In-plane permeability characterization of engineering textiles based on radial flow experiments: A benchmark exercise

May, David; Aktas, A.; Advani, Suresh G.; Berg, David C.; Endruweit, A.; Fauster, Ewald; Lomov, Stepan Vladimirovitch; Long, A.C.; Mitscháng, Peter; Abaimov, Sergey G.; Abliz, Dilmurat; Akhatov, Iskander; Ali, Muhammad A.; Allen, Tom; Bickerton, Simon; Caglar, Baris; Çağlar, Hakan; Chiminelli, A.; Correia, Nuno; Cosson, B.; Danzi, Mario; Dittmann, Jörg; Ermanni, Paolo; Francucci, Gastón Martín; George, Andrew; Grishaev, Viktor; Hancioglu, M.; Kabachi, Ayyoub; Kind, K.; DELEGLISE-LAGARDERE, M.; Laspalas, Manuel; Lebedev, O. V.; Lizaranzu, M.; Liotier, Pierre‐Jacques; Middendorf, Peter; Morán, Juan Ignacio; Park, Chung; Pipes, R. Byron; Pucci, Monica Francesca; Raynal, J.; Rodríguez, E.; Schledjewski, Ralf; Schubnel, R.; Sharp, Nathan; Sims, G D; Sozer, Emre; Sousa, Pedro J.; Thomas, Jimmy; Umer, Rehan; Wijaya, W.; Willenbacher, Björn; Yong, A.X.H.; Zaremba, S.; Ziegmann, Gerhard

doi:10.1016/j.compositesa.2019.03.006

Cited by 79 publications

(59 citation statements)

References 22 publications

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“…As layups of mats and fabrics resemble the ply configuration in most common LCM processes, several setups for this type of material characterisation can be found in the literature. For permeability characterisation, special moulds have been designed for controlled linear or radial impregnation experiments (see literature 25–27 ). Similarly, for compaction experiments, a conventional universal testing machine can be used to test the compaction behaviour of a layup of fabrics or mats.…”

Section: Introductionmentioning

confidence: 99%

Permeability and compaction behaviour of air-texturised glass fibre rovings: A characterisation study

Sandberg

Kabachi

Volk

et al. 2020

Journal of Composite Materials

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Air-texturisation is a process that adds bulkiness to bundles of fibres. In this study, the permeability and compaction behaviour of air-texturised glass fibre rovings are experimentally characterised and compared to conventional unidirectional rovings. Based on radial impregnation experiments and single-step compaction/decompaction tests, the following main findings are highlighted: Compared to conventional unidirectional-rovings, the normalised permeability of the air-texturised rovings was approximately three times higher along the fibre direction and 40 times higher transverse to the fibre direction. Accordingly, the degree of anisotropy was approximately one magnitude lower. At a compaction pressure of 1 and 5 bar, the air-texturised rovings were compacted to a volume fraction of [Formula: see text] and 0.43, respectively, which was approximately 30% lower than the volume fraction achieved for the conventional unidirectional-rovings. Finally, it was observed that the decompaction of air-texturised rovings exhibits a more distinct elastic response when unloaded.

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Section: Introductionmentioning

confidence: 99%

Permeability and compaction behaviour of air-texturised glass fibre rovings: A characterisation study

Sandberg

Kabachi

Volk

et al. 2020

Journal of Composite Materials

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“…Furthermore, the geometry of the roof bar itself as well as the injection strategy might influence the two permeability measurement strategies. Studies have shown that the measured permeability of the same material can change by more than one magnitude dependent on the measurement procedure [51]. Therefore, it can be inferred that, if possible, the permeability measurements used for FSC should be performed in a process near environment.…”

Section: Resultsmentioning

confidence: 99%

“…For this set-up, the permeability tensor can be reduced to a single value representing the permeability along the flow direction. The permeability of the preform was characterized by the use of 2 D in-plane permeability experiments following the radial flow principle [51][52][53]. The preform was built as described in the capillary rise experiments section excluding the automated cutting step.…”

Section: Permeability Measurementsmentioning

confidence: 99%

Flow-speed-controlled quality optimisation for one-shot-hybrid RTM parts

Hergan

Fauster

Perkonigg

et al. 2020

Advanced Manufacturing: Polymer & Composites Science

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This work describes a model-based methodology to improve the bonding quality between the metal and composite constituents of one-shot-hybrid resin transfer moulding (OSH-RTM) parts. In order to reduce void induced defects in the interface an ideal flow front velocity needs to be achieved. This ideal flow front velocity is characterised by capillary rise experiments at the used carbon fibre textile. The flow front velocity during mould filling is controlled by the use of pressure sensors and Darcy's law. Therefore, viscosity characterisation of the resin system and permeability measurements of the preform were carried out. The interface of the produced OSH-RTM roof bar for a car is tested on a component test rig imitating the load of a side impact at a car. A t-test was carried out to prove that the flowspeed-controlled injection strategy is advantageous compared to a constant mass flow injection by means of a higher maximum load transferable by the interface of the hybrid part.

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“…In that context, the effect of different preform characteristics (layer orientation, thickness, fiber volume content, tow structure/ size, etc.) on permeability [25,70,71] as well as the effect of the permeant [72] have been studied while different inter-university benchmark comparisons of permeability results (round robin studies) have been conducted [73][74][75]. The equipment to determine permeability (permeameter) currently is not standardized and its commercial availability is limited.…”

Section: Materials Characteristics Used In Simulationsmentioning

confidence: 99%

Liquid composite molding reproducibility in real-world production of fiber reinforced polymeric composites: a review of challenges and solutions

Konstantopoulos

Hueber

Antoniadis

et al. 2019

Advanced Manufacturing: Polymer & Composites Science

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Liquid composite molding (LCM) suffers from multiple factors that contribute to pronounced uncertainty of process characteristics. This results in compromised reproducibility which is associated to high scrap or the unpredictable behavior of approved parts. However, LCM is still attractive for Fiber-reinforced polymeric composites (FRPC) production due to its economic advantage (i.e. in relation to Autoclave), the capability of some of its variants to produce high performance parts and its potential for process optimization. This review analyzes each uncertainty with respect to its origins and its impact in part or process, based on a combination of past literature and original numerical results. The possible methods to counteract uncertainties are critically discussed, with an eye on both the scientific and feasibility (technical/economical) aspects. The overall aim is to provide to future LCM implementations a roadmap of the most critical challenges and solutions regarding the establishment of a reproducible process.

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In-plane permeability characterization of engineering textiles based on radial flow experiments: A benchmark exercise

Cited by 79 publications

References 22 publications

Permeability and compaction behaviour of air-texturised glass fibre rovings: A characterisation study

Permeability and compaction behaviour of air-texturised glass fibre rovings: A characterisation study

Flow-speed-controlled quality optimisation for one-shot-hybrid RTM parts

Liquid composite molding reproducibility in real-world production of fiber reinforced polymeric composites: a review of challenges and solutions

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