Textile Coloration and Finishing (한국염색가공학회지)

The Korean Society of Dyers and Finishers (한국염색가공학회)
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Simulation Technology of 3D Fabrics

3차원 입체 직물의 시뮬레이션 기술

  • Park, Jung Hyun (Department of Clothing and Textiles, Pusan National University)
  • Received : 2019.09.06
  • Accepted : 2019.09.13
  • Published : 2019.09.27
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Abstract

This investigation reported the simulation technologies to design the 3-dimensional fabrics such as 3 dimensional multi-layered fabric, 3 dimensional braided fabric and spacer fabric. The simulation system or software has been actively used to develop products of 3 dimensional fabric which can be reduced development costs and time. Thus, many countries such as Japan, Germany, China, and U.K. show great interests on simulation technologies for developing new materials and processes including 3 dimensional fabric field. In this study, simulation systems have been reviewed for the 3 dimensional fabric design system from Mikawa Textile Research Center, Japan; ProCad and ProFab from Karl Mayer and Texion, Germany; xComposites from China; TexGen from Nottingham University, U.K.; TexPro from Young Woo CnI, Korea, respectively.

Keywords

References

  1. A. P. Mouritz, M. K. Bannister, P. J. Falzon, and K. H. Leong, Review of Applications for Advanced Three-dimensional Fibre Textile Composites, Composites Part A Applied Science and Manufacturing, 30(12), 1445 (1999). https://doi.org/10.1016/S1359-835X(99)00034-2
  2. H. Jeon, "Woven Fabrics", InTech, London, 2012.
  3. H. Jeon, "Non-woven Fabrics", InTech, London, 2016.
  4. Y. H. Yoon, D. G. Kim, J. H. Park, and S. G. Lee, Manufacturing andDevelopment of 3D Fabrics, Textile Coloration and Finishing, 30(1), 38(2018). https://doi.org/10.5764/TCF.2018.30.1.38
  5. H. B. Kwon, "Understanding of 3D Fabrics", Korea Federation of Textile Industries, Seoul, 2013.
  6. K. Bilisik and N. Sahbaz, Structure-unit Cell-based Approach on Three-dimensional Representative Braided Preforms fromFour-stepBraiding: Experimental Determination of Effects of Structure-process Parameters on Predetermined Yarn Path, Textile Research Journal, 82(3), 220(2012). https://doi.org/10.1177/0040517511404597
  7. X. Chen, L. W. Taylor, and L. Tsai, An Overview on Fabrication of Three-dimensional Woven Textile Preforms for Composites, Textile Research Journal, 81(9), 932(2011). https://doi.org/10.1177/0040517510392471
  8. E. Ghorbani, H. Hasani, H. Rafeian, and B. Hashemibeni, Analysis of the Thermal Comfort and Impact Properties of the Neoprene-spacer Fabric Structure for Preventing the Joint Damages, International Journal of Preventive Medicine, 4(7), 761(2013).
  9. W. Y. Jeong, D. Y. Lim, and Y. C. Park, Comparative Study on the Physical Properties of 3D-spacer Fabrics, Textile Science and Engineering, 47(4), 291(2010).
  10. P. B. Ma and Z. Gao, A Review on the Impact Tension Behaviors of Textile Structural Composites, Journal of Industrial Textiles, 44(4), 572(2015). https://doi.org/10.1177/1528083713503001
  11. K. J. Man, High Added-value Textile Composites for Sports and Leisure Products, KICNews, 17(6), 26(2014).
  12. S. Yoon, C. Jeong, M. Min, and W. Seo, Development Trend of Automotive Chemical and Textile Materials, KIC News, 16(6), 26(2013).
  13. B. Yu, R. S. Bradley, C. Soutis, P. J. Hogg, and P. J. Withers, 2D and 3D Imaging of Fatigue Failure Mechanisms of 3D Woven Composites, Composites Part A Applied Science and Manufacturing, 77, 37(2015). https://doi.org/10.1016/j.compositesa.2015.06.013
  14. B. G. Song, "Textopia Textile Information", KTDI, Seoul, 2010.
  15. http://www.koteri.re.kr/board/content.asp?board_id=koteri_tecinfo&board_gb=&ref=1613&step=1&page=1, 2013.11.26.
  16. www.texion.eu/, 2015.01.01.
  17. www.karlmayer.com/, 2019.01.01.
  18. www.xcomposites.com/, 2019.01.01.
  19. www.texgen.sourceforge.net/, 2019.06.07.
  20. https://www.texclub.com, 2019.01.01.