A Morphology-Based Model to Describe the Low-Temperature Impact Behaviour of Rubber-Toughened Polypropylene

The roles of the rubber particle size, the rubber particle size distribution and the constitutive behaviour of the isotactic polypropylene matrix have been studied by combining the Lazerri–Bucknall energy criterion for cavitation with the Van der Sanden–Meier–Tervoort ligament model adapted for impa...

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Veröffentlicht in:	Polymers 2021-07, Vol.13 (13), p.2218
Hauptverfasser:	Deblieck, Rudy, Remerie, Klaas, Van den Fonteyne, Winke, Boerakker, Mark
Format:	Artikel
Sprache:	eng
Schlagworte:	Cavitation Crack propagation Energy Impact strength Ligaments Low temperature Mechanical properties Morphology Particle size Particle size distribution Polymers Polypropylene Rubber Scanning electron microscopy Stiffness Stress state Yield stress
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container_title	Polymers
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description	The roles of the rubber particle size, the rubber particle size distribution and the constitutive behaviour of the isotactic polypropylene matrix have been studied by combining the Lazerri–Bucknall energy criterion for cavitation with the Van der Sanden–Meier–Tervoort ligament model adapted for impact conditions. It is concluded that an optimised morphology offers great potential to achieve enhanced mechanical properties with far less rubber and hence achieve a superior stiffness/toughness/processing balance.
doi_str_mv	10.3390/polym13132218
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subjects	Cavitation Crack propagation Energy Impact strength Ligaments Low temperature Mechanical properties Morphology Particle size Particle size distribution Polymers Polypropylene Rubber Scanning electron microscopy Stiffness Stress state Yield stress
title	A Morphology-Based Model to Describe the Low-Temperature Impact Behaviour of Rubber-Toughened Polypropylene
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