Effect of microstructural architecture on flow/damage surfaces for metal matrix composites

Studies in Applied Mechanics

Volumn 46, Issue C, 1998, Pages 385-400

  Lissenden, Cliff J ^a   Arnold, Steven M ^b  

^a The Pennsylvania State University   (United States)

^b NASA GLENN RESEARCH CENTER   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

EID: 77957036357     PISSN: 09225382     EISSN: None     Source Type: Book Series    
DOI: 10.1016/S0922-5382(98)80054-8     Document Type: Article

References (17)

1. Aboudi J. Mechanics of Composite Materials: a unified micromechanical approach (1992), Elsevier, Amsterdam
2. Aboudi J. Micromechanical analysis of thermo-inelastic multiphase short-fiber composites. Composites Eng. Vol. 5 (1995) 839-850
3. Arnold S.M., Pindera M.-J., and Wilt T.E. Influence of fiber architecture on the inelastic response of metal matrix composites. Int. J. Plasticity Vol. 12 (1996) 507-545
4. Arnold S.M., Saleeb A.F., and Castelli M.G. A fully associative, nonisothermal, nonlinear kinematic, unified viscoplastic model for titanium based matrices. In: Verrilli M.J., and Castelli M.G. (Eds). Thermomechanical Fatigue Behavior of Materials: Second Volume, ASTM-STP 1263 (1996), American Society for Testing and Materials, Philadelphia 146-173
5. Arnold S.M., Saleeb A.F., and Castelli M.G. A fully associative, nonlinear kinematic, unified viscoplastic model for titanium based matrices. In: Johnson W.S., Larsen J.M., and Cox B.N. (Eds). Life Prediction Methodology for Titanium Matrix Composites, ASTM-STP 1253 (1996), American Society for Testing and Materials, Philadelphia 231-256
6. Brockenbrough J.R., Suresh S., and Wienecke H.A. Deformation of metal-matrix composites with continuous fibers: geometrical effects of fiber distribution and shape. Acta Metall. Mater. Vol. 39 (1991) 735-752
7. Drucker D.C. Relation of experiments to mathematical theories of plasticity. J. Appl. Mech. Vol. 16 (1949) A349-A357
8. HKS. ABAQUS/Standard User's Manual Version 5.5 (1995), Hibbitt, Karlsson, and Sorensen, Inc., Pawtucket
9. in press. Lissenden C.J., and Arnold S.M. Theoretical and experimental considerations in representing macroscale flow/damage surfaces for metal matrix composites. Int. J. Plasticity (1997)
10. Paper No. 38. Lissenden C.J., and Arnold S.M. Factors influencing inelastic flow under multiaxial stress states: a perspective of their importance to composites. HITEMP Review 1997 Advanced High Temperature Engine Materials Technology Program, NASA CP-10192 (1997), NASA Lewis Research Center, Cleveland
11. Lissenden C.J., and Herakovich C.T. Numerical modelling of damage development and viscoplasticity in metal matrix composites. Comput. Methods Appl. Mech. Engng. Vol. 126 (1995) 289-303
12. Majumdar B.S., and Newaz G.M. Inelastic deformation of metal matrix composites: plasticity and damage mechanisms. Phil. Mag. A Vol. 66 (1992) 187-212
13. Nigam H., Dvorak G.J., and Bahei-El-Din Y.A. An experimental investigation of elastic-plastic behavior of a fibrous boron-aluminum composite: I. matrix-dominated mode. Int. J. Plasticity Vol. 10 (1994) 23-48
14. Paley M., and Aboudi J. Micromechanical analysis of composites by the generalized cells model. Mech. Mater. Vol. 14 (1992) 127-139
15. Pindera M.-J., and Aboudi J. Micromechanical analysis of yielding of metal matrix composites. Int. J. Plasticity Vol. 4 (1988) 195-214
16. Robinson D.N., and Ellis J.R. A multiaxial theory of viscoplasticity for isotropic materials. Proc. Turbine Engine Hot Section Technology, NASA CP-2444 (1986), NASA Lewis Research Center, Cleveland 283-292
17. NASA TM-107290. Wilt T.E., and Arnold S.M. Micromechanics analysis code (MAC) User Guide: version 2.0 (1996), NASA Lewis Research Center, Cleveland