한국염색가공학회지 (Textile Coloration and Finishing)

  • 제30권1호
  • /
  • Pages.38-50
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  • 2018
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  • 1229-0033(pISSN)
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  • 2234-036X(eISSN)
한국염색가공학회 (The Korean Society of Dyers and Finishers)
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3차원 입체직물의 특성 및 제조 기술

Manufacturing and Development of 3D Fabrics

  • 윤영훈 (다이텍연구원 부산분원) ;
  • 김대근 (다이텍연구원 부산분원) ;
  • 박정현 (부산대학교 의류학과) ;
  • 이승걸 (부산대학교 유기소재시스템공학과)
  • Yoon, Young Hoon (Korea Dyeing and Finishing Technology Institute(DYETEC)) ;
  • Kim, Dae Geun (Korea Dyeing and Finishing Technology Institute(DYETEC)) ;
  • Park, Jung Hyun (Department of Clothing and Textiles, Pusan National University) ;
  • Lee, Seung Geol (Department of Organic Material Science and Engineering, Pusan National University)
  • 투고 : 2017.11.08
  • 심사 : 2017.12.03
  • 발행 : 2018.03.27
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초록

This investigation reported the recent development of 3 dimensional fabrics such as spacer fabric, 3 dimensional multi-layered fabric and 3 dimensional braided fabric. First, we categorized 3 dimensional fabrics into 3 main products; 3 dimensional woven fabrics, 3 dimensional knitted fabrics and 3 dimensional braided fabrics with reviewing the possible main applications. We also reported the research and development trends of 3 dimensional fabrics by analyzing technical trends in industry and research institutes at domestic and overseas. United State, Germany and Japan lead the manufacturing technology for the mainly preform related products to apply in aerospace, automotive, protections, architecture and clothing applications. Lastly, we reviewed the main products of the leading company which manufactured using the 3 dimensional fabrics.

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참고문헌

  1. A. P. Mouritz, M. K. Bannister, P. J. Falzon, and K. H. Leong, ReviewofApplications forAdvanced Three-dimensional Fibre Textile Composites, Composites: Part A, 30, 1445(1999). https://doi.org/10.1016/S1359-835X(99)00034-2
  2. H. Jeon, "Woven Fabrics", InTech, London, pp. 91-120, 2012.
  3. H. Jeon, "Non-woven Fabrics", InTech, London, pp. 81-141, 2016.
  4. A. Miravete, "3-DTextile Reinforcements in Composite Materials", Woodhead Publishing, Cambridge, 1999.
  5. 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 J. of Preventive Medicine, 4(7), 761(2013).
  6. 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).
  7. S. Yoon, C. Jeong, M. Min, and W. Seo, Development Trend of Automotive Chemical and Textile Materials, KIC News, 16(6), 26(2013).
  8. K. J. Man, High Added-value Textile Composites for Sports and Leisure Products, KIC News, 17(6), 26(2014).
  9. 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
  10. J. Hu, "3-DFibrous Assemblies", Woodhead Publishing Series in Textiles, Cambridge, pp.104-130, 2008.
  11. M. H. Mohamed, Three-dimensional Textiles, American Scientist, 78(6), 530(1990).
  12. X. Chen, L. W. Taylor, and L. Tsai, An Overview on Fabrication of Three-demensional Woven Textile Preforms for Composites, Textile Research J., 81(9), 932(2011). https://doi.org/10.1177/0040517510392471
  13. A. Busgen, Woven Fabric having a Bulging Zone and Method and Apparatus of Forming Same, Patent No. US6000442(1999).
  14. P. Ma and Z. Gao, A Reviewon the Impact Tension Behaviors of Textile Structural Composites, J. of Industrial Textiles, 44(4), 572(2015). https://doi.org/10.1177/1528083713503001
  15. B. Kumar and S. Thakur, "Textiles for Advanced Applications", InTech, London, pp.87-133, 2017.
  16. http://www.karlmayer.com, 2016.11.30.
  17. J. Hu, "3-D Fibrous Assemblies", Woodhead Publishing Series in Textiles, Cambridge, pp.70-103, 2008.
  18. C. W. Rogers and S. R. Crist, Braided Preformfor Composite Bodies, US Patent 5619903(1997).
  19. K. Bilisik and N. Sahbaz, Structure-unit Cell Base Approach on Three Dimensional (3D) Representative Braided Preforms from 4-step Braiding: Experimental Determination of Effect of Structure-process Parameters on Predetermined Yarn Path, Textile Research J., 82, 220(2012). https://doi.org/10.1177/0040517511404597
  20. M. Tsuzuki, Three Dimensional Woven Fabric with Varied Thread Orientations, US Patent 5348056(1994).
  21. http://www.3tex.com, 2016.12.1.
  22. http://www.albint.com, http://www.cfmaeroengines.com, http://www.airbus.com, http://www.boeing.com, 2016.12.6.
  23. www.nasa.gov, 2016.12.6.
  24. K. Y. Kim, Report for Recent R&D Trends in Industrial Textiles, Korea Federation of Textile Industries and Korea Textile Trade Association, Seoul, pp.41-106, 2015.
  25. www.tao-group.de, 2016.12.8.