仿鳞片结构织物的制备及其防刺性能

doi:10.13475/j.fzxb.20220605101

摘要/Abstract

摘要：

针对目前防刺服层数多、柔韧性差等问题,利用针织横编技术成型能力优异的特点,克服高性能纱线编织复杂结构难的问题,以超高分子量聚乙烯(UHMWPE)纱线为基础,编织了一种类似于穿山甲重叠鳞片结构的仿生鳞片织物,并探索其成形原理。通过准静态穿刺实验研究了不同穿刺位置、方向、鳞片大小、穿刺刀具对鳞片织物防刺性能的影响,利用光学显微镜和扫描电子显微镜观察织物的损伤形貌,并分析鳞片织物的防刺机制。结果表明:鳞片织物成形的主要原理是鳞片连接处线圈的收缩及前、后针床的单独编织;增加刀刃处可切割的线圈数量可有效提升鳞片织物的防刺性能;鳞片织物在2种刀具下的穿刺过程存在差异,其损伤行为主要包括纱线的切割断裂失效及拉伸断裂失效。

关键词: 横编技术, 仿生结构, 鳞片结构织物, 准静态穿刺, 防刺性能, 防刺机制

Abstract:

Objective In view of the problems of many layers and poor flexibility of stab equipment in the current market, a bionic scale-like knitted fabric (SLKF) similar to pangolin's overlapping scale structure was knitted from ultra high molecular weight polyethylene (UHMWPE) yarns by using flat knitting technology, overcoming the difficulty of knitting complex structure with high-performance yarn. This novel fabric with overlapping scale structure is expected to further improve the stab-resistance.

Method The forming principle of SLKF was explored through simulation of fabric structure. Through quasi-static stab experiments (Fig. 4), the influences of different puncture positions, directions, scale sizes and puncture tools on the stab-resistance of the SLKF were studied. Through the structure model of a single scale and the change of fabric parameters, the rules of scale area coverage, fabric weight and scale deflection angle changing with the scale size are further clarified. The damage morphology of the SLKF was observed by optical microscope and scanning electron microscope, and the damage mechanism of the SLKF was analyzed.

Results Inspired by the overlapping structure of pangolin (Fig. 1), nine SLKFs were knitted(Fig.2), and the fabric exhibits excellent forming capabilities during the knitting process. Through simulation of the fabric structure, shrinkage of the adjacent loops in the fabric was utilized to form the overlap scale effect (Fig. 3). When stabbing in the overlapping section, or in the 0° direction, the SLKF demonstrated better stab-resistance, mainly by virtue of the large number of coils at the stab edge (Fig. 5). The stab-resistance of nine distinct SLKFs was investigated (Fig. 6), and the findings reveal a positive correlation between scale size and stab-resistance, indicating that larger scales offer enhanced protection. In order to further study the influence of scale size on stab-resistance, structure model of single scale and changes of fabric parameters was explored (Fig. 7), the results showed that the coverage of the total scale area was increased with the increase of the number of rows, the weight of fabric increased linearly with the increase of the number of rows, and the deflection angle of scales decreased gradually with the increase of the number of longitudinal rows. Two different standard knives D1 and D3 were adopted to explore the stab-resistance of SLKF, and the stabbing speed is 10 mm/min. The results demonstrate that the stab-resistance of SLKF under knife D3 is better than that of D1 (Fig. 8), and the reasons for this phenomenon can be explained as follows: under D1, the fabric failure was mainly caused by yarn cutting and tensile, accompanied by yarn extraction; and under D3, the main reasons for fabric failure were mainly extrusion and stretching, accompanied by a small amount of yarn tensile fracture failure(Fig. 9).

Conclusion In this research, inspired by the overlapping scales structure of pangolin, a bionic SLKF is prepared by UHMWPE yarn, and its forming principle and stab-resistance are discussed. The research shows that the shrinkage of the loops at the scale joint and the separate knitting of the front and back needle beds are the main principles for the formation of SLKFs. Overlapping effect of scales can effectively improve the stab-resistance of the fabric. The stabbing process of the SLKF under the two knives is different, and its damage behavior mainly includes yarn cutting fracture failure and tensile fracture failure. This work can provide reference for the preparation of stab-resistant materials.

Key words: flat knitting technology, bionic structure, scale-like knitted fabric, quasi-static stabbing, stab-resistance, damage mechanism

中图分类号:

TS141.8

刘青, 牛丽, 蒋高明, 马丕波. 仿鳞片结构织物的制备及其防刺性能[J]. 纺织学报, 2023, 44(11): 90-97.

LIU Qing, NIU Li, JIANG Gaoming, MA Pibo. Preparation and stab-resistance of bionic scale-like knitted fabrics[J]. Journal of Textile Research, 2023, 44(11): 90-97.

图/表 9

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图9

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