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Autex Research Journal

The Journal of Association of Universities for Textiles (AUTEX)

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Prediction of woven fabric properties using software protkatex

Brigita Kolčavová Sirková
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Textile Technologies, Liberec, Czech Republic Studentská 2, 461 17 Liberec 1
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/ Iva Mertová
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Textile Technologies, Liberec, Czech Republic Studentská 2, 461 17 Liberec 1
  • Email
  • Other articles by this author:
  • De Gruyter OnlineGoogle Scholar
Published Online: 2013-03-27 | DOI: https://doi.org/10.2478/v10304-012-0017-5

Abstract

Fabric properties and fabric structure prediction are important in each industry domain. Generally all professional CAD packages for woven textiles system will be able to achieve basic fabric simulation and production output. A good CAD system should enable you to create design (dobby and jacquard woven fabric) ideas quickly and easily to enhance the way you work. The differences among competing systems fall mainly into the following categories: ease of use; speed of operation; flexibility of operation; advanced features; technical support; and ongoing software development. Computer simulation or prediction is oriented on standard woven fabrics, technical textiles, and composites. This article focuses on the presentation of software ProTkaTex and its use in the prediction of woven fabric properties. The software implements a generalized description of the internal structure of woven fabric on the unit cell level, integrated with mathematical models of the fabric relaxed state. User can calculate selected mechanical and end-use properties of dobby and jacquard woven fabric as well as can evaluate fabric behavior before real weaving. The major challenge is to develop software that industry will use in design centers for creation and development of new fabric structures for technical as well as clothing application.

Keywords: Fabric geometry; weave; warp; weft; property; simulation; prediction

  • Vijay Duggal. “CADD Primer”. Mailmax Publishing, http://www.caddprimer.com/cadd_primer_chapters/ Google Scholar

  • Nosek, S.: The structure and geometry of the woven fabrics, Liberec 1996, Google Scholar

  • Behera, B.K., Hari, P.K.: Woven textile structure, Theory and applications, Woodhead Publishing Limited, ISBN 978-1-84569-514-9 (book), 2010 Google Scholar

  • Neckář, B.: Compression and Packing Density of Fibrous Assemblies. Textile Research Journal, pp. 123-130 Vol. 67 No. 3. Google Scholar

  • Plívová, H., Influence of interlacing and sett of threads on the yarns shape in the weave for the cotton woven fabric – only in Czech, Diploma thesis Faculty of Textile Engineering, Technical University of Liberec 2001 Google Scholar

  • Nový O., Spectral analysis of binding waves in the woven fabric with carbon fibres, – only in Czech, Diploma thesis Faculty of Textile Engineering, Technical University of Liberec 2004 Google Scholar

  • Čaprnková N.: Analysis of the woven fabric cross-section produced from twisted yarns – only in Czech, Diploma thesis Faculty of Textile Engineering, Technical University of Liberec 2007 Google Scholar

  • Kašparová K.: Design possibilities of woven jacquard fabric, Bachelor work, Faculty of Textile Engineering, Technical University of Liberec 2009 Google Scholar

  • Peirce, F.T.: The Geometry of Cloth Structure, Journal of Textile Institute, Vol.28, 1937 Google Scholar

  • Kemp, A. J.: Textile Institute 49, T44, 1958 Google Scholar

  • Duckett, K. E., Cheng C. C.: A Discussion of The Crosspoint Theories, Journal of the Textile Institute, Volume 69, Issue 2 & 3 February 1978, pp. 55-59. Google Scholar

  • CAD/CAM systems for weaving - ScotCad Textiles Limited, www.scotweave.com. Google Scholar

  • CAD/CAM systems for weaving EAT - www.designscopecompany.com. Google Scholar

  • CAD/CAM systems for weaving -NedGraphics, www.nedgraphics.com. Google Scholar

  • CAD /CAM systems for weaving - Arachne, www.arahne.si Google Scholar

  • Lomov, S., Verpoest, I., Modelling of the internal structure and deformability of textile reinforcements: WiseTex software, In Proc. of 10th European Conf. Composite Materials (ECCM-10) (Brugge, Belgium, June 3--7, 2002) Google Scholar

  • Lomov, S. V., G. Huysmans, and I. Verpoest: Hierarchy of Textile Structures and Architecture of Fabric Geometric Models, Textile Research Journal, Jun 2001; vol. 71 Google Scholar

  • Košek M., Mikolanda T., Košková B.: Ideal, Real and Virtual Textile Structure Modeling and Visualization, Afriograpf 2004, Proc. Of 3rd International conference on computer graphics, South Africa 2004 Google Scholar

  • CAD-Simulation of 3D woven shapes, Department of Textile and Clothing Technology, Niederrhein University of Applied Sciences, Germany Google Scholar

  • Křemenáková D., Kolčavová S. B., Mertová I.: Libtex software package, Technical University of Liberec,Textile Faculty, National research Center TEXTIL I, Czech Textile Seminar Greece May 2005 Google Scholar

  • Szosland J.,: Modelling the structural barrier ability of woven fabrics, Textile research, Department of Textile Architecture, Technical University of Łódź, Poland Google Scholar

  • Hearle, J.W.S., Grosberg P., Backer, S.: Structural Mechanics of Fibers, Yarns, and Fabrics, (book) Wiley- Interscience 1969 Google Scholar

  • Hearle, J.W.S.: Engineering design of textiles, Indian Journal of Fibre and Textile Research, Special Issue, 2005 Google Scholar

  • http://www.texeng.co.uk Google Scholar

  • Long A.: TexGen – Open Source Software for Modelling of Technical Textiles, Transfer Summit/UK, Keble college, Oxford, 2011 Google Scholar

  • H. Lin, X. Zeng, M. Sherburn, A. C. Long and M. J. Clifford. “Automated geometric modelling of textile structures”, Textile Research Journal, in press, May 2011 Web of ScienceGoogle Scholar

  • http://texgen.sourceforge.net/index.php/Main_Page Google Scholar

  • Masajtis, J.: Analiza strukturalna tkanin, Polska Akademia Nauk Oddzial w Łodzi, Komisja Włokiennictwa, Łodź 1999 Google Scholar

  • Barburski M., Masajtis J.; Modelling of the Change in Structure of Woven Fabric under Mechanical Loading. FIBRES & TEXTILES in Eastern Europe, January/March 2009, Vol. 17, No. 1 (72) pp. 39-44. Google Scholar

  • Szosland J., ‘Kształtowanie własności tkanin poprzez kształtowanie fazy ich struktury’ (in Polish, ‘Designing of woven fabric features by designing the phase of their structure’), Architektura Tekstyliów, No. 1-3, 1999 Google Scholar

  • Keefe, M.: Solid Modeling Applied to Fibrous Assemblies PartII: Woven Structure, Journal of Textile Institut, Vol.85 No.3, 1994 [350-358] Google Scholar

  • S. Backer. The relationship between the structural geometry of textile and its physical properties, I: Literature review. Text. Res. J. 1948, 18: 650-658. Google Scholar

  • Sirková, B.: Theses, Mathematical model for description of thread’s interlacing in fabric using Fourier series, Liberec 2002 Google Scholar

  • Stepanović, J., Milutinović, Z., Petrović, V., Pavlović, M.: Influence of relative density on deformation characteristics of plain weave fabrics, Indian Journal of Fibre & Textile Research Vol. 34, March 2009 Google Scholar

  • Milašius V.: Woven Fabric’s Cross-Sec¬tion: Problems, Theory, and Experimental Data, Fibres and Textiles in Eastern Europe No 4(23)/98, pp. 48-50. Google Scholar

  • Oloffson B.; „A general model of a fabric as a geometric mechanical structure” J. Textiles Isnt. Nr11,55, pp. 541- 557; 1964. Google Scholar

  • Ozgen, B., Gong, H.: Yarn geometry in woven fabrice, Textile Research Journal, May 2011; vol. 81, 7: pp. 738- 745, Google Scholar

  • Ozgen, B., Gong, H.: Modelling of yarn flattening in woven fabrice, Textile Research Journal, September 2011; vol. 81, 15: pp. 1523-1531. Web of ScienceGoogle Scholar

  • Kolčavová S. B.: Description of fabric thickness and roughness on the basis of fabric structure parameters, 18th International conference Strutex 2011, Liberec, Czech Republic 2011 Google Scholar

  • Kurashiki, T., H. Nakai, S. Hirosawa , M. Imura, M. Zako, S.V. Lomov, and I. Verpoest, Mechanical behaviors for textile composites by FEM based on damage mechanics, Key Engineering Materials, 2007, 334-335 (Advances in Composite Materials and Structures): 257-260. Google Scholar

About the article

Published Online: 2013-03-27


Citation Information: Autex Research Journal, Volume 13, Issue 1, Pages 11–16, ISSN (Print) 1470-9589, DOI: https://doi.org/10.2478/v10304-012-0017-5.

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