eds.).
5. Antolovich S.D., Liu S., Baur R. Low cycle fatigue behavior of René 80 at elevated temperature. Metall. Trans. A 1981, 12:473-481.
6. Ariana M., Martinez-Esnaola J.M., Bressers J. Crack propagation and life prediction in a nickel-based superalloy under TMF conditions. Fatigue under Thermal and Mechanical Loading 1996, 393-402. Kluwer, Amsterdam. J. Bressers, L. Rémy, M. Steen, J.L. Vallès (Eds.).
7. Arrel D.J., Ostolaza K.M., Vallès J.L., Bressers J. Solidification structures and post-fatigue precipitate morphology in a single crystal superalloy. Fatigue under Thermal and Mechanical Loading 1996, 295-304. Kluwer, Amsterdam. J. Bressers, L. Rémy, M. Steen, J.L. Vallès (Eds.).
8. Ashby M.F., Dyson B.F. Creep damage mechanics and micromechanisms. Advances in Fracture Research, Proceedings, ICF 6 1984, vol. 1:3-30. Pergamon.
9. K. R. Bain, 1985, The effect of coatings on the thermomechanical fatigue life of a single crystal turbine blade material. In: "American Institute of Aeronautics and Astronautics, AIAA/SAE/ASME/ASEE 21st Joint Propulsion Conference, Monterey, CA, July 8-10, 1985, AIAA-85-1366, pp. 85-1366.
10. Baratta F.I. Stress intensity factors for internal multiple cracks in thick-walled cylinders stressed by internal pressure using load relief factors. Eng. Fract. Mech. 1981, 14:237-241.
11. Baufeld B., Tzimas E., Hähner P., Müllejans H., Peteves S., Moretto P. Phase angle effects on damage mechanisms of thermal barrier coatings under thermomechanical fatigue. Scr. Mater. 2001, 45:859-865.
12. Beck T., Ratchev R., Moalla M., Lang K.-H., Löhe D. Lifetime, cyclic deformation and damage behaviour of Mar-M 247 CC under in-phase, out-of-phase and phase-shift TMF loadings 2002, 115-124. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
13. Bernard H., Rémy L. Thermal-mechanical fatigue of an aluminide coated nickel base superalloy. Advanced Materials and Process EUROMAT 89 1990, vol. 1:529-534. DGM, Oberursel.
14. P. Bernède, 1994, Effet de l'oxydation sur la fissuration en fatigue-fluage d'un superalliage pour disques de turbines: l'Astroloy. Ph.D. thesis, Ecole des Mines, Paris.
15. Bernède P., Rémy L. Fatigue crack growth of small defects in a superalloy at high temperature in air and in vacuum. Short Fatigue Cracks, ESIS 13 1992, 251-262. Mechanical Engineering Publications, London. K.J. Miller, E.R. de los Rios (Eds.).
16. Bernstein H., Grant T.S., McClung R.C., Allen J.P. Prediction of thermal-mechanical fatigue life for gas turbine blades in electric power generation. Thermal Mechanical Fatigue Behavior of Materials, ASTM STP 1186 1993, 212-238. American Society for testing and Materials, Philadelphia. H. Sehitoglu (Ed.).
17. J. Besson, G. Cailletaud, J. L. Chaboche and S. Forest, 2001, Mécanique non linéaire des matériaux, Hermes.
18. Bignonnet A., Charkaluk E. Thermomechanical fatigue in the automotive industry. Temperature-fatigue Interaction 2002, 319-330. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
19. Bizon P.J., Spera D.A. Thermal-stress fatigue behavior of twenty-six superalloys. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 106-122. ASTM, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
20. Blümm M., Engler-Pinto C.C., Meyer-Olbersleben F., Rezai-Aria F. Grain orientation and size effects on thermal fatigue behaviour of CM247 LC DS. Materials for Power Engineering 1994, Part II:1099-1108. Kluwer, Dordrecht.
21. P. Bonacuse and S. Kalluri, 1996, Axial-torsional thermomechanical fatigue behavior of Haynes 188 superalloy. In: "Thermal Mechanical Fatigue of Aircraft Engine Materials, Agard Conference Proceedings 569, 81st Meeting of the AGARD Structures and Materials Panel, Banff, Canada, October 2-4, 1995," AGARD, Neuilly, France, pp. 15-1, 15-10.
22. Bressers J., Rémy L., Hoffelner W. Fatigue dominated damage processes. High Temperature Alloys 1986: Proceedings of a Conference held in Liege, Belgium, October 6-9, 1986 1986, vol. 1:441-468. Reidel, Dordrecht.
23. Brückner-Foit A., Jäckels H., Quadfasel U. Prediction of the lifetime distribution of high-strength components subjected to fatigue loading. Fatigue Fract. Mater. Struct. 1993, 16:891-908.
24. Buchalet C.B., Bamford W.H. Stress intensity factor solutions for continuous surface flaws in reactor pressure vessels. Mechanics of Crack Growth, ASTM STP 590 1976, 385-402. American Society for Testing and Materials, Philadelphia. J. Rice, P.C. Paris (Eds.).
25. Bueckner H.F. Field singularities and related integral representations. Mechanics of Fracture 1972, vol. 1:239-314. Noordhoff, Leyden.
26. Bui H.D. Mecanique de la rupture fragile 1978, Masson, Paris.
27. Bullough C.K., Toulios M., Oehl M., Lukas P. The characterisation of the single crystal superalloy CMSX-4 for industrial gas turbine applications. Materials for Advanced Power Engineering 1998: Proceedings of the 6th Liege Conference 1998, Part II:861-878. Forschungszentrum, Jülich, Jülich.
28. Burlet H., Cailletaud G. Numerical techniques for cyclic plasticity at variable temperature. Eng. Comp. 1986, 3:143-153.
29. Burlet H., Vasseur S., Cailletaud G., Pineau A. Fatigue crack growth under thermomechanical loading application to life prediction of centrifugal casting equipment. High Temperature Fracture Mechanisms and Mechanics, EGF 6 1990, 379-395. Mechanical Engineering Publications, London. P. Bensussan, J.P. Mascarell (Eds.).
30. Busso E.S., McClintock F.A. Stress-strain histories in coatings on single crystal specimens of a turbine blade alloy. Int. J. Solids Struct. 1988, 11:1113-1130.
31. Cailletaud G., Chaboche J.L. Macroscopic description of the microstructural changes induced by varying temperature: example of IN100 cyclic behaviour of materials. Proceedings of the 3rd International Conference 1979, 23-32. Pergamon, Oxford. K.J. Miller, R.F. Smith (Eds.).
32. G. Cailletaud, J. L. Chaboche, S. Forest and L. Rémy, 2003, On the design of single crystal turbine blades. Autumn Meeting SF2M, La Revue de Métallurgie-CIT/Science des Matériaux, 100th year, pp. 1-8.
33. Cailletaud G., Chaudonneret M., Culie J.P., Darbois F., Peruzetto P., de Roo P. Two- and three-dimensional calculations of anisothermal cyclic plasticity. High Temperature Fracture Mechanisms and Mechanics, EGF 6 1990, 211-225. Mechanical Engineering Publications, London. P. Bensussan, J.P. Mascarell (Eds.).
34. Cailletaud G., Culié J.P., Kaczmareck H. Thermal fatigue of a thermally unstable alloy. Mechanical Behaviour of Materials-IV: Proceedings of the 4th International Conference, Stockholm, Sweden, August 15-19, 1983 1983, vol. 1:225-261. Pergamon, Oxford.
35. Cailletaud G., Depoid C., Massinon D., Nicouleau-Bourles E. Elastoviscoplasticity with aging in aluminum alloys. Continuum Thermodynamics: The Art and Science of Modelling Material Behaviour 2000, 75-86. Kluwer, Dordrecht. G.A. Maugin, R. Drouot, F. Sidoroff (Eds.).
36. Cailletaud G., Levaillant C. Creep-fatigue life prediction what about initiation?. Nucl. Eng. Des. 1984, 83:279-292.
37. B. J. Cane and M. I. Manning, 1981, "Effect of Test Piece Oxidation on Rupture Data," Internal report lm/MATS/407, CEGB.
38. Castelli M.G., Miner R.V., Robinson D.N. Thermomechanical deformation behavior of a dynamic strain ageing alloy, Hastelloy X. Thermomechanical Fatigue Behavior of Materials, ASTM STP 1186 1993, 106-125. American Society for Testing and Materials, Philadelphia. H. Sehitoglu (Ed.).
39. Chaboche J.L. Une loi différentielle d'endommagement de fatigue avec cumulation non linéaire. Revue Française de Mécanique 1974, 50:71-82.
40. Chaboche J.L. Lifetime predictions and cumulative damage under high-temperature conditions. Low Cycle Fatigue and Life Prediction, ASTM STP 770 1982, 81-104. American Society for Testing and Materials, Philadelphia. C. Amzallag, B.N. Leis, P. Rabbe (Eds.).
41. Chaboche J.L. On some modifications of kinematic hardening to improve the description of ratchetting effects. Int. J. Plasticity 1991, 7:661-678.
42. Chaboche J.L., Cailletaud G. Integration methods for complex plastic constitutive equations. Comp. Methods Appl. Mech. Eng. 1996, 133:125-155.
43. Chaboche J.L., Gallerneau F. Durability modelling at elevated temperature. Fatigue Fract. Eng. Mater. Struct. 2000, 24:405-418.
44. Chaboche J.L., Lesne P.M. A non-linear continuous fatigue damage model. Fatigue Fract. Eng. Mater. Struct. 1988, 11:1-17.
45. Charkaluk E., Constantinescu A. An energetic approach in thermomechanical fatigue for silicon molybdenum cast iron. Mater. High Temp. 2000, 17:373-380.
46. Chataigner E., Fleury E., Rémy L. Thermomechanical fatigue of coated and bare nickel base superalloy single crystals. Fatigue under Thermal and Mechanical Loading 1996, 381-392. Kluwer Academic, Dordrecht, The Netherlands. J. Bressers, L. Rémy (Eds.).
47. Chataigner E., Rémy L. Influence d'un revêtement protecteur (C1A) sur la tenue en fatigue d'aubes de turbines monocristallines. Fatigue et Traitements de surface, SF2M 1995, 11-22. Revue de Métallurgie, Paris.
48. Chataigner E., Rémy L. Thermomechanical fatigue of coated and bare nickel base superalloy single crystals. Thermomechanical Fatigue Behaviour of Materials, ASTM STP 1263 1996, 3-23. American Society for Testing and Materials, Philadelphia. M.J. Verrilli, M.G. Castelli (Eds.).
49. E. Chateau and L. Rémy, 2001, Oxidation-assisted creep damage in Udimet 720 LI. In: "EUROMAT 2001: Proceedings of the 7th European Conference on Advanced Materials and Processes, Rimini, Italy, June 10-14, 2001," Associazione Italiana di Metallurgia, Milano, CD Rom, ISBN 88-85298.
50. Cheng C.Y., Diercks D.R. Effects of hold time on low-cycle fatigue behavior of AISI type 304 stainless steel. Metall. Trans. 1973, 4:615-617.
51. Chieragatti R., Paun F. A new technique for high frequency multiaxial thermo-mechanical fatigue testing of materials. Thermomechanical Fatigue Behavior of Materials: 3rd Volume, ASTM STP 1371 2000, 319-332. American Society for Testing and Materials, West Conshohoken, PA. H. Sehitoglu, M.J. Maier (Eds.).
52. Christl W., Rahmel A., Schütze M. Behavior of oxide scales on 2.25Cr-1Mo steel during thermal cycling: I. Scales formed in oxygen and air, II. Scales grown in water vapor. Oxidat. Metals 1989, 31:1-69.
53. Clavel M., Pineau A. Frequency and wave-form effects on the fatigue crack growth behaviour of alloy 718 at 298 and 823 K. Metall. Trans. A 1978, 9:471-480.
54. Clément P., Angeli J.P., Pineau A. Short crack behaviour in nodular cast iron. Fatigue Eng. Mater. Struct. 1984, 7:251-265.
55. Coffin L.F. The effect of high vacuum on the low cycle fatigue law. Metall. Trans. 1972, 3:1777-1788.
56. Coffin L.F. Fatigue at high temperature. Fatigue at Elevated Temperatures, ASTM STP 520 1973, 5-34. American Society for Testing and Materials, Philadelphia. A.E. Carden, A.J. Mc Evily, C.H. Wells (Eds.).
57. Cook R.H., Skelton R.P. Environment-dependence of the mechanical properties of metals at high temperature. Int. Metall. Rev. 1974, 19:199-222.
58. T. S. Cook, J. H. Loflen, R. H. Van Stone and P. K. Wright, 1996, TMF experience with gas turbine engine materials. In: "Thermal Mechanical Fatigue of Aircraft Engine Materials, AGARD Conference Proceedings 569, 81st Meeting of the AGARD Structures and Materials Panel, Banff, Canada, October 2-4, 1995," pp. 2-1, 2-15.
59. Courtright E.L., Prater J.T., Holcomb G.R., Pierre St.G.R., Rapp R.A. Oxidation of hafnium carbide and hafnium carbide with additions of tantalum and praseodymium. Oxidat. Metals 1991, 36:423-437.
60. Dambrine B., Mascarell J.P. On the interest of using unified viscoplastic models in the life prediction of engine hot components. High Temperature Fracture Mechanisms and Mechanics, EGF 6 1990, 195-210. Mechanical Engineering Publications, London. P. Bensussan, J.P. Mascarell (Eds.).
61. Danzer R., Bressers J. A new method to predict the life under high-temperature low cyle fatigue conditions. Fatigue Fract. Eng. Mater. Struct. 1986, 9:151-168.
62. Dell'Erba D.N., Aliabadi M.H. Three-dimensional thermo-mechanical fatigue crack growth using BEM. Int. J. Fatigue 2000, 22:261-273.
63. Dowling N.E. Crack growth during low cycle fatigue of smooth axial specimens. Cyclic Stress-Strain and Plastic Deformation Aspects of Fatigue Crack Growth, ASTM STP 637 1977, 97-121. American Society for Testing and Materials, Philadelphia.
64. Dowling N.E., Begley J.A. Fatigue crack growth during gross plasticity and the J-integral. Mechanics of Crack Growth, ASTM STP 590 1976, 82-103. American Society for Testing and Materials, Philadelphia. J. Rice, P.C. Paris (Eds.).
65. Dufrénoy P., Bodovillé G., Degallaix G. Damage mechanisms and thermomechanical loading of brake discs. Temperature-fatigue Interaction 2002, 167-176. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
66. C. Duret-Thual, R. Morbioli and P. Steinmetz, 1986, A guide to the control of high temperature corrosion and protection of gas turbine materials. In: "Commission of European Communities, Directorate General Science, Research and Development, EUR 10G82 EN CEC," ed. O. Morocutti, Office for Official Publications of European Communities, Luxembourg.
67. Dyson B.F., McLean M. Microstructural evolution and its effects on the creep performance of high temperature alloys. Microstructural Stability of Creep Resistant Alloys for High Temperature Plant Applications 1998, 371-392. Institute of Materials, London. A. Strang, J. Cawley, G.W. Greenwood (Eds.).
68. Dyson B.F., Osgerby S. Modelling creep-corrosion interactions in nickel-base superalloys. Mater. Sci. Technol. 1987, 3:545-553.
69. Elber W. The significance of fatigue crack closure. Damage Tolerance in Aircraft Structures, ASTM STP 486 1971, 230-242. American Society for Testing and Materials, Philadelphia.
70. Engler-Pinto C.C., Harkegard G., Ilschner B., Nazmy M.Y., Noseda C., Rezai-Aria F. Thermo-mechanical fatigue behavior of IN738LC. Materials for Advanced Power Engineering 1994, part I:853-862. Kluwer Academic, Dordrecht, The Netherlands.
71. Engler-Pinto C.C., Sehitoglu H., Maier H.J., Foglesong T.J. Thermo-mechanical fatigue behaviour of cast 319 aluminum alloys. Temperature-fatigue Interaction 2002, 3-14. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
72. L. Espié, 1996, Etude expérimentale et modélisation numérique du comportement mécanique de monocristaux de superalliage (in French), Thesis, Ecole des Mines de Paris.
73. Esslinger J., Affeldt E.E. Thermo-mechanical fatigue (TMF) in turbine airfoils: typical loading, 3D effects and adjusted testing. Low Cycle Fatigue and Elasto-plastic Behaviour of Materials 1998, 131-136. Elsevier, Amsterdam. K.T. Rie, P.D. Portella (Eds.).
74. Evans A.G., Crumley G.B., Demaray R.E. On the mechanical behaviour of brittle coatings and layers. Oxidat. Metals 1983, 20:193-216.
75. Fatemi A., Socie D.F. A critical plane approach to multiaxial fatigue damage including out-of-phase loading. Fatigue Fract. Eng. Mater. Struct. 1988, 11(3):149-165.
76. Fischmeister H.F., Danzer R., Buchmayr B. Life time prediction models. High Temperature Alloys 1986: Proceedings of a Conference held in Liege, Belgium, October 6-9, 1986 1986, vol. 1:495-549. Reidel, Dordrecht.
77. Fissolo A., Marini B. Multiple cracking in thermal fatigue. Fracture from Defects, ECF 12, Proc. 12th Conference on Fracture 1998, vol. I:31-36. EMAS, Cradley Heath, Warley.
78. Fissolo A., Marini B., Berrada A., Nais G., Wident P. Initiation and growth of cracks under thermal fatigue loading for a 316L type steel. Fatigue under Thermal and Mechanical Loading 1996, 67-77. Kluwer, Dordrecht. J. Bressers, L. Rémy (Eds.).
79. Fleury E., Rémy L. Low cycle fatigue damage in nickel-base superalloy single crystals at elevated temperature. Mater. Sci. Eng. A 1993, 167:23-30.
80. Fleury E., Rémy L. Behaviour of nickel-base superalloy single crystals under thermal-mechanical fatigue. Metall. Mater. Trans. A 1994, 25:99-109.
81. R. Foerch, V. Gros, V. Mounoury, S. Quilici and G. Cailletaud, 2000, Cyclic calculations and life prediction in thermomechanical fatigue using the Zmat library. Abaqus User's Meeting, USA.
82. François M., Rémy L. Influence of microstructure on the thermal fatigue behaviour of a cast cobalt based superalloy. Metall. Trans. A 1990, 21:949-958.
83. Franklin C.J. Cyclic creep and fatigue life prediction. High Temperature Alloys for Gas Turbines: Proceedings of a Conference held in Liège, September 25-27, 1978 1978, 513-547. Applied Science Publishers, Barking. E. Glenny (Ed.).
84. Frost H.J., Ashby M.F. Deformation-mechanism Map 1982, 1-5. Pergamon, Oxford.
85. Fujino M., Taira S. Effect of thermal cycle on low cycle fatigue of steels and grain boundary sliding characteristics. Proceedings of the 3rd Int. Conf. on Mechanical Behaviour of Material 1980, vol. 2:49-58. Pergamon, Oxford.
86. F. Gallerneau, 1999, Modelling of anisotropy effects of a single crystal superalloy on its creep-fatigue resistance. In: "Proceedings ICAF'99, Seattle, July 12-16, 1999," TP ONERA no. 1999-95.
87. Gallerneau F., Nouailhas D., Chaboche J.L. Fatigue damage behaviour of a coated Ni-base single crystal superalloy. Mechanisms and Mechanics of Damage and Failure, ECF 11, Proc. 11th Conference on Fracture 1996, vol. II:1275-1280. EMAS, Cradley Heath, Warley.
88. Gallerneau F., Nouailhas D., Chaboche J.L. A fatigue damage model including interaction effects with oxidation and creep damage. Fatigue 96: Proceedings of the 6th International Fatigue Congress 1996, vol. II:861-866. Pergamon, Oxford.
89. Gell M., Leverant G.R., Wells C.H. The fatigue strength of nickel-base superalloys. Achievement of High Fatigue Resistance in Metals and Alloys, ASTM STP 467 1970, 113-153. American Society for Testing and Materials, Philadelphia.
90. Gemma A.E., Langer B.S., Leverant G.R. Thermomechanical fatigue crack propagation in an anisotropic (directionally solidified) nickel-base superalloy. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 199-213. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
91. Gemma A.E., Phillips J.S. The application of fracture mechanics to life prediction of cooling hole configuration in thermal mechanical fatigue. Eng. Fract. Mech. 1977, 9:25-36.
92. Glenny E. The influence of specimen geometry on thermal-fatigue behaviour. Thermal and High Strain Fatigue 1967, 346-363. The Institute of Metals and the Iron and Steel Institute, London.
93. E. Glenny and T. A. Taylor, 1959-1960, A study of the thermal-fatigue behaviour of metals. J. Inst. Metals, 88, 449-461.
94. Goldman N.L., Hutchinson J.W. Fully plastic crack problems: the centre-cracked strip under plane strain. Int. J. Solids Struct. 1975, 11:575-591.
95. Granacher J., Scholz A. Creep-fatigue behaviour of heat resistant steels under service-type long-terms conditions. Low Cycle Fatigue and Elasto Plastic Behavior of Materials-3 1992, 235-241. Elsevier, London. K.R. Rie (Ed.).
96. Granacher J., Scholz A. Creep-fatigue behaviour under service type strain cycling. Fatigue under Thermal and Mechanical Loading 1996, 209-214. Kluwer, The Netherlands. J. Bressers, L. Rémy (Eds.).
97. Grison J., Rémy L. Fatigue failure probability in a powder metallurgy Ni-base superalloy. Eng. Fract. Mech. 1997, 57:41-55.
98. Grünling H.W., Ilschner B., Leistikov S., Rahmel A., Schmidt M. Interaction between creep deformation and hot gas corrosion. Behaviour of High Temperature Alloys in Aggressive Environments: Proceed. Petten Inter. Conf 1980, 869-893. The Metals Society, London. I. Kirman, J.B. Marriott, M. Merz, P.R. Sahm, D.P. Whittle (Eds.).
99. Grünling H.W., Schneider K., Singheiser L. Mechanical properties of coated systems. Mater. Sci. Eng. 1987, 88:177-189.
100. Guedou J.Y., Honnorat Y. Thermomechanical fatigue of turbo-engine blade superalloys. Thermomechanical Fatigue Behavior of Materials, ASTM STP 1186 1993, 157-175. American Society for Testing and Materials, Philadelphia. H. Sehitoglu (Ed.).
101. Haddar N., Rémy L., Koster A., Akamatsu M. Thermal-mechanical fatigue of 304 stainless steel. Fatigue 2002: Proceedings of the 8th International Fatigue Congress, Stockholm, Sweden, June 3-7, 2002 2002, vol. 3:1665-1672. EMAS, Cradley Heath, UK.
102. Haigh J.R., Skelton R.P. A strain intensity approach to high temperature fatigue crack growth and failure. Mater. Sci. Eng. 1978, 36:133-137.
103. Haigh J.R., Skelton R.P., Richards C.E. Oxidation-assisted crack growth during high cycle fatigue of a 1%Cr-Mo-V steel at 550°C. Mater. Sci. Eng. 1976, 26:167-174.
104. Hales R. A quantitative metallographic assessment of structural degradation of type 316 stainless steel. Fatigue Eng. Mater. Struct. 1980, 3:339-356.
105. Halford G.R., Manson S.S. Life prediction of thermal-mechanical fatigue using strain range partitioning. Thermal Fatigue, ASTM STP 612 1976, 239-254. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
106. Halford G.R., McGaw M.A., Bill R.C., Fanti P.D. Bithermal fatigue: a link between isothermal and thermomechanical fatigue. Low Cycle Fatigue, ASTM STP 942 1988, 1115-1132. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
107. Hancock P., Nicholls J.R. Application of fracture mechanics to failure of surface oxide scales. Mater. Sci. Technol. 1988, 4:398-406.
108. F. Hanriot, 1993, Etude du comportement du superalliage mono-cristallin AM1 sous sollicitations cycliques (in French)," Ph.D. thesis, Ecole des Mines, Paris.
109. Hanriot F., Cailletaud G., Rémy L. Mechanical behaviour of a nickel base superalloy single crystal. High Temperature Constitutive Modeling. Theory and Application 1991, vol. 121:139-150. American Society of Mechanical Engineers, New York, USA, MD-Vol. 26/AMD.
110. Hasan S.T., Brown M.W. Thermal downshock fatigue testing in AISI 316 stainless steel plate. High Temp. Technol. 1990, 8:89-97.
111. M. Hayashi, K. Enomoto, T. Saito and T. Miyagawa, 1994, Development of thermal fatigue apparatus with BWR water environment and thermal fatigue strength of stainless steel. In: "Fracture Mechanics Application," ASME PVP-vol. 287/MD-vol. 47.
112. Hayhurst D.R. Creep rupture inter multiaxial state of stress. J. Mech. Solids 1972, 20(6):381-390.
113. He M.Y., Hutchinson J.W. The penny-shaped crack and the plane strain crack in an infinite body of power-law material. J. Appl. Mech. 1981, 48:830-840.
114. Holmes J.W., McClintock F.A. The chemical and mechanical processes of thermal fatigue degradation of an aluminide coating. Metall. Trans. A 1990, 21:1209-1222.
115. Holmes J.W., McClintock F.A., O'Hara K.S., Conners M.E. Thermal fatigue testing of coated monocrystalline superalloys. Low Cycle Fatigue, ASTM STP 942 1988, 672-691. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
116. Hopkins S.W. Low-cycle thermal mechanical fatigue testing. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 157-169. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
117. Howes M.A.H. A study of thermal fatigue mechanisms. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 86-105. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
118. Huang J.S., Pelloux R.M. Low cycle fatigue crack propagation in Hastelloy X at 25 and 760°C. Metall. Trans. A 1980, 11:899-904.
119. Hutchinson J.W., Suo Z. Mixed mode cracking in layered materials. Advances in Applied Mechanics 1992, vol. 29:63-191. Academic Press, New York.
120. Jaske C.E. Thermal-mechanical, low cycle fatigue of AISI 1010 steel. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 170-198. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
121. Jordan E.H., Meyers G.J. Fracture mechanics applied to nonisothermal fatigue crack growth. Eng. Fract. Mech. 1986, 23:345-358.
122. Kadioglu Y., Sehitoglu H. Modeling of thermomechanical fatigue damage in coated alloys. Thermomechanical Fatigue Behavior of Materials, ASTM STP 1186 1993, 17-34. American Society for Testing and Materials, Philadelphia. H. Sehitoglu (Ed.).
123. Kaguchi H., Koto H., Date S., Takahashi Y. Fatigue crack propagation under cyclic thermal stress. Mater. High Temp. 1998, 15:285-290.
124. Kim K.S., Van Stone R.H. Characterization of elevated temperature crack growth in Hastelloy X using integral parameters. ASME J. Eng. Mater. Technol. 1998, 117:299-304.
125. King J.E., Cotterill P.J. Role of oxides in fatigue crack propagation. Mater. Sci. Technol. 1991, 6:19-31.
126. Kishimoto K., Aoki S., Sakada M. On the path-independent integral. J. Eng. Fract. Mech. 1980, 13:841-850.
127. Kleinpass B., Lang K.H., Löhe D., Macherauch E. Thermal-mechanical fatigue behaviour of NiCr 22-Ci-12Mo9. Fatigue under Thermal and Mechanical Loading 1996, 327-337. Kluwer, Dordrecht. J. Bressers, L. Rémy, M. Steen, J. Valles (Eds.).
128. Knott J. Fundamentals of Fracture Mechanics 1973, 227. Butterworths, London.
129. Koizumi T., Okazaki M. Crack growth and prediction of endurance in thermal-mechanical fatigue of 12Cr-Mo-V-W steel. Fatigue Eng. Mater. Struct. 1979, 1:509-520.
130. A. Koster, 1997, Fatigue thermique d'un alliage pour aubes de turbopompage astronautique: le Superwaspaloy (in French), Ph.D. thesis, Ecole des Mines de Paris.
131. Koster A., Alam A., Rémy L. A physical-base model for life prediction of single crystal turbine blades under creep-fatigue loading and thermal transient conditions. Temperature-fatigue Interaction, 9th International Spring Meeting, Paris, May 29-31, 2001 2002, 203-212. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
132. A. Koster, E. Chataigner and L. Rémy, 1996a, Thermal fatigue, a useful tool to assess low cycle fatigue damage in superalloys for components experiencing thermal transient. In: "81st AGARD Structures and Materials Panel, Thermal-mechanical Fatigue of Aircraft Engine Materials, Banff, Canada, October 2-4, 1995, AGARD-CP-569," AGARD, Neuilly, France, pp. 8-1, 8-8.
133. A. Koster, E. Fleury, E. Vasseur and L. Rémy, 1994, "Thermal-mechanical Fatigue Testing, Automation in Fatigue and Fracture: Testing and Analysis, ASTM STP 1231," ed. C. Amzallag, American Society for Testing and Materials, West Conshohocken, pp. 559-576.
134. Koster A., Laurent G., Cailletaud G., Rémy L. Development of a thermal fatigue facility to simulate the behaviour of superalloy components. Fatigue under Thermal and Mechanical Loading 1996, 25-35. Kluwer Academic, Dordrecht, The Netherlands. J. Bressers, L. Rémy (Eds.).
135. Koster A., Rémy L. An oxidation-creep-fatigue damage model for fatigue at high temperature and under thermal transients. Fatigue 99: Proceedings of the 7th International Fatigue Congress, Beijing, China, June 8-12, 1999 1999, vol. 4:2139-2144. Higher Education Press and EMAS, Cradley Heath.
136. Koterazawa R. Creep-fatigue crack growth and fractography of metallic materials in air and vacuum at elevated temperatures. Fatigue Fract. Eng. Mater. Struct. 1993, 16:619-630.
137. Kowaleski R., Mughrabi H. Thermal-mechanical and isothermal fatigue of a coated columnar-grained directionally solidified nickel-base superalloy. Thermo-mechanical Fatigue Behaviour of Materials: 3rd Volume, ASTM STP 1371 2000, 223-238. American Society for Testing and Materials, West Conshohocken, PA. H. Sehitoglu, H.J. Maier (Eds.).
138. Kuwabara K., Nitta A. Thermal-mechanical low cycle fatigue under creep fatigue interaction on type 304 stainless steels. Proceedings of the 3rd Int. Conf. on Mechanical Behaviour of Material 1980, vol. 2:69-78. Pergamon, Oxford.
139. Kuwabara K., Nitta A., Kitamura T. Thermal-mechanical fatigue life prediction in high-temperature component materials for power plant. Advances in Life Prediction Methods 1983, 131-141. American Society of Mechanical Engineers, New York. D.A. Woodford, J.R. Whitehead (Eds.).
140. Lamba H.S. The J-integral applied to cyclic loading. Eng. Fract. Mech. 1975, 7:693-703.
141. Landes J.D., Begley J.A. A fracture mechanics approach to creep crack growth. Mechanics of Crack Growth, ASTM STP 590 1976, 128-148. American Society for Testing and Materials, Philadelphia. J.R. Rice, P.C. Paris (Eds.).
142. Lautridou J.C., Debussac A., Soniak F. A probabilistic model for fatigue life prediction of P. M. Ni base superalloy containing inclusions. Fatigue 93 1993, vol. 1:285-290. EMAS, Cradley Heath.
143. Leckie F.A., Hayhurst D.R. Constitutive equations for creep rupture. Acta Metall. 1977, 25:1059-1070.
144. Lemaitre J., Chaboche J.L. Mécanique des matériaux solides 1985, Dunod, Paris.
145. Lemaitre J., Plumtree A. Application of damage concepts to predict creep-fatigue failures. ASME J. Eng. Mater. Technol. 1979, 101:284-292.
146. Levaillant C., Grattier J., Mottot M., Pineau A. Creep and creep-fatigue intergranular damage in austenitic stainless steels: discussion of the creep-dominated regime. Low Cycle Fatigue ASTM STP 942 1988, 414-437. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
147. Levaillant C., Pineau A. Assessment of high-temperature low-cycle fatigue life of austenitic stainless steel using intergranular damage as a correlating parameter. Low-cycle Fatigue and Life Prediction, ASTM STP 770 1982, 169-193. American Society for Testing and Materials, Philadelphia. C. Amzallag, B.N. Leis, P. Rabbe (Eds.).
148. Leverant G.R., Strangman T.E., Langer B.S. Parameters controlling the thermal fatigue properties of conventionally-cast and directionally-solidified turbine alloys. Proceedings of the 3rd International Symposium on Superalloys, Metallurgy and Manufacture, September 12-15, 1976 1976, 285-295. Claitor, Seven Springs. B.H. Kear, D.R. Muzyka, J.K. Tien, S.T. Wlodek (Eds.).
149. Li S.X., Smith D.J., Ellison E.G. Creep-fatigue crack growth in a single crystal nickel base superalloy. Behaviour of Defects at High Temperatures, ESIS 15 1993, 351-365. Mechanical Engineering Publications, London. R.A. Ainsworth, R.P. Skelton (Eds.).
150. Maier H.J., Christ H.-J. Validating the predictive capabilities: a key issue in modelling thermomechanical fatigue life. Temperature-Fatigue Interaction 2002, 25-35. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
151. Maier H.J., Teteruk R.G., Christ H.J. Modeling thermomechanical fatigue life of high-temperature titanium alloy IMI 834. Metall. Mater. Trans. A 2000, 31:431-444.
152. Maillot V., Fissolo A., Degallaix G., Degallaix S., Degallaix S., Marini B., Akamatsu M. Thermal fatigue of a 304 type steel. Temperature-fatigue Interaction 2002, 135-193. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
153. Maiya P.S. Effect of wave shape and ultrahigh vacuum on elevated temperature low cycle fatigue in type 304 stainless steel. Mater. Sci. Eng. 1981, 47:13-21.
154. Majumdar S., Maiya P.S. A mechanistic model for time-dependent fatigue. ASME J. Eng. Mater. Technol. 1980, 102:159-167.
155. Malm S., Norström L.-A. Material-related model for thermal fatigue applied to tool steels in hot-work applications. Metal Sci. 1979, 13:544-550.
156. Malpertu J.L., Rémy L. Influence of test parameters on the thermal-mechanical fatigue behavior of a superalloy. Metall. Trans. A 1990, 21:389-399.
157. Manning M.I. Limits to the integrity of oxide scales growing on curved surfaces and distending metal substrates. Corrosion and Mechanical Stress at High Temperatures 1981, 323-338. Applied Science Publishers, London. V. Guttmann, M. Merz (Eds.).
158. Manson S.S. Thermal Stress and Low-cycle Fatigue 1966, McGraw-Hill, New York.
159. Manson S.S. The challenge to unify treatment of high temperature fatigue a partisan proposal based on strain range partitioning. Fatigue at Elevated Temperature, ASTM STP 520 1973, 744-782. American Society for Testing and Materials, Philadelphia. A.E. Carden, A.J. McEvily, C.H. Wells (Eds.).
160. Manson S.S., Freche J.C., Ensign C.R. Application of a double linear damage rule to cumulative fatigue. Fatigue Crack Propagation, ASTM STP 415 1967, 384-412. American Society for Testing and Materials, Philadelphia.
161. Manson S.S., Halford G.R. Practical implementation of the double linear damage rule and damage curve approach for treating cumulative damage. Int. J. Fract. 1981, 17:169-192.
162. Manson S.S., Halford G.R. Discussion on multiaxial low cycle fatigue of type 304 stainless steel. ASME J. Eng. Mater. Technol. 1977, 99:283-285.
163. I-solutions for single edge notch specimens under fixed-end displacements. Int. J. Fract. 1986, 31:53-65.
164. Marchand N.J., Pelloux R.M., Ilschner B. A fracture mechanic criterion for thermal-mechanical fatigue crack growth of gas turbine materials. Eng. Fract. Mech. 1988, 31:535-551.
165. Marsh D.J. A thermal shock fatigue study of type 304 and 316 stainless steels. Fatigue Eng. Mater. Struct. 1981, 4:179-195.
166. Marsh D.J., Green D., Parker R. Comparison of theoretical estimates and experimental measurements of fatigue crack growth under severe thermal shock conditions: Part I. Experimental observations. ASME J. Pres. Ves. Technol. 1986, 108:501-506.
167. J. M. Martinez-Esnaola, M. Ariana, J. Bressers, J. Timm, A. Martin-Meizoso, A. Bennet and E. E. Affeldt, 1996, Crack initiation in an aluminide coated single crystal during thermo-mechanical fatigue. In: "Thermomechanical Fatigue Behavior of Materials: 2nd Volume, ASTM STP 1263," eds. M. J. Verrilli and M. G. Castelli, American Society for Testing and Materials, Philadelphia, pp. 68-81.
168. Mc Clintock F.A. On the plasticity of the growth of fatigue cracks. Fracture of Solids 1963, 65-102. Interscience, New York. D.C. Drucker, J.J. Gilman (Eds.).
169. Mc Mahon C.J., Coffin L.F. Mechanisms of damage and fracture in high-temperature, low-cycle fatigue of a cast nickel-based superalloy. Metall. Trans. 1970, 1:3443-3450.
170. S. M. Meier, D. M. Nissley, K. D. Sheffler and T. A. Cruse, 1991, Thermal barrier coating life prediction model development. In: "Int. Gas Turbine and Aeroengine Congress, Orlando, FL, June 3-6, 1991.".
171. Méric L., Poubanne P., Cailletaud G. Single crystal modeling for structural applications. ASME J. Eng. Mater. Technol. 1991, 113:165-170.
172. Meyer-Obersleben F., Engler-Pinto C.C., Rezai-Aria F. On thermal fatigue of nickel based superalloys. Thermomechanical Fatigue Behavior of Materials: 2nd Volume, ASTM STP 1263 1996, 41-55. American Society for Testing and Materials, Philadelphia. M.J. Verrilli, M.G. Castelli (Eds.).
173. Meyer-Obersleben F., Rezai-Aria F., Ilschner B. The effect of grain size and upper cycle temperature in thermal fatigue behaviour of IN 100 superalloy. High Temperature Alloys for Gas Turbines and other Applications 1990, vol. II:1121-1129. Reidel, Dordrecht.
174. Miller M.P., Mc Dowell D.L., Oehmke R.L.T. A creep-fatigue-oxidation microcrack propagation model for thermomechanical fatigue. J. Eng. Mater. Technol. 1992, 114:282-288.
175. Miller R.A. Progress toward life modeling of thermal barrier coatings for aircraft gas turbine engines. ASME J. Eng. Gas Turbines Power 1987, 109:448-451.
176. R. A. Miller, 1988, Life modeling of thermal barrier coatings for aircraft gas turbine engines. In: "32nd ASME International Gas Turbines and Aeroengine Congress, Amsterdam, June 5-9, 1988," pp. 109-115.
177. Miner M.A. Cumulative damage in fatigue. J. Appl. Mech. 1945, 12:A159-A164.
178. Miquel B., Jean S., Le Roux S., Lamesle P., Rezai-Aria F. Heat-checking of hot work tool steels. Temperature-fatigue Interaction 2002, 185-193. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
179. Moalla M., Lang K.H., Löhe D. Cycle deformation and life time behaviour of NiCr22-Co12Mo isothermal and thermal-mechanical fatigue. Temperature-fatigue Interaction 2002, 85-94. ESIS Publication 29, Elsevier, Oxford. L. Rémy, J. Petit (Eds.).
180. Mowbray D.F., Mc Connelee J.E. Nonlinear analysis of a tapered disk thermal fatigue specimen. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 10-29. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
181. Mowbray D.F., Woodford D.A. Observations and interpretation of crack propagation under conditions of transient thermal strain. International Conference on Creep and Fatigue 1973, 179.1-179.11. Institute of Mechanical Engineers, Conference Publication 13.
182. Mowbray D.F., Woodford D.A., Brandt D.E. Thermal fatigue characterization of cast cobalt and nickel-base superalloys. Fatigue at Elevated Temperatures, ASTM STP 520 1973, 416-426. American Society for Testing and Materials, Philadelphia. A.E. Larden, A.J. McEvily, C.H. Wells (Eds.).
183. Nairn J.A., Kim S.R. A fracture mechanics analysis of multiple cracking in coatings. Eng. Fract. Mech. 1992, 42:195-208.
184. Neate G.J. Crack growth in a CrMoV steel under cyclic loading at 873 K. High Temp. Technol. 1985, 3:195-202.
185. Neu R.W., Sehitoglu H. Thermomechanical fatigue, oxidation and creep: Part I. Damage mechanisms. Metall. Trans. A 1989, 20:1755-1767.
186. Neu R.W., Sehitoglu H. Thermomechanical fatigue, oxidation and creep: Part II. Life prediction. Metall. Trans. A 1989, 20:1769-1783.
187. Nicholas T., Heil M.L., Haritos G.K. Predicting crack growth under thermo-mechanical cycling. Int. J. Fract. 1989, 41:157-176.
188. Nicouleau E., Feyel F., Quilici S., Cailletaud G. Structural calculation and lifetime-prediction in thermomechanical fatigue of engine components. Temperature-fatigue Interaction 2002, 331-340. Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
189. Northcott L., Baron M.G. The craze-cracking of metals. J. Iron Steel Inst. 1956, 184:385-408.
190. Ohtani R., Kitamura T. Creep-fatigue interaction under high-temperature conditions. Handbook of Fatigue Crack Propagation in Metallic Structures 1994, 1347-1383. Elsevier, Amsterdam. A. Carpinteri (Ed.).
191. Ohtani R., Kitamura T., Nitta A., Kuwabara K. High-temperature low cycle fatigue crack propagation and life laws of smooth specimens derived from the crack propagation laws. Low Cycle Fatigue, ASTM STP 942 1988, 1163-1180. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
192. Okazaki M., Hattori I., Shiraiwa F., Koizumi T. Effect of strain wave shape on low-cycle fatigue crack propagation of SUS 304 stainless steel at elevated temperatures. Metall. Trans. A 1983, 14:1649-1659.
193. Okazaki M., Koizumi T. Crack Propagation of steels during low cycle thermal-mechanical fatigue and isothermal fatigue at elevated temperatures. Metall. Trans. A 1983, 14:1641-1648.
194. Okazaki M., Koizumi T. Relationship of crack growth between thermal-mechanical and low cycle fatigue at elevated temperatures. ASME J. Eng. Mater. Technol. 1987, 109:114-118.
195. Osgerby S., Dyson B.F. Effect of oxygen on creep performance: mechanisms and predictive modelling. Mater. Sci. Technol. 1990, 6:2-8.
196. Oshida Y., Liu H.W. Grain boundary oxidation and an analysis of the effects of oxidation on fatigue crack nucleation life. Low Cycle Fatigue, ASTM STP 942 1988, 1199-1217. American Society for Testing and Materials, Philadephia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
197. Ostergren W.J. A damage function and associated failure equations for predicting hold time and frequency effects in elevated temperature, low-cycle fatigue. J. Test. Evaluat. 1976, 4:327-339.
198. Oudin A., Lamesle P., Penazzi L., Le Roux S., Rezai-Aria F. Thermomechanical fatigue behaviour and life assessment of hot work tool steels. Temperature-fatigue Interaction 2002, 195-201. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
199. Pédron J.P., Pineau A. The effect of microstructure and environment on the crack growth behaviour of Inconel 718 alloy at 650°C under fatigue, creep and combined loading. Mater. Sci. Eng. 1982, 56:143-156.
200. Perruchaut P., Villechaise P., Mendez J. Influence of a coating on the fatigue damage of the 〈001〉 AM1 single crystal superalloy at 950°C. Mechanisms and Mechanics of Damage and Failure, ECF 11, Proc. 11th Conference on Fracture 1996, vol. II:1219-1224. EMAS, Cradley Heath.
201. H. Policella and P. M. Lesne, 1986, Amorçage et propagation de fissures en fatigue thermique, calculs de prevision. In: "Fatigue at High Temperature: Proceed. Int. Spring Meeting SFM, Paris, June 9-11, 1986," pp. 275-289.
202. M. Probst-Hein and G. Eggeler, 2001, Predictive microstructural assessment and micromechanical modelling of deformation and damage accumulation in single crystal gas turbine blading, Micromod-SX, Brite-Euram III, final report.
203. Rabotnov Y.N. Creep Problems in Structural Members 1969, North-Holland, Amsterdam.
204. Ratchev R., Beck T., Lang K.-H., Löhe D. Lifetime, cyclic deformation and damage behaviour of IN706 and IN718 under out-of-phase TMF loadings. Fatigue 2002: Proceedings of the 8th International Fatigue Congress, Stockholm, June 3-7, 2002 2002, vol. 2:1267-1274. EMAS, Cradley Heath.
205. Rau C.A., Gemma A.E., Leverant G.R. Thermal-mechanical fatigue crack propagation in nickel and cobalt base superalloys under various strain temperature cycles. Fatigue at Elevated Temperatures, ASTM STP 520 1973, 166-178. American Society for Testing and Materials, Philadelphia. A.E. Carden, A.J. McEvily, C.H. Wells (Eds.).
206. Reger M., François M., Rémy L. Interaction between oxidation and cyclic straining at high temperature. Physical Chemistry of the Solid State: Applications to Metals and their Compounds 1984, 413-420. Elsevier, Amsterdam. P. Lacombe (Ed.).
207. Reger M., Rémy L. Fatigue oxidation interaction in IN100 superalloy. Metall. Trans. A 1988, 19:2259-2268.
208. Reger M., Rémy L. High temperature low cycle fatigue behaviour of IN100 superalloy: I. Influence of temperature on the low cycle fatigue behaviour. Mater. Sci. Eng. A 1988, 101:47-54.
209. Reger M., Rémy L. High temperature low cycle fatigue behaviour of IN100 superalloy: II. Influence of frequency and environment at high temperature. Mater. Sci. Eng. A 1988, 101:55-63.
210. Reger M., Soniak F., Rémy L. Propagation of short cracks in low cycle fatigue. Fatigue 84: Proceedings of the 2nd International Conference on Fatigue and Fatigue Thresholds, Birmingham, September 3-7, 1984 1984, vol. II:797-806. EMAS, London.
211. Rémy L. Recent developments in thermal fatigue. High Temperature Fracture Mechanisms and Mechanics, EGF 6 1990, 353-377. Mechanical Engineering Publications, London. P. Bensussan, J.P. Mascarell (Eds.).
212. Rémy L. Oxidation effects in high temperature creep and fatigue of engineering alloys. Corrosion-Deformation Interactions CDI'92 1993, 425-459. Les Editions de Physique, Courtaboeuf. T. Magnin, J.M. Gras (Eds.).
213. Rémy L. Oxidation and damage in turbojet superalloys under cyclic loading. Actes du 16e colloque Matériaux pour l'Aéronautique et l'Espace: Proceedings of a Conference organized by AAAF, Paris, June 13-14, 1995 1995, 45-62.
214. Rémy L. Thermal-mechanical fatigue and thermal fatigue experiments: damage modelling in thermal mechanical fatigue. Mechanical Behaviour of Materials at High Temperature, NATO ASI Series 1996, 381-418. Kluwer, Dordrecht. C. Moura-Branco, T. Ritchie, V. Sklenicka (Eds.).
215. Rémy L. Thermal and thermal-mechanical fatigue of superalloys, a challenging goal for mechanical tests and models. Low Cycle Fatigue and Elasto-plastic Behaviour of Materials: Proceedings of the 4th International Conference, September 7-11, 1998 1998, 119-130. Elsevier, Garmisch-Partenkirchen, Germany. K.-T. Rie, P.D. Portella (Eds.).
216. Rémy L., Alam A., Bickard A. Thermo-mechanical creep-fatigue of coated systems. Thermomechanical Fatigue Behavior of Materials: 4th Volume, ASTM STP 1428 2002, American Society for Testing and Materials, West Conshohocken, PA. M.A. McGaw, S. Kalluri, J. Bressers, S.D. Peteves (Eds.).
217. Rémy L., Bernard H., Malpertu J.L., Rezai-Aria F. Fatigue life prediction under thermal-mechanical loading in a nickel-base superalloy. Thermomechanical Fatigue Behaviour of Materials, ASTM STP 1186 1993, 3-16. American Society for Testing and Materials, Philadelphia. H. Sehitoglu (Ed.).
218. Rémy L., Guédou J.-Y. Thermal-mechanical fatigue problems in aero-engine components. Fatigue 2002: Proceedings of the 8th International Fatigue Congress, Stockholm, Sweden, June 3-7, 2002 2002, vol. 3:1045-1062. EMAS, Cradley Heath, UK.
219. Rémy L., Koster A., Chataigner E., Bickard A. Thermal-mechanical fatigue and the modelling of materials behaviour under thermal transients. Thermo-mechanical Fatigue Behaviour of Materials: 3rd Volume, ASTM STP 1371 2000, 223-238. American Society for Testing and Materials, West Conshohocken, PA. H. Sehitoglu, H.J. Maier (Eds.).
220. Rémy L., Reger M., Reuchet J., Rezai-Aria F. An operational definition of life to crack initiation in high temperature fatigue. High Temperature Alloys for Gas Turbines 1982, 619-632. Reidel, Dordrecht. R. Brunetaud, D. Coutsouradis, T.B. Gibbons, Y. Lindblom, D.B. Meadowcroft, R. Stickler (Eds.).
221. Rémy L., Rézaï-Aria F., Danzer R., Hoffelner W. Evaluation of life prediction methods in high temperature fatigue. Low Cycle Fatigue, ASTM STP 942 1988, 1115-1132. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
222. Rémy L., Skelton P. Damage assessment of components experiencing thermal transients. High Temperature Structural Design, ESIS 12 1992, 283-315. Mechanical Engineering Publications, London. L.H. Larsson (Ed.).
223. Renner E., Vehoff H., Neumann P. Life prediction for creep-fatigue based on the growth of short cracks. Fatigue Fract. Eng. Mater. Struct. 1989, 12:569-584.
224. Reuchet J., Reger M., Rézaï-Aria F., Rémy L. The cumulation of damage in high temperature low cycle fatigue. Low Cycle Fatigue and Life Prediction, ASTM STP 770 1982, 194-211. American Society for Testing and Materials, Philadelphia. C. Amzallag, P. Rabbe, B.N. Leis (Eds.).
225. Reuchet J., Rémy L. Fatigue oxidation interaction in a superalloy. Application to life prediction in high temperature low cycle fatigue. Metall. Trans. A 1983, 14:141-149.
226. Reuchet J., Rémy L. High temperature low cycle fatigue of superalloy Mar-M509: Part I. The influence of temperature on the low cycle fatigue behaviour. Mater. Sci. Eng. 1983, 58:19-32.
227. Reuchet J., Rémy L. High temperature low cycle fatigue of superalloy Mar-M509: Part II. The influence of oxidation at high temperatures. Mater. Sci. Eng. 1983, 58:33-42.
228. Rézaï-Aria F., Dambrine B., Rémy L. Thermal fatigue of MAR-M509 superalloy: II. Evaluation of life prediction models. Fatigue Fract. Eng. Mater. Struct. 1988, 11:291-302.
229. Rézaï-Aria F., François M., Rémy L. Thermal fatigue of MAR-M509 superalloy: I. The influence of specimen geometry on the thermal fatigue behaviour. Fatigue Fract. Eng. Mater. Struct. 1988, 11:277-289.
230. Rézai-Aria F., Rémy L. An oxidation fatigue interaction damage model for thermal fatigue crack growth. Eng. Fract. Mech. 1989, 34:283-294.
231. Rice J.R. A path independent integral and the approximate analysis of strain concentration by notches and cracks. ASME J. Appl. Mech. E 1968, 35(2):379-386.
232. Rice J.R. Elastic fracture mechanics concepts for interfacial cracks. Trans. ASME, J. Appl. Mech. 1988, 55:98-103.
233. Rice J.R., Sih G.C. Plane problems of cracks in dissimilar media. Trans. ASME, J. Appl. Mech. 1965, 32:418-423.
234. Riedel H. Deformation and cracking of thin second-phase layers on deforming metals at elevated temperatures. Metal Sci. 1982, 16:569-574.
235. Riedel H., Rice J.R. Tensile cracks in creeping solids. Fracture Mechanics: 12th Conference, ASTM STP 700 1980, 121-130. American Society for Testing and Materials, Philadelphia, PA.
236. Robertson J., Manning M.I. Limits to adherence of oxide scales. Mater. Sci. Technol. 1990, 6:81-91.
237. Robinson E.L. Effect of temperature variation on the long-time rupture strength of steels. Trans. ASME 1952, 74:777-781.
238. Rousseau D., Riegert J.P., Séraphin L., Tricot R. Fatigue thermique des aciers à outils pour travail à chaud. Revue de Métallurgie 1975, 875-889.
239. Säuberlich T., Pitz G., Löhe D. Thermal-mechanical fatigue behaviour of a 9% chromium steel. Materials for Advanced Power Engineering 1998: Proceedings of the 6th Liege Conference 1998, Part 1:341-350. Forschungszentrum Jülich, Jülich.
240. Savalle S., Cailletaud G. Microinitiation, micropropagation and damage. La Recherche Aérospatiale (french and english editions) 1982, 6:395-411.
241. Schmitt W., Mohrman R., Riedel H., Dietsche A., Fischersworring-Bunk A. Modelling of the fatigue life of automobile exhaust components. Fatigue 2002: Proceeding of the 8th International Fatigue Congress, Stockholm, June 3-7, 2002 2002, vol. 2:781-788. EMAS, Cradley Heath.
242. Schneider K., Grünling H.W. Mechanical properties of high temperature coatings. Thin Solid Films 1983, 107:395-416.
243. Scholz A., Granacher J., Berger C. Simulation of long term creep-fatigue behaviour by multiatage service type strain cycling. Low Cycle Fatigue and Elasto-plastic Behaviour of Materials 1998, 741-746. Elsevier, Amsterdam. K.T. Rie, P.D. Portella (Eds.).
244. Schütze M. Deformation and cracking behavior of protective oxide scales on heat-resistant steels under tensile strain. Oxidat. Metals 1985, 24:199-232.
245. Schütze M. Plasticity of protective oxide scales. Mater. Sci. Technol. 1990, 6:32-38.
246. Schütze M. Protective Oxide Scales and their Breakdown 1997, Wiley, New York.
247. Sehitoglu H. Constraint effect in thermo-mechanical fatigue. ASME J. Eng. Mater. Technol. 1985, 107:221-226.
248. Sehitoglu H. Crack growth studies under selected temperature-strain histories. Eng. Fract. Mech. 1987, 26:475-489.
249. Sehitoglu H. Thermo-mechanical deformation of engineering alloys and components-experiments and modelling. Mechanical Behaviour of Materials at High Temperature 1996, 349-379. NATO ASI Series, Kluwer, Dordrecht. C. Moura-Branco, T. Ritchie, V. Sklenicka (Eds.).
250. Sehitoglu H., Boismier D.A. Thermo-mechanical fatigue of Mar-M247: Part 1. Experiments. ASME J. Eng. Mater. Technol. 1990, 112:68-79.
251. Sehitoglu H., Boismier D.A. Thermo-mechanical fatigue of Mar-M247: Part 2. Life prediction. ASME J. Eng. Mater. Technol. 1990, 112:80-89.
252. Sehitoglu H., Qing X., Smith T., Maier H.J., Allison J.A. Stress-strain response of a cast 319-T6 aluminium under thermomechanical loading. Metall. Mater. Trans. A 2000, 31:139-151.
253. Sehitoglu H., Smith T.J., Maier H.J. Thermo-mechanical deformation of Al 319-T7B with small secondary dendrite arm spacing. Thermo-mechanical Fatigue Behavior of Materials: 3rd Volume, ASTM STP 1371 2000, 53-68. American Society for Testing and Materials, West Conshohocken, PA. H. Sehitoglu, H.J. Maier (Eds.).
254. Shepherd D.P., Wisbey A., Harrison G.F., Ward T.J., Vermeulen B. Cyclic operation in aero gas turbines-materials and component life implications. Mater. High Temp. 2001, 18:231-239.
255. Shida Y., Moroishi T. Oxidation behaviour of alloy 800 in an impure helium atmosphere at high temperatures. Corros. Sci. 1992, 33:211-224.
256. Shih C.F., Hutchinson J.W. Fully plastic solutions and large scale yielding estimates for plane stress crack problems. J. Eng. Mater. Technol. 1976, 98:289-295.
257. Sidey D., Coffin L.F. Low-cycle fatigue damage mechanisms at high temperature. Fatigue Mechanisms, ASTM STP 675 1979, 528-568. American Society for Testing and Materials, Philadelphia. J.T. Fong (Ed.).
258. Singheiser L., Steinbrech R., Quadakkers W.J., Herzog R. Failure aspects of thermal barrier coatings. Mater. High Temp. 2001, 18:249-259.
259. Skelton R.P. Crack propagation in metals during thermal shock. Proceedings of the 3rd Int. Conf. on Mechanical Behaviour of Materials 1980, vol. 2:13-22. Pergamon, Oxford.
260. Skelton R.P. Growth of short cracks during high strain fatigue and thermal fatigue and thermal cycling. Low-cycle Fatigue and Life Prediction, ASTM STP 770 1982, 337-381. American Society for Testing and Materials, Philadelphia. C. Amzallag, B.N. Leis, P. Rabbe (Eds.).
261. Skelton R.P. Crack initiation and growth in simple metal components during thermal cycling. Fatigue at High Temperature 1983, 1-62. Applied Science Publishers, London. R.P. Skelton (Ed.).
262. Skelton R.P. Application of small specimen crack growth data to engineering components at high temperature: a review. Low-cycle Fatigue, ASTM STP 942 1988, 209-235. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
263. Skelton R.P. Introduction to thermal shock. High Temp. Technol. 1990, 8:75-88.
264. Skelton R.P., Bucklow J.I. Cyclic oxidation and crack growth during high strain fatigue of low alloy steel. Metal Sci. 1978, 12:64-70.
265. Skelton R.P., Nix K.J. Crack growth behaviour in austenitic and ferritic steels during thermal quenching from 550°C. High Temp. Technol. 1987, 5:3-12.
266. Smith K.N., Watson P., Topper T.M. A stress strain function for the fatigue of metals. J. Mater. 1970, 4:767-778.
267. Smith T.J., Maier H.J., Sehitoglu H., Fleury E., Allison J. Modeling high-temperature stress-strain behavior of cast aluminium alloys. Metall. Mater. Trans. A 1999, 30:133-146.
268. Socie D.F. Multiaxial fatigue damage models. J. Eng. Mater. Technol. 1987, 109:293-298.
269. Solomon H.D., Coffin L.F. Effects of frequency and environment on fatigue crack growth in A286 at 1100F. Fatigue at Elevated Temperatures, ASTM STP 520 1973, 112-121. American Society of Testing and Materials, Philadelphia. A.E. Carden, A.J. McEvily, C.H. Wells (Eds.).
270. Soniak F., Rémy L. Fatigue crack growth of small defects in a powder metallurgy superalloy at high temperature. Fatigue 90 1990, vol. 3:1583-1588. Materials and Component Engineering Publications, Edgbaston, UK.
271. D. A. Spera, 1969, The calculation of thermal fatigue life based on accumulated creep damage, NASA TMX-52558, National Aeronautics and Space Administration.
272. Spera D.A. Comparison of experimental and theoretical fatigue lives for five nickel-base alloys. Fatigue at Elevated Temperatures, ASTM STP 520 1973, 744-782. American Society for Testing and Materials, Philadelphia. A.E. Carden, A.J. McEvily, C.H. Wells (Eds.).
273. Spera D.A. What is thermal fatigue?. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 3-9. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
274. Spera D.A., Cox E.C. Description of a computerized method for predicting thermal fatigue life of metals. Thermal Fatigue of Materials and Components, ASTM STP 612 1976, 69-85. American Society for Testing and Materials, Philadelphia. D.A. Spera, D.F. Mowbray (Eds.).
275. D. A. Spera and D. F. Mowbray (eds.), 1976, "Thermal Fatigue of Materials and Components, ASTM STP 612" American Society for Testing and Materials, Philadelphia, p. 262.
276. Starkey M.S., Skelton R.P. A comparison of the strain intensity and cyclic J approaches to crack growth. Fatigue Eng. Mater. Struct. 1982, 5:329-341.
277. Stephan J.M., Curtit F., Vindeirinho C., Taheri S., Akamatsu M., Peniguel C. Evaluation of the risk of damages in mixing zones: EDF R&D programme. Fatigue 2002: Proceedings of the 8th International Fatigue Congress, Stockholm, June 3-7, 2002 2002, vol. 3:1707-1714. EMAS, Cradley Heath.
278. Strang A., Lang E. Effect of coatings on the mechanical properties of superalloys. High Temperature Alloys for Gas Turbines, Proc. Conf. Liege, Belgium 1982, 469-506. Reidel, Dordrecht. T.E. Brunetaud (Ed.).
279. Strangman T.E. Thermal-mechanical fatigue life model for coated superalloy turbine components. Superalloys 1992 1992, 795-804. The Minerals, Metals and Materials Society, Warrendale. S.D. Antolovitch, R.W. Stusrud, R.A. Mackay, D.L. Anton, T. Khan, R.D. Kissinger, D.L. Klarstrom (Eds.).
280. Strangman T.E., Hopkins S.W. Thermal fatigue of coated superalloys. Ceram. Bull. 1976, 55:304-306.
281. Stringer J. Role of coatings in energy-producing systems: an overview. Mater. Sci. Eng. 1987, 87:1-10.
282. Swindeman R.W. Cyclic stress-strain time response of a 9Cr-1Mo-V-Nb pressure vessel steel at high temperature. Low Cycle Fatigue, ASTM STP 942 1988, 107-122. American Society for Testing and Materials, Philadelphia. H.D. Solomon, G.R. Halford, L.R. Kaisand, B.N. Leis (Eds.).
283. Taira S. Lifetime of structures subjected to varying load and temperature. Creep in Structures 1962, 96-124. Springer, Berlin. N.J. Hoff (Ed.).
284. Taira S. Relationship between thermal fatigue and low-cycle fatigue at elevated temperature. Fatigue at Elevated Temperature, ASTM STP 520 1973, 744-782. American Society for Testing and Materials, Philadelphia. A.E. Carden, A.J. Mc Evily, C.H. Wells (Eds.).
285. Taira S., Ohtani R., Kitamura T. Application of J-integral to high temperature crack propagation: Part I. Creep crack propagation. J. Eng. Mater. Technol., Trans. ASME 1979, 101:154-161.
286. Taira S., Ohtani R., Komatsu T. Application of J-integral to high temperature crack propagation: Part II. Fatigue crack propagation. J. Eng. Mater. Technol., Trans. ASME 1979, 101:162-167.
287. Tomkins B. Fatigue crack propagation-an analysis. Phil. Mag. 1968, 18:1041-1066.
288. Totemeier T.C., Gale W.F., King J.E. Isothermal fatigue of an aluminide coated single crystal superalloy: Part II. Effects of brittle precracking. Metall. Mater. Trans. A 1996, 27:363-369.
289. Totemeier T.C., King J.E. Isothermal fatigue of an aluminide coated single crystal superalloy: Part I. Metall. Mater. Trans. A 1996, 27:353-361.
290. E. Vasseur, 1993, Fatigue anisotherme at microstructure de superalliages colonnaires (in French). Ph.D. thesis, Ecole des Mines, Paris.
291. Vasseur E., Rémy L. High temperature low cycle fatigue and thermal-mechanical fatigue behaviour of an oxide-dispersion-strengthened nickel-base superalloy. Mater. Sci. Eng. A 1994, 184:1-15.
292. Verger L., Constantinescu A., Charkaluk E. Thermomechanical fatigue design of aluminum components. Temperature-fatigue Interaction 2002, 309-318. ESIS Publication 29, Elsevier, Amsterdam. L. Rémy, J. Petit (Eds.).
293. Ward G., Hockenhull B.S., Hancock P. The effect of cyclic stressing on the oxidation of a low-carbon steel. Metall. Trans. 1974, 5:1451-1455.
294. Woodford D.A. Environmental damage of a cast nickel base superalloy. Metall. Trans. A 1981, 12:299-308.
295. Woodford D.A., Mowbray D.F. Effect of material characteristics and test variables on thermal fatigue of cast superalloys. Mater. Sci. Eng. 1974, 16:5-43.
296. Wright P.K. Influence of cyclic strain on life of a PVD TBC. Mater. Sci. Eng. A 1998, 245:191-200.
297. Wütrich C. The extension of the J-integral concept to fatigue cracks. Int. J. Fract. 1982, 20:R35-R37.
298. Yagawa G., Takahashi Y., Ueda H. Three-dimensional fully plastic solutions for plates and cylinders with through-wall cracks. J. Appl. Mech. 1985, 52:319-325.
299. Yamauchi M., Ohtani T., Takahashi Y. Thermal fatigue behavior of a SUS 304 pipe under longitudinal cyclic movement of axial temperature distribution. Thermomechanical Fatigue Behavior of Materials: 2nd Volume, ASTM STP 1263 1996, 117-129. American Society for Testing and Materials, Philadelphia. M.J. Verrilli, M.G. Castelli (Eds.).
300. Zamrik S.Y., Renauld M.L. Thermo-mechanical out-of-phase fatigue life of overlay coated IN-738LC gas turbine material. Thermomechanical Fatigue Behavior of Materials: 3rd Volume, ASTM STP 1371 2000, 119-137. American Society for Testing and Materials, West Conshohocken, PA. M. Sehitoglu, H.J. Maier (Eds.).
301. Zauter R., Petry F., Christ H.-J., Mughrabi H. Thermomechanical fatigue of the austenitic stainless steel AISI 304L. Thermomechanical Fatigue Behaviour of Materials, ASTM STP 1186 1993, 70-90. American Society for Testing and Materials, Philadelphia. H. Sehitoglu (Ed.).
302. Ziebs J., Meersmann J., Kühn H.J., Hülsmann N., Olchewski J. Multiaxial thermomechanical behaviour of 738LC. Proceedings of 4th International Conference on Biaxial/Multiaxial Fatigue, St. Germain en Laye, France, May 31-June 3, 1994 1994, vol. 2:247-259. SF2M, Paris.
303. Ziebs J., Meersmann J., Kühn H.-J., Klingelhöffer H. Multiaxial thermo-mechanical deformation behavior of 738LC and SC16. Thermomechanical Fatigue Behavior of Materials: 3rd Volume, ASTM STP 1371 2000, 257-278. American Society for Testing and Materials, West Conshohocken, PA. H. Sehitoglu, H.J. Maier (Eds.).
304. Ziebs J., Meersmann J., Kühn H.-J., Ledworoski S. High temperature inelastic deformation of IN738 LC under uniaxial and multiaxial loading. Low Cycle Fatigue and Elasto-plastic Behaviour of Materials, LCF3 1992, 248-255. Elsevier, Amsterdam. K.T. Rie (Ed.).