Load separation principle in determination of J‐R curve for ductile polymers: Suitability of different material deformation functions used in the normalization method

The load separation principle states that the load, P , can be represented as the multiplication of two independent functions: A crack geometry function, G(a) , and a material deformation function, H(v) . The principle constitutes the theoretical basis for the single‐specimen J ‐integral experiment and the incremental calculation of J ‐integral crack growth resistance ( J‐R ) curves. The normalization method is a new method, which assumes load separation and uses characteristic deformation properties of materials to relate load, displacement and crack length in a functional form. From the deformation material function or “material key curve”, J‐R curve can be developed from a single precracking experiment. This investigation deals with the applicability of the load separation criterion to evaluation of ductile fracture mechanics parameters in rubber‐modified polystyrene, polypropylene, rubber‐modified PMMA, ABS resin and high‐density polyethylene in the bending configuration. Different mathematical relationships for the deformation function (power law function, LMN function and combined power law straight line relationship) have been proposed and compared. The resulting J‐R curves are in good agreement with those obtained by the traditional multiple‐specimen technique. The results presented here imply that the use of a single load‐displacement method for evaluation of J ‐integrals for ductile polymers is possible and hence also the normalization method can be used for evaluation of J‐R curves from a single‐test record.