A review on damage mechanisms, models and calibration methods under various deformation conditions

International Journal of Damage Mechanics

Volumn 14, Issue 4, 2005, Pages 299-319

  Lin, J ^a   Liu, Y ^a   Dean, T A ^a  

^a UNIVERSITY OF BIRMINGHAM   (United Kingdom)

Author keywords

Cold and hot metal forming; Creep and viscoplasticity; Damage calibrations; Damage mechanisms

Indexed keywords

CREEP; CRYSTAL MICROSTRUCTURE; FAILURE (MECHANICAL); GRAIN BOUNDARIES; MATHEMATICAL MODELS; METAL FORMING; VISCOELASTICITY;

DAMAGE CALIBRATIONS; DAMAGE MECHANISMS;

DEFORMATION;

EID: 27144525229     PISSN: 10567895     EISSN: None     Source Type: Journal    
DOI: 10.1177/1056789505050357     Document Type: Review

References (55)

1. Ahsam, Q. (1997). PhD Thesis, University of Birmingham, UK.
2. Ashby, M.F. and Dyson, B.F. (1984a). Creep Damage Mechanics and Micro-mechanisms, National Physical Laboratory, UK.
3. Ashby, M.F. and Dyson, B.F. (1984b). Creep Damage Mechanics and Micro-mechanisms, In: ICF Advance in Fracture Research, pp. 3-30, Pergamon Press.
4. Bellenger, E. and Bussy, P. (1998). Plastic and Viscoplastic Damage Models with Numerical Treatment for Metal Forming Processes, J. of Materials Processing Technology, 80: 591-596.
5. Bogatov, A.A. (2003). The Mechanics of the Ductile Damage Under the Metal Forming, In: The 6th Int. ESAFORM Conference on Metal Forming, Salerno, Italy.
6. Bonora, N. (1997). A Non-linear CMD Model for Ductile Failure, Eng. Fract. Mech., 58(1/2): 11-28.
7. Boyer, J.C., Vidalsalle, E. and Staub, C. (2002). A Shear Stress Dependent Ductile Damage Model, J. of Materials Processing Technology, 121: 87-93.
8. Brust, F.W. and Leis, B.N. (1992). A New Model for Characterizing Primary Creep Damage, Int. J. Fract., 54: 45-63.
9. Chaboche, J.L. (1987). Continuum Damage Mechanics: Present State and Future Trends, Nuclear Engineering and Design, 105: 19-33.
10. Cocks, A.C.F. and Ashby, M.F. (1982). On Creep Fracture by Void Growth, Progress in Material Science, 27: 189-244.
11. Chokshi, A.H. and Langdon, T.G. (1987). A Model for Diffusional Cavity Growth in Superplasticity, Acta Metallurgica, 35:1089-1101.
12. Cottingham, D.M. (1966). The Hot Workability of Low-carbon Steels, Proceedings of The Conference on Deformation Under Hot working Conditions, pp. 146-156.
13. Dieter, G.E., Mullin, J.V. and Shapiro, E. (1966). Fracture of Inconel under conditions of hot working, Proceedings of The Conference on Deformation Under Hot Working Conditions, pp. 7-12.
14. Du, Z. and Wu, S. (1995). A Kinetic Equation for Damage During Superplastic Deformation, J. of Material Processing Technology, 52: 270-279.
15. Dunne, F.P.E. and Hayhurst, D.R. (1992). Continuum Damage Based Constitutive Equations for Copper Under High Temperature Creep and Cyclic Plasticity, Proc. R. Soc. Lond., A, 437: 545-566.
16. Dyson, B.F. (1988). Creep and Fracture of Metals: Mechanisms and Mechanics, Rev. Phys. Appl., 23: 605-613.
17. Dyson, B.F. (1990). Physically-based Models of Metal Creep for use in Engineering Design, In: Embury, J.D. and Thompson, A.W. (eds) Modelling of Materials Behaviour and Design, pp. 59-75, The Materials, Metals and Materials Society, London, UK.
18. Dyson, B.F. and Loveday, M.S. (1981). Creep Fracture in Nomonic 80A Under Triaxial Tensile Stressing, In: Ponter, A.R.S. and Hayhurst, D.R. (eds) Creep in Structure, pp. 406-421, Springer-Verlag, Berlin.
19. 0 and Tertiary Creep, Acta. Met., 30: 17-27.
20. Dyson, B.F., Verma, A.K. and Szkopiak, Z.C. (1981). The Influence of Stress State on Creep Resistance: Experimentation and Modeling, Acta Met., 29: 1573-1580.
21. Gelin, J.C. (1998). Modelling of Damage in Metal Forming Processes, J. of Materials Proc. Tech., 80-81: 24-32.
22. Gurson, A.L. (1977). Continuum Theory of Ductile Rupture by Void Nucleation and Growth: Part-I yield Criteria and Flow Rule for Porous Ductile Metals, J. Eng. Mat. & Tech., 99: 2-15.
23. Hayhurst, D.R. (1972). Creep Rupture under Multi-axial States of Stress, J. Mech. Phys. Solids, 20: 381-390.
24. Hayhurst, D.R., Dyson, B.R. and Lin, J. (1994). Breakdown of the Skeletal Stress Technique for Lifetime Prediction of Notched Tension Bars due to Creep Crack Growth, Engineering Fracture Mechanics, 49(5): 711-726.
25. Ibijola, E.A. (2002). On Some Fundamental Concepts of Continuum Damage Mechanics, Computer Methods in Applied Mechanics and Engineering, 191: 1505-1520.
26. Kachanov, L.M. (1958). The Theory of Creep, Kennedy A.J. (ed., English Translation), National Lending Library, Boston Spa.
27. Khaleel, M.A., Zbib, H.M. and Nyberg, E.A. (2001). Constitutive Modelling of Deformation and Damage in Superplastic Materials, Int. J. of Plasticity, 17: 277-296.
28. Kim, J.S., Kim, J.H., Lee, Y.T. Park, C.G. and Lee, C.S. (1999). Microstructural Analysis on Boundary Sliding and its Accommodation Mode during Superplastic Deformation Ti-6AL-4V Alloy, Materials Science and Engineering, A263: 272-280.
29. Krajcinovic, D. (2000). Damage Mechanics: Accomplishments, Trends and Needs, J. of Solids and Structures, 37: 267-277.
30. Leckie, F.A. and Hayhurst, D.R. (1977). Constitutive Equations for Creep Rupture, Acta Metallurgica, 25: 1059-1070.
31. Lemaitre, J. (1984). How to use Damage Mechanics, Nuclear Engineering and Design, 80: 233-235.
32. Lemaitre, J. and Chaboche, J.L. (1990). Solid Mechanics, Press Syndicate of the University of Cambridge, Cambridge, UK.
33. Li, Z.H., Bilby, B.A. and Howard, I.C. (1994). A Study of the Internal Parameters of Ductile Damage Theory, Fatigue Fract. Engng. Mater. Struct., 17(9): 1075-1087.
34. Li, B., Lin, J. and Yao, X. (2002). A Novel Evolutionary Algorithm for Determining Unified Creep Damage Constitutive Equations, Int. J. of Mech. Sci., 44: 987-1002.
35. Lin, J., Cheong, B.H. and Yao, X. (2002). Universal Multi-objective Function for Optimizing Superplastic Damage Constitutive Equations, J. of Materials Proc. Tech., 125-126: 199-205.
36. Lin, J. and Dunne, F.P.E. (2001). Modelling Grain Size Evolution and Necking in Superplastic Blow-forming, Int. J. of Mech. Sci., 43: 595-609.
37. Lin, J., Dunne, F.P.E. and Hayhurst, D.R. (1999). Aspects of Testpiece Design Responsible for Errors in Cyclic Plasticity Experiments, Int. J. of Damage Mechanics, 8(2): 109-137.
38. Lin, J., Hayhurst, D.R. and Dyson, B.F. (1993). The Standard Ridges Uniaxial Testpiece: Computed Accuracy of Creep Strain, J. of Strain Analysis, 28(2): 101-115.
39. Lin, J., Kowalewski, Z.L. and Cao, J. (2003). Modelling of Effects of Stress-states on Creep Damage for Copper and Aluminium Alloy, Dislocations, Plasticity and Metal Forming (Editor A.S. Khan), Neat Press, Maryland, USA. pp. 142-144.
40. Mabuchi, M. and Higashi, K. (1999). On accommodation of helper mechanism for superplasticity in Metal Matrix Composites, Acta Mater., 47(6): 1915-1922.
41. Othman, A.M., Hayhurst, D.R. and Dyson, B.F. (1993). Skeletal, Tertiary Creep in Circumferentially Notched Tension Bars undergoing Tertiary Creep Modelled with Physically-based Constitutive Equations, Pro. R. Soc. Lond., 441: 345-358.
42. Pervezentsev, V.N., Rybin, V.V. and Chuvil'deev, V.N. (1992). Overview No. 97: The Theory of Structural Superplasticity - I: the Physical Nature of the Superplasticity Phenomenon, Acta Metallurgica Materiallia, 40(5): 887-894.
43. Pilling, J. (1985). Effect of Coalescence on Cavity Growth During Superplastic Deformation, Materials Science and Technology, 1: 461-465.
44. Rabotnov, Y.N. (1969). In: Creep Problems in Structural Members, North Holland Publishing Company, Amsterdam.
45. Raj, R. and Ashby, M.F. (1975). Intergranular Fracture at Elevated Temperatures, Acta Metallurgica, 23: 653-666.
46. Rice, R.J. and Tracey, D.M. (1969). On the Ductile Enlargement of Voids in Triaxial Stress Fields, J. Mech. Phys. Solids, 17: 201-217.
47. Ridley, N. (1989). Cavitations and Superplasticity, In Superplasticity, AGARD Lecture Series No. 168, Essex: Specialised Printing Services Limited, pp. 4.1-4.14.
48. Semiatin, S.L., Seetharaman, V., Ghosh, A.K., Shell, E.B., Simon d, M.P. and Fagin, P.N. (1998). Cavitation during Hot Tension Testing of Ti-6Al-4V, Materials Science and Engineering, A256:92-110.
49. Socha, G. (2003). Experimental Investigations of Fatigue Cracks Nucleation, Growth and Coalescence in Structural Steel, Int. J. of Fatigue, 25: 139-147.
50. Staub, C.J. and C. Boyer, (1996). An Orthotropic Damage Model for Visco-plastic Materials, J. of Materials Processing Technology, 60: 297-304.
51. Thomason, P.F. (1990). In: Ductile Fracture of Metals, Pergamon Press, UK.
52. Tvergaard, V. (1990). Material Failure by Void Growth to Coalescence, Adv. App. Mech., 27: 83-147.
53. Vetrano, J.S., Simonen, E.P. and Bruemmer, S.M. (1999). Evidence for Excess Vacancies at Sliding Grain Boundaries During Superplastic Deformation, Acta Metallia, 47(15): 4125-4149.
54. Zhang, P. and Lee, H. (1993). Creep Damage and Fracture at High Temperature, Eng. Fract. Mech., 44(2): 283-288.
55. Zheng, M. Hu, C., Luo, Z.J. and Zheng, X. (1996). A Ductile Damage Model Corresponding to the Dissapation of Ductility of Metal, Engineering Fracture Mechanics, 53 (4): 653-659.