Time Dependent Behavior of Continuous Fiber Reinforced Metal Matrix Composites: Modeling and Applications

Volume 16, Issue 4 (October 1994)

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ISSN: 0884-6804
CODEN: JCTRER
Page Count: 9

Time-Dependent Behavior of Continuous-Fiber-Reinforced Metal Matrix Composites: Modeling and Applications
Zheng, D
University of Rhode Island, RI

Ghonem, H
University of Rhode Island, RI

Tamin, MN
University of Rhode Island, RI

Abstract

A time-dependent approach employing a four-phase concentric cylinder model has been developed to predict the response of metal matrix composites (MMCs) subjected to thermomechanical loadings in which both plastic and creep responses of the composites are considered. The progressive development of plasticity in the matrix phase is determined using the deformation theory of plasticity while the creep deformation of this phase is estimated using the Bailey-Norton equation with an Arrhenius-type expression for the time-dependent creep coefficient. The model is applied to SCS-6/Ti-β21S composite to study the evolution of the stress and strain states in the constituents of the composite during initial cool-down and subsequent thermal cycles. The model is then employed to examine the influence of several critical parameters on the composite internal stress and strain states. These parameters include the thickness of the equivalent composite media, the type of fiber coating material, the thickness of the reaction zone, cooling rate during initial cool-down, and the kinetics of creep process during thermal cyclic loading. Results of these applications indicated that the process-induced thermal stresses in the matrix phase can be relaxed due to creep following initial cool-down from fabrication. This stress reduction is enhanced at a slower cooling rate. Comparison of different fiber coating materials shows that the use of carbon coating induces compressive stress state in the brittle interfacial region. TiB²-coated fibers, however, are found to be less affected by the growing interphase thickness in preserving the compressive radial stress component in the matrix and the interphase zone. Furthermore, it is found that the matrix activation energy for creep, Q, is history-dependent and can be correlated with the level of creep strain accumulated in the matrix phase. In addition, the residual thermal stresses induced in the matrix phase during initial cool-down can be relaxed by the application of subsequent thermal cycles.

Keywords:
residual stress, metal matrix composite (MMC), interfacial region, coefficient of thermal expansion (CTE), activation energy, creep, plastic deformation

Paper ID: CTR10591J
DOI: 10.1520/CTR10591J
ASTM International is a member of CrossRef.

Author Title Time-Dependent Behavior of Continuous-Fiber-Reinforced Metal Matrix Composites: Modeling and Applications Symposium , 0000-00-00 Committee D30

		SEDL / Journal of Composites Technology and Research (JCTR) / Citation Page Volume 16, Issue 4 (October 1994) Click here to download this paper now for $25 PDF (288K) View License Agreement ISSN: 0884-6804 CODEN: JCTRER Page Count: 9 Time-Dependent Behavior of Continuous-Fiber-Reinforced Metal Matrix Composites: Modeling and Applications Zheng, D University of Rhode Island, RI Ghonem, H University of Rhode Island, RI Tamin, MN University of Rhode Island, RI Abstract A time-dependent approach employing a four-phase concentric cylinder model has been developed to predict the response of metal matrix composites (MMCs) subjected to thermomechanical loadings in which both plastic and creep responses of the composites are considered. The progressive development of plasticity in the matrix phase is determined using the deformation theory of plasticity while the creep deformation of this phase is estimated using the Bailey-Norton equation with an Arrhenius-type expression for the time-dependent creep coefficient. The model is applied to SCS-6/Ti-β21S composite to study the evolution of the stress and strain states in the constituents of the composite during initial cool-down and subsequent thermal cycles. The model is then employed to examine the influence of several critical parameters on the composite internal stress and strain states. These parameters include the thickness of the equivalent composite media, the type of fiber coating material, the thickness of the reaction zone, cooling rate during initial cool-down, and the kinetics of creep process during thermal cyclic loading. Results of these applications indicated that the process-induced thermal stresses in the matrix phase can be relaxed due to creep following initial cool-down from fabrication. This stress reduction is enhanced at a slower cooling rate. Comparison of different fiber coating materials shows that the use of carbon coating induces compressive stress state in the brittle interfacial region. TiB²-coated fibers, however, are found to be less affected by the growing interphase thickness in preserving the compressive radial stress component in the matrix and the interphase zone. Furthermore, it is found that the matrix activation energy for creep, Q, is history-dependent and can be correlated with the level of creep strain accumulated in the matrix phase. In addition, the residual thermal stresses induced in the matrix phase during initial cool-down can be relaxed by the application of subsequent thermal cycles. Keywords: residual stress, metal matrix composite (MMC), interfacial region, coefficient of thermal expansion (CTE), activation energy, creep, plastic deformation Paper ID: CTR10591J DOI: 10.1520/CTR10591J ASTM International is a member of CrossRef. Author Title Time-Dependent Behavior of Continuous-Fiber-Reinforced Metal Matrix Composites: Modeling and Applications Symposium , 0000-00-00 Committee D30