Creep behavior of rotating discs made of functionally graded materials with linearly varying thickness has been investigated. The discs under investigation are made of composite containing silicon carbide particles in a matrix of pure aluminum. The creep behavior of the composite has been described by threshold stress based creep law by assuming a stress exponent of 5. The effect of imposing linear particle gradient on the distribution of stresses and strain rates in the composite disc has been investigated. The study indicates that with increase in particle gradient in the disc, the radial stress increases throughout the disc, whereas the tangential and effective stresses increase near the inner radius but decrease near the outer radius. The steady state strain rates in the composite disc, having gradient in the distribution of reinforcement, are significantly lower than that observed in a disc having uniform distribution of reinforcement.

1 V. Mises, "Translation of Mechanik der festen koerper im plastisch-deformablem Zustrand Nachrichten von der koniglichen Gasellschaft der Wissenschaften"

2 J. Cadek, "Threshold creep behavior of discontinuous aluminium and aluminium alloy matrix composites: An Overview" 190 : 9-21, 1995

3 M. N. Bayat, "Thermo elastic analysis of a functionally graded rotating disk with small and large deflections" 45 : 677-691, 2005

4 S. A. H. Kordkheili, "Thermo elastic analysis of a functionally graded rotating disk" 79 (79): 508-516, 2007

5 S. P. Timoshenko, "Theory of Elasticity" McGraw-Hill, 1970

6 M. H. Hojjati, "Theoretical and numerical analysis of rotating discs of non-uniform thickness and density" 85 (85): 694-700, 2008

7 R. Lagneborg, "The stress/creep behavior of precipitation-hardened alloys" 10 (10): 20-28, 1976

8 N. S. Bhatnagar, "Steadystate creep of orthotropic rotating disks of variable thickness" 91 (91): 121-144, 1986

9 D. Deepak, "Steady state creep in a rotating composite disc of variable thickness," 101 : 780-786, 2010

10 A. B. Pandey, "Steady state creep behavior of silicon carbide particulate reinforced aluminium composites" 40 : 2045-2052, 1992

11 S. B. Singh, "Steady state creep behavior in an isotropic functionally graded material rotating disc of Al-SiC composite" 32 (32): 1679-1685, 2001

12 V. K. Gupta, "Steady state creep and material parameters in a rotating disc of Al-SiCp composite" 23 : 335-344, 2004

13 R. S. Mishra, "Some observation on the high-temperature creep behavior of 6061 Al-SiC composites" 21 : 2089-2090, 1990

14 B. Farshi, "Optimum design of inhomogeneous rotating discs under secondary creep" 85 : 507-515, 2008

15 B. Farshi, "Optimum design of inhomogeneous non-uniform rotating discs" 82 : 773-779, 2004

16 L. H. You, "On rotating circular disks with varying material properties" 58 : 1068-1084, 2007

17 S. B. Singh, "Modeling the anisotropy and creep in orthotropic aluminum-silicon carbide composite rotating disc" 34 : 363-372, 2002

18 V. K. Gupta, "Modeling of creep behavior of a rotating disc in the presence of both composition and thermal gradients," 127 : 97-105, 2005

19 H. Jahed, "Minimum weight design of inhomogeneous rotating discs" 82 : 35-41, 2005

20 S. C. Tjong, "Microstructural and mechanical characteristics in situ metal matrix composites," 29 : 49-113, 2000

21 "Metals Handbook (vol. 2), in ), American Society of Metals, 9th Ed" Metals Park, Ohio 1978

22 T. G. Nieh, "Mechanical properties of discontinuous SiC reinforced aluminium composites at elevated temperatures," 110 : 77-82, 1988

23 M. Laskaj, "Improving the efficiency of cooling the front disc brake on a V8 racing car" Monash Univ 1999

24 A. B. Pandey, "Hightemperature creep of Al-TiB2 particulate composites" 189 : 95-104, 1994

25 K. T. Park, "High temperature creep of silicon carbide particulate reinforced aluminum" 38 (38): 2149-2159, 1990

26 G. Gonzalez-Doncel, "High temperature creep behavior of metal matrix aluminium-SiC composites," 41 (41): 2797-2805, 1993

27 S. Suresh, "Fundamentals of Functionally Graded Materials, processing and thermomechanical behavior of graded metals and metals-ceramic composites" IOM Communications Limited 1998

28 Y. Orcan, "Elastic-plastic stresses in linearly hardening rotating solid disks of variable thickness" 29 : 269-281, 2002

29 A. N. Eraslan, "Elastic-plastic deformation of a rotating disk of exponentially varying thickness" 34 : 423-432, 2002

30 S. K Gupta, "Creep transition in a thin rotating disc having variable thickness and variable density," 31 (31): 1235-1248, 2000

31 A. M. Wahl, "Creep tests of rotating disks at elevated temperature and comparison with theory," 21 : 225-235, 1954

32 K. T. Park, "Creep strengthening in a discontinuous SiC–Al composite" 26 : 3119-3129, 1995

33 T. G. Nieh, "Creep rupture of a silicon carbide reinforced aluminum composite" 15 : 139-146, 1984

34 Z. Y. Ma, "Creep deformation characteristics of discontinuously reinforced aluminium matrix composites" 61 (61): 771-786, 2001

35 F. A. Mohamed, "Creep behavior of discontinuous SiC–Al composites" 150 : 21-35, 1992

36 Y. Li, "Creep behavior of an Al-6061 metal matrix composite reinforced with alumina particulates" 45 (45): 4797-4806, 1997

37 H. Yoshioka, "Creep behavior of ODS aluminium reinforced by silicon carbide particulates: ODS Al–30 SiCP composite" 248 (248): 65-72, 1998

38 V. K. Gupta, "Artificial neural network modeling of creep behavior in a rotating composite disc, Engineering Computations" 24 (24): 151-164, 2007

39 M. Bayat, "Analysis of functionally graded rotating disks with variable thickness" 35 : 283-309, 2008

40 J. N. Reddy, "Analysis of functionally graded plates" 47 : 663-684, 2000

41 Y. Li, "An investigation of creep behavior in an SiC-2124 Al composite" 45 (45): 4775-4785, 1997

42 Y. Li, "An examination of a substructure- invariant model for the creep of metal matrix composites" 265 : 276-284, 1999

43 T. W. Clyne, "An Introduction to Metal Matrix Composites," Cambridge Univ. Press, 1993