Saturated out-of-plane permeability and deformation metrology of textiles at high levels of injection pressure

Out-of-plane impregnation and high levels of injection pressure are key strategies for cycle time reduction in Liquid Composite Molding processes. The combination of these two strategies provides a promising approach for large volume production of automotive components. In this context, a novel test...

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Veröffentlicht in:	Advanced manufacturing. Polymer & composites science 2022-04, Vol.8 (2), p.97-101
Hauptverfasser:	Willenbacher, Bjoern, May, David, Mitschang, Peter
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Sprache:	eng
Schlagworte:	Automotive parts compaction Cycle time Fiber volume fraction Flow velocity Fluid dynamics Fluid flow Folding hydrodynamic Liquid composite molding Permeability textile Textiles
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container_title	Advanced manufacturing. Polymer & composites science
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creator	Willenbacher, Bjoern May, David Mitschang, Peter
description	Out-of-plane impregnation and high levels of injection pressure are key strategies for cycle time reduction in Liquid Composite Molding processes. The combination of these two strategies provides a promising approach for large volume production of automotive components. In this context, a novel test system is presented, which allows the textile reaction characterization to saturated out-of-plane fluid flow at injection pressure levels of up to 200 bar. For any given engineering textile, the resulting out-of-plane permeability and total hydrodynamic compaction can be measured for different combinations of initial fiber volume content, number of layers and injection pressure. Initial tests on a conventional non-crimp fabric show a compaction-induced out-of-plane permeability decrease for pressure levels up to 95 bar, while for pressure levels between 95 and 170 bar the permeability remains constant. In other words above 95 bar, a further increase in pressure directly pays off in terms of increased flow rate. The identification of such processing windows can be very valuable for process design.
doi_str_mv	10.1080/20550340.2022.2064070
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subjects	Automotive parts compaction Cycle time Fiber volume fraction Flow velocity Fluid dynamics Fluid flow Folding hydrodynamic Liquid composite molding Permeability textile Textiles
title	Saturated out-of-plane permeability and deformation metrology of textiles at high levels of injection pressure
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