Effect of Fiber Volume Fraction in Fiber Reinforcement Compaction in Resin Injection Pultrusion Process

Shakya, N.; Roux, J. A.; Jeswani, A. L.

doi:10.1177/096739111602400102

Cited by 4 publications

(3 citation statements)

References 10 publications

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“…In order to compensate scarcity of experimental data and its inherent inconclusive interpretations of real pultrusion trials, two main approaches have been established for pultrusion investigations in addition to full-scale pultrusion trials:- Analytical and numerical models , ranging from rather simple analytical 1D-models for the calculation of temperature distributions within the die, considering exothermal heat generation, to complex 3D-Computational Fluid Dynamics and Multiphysics simulations for modeling the whole process, including impregnation as well as cure- and temperature-dependent viscosity development 8,17–28 - Simplified experimental representations , where specific aspects of the pultrusion process are evaluated empirically in distinctively developed experimental setups of reduced complexity 29–32 …”

Section: Investigations On the Flow Field In Injection Boxesmentioning

confidence: 99%

“…- Analytical and numerical models , ranging from rather simple analytical 1D-models for the calculation of temperature distributions within the die, considering exothermal heat generation, to complex 3D-Computational Fluid Dynamics and Multiphysics simulations for modeling the whole process, including impregnation as well as cure- and temperature-dependent viscosity development 8,17–28…”

Section: Investigations On the Flow Field In Injection Boxesmentioning

confidence: 99%

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Experimental study of roving configuration’s influence on the flow field in a full-scale transparent pultrusion injection box

Hopmann

Wruck

Schneider

et al. 2022

Journal of Composite Materials

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Resin injection pultrusion gains increasing attention as it enables the use of highly reactive resins and resins sensitive to environmental conditions, while also decreasing the emission of harmful volatile organic compounds. Nevertheless, a comprehensive understanding of the flow field based on the geometric characteristics within open injection boxes is lacking due to a multitude of interdependent parameters. In this research, a novel setup for an experimental evaluation of the flow field in injection pultrusion practically is proposed. The setup consists of a full size, two-dimensionally tapered, transparent injection box that is installed within a pultrusion line and is operated with non-reactive fluids. Investigations are conducted with two different guide plate setups. Pulling forces and filling degree are evaluated for four pulling speeds, four fiber volume fractions and for four fluids. The non-reactive fluids are three grades of sucrose solution and Mesamoll with viscosities ranging from 13 to 246 mPa.s. Obtained pulling forces correlate linearly with the product of viscosity and pulling speed. Better fiber wettability properties and additional fiber guiding plates result in lower pulling forces. Backflow fill length displays an asymptotic correlation to pulling forces, indicating different governing mechanisms for these two phenomena. Backflow fill length corresponds directly with resin residence time, which ranges from about 10 to 3 min. The results indicate the possibility of manipulating pressure build-up and resin residence time separately, which would enable tailoring injection box cavity geometries systematically to a specific profile.

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Section: Investigations On the Flow Field In Injection Boxesmentioning

confidence: 99%

Section: Investigations On the Flow Field In Injection Boxesmentioning

confidence: 99%

Experimental study of roving configuration’s influence on the flow field in a full-scale transparent pultrusion injection box

Hopmann

Wruck

Schneider

et al. 2022

Journal of Composite Materials

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“…The trial, especially for the Z 60-40 , has yielded good results: the tensile properties were observed under the design requirements. When making pultruded composites, some researchers may use fibre with volume fractions from 40-80%, depending on the production methods [50,51]. The greater the amount of reinforcement, the higher the strength and stiffness of the resulting composite.…”

Section: Discussionmentioning

confidence: 99%

A Novel Z Profile of Pultruded Glass-Fibre-Reinforced Polymer Beams for Purlins

et al. 2022

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Purlins made from galvanised steel in fertiliser warehouses have often been considered less efficient, necessitating a new purlin made using corrosion-resistant material to increase building efficiency. This study was an attempt to design a nine-metre purlin from glass-fibre-reinforced polymer (GFRP) composite material for a new fertiliser warehouse in Bontang-East Kalimantan, Indonesia. The purlin design selected in this study was the Z profile of pultruded beams from GFRP composite material that met the criteria of an efficient purlin, such as corrosion resistance, compact stacking, and ability to withstand technical loads. In particular, the Z profile becomes compact when stacked, and the GFRP material used is corrosion-resistant yet affordable. The primary materials for GFRP composites consist of long yarn glass fibre bundles for reinforcement and unsaturated polyester resin (UPR) for the matrix. Material strength modelling was based on analytical and finite element approaches. The analysis shows that the most considerable normal stress of “64.41 MPa” occurred at the two fixed end supports, while the most significant deflection of “45.9 mm” occurred at the mid-span of the purlin structure. The purlin structure was considered safe, as the strength and deflection were below the threshold. Thus, the Z profile of the pultruded purlin beams built using the GFRP composite material meets the technical criteria.

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