Research Article
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Year 2020, Volume: 3 Issue: 1, 1 - 4, 30.07.2020

Duygu Yavuzkasap Ayakta , Eren Öner

Abstract

Bu çalışmada, kamgarn dokuma kumaşların hava geçirgenliği, termal iletkenlik, termal yayılım, termal emicilik ve termal direnç özelliklerine kaşmir lifi kullanımın etkileri detaylarıyla araştırılmıştır Bu amaçla, beş farklı kaş mir/yün karışım oranlarına sahip kamgarn dokuma kumaşlar sistematik üretilmiştir. Test sonuçlar kamgarn kumaş yapısında kaşmir lifi kullanımının son kullanıcı açısından daha iyi termal konfor özellikleri verdiğini göstermiştir.                                                                                                                                   

Keywords

Kaşmir yün kamgarn kumaş hava geçirgenliği termal konfor

References

  • [1] Başer İ. (2002). In Elyaf Bilgisi; Kaşmir. 2. Baskı. İstanbul:Marmara Üniversitesi Teknik Eğitim Fakültesi Yayınları: İstanbul, Türkiye, p 87.
  • [2] Tang M.; Zhang W.; Zhou H. et al. (2014). A real-time PCR method for quantifying mixed cashmere and wool based on hair mitochondrial DNA, Textile Research Journal, 84(15): 1612–1621.
  • [3] McGregor, B. A. and Naebe (2013). M. Effect of fibre, yarn and knitted fabric attributes associated with wool comfort properties. Journal of The Textile Institute, 104(6): 606-617.
  • 4. McGregor, B. A. and Postle, R. (2008). Mechanical properties of cashmere single jersey knitted fabrics blended with high and low crimp superfine Merino wool. Textile Research Journal, 78(5): 399-411.
  • 5. Raja, A.S.M. Shakyawar, D. B., Pareek, P. K. and Wani, S. (2011). A. Production and performance of pure cashmere shawl fabric using machine spun yarn by nylon dissolution process. Indian Journal of Small Ruminants, 17(2): 203-206.
  • 6. Li, L. and Zhou (2006). W. Analysis on the pilling factors of cashmere knitted fabric. Fibers and Polymers, 7(2), 213-216.
  • 7. Alimaa, D., Matsuo, T., Nakajima, M. and Takahashi, M. (2000). Effects of yarn bending and fabric structure on the bending properties of plain and rib knitted fabrics. Textile Research Journal, 70(9): 783-794.
  • 8. Hes L, Araujo M and Djulay V. (1996). Effect of mutual bonding of textile layers on thermal insulation and thermal-contact properties of fabric assemblies. Textile Research Journal, 66, 245–255.
  • 9. Can, Ö.; Kaşıkçı, D. (2017). Sürdürülebilirlik açisindan keçi lifleri ve geleceği üzerine bazi değerlendirmeler. Akademia Mühendislik ve Fen Bilimleri Dergisi, 1 (3), 184-195.

The Effect of Cashmere Fibres on the Thermal Comfort Properties of Worsted Fabrics

Year 2020, Volume: 3 Issue: 1, 1 - 4, 30.07.2020

Duygu Yavuzkasap Ayakta , Eren Öner

Abstract

In this study, the effects of cashmere fibre using on the air permeability, thermal conductivity, thermal diffusivity, thermal absorptivity and thermal resistance of the worsted fabrics were investigated in detail. For this purpose, worsted fabrics hav ing five different cashmere/wool blend were produced systematically. The test results have revealed the using of the cashmere fibre in the structure of worsted fabrics causes better thermal comfort in terms of end user.                                                                                                                                                                        

Keywords

Cashmere wool worsted fabric air permeability thermal comfort

References

  • [1] Başer İ. (2002). In Elyaf Bilgisi; Kaşmir. 2. Baskı. İstanbul:Marmara Üniversitesi Teknik Eğitim Fakültesi Yayınları: İstanbul, Türkiye, p 87.
  • [2] Tang M.; Zhang W.; Zhou H. et al. (2014). A real-time PCR method for quantifying mixed cashmere and wool based on hair mitochondrial DNA, Textile Research Journal, 84(15): 1612–1621.
  • [3] McGregor, B. A. and Naebe (2013). M. Effect of fibre, yarn and knitted fabric attributes associated with wool comfort properties. Journal of The Textile Institute, 104(6): 606-617.
  • 4. McGregor, B. A. and Postle, R. (2008). Mechanical properties of cashmere single jersey knitted fabrics blended with high and low crimp superfine Merino wool. Textile Research Journal, 78(5): 399-411.
  • 5. Raja, A.S.M. Shakyawar, D. B., Pareek, P. K. and Wani, S. (2011). A. Production and performance of pure cashmere shawl fabric using machine spun yarn by nylon dissolution process. Indian Journal of Small Ruminants, 17(2): 203-206.
  • 6. Li, L. and Zhou (2006). W. Analysis on the pilling factors of cashmere knitted fabric. Fibers and Polymers, 7(2), 213-216.
  • 7. Alimaa, D., Matsuo, T., Nakajima, M. and Takahashi, M. (2000). Effects of yarn bending and fabric structure on the bending properties of plain and rib knitted fabrics. Textile Research Journal, 70(9): 783-794.
  • 8. Hes L, Araujo M and Djulay V. (1996). Effect of mutual bonding of textile layers on thermal insulation and thermal-contact properties of fabric assemblies. Textile Research Journal, 66, 245–255.
  • 9. Can, Ö.; Kaşıkçı, D. (2017). Sürdürülebilirlik açisindan keçi lifleri ve geleceği üzerine bazi değerlendirmeler. Akademia Mühendislik ve Fen Bilimleri Dergisi, 1 (3), 184-195.
There are 9 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Articles
Authors

Duygu Yavuzkasap Ayakta 0000-0003-0108-9839

Eren Öner 0000-0003-2770-414X

Publication Date July 30, 2020
Submission Date July 6, 2019
Published in Issue Year 2020 Volume: 3 Issue: 1