Lc. Pardini et B. Mcenaney, EFFECTS OF FIBER SURFACE-TREATMENT ON FRACTURE AND ACOUSTIC-EMISSION FROM SINGLE AND HYBRID CFRC, Carbon, 32(5), 1994, pp. 815-824
Two classes of unidirectional carbon fibre reinforced carbon composite
s (CFRC) with resin carbon matrix and heat-treated to 1100 and 2500-de
grees-C were manufactured by using PAN-based carbon fibres with contra
sting surface activities; a third class of hybrid, unidirectional CFRC
, was made from alternating laminae containing the fibres with differe
nt surface activities. The CFRC were subject to flexural loading with
acoustic emission (AE) monitoring. For the 1100-degrees-C CFRC-contain
ing surface-treated fibres, there was brittle failure, whereas failure
of CFRC with untreated fibres was dominated by fibre bundle sliding.
The flexural strength of the hybrid CFRC was greater than that of the
other two composites. For the CFRC with surface-treated fibres, there
was a substantial increase in flexural strength on heat treatment to 2
500-degrees-C and a tougher failure mode; for the CFRC with untreated
fibres, there was a reduction in flexural strength on heat treatment t
o 2500-degrees-C but no change in the failure mode; these changes were
related to stress graphitisation at the fibre/matrix interface. The f
lexural strength of the hybrid CFRC lay between those for the other tw
o composites. Analysis of AE event counts and AE amplitude distributio
ns supported these interpretations of the deformation and flexural fai
lure of the three types of composite. The development of hybrid compos
ites containing different carbon fibre types seems to be a promising r
oute for controlling properties of CFRC.