Investigating the shear behaviour of high-performance fabrics

El Messiry, Magdi; Eid, Elshiamaa; Ayman, Yasmin

doi:10.1177/15280837231213138

Journal of Industrial Textiles

2023

DOI: 10.1177/15280837231213138

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Investigating the shear behaviour of high-performance fabrics

Magdi El Messiry,

Elshiamaa Eid,

Yasmin Ayman

Abstract: Shear modulus is a critical factor that significantly influences the mechanical properties and overall performance of these textiles. Understanding the mechanics behind fabric performance during forming operations is of paramount importance, especially given the diverse use of various fabric types as key components in composite products. Fabric's ability to undergo shear deformation is a pivotal attribute in forming and facilitating the transformation of 2-dimensional preforms into intricate 3-dimensional stru… Show more

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2024

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Concave and convex small radius bending behavior of single and multiple layers reinforcement fabrics

Kanz,

Robitaille

2024

Textile Research Journal

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Multilayer reinforcement fabrics are increasingly used for manufacturing structural polymer composites. In liquid molding processes, dry reinforcement fabrics are draped on a mold first, and infused with a liquid resin such as an epoxy in a subsequent manufacturing step. This presents major advantages in terms of operational flexibility and costs. However, draping multilayer reinforcement fabrics on complex mold geometries is challenging. Small radius mold corners constitute a major manufacturing challenge as they lead to variability in dry fabric positioning and resin-rich corners in polymer composite parts. Spring-back of fabrics bent over or into single curvature mold corners is a widespread industrial concern. However, contrary to draping over double-curvature surfaces, bending spring-back from convex or concave single-curvature corners has received very limited attention. No testing method is available. This paper quantifies reinforcement fabric bending spring-back. Single and multiple layer stacks were bent along three directions over convex and into concave 90° corners with five radii spanning 1.59 mm to 12.70 mm. In all cases, five replicated tests enabled variability quantification. Fabric stacks were also quantified using cantilevered bending tests for comparison purposes. Mold radius was found to affect the behavior to a larger extent than testing direction, number of layers or use of a binder.

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Concave and convex small radius bending behavior of single and multiple layers reinforcement fabrics

Kanz,

Robitaille

2024

Textile Research Journal

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show abstract

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Investigating the shear behaviour of high-performance fabrics

Cited by 1 publication

References 46 publications

Concave and convex small radius bending behavior of single and multiple layers reinforcement fabrics

Concave and convex small radius bending behavior of single and multiple layers reinforcement fabrics

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