Anisotropy in geometrical and tensile properties of plain weave fabric: verifying a semi-empirical model

IF 1.5 4区工程技术 Q2 MATERIALS SCIENCE, TEXTILES

Journal of the Textile Institute Pub Date : 2017-09-02 DOI:10.1080/00405000.2016.1261422

Mehdi Kamali Dolatabadi

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引用次数: 1

Abstract

Abstract Geometrical and mechanical behaviors of fabric are extremely anisotropic. Exploit of fabric in multiplicity applications is dependent on its behavior in differ directions. Thus, attempts had been made to study the behavior of fabric in off and on axis systematically. For this purpose, authority of a semi-empirical model, based on earlier work, was experimentally investigated. The model consists of a numerical way to estimate yarn path under axial and normal tension simultaneously. A test method to evaluate flattening of yarn was presented in this study. Moreover, to reduce stress concentration at the sample’s corners a modified griper was applied. On the basis of initial data of fabric and flattening behavior of constitutive yarns, the fabric geometry and tensile force–strain (TF–S) curve of a strip fabric in arbitrary direction are capable to estimate using stated model. The variations in density of warp and weft yarns, shear angle, and TF–S curve of a fabric in different directions were measured and are compared with theoretical values. It was found that the stated model is applicable to predict fabric geometry and tensile behavior of a plain weave fabric under stress in arbitrary direction. Experimental results indicated that the strength of fabric at 45 degree was 22.59% higher than the strength of fabric in average of principal directions. On the basis of semi-empirical model, it is anticipated that the maximum strength of presented fabric would be occurred at 60 degree with 27.99% higher than the strength of fabric in average of principal directions.

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平纹织物几何和拉伸性能的各向异性:半经验模型的验证

摘要织物的几何和力学行为具有极强的各向异性。织物在多重应用中的开发取决于其在不同方向上的行为。因此，尝试系统地研究织物在离轴和上轴上的行为。为此，在早期工作的基础上，对半经验模型的权威进行了实验研究。该模型包括一种同时估计轴向和法向张力下纱线路径的数值方法。提出了一种评价纱线压扁度的试验方法。此外，为了减少试样角处的应力集中，采用了改良的夹持器。根据织物的初始数据和本构纱的展平行为，利用所述模型可以估计任意方向上条形织物的几何形状和拉伸力-应变曲线。测定了织物在不同方向上经纬纱密度、剪切角和TF-S曲线的变化，并与理论值进行了比较。结果表明，该模型适用于平纹织物在任意方向应力作用下的几何形状和拉伸性能预测。实验结果表明，织物在45度方向上的强度比织物在主方向上的平均强度高22.59%。在半经验模型的基础上，预测织物的强度最大值出现在60度处，在各主方向上的平均值比织物的强度高27.99%。

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来源期刊

Journal of the Textile Institute 工程技术-材料科学：纺织

CiteScore

4.20

自引率

5.90%

发文量

149

审稿时长

1.0 months

期刊介绍： The Journal of The Textile Institute welcomes papers concerning research and innovation, reflecting the professional interests of the Textile Institute in science, engineering, economics, management and design related to the textile industry and the use of fibres in consumer and engineering applications. Papers may encompass anything in the range of textile activities, from fibre production through textile processes and machines, to the design, marketing and use of products. Papers may also report fundamental theoretical or experimental investigations, including materials science topics in nanotechnology and smart materials, practical or commercial industrial studies and may relate to technical, economic, aesthetic, social or historical aspects of textiles and the textile industry. All published research articles in The Journal of The Textile Institute have undergone rigorous peer review, based on initial editor screening and anonymized refereeing by two expert referees.