Recent experimental studies of the hot isostatic consolidation of Ti-6Al-4V
-coated SiC fibers contained in cylindrical canisters have revealed an unex
pectedly high rate of creep densification. A creep consolidation model has
been developed to analyze its origin. The initial stage of consolidation ha
s been modeled using the results of contact analyses for perfectly plastic
and power-law creeping cylinders that contain an elastic ceramic core. Fina
l stage densification was modeled using a creep potential for a power-law m
aterial containing a dilute concentration of cusp-shaped voids with a shape
factor similar to that observed in the experiments. Creep rates were micro
structure sensitive and so the evolution of matrix grain size and the tempe
rature dependence of the alpha/beta-phase volume fractions were introduced
into the model using micromechanics-based creep constitutive relationships
for the matrix. To account for load shielding by the deformation resistant
canister, the consolidation model was combined with an analysis of the cree
p collapse of a fully dense pressure vessel. The predicted densification ra
tes were found to agree well with the experimental observations. The high d
ensification rate observed in experiments was the result of the small initi
al grain size of the vapor-deposited matrix combined with retention of the
cusp shape of the interfiber pores.