Hybrid Fabrics for Structural Composites

Shekar, R. Indu; Kotresh, T. M.; Prasad, Arvind; Rao, P. M. Damodhara; Ananthakrishnan, T. N.; Kumar, M. N. Satheesh; Siddaramaiah,

doi:10.1177/1528083710396263

Cited by 7 publications

(4 citation statements)

References 32 publications

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“…The tightly woven fabrics are typically the choice to maintaining fibre orientation during the manufacturing process and minimizing resin void size due to the shorter impregnation distance. Therefore, the laminar and crosswise flow of resin along and between the fibres, in between the yarns and fabric layers is easier [24,25]. Moreover, basket weave has higher quantity of interlace points per unit area compared to satin.…”

Section: Composite Porositymentioning

confidence: 98%

Characterization of thermoplastic natural fibre composites made from woven hybrid yarn prepregs with different weave pattern

Baghaei

Skrifvars

Berglin

2015

Composites Part A: Applied Science and Manufacturing

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Section: Composite Porositymentioning

confidence: 98%

Characterization of thermoplastic natural fibre composites made from woven hybrid yarn prepregs with different weave pattern

Baghaei

Skrifvars

Berglin

2015

Composites Part A: Applied Science and Manufacturing

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“…In the past decades, the automotive industry had to deal with two major issues concerning these biobased-composites: i) the ability to process the composite parts both in one step process and reduced production time, ii) by keeping a good quality of obtained structures (resistance to mechanical loading, for example). Nowadays, only few manufacturing processes such as light resin transfer molding (light RTM) or thermalcompression are considered by this industry [9][10][11]. When using conventional heating equipment such as a hot press Picher-Martel et al [12] showed that short carbon fibre/PEEK structures were successfully obtained by thermo-compression in about 40 min at 400°C which is the melting temperature of the resin [12].…”

Section: Introductionmentioning

confidence: 99%

Rapid manufacturing of woven comingled flax/polypropylene composite structures

2018

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The use of natural fibre reinforced composites such as flax fibre / polypropylene is in a constant expansion particularly in automotive and marine industries due to their good mechanical properties, low density and thus, lightness, low environmental impact, low cost, recyclability, renewable properties of flax fibres and a minimum energy intake during their process. One of the major challenges of thermoplastic composites for the automotive industry is to manufacture finished parts in a single processing step within a minimum amount of time. For this purpose, a stamping airflow device was specifically developed. It is designed to produce woven comingled composite parts from comingled woven fabrics such as flax/polypropylene in only 200 s. Firstly, preliminary tests and the optimization of processing parameters were performed. Then, a quasi-static mechanical characterization of the formed parts was realized. By using criteria based on mechanical properties, the optimal process parameters such as the level of pressure, temperature, holding time and cooling rate so that to obtain the lowest voids rate were determined. Finally, a comparison of the mechanical properties of parts obtained from using the new manufacturing process and a conventional thermocompression process is presented to demonstrate the interest and the level of performance achieved by this original and fast manufacturing device.

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“…Except for direct polymer melting methods, such as pultrusion and co-extrusion [34,35], currently, there are two main technologies that can be used for continuous fiber-reinforced thermoplastic polymer matrix composite production. One of them is bringing the fiber as close as possible to the thermoplastic polymer matrix before the composite consolidation, which includes powder impregnation [36][37][38], commingled yarn fabrication [39,40], cowoven fabric producing [41,42], and film stacking method [43][44][45] technologies, to reduce void and improve the matrix distribution. The other is synthesizing the thermoplastic polymer matrix directly in the composite fabrication step, such as in situ polymerization, due to the easier process of impregnation of the fiber bundles with low viscosity polymer precursors [46][47][48].…”

Section: Introductionmentioning

confidence: 99%

Structure, Thermal, and Mechanical Behavior of the Polysulfone Solution Impregnated Unidirectional Carbon Fiber Yarns

Chukov,

Tcherdyntsev,

Stepashkin

et al. 2023

Polymers

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The paper is devoted to the study of thermal and mechanical behavior and structural features of the polysulfone solution impregnated unidirectional carbon fiber yarns depending on fabrication conditions and appearance for optimum production method of the composites. The effect of producing conditions, such as polysulfone solution concentration, drying and post-heating temperatures, and the residual solvent content on the structure, mechanical, and thermal properties of the carbon fiber-reinforced composites was studied. The polysulfone solution impregnated carbon fiber yarns show relatively high mechanical properties, realizing up to 80% of the carbon fibers’ tensile strength, which can be attributed to good wettability and uniform polymer matrix distribution throughout the entire volume of the composites. It was found that the composites impregnated with 40 wt.% of the polysulfone solution showed lower porosity and higher mechanical properties. The results of a dynamic mechanical analysis indicate that residual solvent has a significant effect on the composites’ thermal behavior. The composites heated to 350 °C for a 30 min showed higher thermal stability compared to ones dried at 110 °C due to removal of residual solvent during heating. The impregnated carbon fiber yarns can be used for the further producing bulk unidirectional composites by compression molding and the proposed method can be easily transformed to continuous filament production, for example for further use in 3-D printing technology.

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Hybrid Fabrics for Structural Composites

Cited by 7 publications

References 32 publications

Characterization of thermoplastic natural fibre composites made from woven hybrid yarn prepregs with different weave pattern

Characterization of thermoplastic natural fibre composites made from woven hybrid yarn prepregs with different weave pattern

Rapid manufacturing of woven comingled flax/polypropylene composite structures

Structure, Thermal, and Mechanical Behavior of the Polysulfone Solution Impregnated Unidirectional Carbon Fiber Yarns

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