Polypropylene/cycloolefin copolymer blends: effects of fibrous phase structure on tensile mechanical properties

Abstract

Tensile mechanical properties of polypropylene (PP)/cycloolefin copolymer (COC) blends were studied using an Instron tensile tester. As COC was expected to impart enhanced mechanical properties to the blends, their modulus, yield strength, tensile strength and tensile energy to break were measured as functions of blend composition. With regard to the reported sensitivity of the COC structure to thermal history, the influence of annealing at two different temperatures was also tested. The attention was primarily concentrated on blends with the volume fraction of COC in the interval 0< v 2<0.40, where COC formed (short) fibres almost uniaxially oriented in the direction of injection moulding. In the interval 0.40< v 2<0.75, the blends consisted of partially co-continuous components. Two different models were applied in the analysis of mechanical properties, namely (i) the rule of mixtures for fibre composites and (ii) the equivalent box model for isotropic blends (employing the data on the phase continuity of components obtained from modified equations of the percolation theory). Experimental data on the studied mechanical properties were better fitted by the models for fibre composites. Annealing of the samples (75 °C for 45 days; 120 °C for 3 h) did not markedly affect the tensile modulus, yield stress, and stress at break of the blends. On the other hand, the strain at break was markedly reduced by the annealing up to v 2=0.2; COC and the blend with 75% of COC ruptured in a brittle manner without yielding.