Fashion & Textile Research Journal (한국의류산업학회지)

The Society of Fashion and Textile Industry (한국의류산업학회)
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Physical Properties of Polyester, Tencel and Cotton MVS Blended Yarns with Yarn counts and Blend Ratio

PET, Tencel, Cotton MVS 혼방사의 섬도와 혼용률에 따른 물성 특성

  • Sa, A-Na (Korea Research Institute for Fashion Industry) ;
  • Lee, Jung Soon (Dept. of Clothing and Textiles, Chungnam National University)
  • 사아나 (한국패션산업연구원 연구개발본부) ;
  • 이정순 (충남대학교 의류학과)
  • Received : 2014.11.11
  • Accepted : 2015.02.24
  • Published : 2015.04.30
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Abstract

This study investigates the physical properties of Murata Vortex Spinning (MVS) blended yarn with yarn count(20's, 30's, 40's) and blend ratio(Polyester 100, Polyester70:Cotton30, Polyester50:Cotton50, Polyester30:Cotton70, and Polyester50:Tencel40:Cotton10). This study evaluated tenacity, elongation, bending rigidity, bending hysteresis, hairiness coefficient, irregularity and twist number. The structure of MVS blended yarn influenced stress, strain, bending rigidity, bending hysteresis and the hairiness coefficient of MVS blended yarn decreased as the yarn count increased. MVS blended yarn consists of core and sheath. The core of MVS blended yarn is composed of a parallel fiber with a wrapping fiber that covers thecore fiber. This special structure of the MVS blended yarn effects the physical properties of the yarn; in addition, the mechanical properties of the component fibers influenced the stress, strain, bending rigidity, bending hysteresis and hairiness coefficient of MVS blended yarn with the blend ratio. Polyester decreases and cotton increases resulted in decreased physical properties. A similar polyester content increased the tencel and physical properties. Appropriate physical properties and a variety of touch expression can be realized through a correct blend ratio.

Keywords

References

  1. '100% 면을 이용한 보텍스 정방의 한계' [Limits of the vortex spinning using a 100% cotton. (2011, February 24). Korea Textile Inspection & Testing Institute. Retrieved October 28, 2014, from http://kotiti.re.kr:8081/support/textile.
  2. '2015 F/W Men Fabric Trend'. (n. d). SamsungDesignNet. Retrieved November 3, 2014, http://www.samsungdesign.net/Trend/sfitrends/ForMen/TrendPreview_body.asp?year1=2015&season=fw&an=3&category_seq=3&body_seq=2
  3. '2015 S/S Women Fabric Trend.' (n. d). SamsungDesignNet. Retrieved November 3, 2014, from http://www.samsungdesign.net/Trend/sfitrends/FabricAll/Women_fabric_content.asp?an=67&category_seq=2&body_seq=6&year1=2015&season=ss&sex=For+Women
  4. Aung, K. S., Masaoki, T., & Masaru, N. (2004). Structure and properties of MVS yarns in comparison with ring yarns and openend rotor spun yarns. Textile Research Journal, 74, 819-826. doi:10.1177/004051750407400911
  5. Badmaanyambuu, S. (2010). The effects of physical properties on tactile sensibility and preference of felt. Unpublished master's thesis, Jeju National University, Jeju.
  6. Choi, I. R., Bang, H. K., Choi, J. I., & Jung, E. J. (2008). Fashion & Textile. Seoul: Sungshin Women's University Press.
  7. Choi, H. Y., Choi, H. N., Lee, S. W., Hong, Y. K., & Lee, S. G. (2011). Effects of blend ratio and fineness on the physical properties of CDP/Tencel blended yarns. Journal of the Korean Fiber Society, 48(3), 187-192.
  8. Herbert, S. (2009). Alternative spinning system. The Rieter Manual of Spinning, 6, 40-49.
  9. Kang, T. J. (1987). The hairiness measurement method of spun fiber and effect of the spinning processing condition. Journal of the Korean Fiber Society, 24(5), 103-113.
  10. Kim, H. S., & Na, M. H. (2014). Evaluation of texture image and preference to men's suit fabrics according to mechanical properties, hand and fabric information of wool blended fabrics. Korean Journal of Human Ecology, 23(2), 317-328. doi:10.5934/kjhe.2014.23.2.317
  11. Kim, S. R. (2000). 피복재료학 [Textiles Material] (3rd ed.). Paju: Kyomunsa.
  12. Koo, Y. S. (2001). Bending behavior of coated yarns. Fibers and Polymers, 2(3), 148-152. https://doi.org/10.1007/BF02875328
  13. Korea Textile Inspection & Testing Institute. (1994). 링 방적사와 에어젯 방적사에서 꼬임수와 방출번수와의 관계 [Relationship of twist-number and yarn-count in Ring-spun-yarn and air-jetspun-yarn]. Fibers Technology, 23(4), 9-15.
  14. Korea Textile Inspection & Testing Institute. (1991). 에어젯 정방에 대한 고찰[Discussion air-jet spinning]. Fibers Technology, 20(5), 8-13.
  15. Korea Textile Inspection & Testing Institute. (2004). 에어젯 정방 기술의 개선[Improvement of air-jet spinning technology]. Fibers Technology, 33(1), 45-48.
  16. Korea Textile Inspection & Testing Institute. (2005). 최근의 정방기와 보텍스 정방 [Recent spinner and vortex spinning]. Fibers Technology, 34(4), 26-34.
  17. Yea, S. J., & Song, W. S. (2013). Comfort and physical properties of linen blended knitted fabrics. Journal of the Korean Society of Clothing and Textiles, 37(5), 715-723. doi:10.5850/JKSCT.2013.37.5.715
  18. Zhuanyong, Z., Longdi, C., Wenliang, X., & Jianyong, Y. (2008). A study of the twisted strength of the whirled airflow in Murata Vortex Spinning. Textile Research Journal, 78(8), 682-687. doi:10.1177/0040517508089753.
  19. Zeguang, P., & Chongwen, Y. (2009). Study on the principle of yarn formation of Murata Vortex Spinning using numerical simulation. Textile Research Journal, 79(14), 1274-1280. doi:10.1177/0040517509102227.

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