11—an Energy Method for Calculations in Fabric Mechanics Part I: Principles of the Method

Hearle, J. W. S.; Shanahan, W. J.

doi:10.1080/00405007808631425

Cited by 110 publications

(48 citation statements)

References 3 publications

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“…In 1958, Kemp proposed a racetrack model (Kemp, 1958). Hearle and Shanahan proposed lenticular geometry (Hearle & Shanahan, 1978) for calculation in fabric mechanics by energy method in 1978. And many researches related to the fabric mechanical properties under the base of fabric structural model were carried out by Grosberg (Grosberg & Kedia, 1966), Backer (Backer, 1952) Postle (Postle et al, 1988).…”

Section: Background Of Fabric Structural Designmentioning

confidence: 99%

Data Base System on the Fabric Structural Design and Mechanical Property of Woven Fabric

Kim¹,

Kim²

2010

Woven Fabric Engineering

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Section: Background Of Fabric Structural Designmentioning

confidence: 99%

Data Base System on the Fabric Structural Design and Mechanical Property of Woven Fabric

Kim¹,

Kim²

2010

Woven Fabric Engineering

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“…The outline of the cross sections is defined using 2D parametric equations. Standard formulae for various yarn shapes, such as the ellipse proposed by Peirce, 1 the power ellipse 4 and the lenticular proposed by Hearle and Shanahan, 5 have been implemented in TexGen, hence these cross-sectional shapes can be assigned to each section of yarns accurately and easily. The ellipse form is described as…”

Section: Yarn Cross Sectionmentioning

confidence: 99%

Automated geometric modelling of textile structures

Lin

Zeng

Sherburn

et al. 2012

Textile Research Journal

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An automated approach (TexGen) for modeling the geometry of textile structures is presented. This model provides a generic approach to the description of yarn geometry and yarn interlacement for all types of weaving. One feature of this model is that the shape and size of the cross sections may change locally; this is exploited in the functions for interference correction, which modify the textile according to geometric considerations to avoid penetration of yarns. Another feature of this model is that it acts as a pre-processor for finite element simulations by generating a mesh, definition of contact, materials orientation and boundary conditions, thus providing an automatic procedure. This paper describes the modeling techniques, algorithms and concepts implemented in TexGen and examines the functionality of their implementation for a range of twodimensional/three-dimensional commercial fabrics. Comparisons between the images of real fabrics and modeled fabric structures confirm that the software is capable of modeling sophisticated fabric architectures, including twisted yarns with varied yarn cross sections. Accurate input measurements of fabric geometry are critical for successful results. The paper also discusses directions for further development of the approach to overcome current limitations. Keywords fabric geometry, modeling, simulationRealistic fabric geometric description is essential for modeling of the mechanical and physical properties of textiles and textile composites. It determines the accuracy of modeling results and geometric non-linear response to external loadings. Attempts to model textile geometry were recorded as early as the1930s 1 and have continued up to the present time. 2 There are many challenging aspects of modeling fabric structures, for example, even the geometry of relatively simple plain-weave fabrics is complicated and requires careful modeling to obtain accurate results. There are two major obstacles: the

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“…They already done over 100 years of attempts in combining all the major parameters to represent the fabric that can be helpful for our prediction in terms of different weave factors "Table-2" [4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19].…”

Section: Representation Of Woven Fabricmentioning

confidence: 99%

“…Among all the study most work done to predict either tensile strength or the load-elongation behaviour of woven fabric based on the behaviour of yarn [13][14][15][16][17][18][19]. Woven fabrics used as technical textiles are subjected to forces, which are parallel and perpendicular to fabric plane also.…”

Section: Literature Reviewsmentioning

confidence: 99%

A Review on Different Factors of Woven Fabrics’ Strength Prediction

Hossain¹

2016

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Abstract:There are different fabric manufacturing methods like weaving, knitting, non-woven and braiding. Among them woven fabric shows good dimensional stability and good cover. One of the most important characteristics of woven fabric is strength. Strength is also measured in tensile, tearing or bursting strength. But, so many factors are related to the fabric strength like yarn count, twist, fibre fineness, stiffness, fibre density, fabric structure, cover, yarn density, no. of layer, tightness factor and so on. It is very complex to establish a mathematical relation to determine strength considering all these parameters. This paper will make the clear understanding on the factors that directly or indirectly influence the woven fabric's strenght and thus, will be more helpful during further research in woven fabric strenght prediction.

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11—an Energy Method for Calculations in Fabric Mechanics Part I: Principles of the Method

Cited by 110 publications

References 3 publications

Data Base System on the Fabric Structural Design and Mechanical Property of Woven Fabric

Data Base System on the Fabric Structural Design and Mechanical Property of Woven Fabric

Automated geometric modelling of textile structures

A Review on Different Factors of Woven Fabrics’ Strength Prediction

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