Abstract
The failure process in waisted tensile specimens of pultruded 60% volume fraction carbon fibre-epoxide was investigated at atmospheric and superposed hydrostatic pressures up to 300 MN m−2. The maximum principal stress at fracture decreased from ~ 2.0 GN m−2 at atmospheric pressure to ~ 1.5 GN m−2 by 200 MN m−2 superposed pressure and then remained approximately constant. These latter failures were fairly flat and no damage preceding the catastrophic fracture was detected, which indicates that composite strength is solely controlled by fibre strength. Fracture of fibres at lower pressures appeared to commence also in the range 1.5 to 1.6 GN m−2, but, as it did not result in catastrophic failure, account has to be taken of the resin and the fibre bundles. Debonding was initiated at ~ 1.2 GN m−2 at atmospheric pressure and this stress increased to ~ 1.5 GN m−2 when 150 MN m−2 superposed pressure was applied; the pressure dependence was related to that of the resin tensile strength. This process is described as the first stage, straightening and debond initiation of curved surface bundles, on our model of tensile failure. The second stage, delamination, i.e. the growth of transverse cracks leading to the detachment of these bundles, was impeded by the transverse pressure, being suppressed beyond 150 MN m−2. Only below this pressure was load redistribution between bundles possible, but, as the pressure was increased from atmospheric, it become more difficult, resulting in a decrease in the composite tensile strength and reduced fibre pull-out.
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Parry, T.V., Wronski, A.S. The effect of hydrostatic pressure on the tensile properties of pultruded CFRP. J Mater Sci 20, 2141–2147 (1985). https://doi.org/10.1007/BF01112298
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DOI: https://doi.org/10.1007/BF01112298