Thermomechanical environment characterisation in injection moulding and its relation to the mechanical properties of talc-filled polypropylene

Thermomechanical environment characterisation in injection moulding and its relation to the mechanical properties of talc-filled polypropylene

This study is focused on the establishment of relationships between the injection moulding processing conditions, the applied thermomechanical environment (TME) and the tensile properties of talc-filled polypropylene, adopting a new extended concept of thermomechanical indices (TMI). In this approac...

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Bibliographic Details
Published in:Journal of materials science Vol. 48; no. 6; pp. 2597 - 2607
Main Authors: Barbosa, Carlos N., Simoes, Ricardo, Franzen, Markus, Viana, Júlio C.
Format: Journal Article
Language:English
Published: Boston Springer US 01-03-2013
Springer
Springer Nature B.V
Subjects:
Breaking
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Computer simulation
Crystallography and Scattering Methods
Design of experiments
Filling
Flow rate
Flow velocity
Injection molding
Materials Science
Mechanical analysis
Mechanical properties
Melt temperature
Modulus of elasticity
Molding (process)
Moldings
Morphology
Orthogonal arrays
Parameters
Polymer Sciences
Polypropylene
Polypropylenes
Solid Mechanics
Strain
Talc
Tensile properties
Thermomechanical properties
Variance analysis
Wall temperature
Yield stress
Filling Stage
Injection Flow Rate
Injection Moulding
Bulk Temperature
Mould Temperature
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Summary:This study is focused on the establishment of relationships between the injection moulding processing conditions, the applied thermomechanical environment (TME) and the tensile properties of talc-filled polypropylene, adopting a new extended concept of thermomechanical indices (TMI). In this approach, TMI are calculated from computational simulations of the moulding process that characterise the TME during processing, which are then related to the mechanical properties of the mouldings. In this study, this concept is extended to both the filling and the packing phases, with new TMI defined related to the morphology developed during these phases. A design of experiments approach based on Taguchi orthogonal arrays was adopted to vary the injection moulding parameters (injection flow rate, injection temperature, mould wall temperature and holding pressure), and thus, the TME. Results from analysis of variance for injection-moulded tensile specimens have shown that among the considered processing conditions, the flow rate is the most significant parameter for the Young’s modulus; the flow rate and melt temperature are the most significant for the strain at break; and the holding pressure and flow rate are the most significant for the stress at yield. The yield stress and Young’s modulus were found to be governed mostly by the thermostress index (TSI, related to the orientation of the skin layer), whilst the strain at break depends on both the TSI and the cooling index (CI, associated to the crystallinity degree of the core region). The proposed TMI approach provides predictive capabilities of the mechanical response of injection-moulded components, which is a valuable input during their design stage.
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ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-012-7052-4