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Twist-Controlled Force Amplification and Spinning Tension Transition in Yarn

Antoine Seguin, Jérôme Crassous

2022Physical Review Letters37 citationsDOI

Abstract

Combining experiments and numerical simulations with a mechanical-statistical model of twisted yarns, we discuss the spinning transition between a cohesionless assembly of fibers into a yarn. We show that this transition is continuous but very sharp due to a giant amplification of frictional forces which scales as expθ^{2}, where θ is the twist angle. We demonstrate that this transition is controlled solely by a nondimensional number H involving twist, friction coefficient, and geometric lengths. A critical value of this number H_{c}≃30 can be linked to a locking of the fibers together as the tensile strength is reached. This critical value imposes that yarns must be very slender structures with a given pitch. It also induces the existence of an optimal yarn radius. Predictions of our theory are successfully compared to yarns made from natural cotton fibers.

Topics & Concepts

SpinningYarnMaterials scienceUltimate tensile strengthTension (geology)Composite materialTwistMechanicsComputer simulationValue (mathematics)Textile materials and evaluationsAdvanced Materials and MechanicsStructural Analysis and Optimization
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