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http://dx.doi.org/10.5850/JKSCT.2009.33.5.711

Characteristics of the Leaf Fiber Plants Cultivated in Korea  

Lee, Hye-Ja (Dept. of Home Economics Education, Korea National University of Education)
Kim, Nam-Eun (Dept. of Home Economics Education, Korea National University of Education)
Yoo, Hye-Ja (Dept. of Clothing & Textiles Seowon University)
Han, Young-Sook (Shinsung Girls' Highschool)
Publication Information
Journal of the Korean Society of Clothing and Textiles / v.33, no.5, 2009 , pp. 711-720 More about this Journal
Abstract
Leaf fibers have many good properties; they are strong, long, cheap, abundant and bio-degradable. Since they, however, contain a great quantity of non-cellulose components, they have been used for the materials of mats, ropes, bags and nets rather than those of clothing. In this study, we investigated the characteristics of leaf fibers in order to promote the use of leaf fibers for the materials of clothing as well as develop the high value-added textile fibers. Leaf fiber plants including New Zealand Flax, Henequen and Banana plant, which have various nature and shape, were used. New Zealand Flax and Henequen leaves were cut from lower part of plants. Banana leaves and pseudo-stems were peeled and cut from the stem of Banana plants. First, the thin outer skins like film of leaves, veins and stems were removed before retting. The chemical retting had been processed for 1hour, at 100 in 0.4% $H_2SO_4$ aqueous solution(liquid ratio 50:1). Then, the retted leaf fibers had been soaked for 1hour, at room temperature in 0.5% NaClO solution(v/v) to remove the miscellaneous materials. We investigated the physical characteristics of three leaf fibers including the transversal and longitudinal morphology, the contents(%) of pectin, lignin and hemicellulose, the length and diameter of fibers, the tensile strength of the fiber bundles, and the fiber crystallinity and the moisture regain(%). The lengths of fiber from three leaf fibers were similar to their leaf lengths. The fiber bundles were composed of the cellulose paralleled to the fiber axis and the non-cellulose intersecting at right angle with the fiber axis. The diameters of New Zealand Flax, Henequen and Banana fibers were $25.13{\mu}m$, $18.16{\mu}m$ and $14.01{\mu}m$, respectively and their tensile strengths were 19.40 Mpa, 32.16 Mpa and 8.45 Mpa, respective. The non-cellulose contents of three leaf fibers were relatively as high as 40%. If the non-cellulose contents of leaf fibers might be controlled, leaf fibers could be used for the materials of textile fiber, non-wovens and Korean traditional paper, Hanjee.
Keywords
Leaf fiber; Henequen fiber; New Zealand Flax; Banana fiber;
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Times Cited By KSCI : 1  (Citation Analysis)
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1 배현영, 이혜자, 유혜자, 한영숙. (2008). 식물섬유의 특성에 관한 연구. 한국의류학회지, 32(4), 598-607
2 송경헌, 유혜자, 이혜자, 김정희, 안춘순, 한영숙, 이전숙. (2005). 의류재료학. 서울: 형설출판사
3 이혜자, 유혜자, 한영숙. (2006). 비셀룰로스 함량에 따른 케나프 섬유의 특성 변화. 한국의류학회지, 30(11), 1681-88
4 Franck, R. R. (2005). Bast and other plant fibers. Cambridge England: Woodhead Publishing Limited
5 Idicula, M. & Neelakantan, N. R. (2005). A study of the mechanical properties of randomly oriented short Banana and sisal hybrid fiber reinforced polyester composites. Journal of Applied Polymer Science, 96(5), 1699-1709   DOI   ScienceOn
6 にわゆぎ. (2004). 바나나섬유와 그 제조방법, 그것을 이용한 혼방사, 및 섬유구조물, 대한민국 특허등록번호 2004- 0010138. 서울: 특허청
7 Joseph, S., Oommen, Z., & Thomas, S. (2006). Environmental durability of Banana-fiber-interforced phenol foraldehyde composites. Journal of Applied Polymer Science, 100(3), 2521−2531   DOI   ScienceOn
8 Aguilar-Vega, M. & Cruz-Ramos, C. A. (1995). Properties of henequen cellulosic fibers. J. Applied Polymer Science, 56, 1245-1252   DOI   ScienceOn
9 이혜자, 한영숙, 유혜자, 김정희, 송경헌, 안춘순. (2004). 케냐프섬유 분리에 대한 화학적 레팅 효과. 한국의류학회지, 28(9/10), 1281-1291
10 Piedad, G. (2004). Biological natural retting for determining the hierarchical structuration of Banana fibers. Macromolecular bioscience, 4(10), 978-983   DOI   PUBMED   ScienceOn
11 Malunka, M. E., Luyt, S. S., & Krump, H. (2006). Preparation and charaterization of Eva-sisal fiber composites. Journal of Applied Polymer Science, 100(2), 1607−1617   DOI   ScienceOn
12 Pothan, L. A. & Thomas, S. (2004). Effect of hybridization and chemical modification on the water-absorption behavior of Banana fiber-reinforced polyester composites. Journal of Applied Polymer Science, 91(6), 3856-3865   DOI   ScienceOn
13 이규배. (2004). 식물형태학. 서울: 라이프사이언스
14 Canche-escamilla, G., Rodriguez-trujillo, G., Herrera-franco, P.J., Mendizabal, E., & Puig, J. E. (1997). Preparation and characterization of Henequen Cellulose grafted with methyl methacrylate ant its application in composites. J. Applied Polymer Science, 66, 339-346   DOI   ScienceOn
15 Ramirez, A. P. & Solis, A. S. (1984). Development of a New composite material from Waste polymers, Natural fiber and Mineral fillers. J. of Applied Polymer Science, 29, 205−2412
16 Abou-Zeid, N. Y., Higazy, A., & Hebeish, A. (1984). Graft copolymerization of styrene, methylmetharylate, and acryonitrile onto jute fibers. Die Angevandte Makromolekulare Chemie, 121, 69-87   DOI
17 Removing fiber from Henequen plants. (2008, January 7). mexicanmercados. Retrieved July 15, 2008, http://www.mexicanmercados.com
18 Banana Fiber Silk Yarn. (2008, October 21). shangri-lacrafts. Retrieved November 10, 2008, from http://www.shangrilacrafts. com/banana_yarn.html
19 최봉용. (2002). 미이용 농산자원인 뉴질랜드마의 고기능 섬유화 기술 및 이 섬유를 이용한 초경량 인쇄용지 개발.대구: 경북대학교출판부
20 Piedad, G., Javier C., Saioa, G., Aitor A., & Inaki, M. (2004). Stem and bunch Banana fibers from cultivation wastes: Effect of treatments on physico-chemical behavior. J. of Applied Polymer Science, 94(4), 1489-1495   DOI   ScienceOn
21 Carr, D. J., Cruthers, N. M., Laing R. M., & Niven, B. E. (2005). Fibers from three cultivars of New Zealand Flax(Phormium tenax). Textile research J., 75(2), 99-105   DOI   ScienceOn
22 스타, C. (2006). 생명과학 이론과 응용 (6판). 홍영남, 권덕기, 김경진, 김영환, 김은희, 김재범, 김재진, 김희백, 노유선, 박순철, 박연일, 부문종, 부성민, 신현철, 안정선, 이강석, 이경호, 이성태, 이은주, 정학성, 조도순, 조형택, 진창덕 공역 (2006). 서울: 라이프사이언스
23 Natasha, M. C., Dbra J. C., Raechel M. L., & Brian E. N. (2006). Structural diffences among fibers from six cultivars of harakeke(Phormium tenaz, New Zealand flax). Textile Research Journal, 76(8), 601-606   DOI   ScienceOn
24 Joseph, M. L. (1986). Introductory to textile science. New York: CBS college publishing
25 Kijoka Banana Fiber Cloth. (2008, October 21). kougei. Retrieved November 10, 2008, from http://www.kougei.or. jp/english/crafts/0130/f0130.htm
26 El-Zawawy, W. K. (2006). Blended graft copolymer of carboxymethyl cellulose and poly(vinyl alcohl) with Banana fiber. Journal of Applied Polymer Science, 100(3), 1842-1848   DOI   ScienceOn
27 Cszaurang-Martinez, M. N., Herrera-Franco, P. J., Gonzalez-Chi, P. I., & Aguilar-Vega, M. (1991). Physical and mechanical properties of Henequen fibers. J., Applied Polymer Science, 43, 749-756   DOI
28 100년전 한인 이민 직후 사진 최초 입수. (2005, 1. 9). 연합뉴스. 자료검색일 2005, 10. 20, 자료출처 http://news.paran.com
29 이승구, 조동환, 박원호, 한성옥. (2004). 천연섬유를 이용한 친환경성 복합재료. 섬유기술과 산업, 8(4), 378-397   과학기술학회마을