A yarn hanging model for estimating the applied initial warp tension in the multi-layer weaving process

Abstract

Carbon fiber warp yarns tend to hang due to the gravity in the multi-layer weaving process, which leads to chaotic shedding and impairs fabric quality. The hanging shape of carbon fiber warp yarns is mainly determined by the applied initial warp tension in the weaving process, and excessive warp tension increases the friction between the yarn and the heald frame, resulting in yarn wear. A yarn hanging model based on catenary theory was established to estimate the applied minimum initial warp tension that could ensure clear shedding in the multi-layer weaving process. The relationship between the warp hanging shape and various weaving process parameters (warp tension, yarn specifications and the size of shedding) was obtained. According to the weaving conditions, the applied initial yarn tension could be estimated using the model before manufacturing. Multi-layer yarn hanging experiments were conducted using different specification carbon fibers and yarn tension, and the theoretical predictions and experimental results were compared. The results showed that the yarn hanging model could well simulate the actual hanging characteristics of carbon fiber warp yarn under different tension. The research results provide a tool for estimating the applied initial warp tension in the multi-layer weaving process.

Keywords

Warp tension yarn hanging shedding shape multi-layer weaving process carbon fiber

Get full access to this article

View all access options for this article.

References

Mathes

The composites industry: plenty of opportunities in heterogeneous market. Reinforced Plastics 2018; 62: 44–51.

Bilisik

Multiaxis three-dimensional weaving for composites: a review. Text Res J 2012; 82: 725–743.

Gao

Chen

A review of multi-scale numerical modeling of three-dimensional woven fabric. Composit Struct 2021; 263: 113685.1–113685.10.

Schindler

Bauder

Wolfrum

, et al. Engineering of three-dimensional near-net-shape weave structures for high technical performance in carbon fibre-reinforced plastics. J Eng Fibers Fabrics 2019; 14: 1–16.

Tourlonias

Bueno

M-A.

Experimental simulation of friction and wear of carbon yarns during the weaving process. Composit Part A Appl Sci Manufact 2016; 80A: 228–236.

Kim

HA.

Effect of fabric structural parameters and weaving conditions to warp tension of aramid fabrics for protective garments. Text Res J 2018; 88: 987–1001.

Wang

Boussu

, et al. Investigation of the strength loss of HMWPE yarns during manufacturing process of 3D warp interlock fabrics. Appl Composit Mater 2021; 29: 357–371.

Leng

Huang

Heald frame motion trajectory based on minimum warp friction in the shedding process of three-dimensional woven fabrics. Text Res J 2022; 92: 2424–2432.

Gong

Shilin

, et al. Characteristics of warp yarn hanging path under weaving tension. J Text Res 2016; 37: 32–36 [in Chinese].

10.

de Vasconcelos

Marcicano

JPP

Sanches

. Influence of yarn tension variations before the positive feed on the characteristics of knitted fabrics. Text Res J 2015; 85: 1864–1871.

11.

Ying

, et al. Effect of the frictional coefficient and pre-tension on stress distribution of fabric during the weaving process. Text Res J 2018; 88: 904–912.

12.

Süle

Investigation of bending and drape properties of woven fabrics and the effects of fabric constructional parameters and warp tension on these properties. Text Res J 2012; 82: 810–819.

13.

Mebrate

Gessesse

Zinabu

Effect of loom tension on mechanical properties of plain woven cotton fabric. J Nat Fibers 2020; 2: 1–6.

14.

Yao

Adjustment method of loom tension for mini-jacquard fabric using double beams. Cotton Text Technol 2016; 44: 78–80 [in Chinese].

15.

Lee

Effect of weaving damage on the tensile properties of three-dimensional woven composites. Composit Struct 2002; 57: 405–413.

16.

Behroozi

A fresh look at the catenary. Eur J Phys: A journal of the European Physical Society 2014; 35: 55007-1–55007-11.

17.

Wang

CY.

The optimum elastica catenary cable. Structures 2020; 28: 878–880.

18.

Liu

Design of hanger tension and cable configuration for self-anchored suspension bridges. China Civil Engng J 2008; 41: 79–83 [in Chinese].

19.

Zhou

Chen

Iterative nonlinear cable shape and force finding technique of suspension bridges using elastic catenary configuration. J Engng Mechan 2019; 145: 5.

20.

Zhang

Yang

Research of variation characteristic of conveyor belt of vehicle group chain conveyor based on elastic catenary theory. J Mech Transmis 2020; 44: 34–38, 45 [in Chinese].

21.

Yang

Detection method of warp tension in multilayer loom for carbon fiber fabric. J Text Res 2016; 37: 137–141 [in Chinese].