High temperature and long duration applications of monolithic ceramics can place their failure mode in the creep rupture regime. A previous model advanced by the authors described a methodology by which the creep rupture life of a loaded component can be predicted. That model was based on the life fraction damage accumulation rule in association with the modified Monkman-Grant creep rupture criterion. However, that model did not take into account the deteriorating state of the material due to creep damage (e.g., cavitation) as time elapsed. In addition, the material creep parameters used in that life prediction methodology, were based on uniaxial creep curves displaying primary and secondary creep behavior, with no tertiary regime. The objective of this paper is to present a creep life prediction methodology based on a modified form of the Kachanov-Rabotnov continuum damage mechanics (CDM) theory. In this theory, the uniaxial creep rate is described in terms of stress, temperature, time, and the current state of material damage. This scalar damage state parameter is basically an abstract measure of the current state of material damage due to creep deformation. The damage rate is assumed to vary with stress, temperature, time, and the current state of damage itself. Multiaxial creep and creep rupture formulations of the CDM approach are presented in this paper. Parameter estimation methodologies based on nonlinear regression analysis are also described for both, isothermal constant stress states and anisothermal variable stress conditions. This creep life prediction methodology was preliminarily added to the integrated design code named Ceramics Analysis and Reliability Evaluation of Structures/Creep (CARES/Creep), which is a postprocessor program to commercially available finite element analysis (FEA) packages. Two examples, showing comparisons between experimental and predicted creep lives of ceramic specimens, are used to demonstrate the viability of this methodology and the CARES/Creep program.

1.
Boyle, J., and Spence, J., 1983, Stress Analysis for Creep, Butterworth & Co., London.
2.
Dunne
F. P. E.
,
Othamn
A. M.
,
Hall
F. R.
, and
Hayhurst
L. M.
,
1990
, “
Representation of Uniaxial Creep Curves Using Continuum Damage Mechanics
,”
International Journal of Mechanical Science
, Vol.
32
, No.
11
, pp.
945
957
.
3.
Ferber, M. K., and Jenkins, M. G., 1992, “Empirical Evaluation of Tensile Creep and Creep Rupture in a HIPed Silicon Nitride,” in Creep: Characterization, Damage and Life Assessment, ASM International Woodford, D. A., Townley, C. H. A., and Ohnami, M., eds., pp. 81–90.
4.
Foley, M., Rossi, G., Sundberg, G., Wade, J., and Wu, F., 1992, “Analytical and Experimental Evaluation of Joining Silicon Carbide to Silicon Carbide and Silicon Nitride to Silicon Nitride for Heat Engine Applications,” final report, Ceramic Technology for Advanced Heat Engines, Oak Ridge National Lab.
5.
French
J. D.
, and
Wiederhorn
S. M.
,
1996
, “
Tensile Specimens from Ceramic Components
,”
Journal of the American Ceramic Society
, Vol.
79
, No.
2
, pp.
550
552
.
6.
Hales, R., 1988, “Physical Mechanisms of Fracture in Combined Creep and Fracture,” Proceedings, Inst. Metals Conference on Materials and Engineering Design, London.
7.
Hault, J., 1987, “Introduction and General Overview,” Continuum Damage Mechanics Theory and Applications, D. Krajcinovic, and J. Lemaitre, eds., Springer Verlag, New York.
8.
Hayhurst
D. R.
,
Dimmer
P. R.
, and
Cheruka
M. W.
,
1975
, “
Estimates of the Creep Rupture Lifetime of Structures Using the Finite Element Method
,”
Journal of Mechanical Physics of Solids
, Vol.
23
, pp.
335
355
.
9.
Hayhurst
L. M.
,
Dimmer
P. R.
, and
Morrison
C. J.
,
1984
a, “
Development of Continuum Damage in the Creep Rupture of Notched Bars
,”
Phil. Trans. R. Soc. Lond.
, Vol.
311
, pp.
103
129
.
10.
Hayhurst
L. M.
,
Brown
P. R.
, and
Morrison
C. J.
,
1984
b, “
The Role of Continuum Damage in Creep Crack Growth
,”
Phil. Trans. R. Soc. Lond.
, Vol.
311
, pp.
131
158
.
11.
Hazime, R. M., and White, C. S., 1996, “An Internal Variable, Creep Damage Model of a Silicon Nitride,” submitted for publication in Materials Science and Engineering.
12.
Jadaan, O. M., Powers, L. M., and Gyekenyesi, J. P., 1997, “Creep Life Prediction of Ceramic Components Subjected to Transient Tensile and Compressive Stress States,” ASME Paper 97-GT-319.
13.
Kachanov, L. M., 1958, “On Creep Rupture Time,” Izv. Acad. Nauk SSSR, Otd. Tech. Nauk, No. 8.
14.
Kachanov, L. M., 1986, Introduction to Continuum Damage Mechanics, MartinusNijhof, Boston.
15.
Kraus, H., 1980, Creep Analysis, John Wiley and Sons Inc., New York.
16.
Leckie
F. A.
,
Hayhurst
L. M.
,
1977
, “
Constitutive Equations for Creep Rupture
,”
Acta Metallurgica
, Vol.
25
, pp.
1059
1070
.
17.
Luecke
W. E.
, and
Wiederhorn
S. M.
,
1997
, “
Interlaboratory Verification of Silicon Nitride Tensile Creep Properties
,”
Journal of the American Ceramic Society
, Vol.
80
, No.
4
, pp.
831
838
.
18.
Menon
M.
,
Fang
H.
,
Wu
D.
,
Jenkins
M.
, and
Ferber
M.
,
1994
, “
Creep and Stress Rupture Behavior of an Advanced Silicon Nitride: Part III, Stress Rupture and Monkman-Grant Relationships
,”
Journal of the American Ceramic Society
, Vol.
77
, pp.
1235
1241
.
19.
Miner
M. A.
,
1945
, “
Cumulative Damage in Fatigue
,”
ASME Journal of Applied Mechanics
, Vol.
12
, pp.
A159–A164
A159–A164
.
20.
Monkman
F.
, and
Grant
N.
,
1956
, “
An Empirical Relationship Between Rupture Life and Minimum Creep Rate in Creep-Rupture Test
,”
Proceedings, American Society for Testing and Materials
, Vol.
56
, pp.
593
620
.
21.
Norton, F., 1929, The Creep of Steel at High Temperatures, McGraw-Hill, New York.
22.
Othman
A. M.
, and
Hayhurst
L. M.
,
1990
, “
Multi-Axial Creep Rupture of a Model Structure Using a Two Parameter Material Model
,”
International Journal of Mechanical Science
, Vol.
32
, No.
1
, pp.
35
48
.
23.
Penny, R. K., and Marriott, D. L., 1995, Design for Creep, Chapman & Hall, London.
24.
Powers, L. M., Jadaan, O. M., and Gyekenyesi, J. P., 1996, “Creep Life of Ceramic Components Using a Finite Element Based Integrated Design Program (CARES/Creep),” ASME Paper 96-GT-369.
25.
Press, W. H., Flannery, B. P., Teukolsky, S. A., and Vetterling, 1989, Numerical Recipes, Cambridge University Press, Cambridge.
26.
Rabotonov, Yu. N., 1969, Creep Problems in Structural Members, North-Holland, Amsterdam.
27.
Robinson, E. L., 1952, “Effect of Temperature Variation on the Long-Time Rupture Strength of Steels,” Trans. ASME 74, pp. 777–780.
28.
Stamm, H., and von Estorff, U., 1992, “Determination of Creep Damage in Steels,” Proceedings, 5th International Conference on Creep of Materials, FL.
29.
Sundberg, G., Vartabedian, A., Wade, J., and White, C., 1994, “Analytical and Experimental Evaluation of Joining Silicon Carbide to Silicon Carbide and Silicon Nitride to Silicon Nitride for Advanced Heat Engine Applications Phase II,” final report, Ceramic Technology Project, Oak Ridge National Lab.
30.
Todd
J. A.
, and
Xu
A.-Y.
,
1989
, “
The High Temperature Creep Deformation of Si3N4-6Y2O3-2Al2O3
,”
Journal of Materials Science
, Vol.
24
, pp.
4443
4452
.
31.
Wade, J., White, C., and Wu, F., 1994, “Predicting Creep Behavior of Silicon Nitride Components Using Finite Element Techniques,” in Life Prediction Methodologies and Data for Ceramic Materials, ASME STP 1201, C. Brinkman, and S. Duffy, eds., American Society for Testing and Materials, Philadelphia, PA, pp. 360–372.
32.
White
C.
,
Vartabedian
A.
,
Wade
J.
, and
Tracey
D.
,
1995
, “
Notched Tensile Creep Testing of Ceramics
,”
Materials Science and Engineering
, Vol.
A203
, pp.
217
221
.
33.
Wiederhorn, S., Quinn, G., and Krause, R., 1994, “Fracture Mechanism Maps: Their Applicability to Silicon Nitride,” Life Prediction Methodologies and Data for Ceramic Materials, ASTM STP-1201, C. R. Brinkman, and S. F. Duffy, eds., American Society for Testing and Materials, Philadelphia, PA, pp. 36–61.
34.
Zamrik, S. Y., and Davis, D. C, 1990, “A Ductility Exhaustion Approach for Axial Fatigue-Creep Damage Assessment Using Type 316 Stainless Steel,” ASME PVP 215.
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