Published
2018-02-07
Issue
Section
Original Research Article
License
The Author(s) warrant that permission to publish the article has not been previously assigned elsewhere.
Author(s) shall retain the copyright of their work and grant the Journal/Publisher right for the first publication with the work simultaneously licensed under:
OA - Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC 4.0). This license allows for the copying, distribution and transmission of the work, provided the correct attribution of the original creator is stated. Adaptation and remixing are also permitted.
This license intends to facilitate free access to, as well as the unrestricted reuse of, original works of all types for non-commercial purposes.
How to Cite
Quantitative Analysis of Chemical Components of Plant Fiber
Huiping Song
Huaiqiang Wu
Xiaoguang Li
DOI: https://doi.org/10.24294/ace.v1i1.347
Abstract
With the shortage of petrochemical resources and the constant pursuit of high quality of life, natural cellulose fiber is widely used in the papermaking field because of its good comfort, resource availability and environmental friendliness. At the same time plant resources as an important source of natural cellulose fiber, also received attention. China is rich in plant resources, paper that made by plant fiber and a wide range of raw materials, such as cotton, linen, mulberry bark, Eulaliopsis, palm leaves, all kinds of bamboo, coconut shells, straw and so on. Quantitative analysis of the chemical composition of plant fiber and its resources is usually carried out by the national standard GB/T5889-865 quantitative analysis of chemical composition of wheat straw but the standard is formulated for wheat straw raw materials, in the analysis of other plant fiber raw materials will inevitably exist some of the problems, therefore, require a relatively accurate and generally applicable method for chemical analysis of plant fiber raw materials.
References
1. Zhuang Fucui. Plant fiber and fiber plant [J]. Biological Bulletin, 2001,36 (n): 16-18.2. Yang Shuhui. Plant fiber chemistry [M]. Beijing: China Light Industry Press, 2001,4-20,43,50,69,112,163,2-4.
3. Guo Jianxin, Wang Gaosheng, Chen Fushan. Liquefaction of plant fiber raw materials and its application [J]. World Forestry Research, 2007,2,20 (1): 55-60.
4. Jing Xueqian.Study and performance of mulberry fiber in southern Shaanxi [D]. Xi'an: Xi'an University of Engineering, 2007,1-7.
5. Zhang Sumei. Natural plant fiber [J]. China Fiber Inspection, 2004,11: 45-47.
6. XIANG Xin-zhu, ZENG Ying, YANG Ming et al.Quantitative analysis of chemical composition of phragmites [J]. Progress in Papermaking Science and Technology, 2007, 5: l.
7. IshikawaA, okanoT, SugiyamaJ.Fine strueture and tensile properties of rie fibers in the erystalline form of eellulose l, 11,111 and IV [J]. Polymer, 1997, 38 (2): 463.
8. Zhang Yanhui, Yu Chongwen. Preliminary Study on Chemical Degumming Technology of Eulaliopsis binata [J]. Progress in Papermaking Science and Technology, 2005,5: 54-56.
9. YU Li-hong, TANG Shu-juan, HAN Li-shun.New papermaking fiber material [J].
10. Technology, 2006, 1: 54-56.
11. Jiang Wei. Fast quantitative analysis of chemical composition of Lambda chinensis based on near-infrared technology [D]. Qingdao: Qingdao University, 2009,2-9,15-26
12. Tan Renxiang. Plant composition analysis [M]. Beijing: Science Press, 2002,597-610.
13. GB / T2677.1-10. Paper National Standard [S]. Beijing: China Standard Press, 1993-1996.
14. Pei Huaqiang, Zhai Yaohua. Cotton stalk fiber chemical degumming technology [J]. Shandong Paper Science and Technology, 2008 (4): 30-32.
15. X.PhilipYe, LuLiu, DouglasHays.Fast classifieation and eompositional analysis of eornstover fraetions using Fourier transfor near-infrared teehniques [J]. Bioresouree Technology 99 (2008) 7323-733.
16. GONG Hui-he.Studies on Quantitative Analysis Methods of Chemical Constituents of Wheat Straw Fibers [J]. Fiber Standard and Testing, 1988, 12: 8-9.
17. JIANG Shao-jun, WU Hong-ling, LI Zhi-zhong et al.Study on quantitative analysis method and properties of chemical composition of flax fiber [J].
18. Zhao Xiaofeng, Zhang Jun, Li Subo et al. Quantitative analysis of chemical composition of flax fiber [J]. Shanghai Papermaking Technology, 2008,2,36 (2): 49-51.
19. James S. Han, Jeffrey S. R.owell. Paer and composites from agro-based resourees-ChaPter5: Chemieal Composition of Fibers
[M]. BoeaRaton: CRC / LewisPublishers, 1997, 84-106.
20. Stephen S. Kellley, Roger M. Rowell, Mark Davis, et al. Rapidal analysis of the chemieal Composition of agrieultural fibers using near in frared spectroseopy and pyrolysis Molexular beam mass speetrometry [J]. Biomass and Bioenergy 27 (2004) 77 -88
21. Wu Jun. Near-infrared Reflectance Spectroscopy Analysis of Corn Straw Cellulose Content [J]. Chinese Journal of Analytical Chemistry, 2005, 33 (10): 1421-1423.
22. Zaldivar, NielsenJ, 01ssonL.Fuel ethanol Produetion from lignoeellulose: Aehallenge for metabolic engineering and proeess
integration [J]. Applied Microbiology and Bioteehnology, 2001, 56 (l-2): 17-34.
23. Qu Cai Lian, Dou Mingchi, Wang Bo. Several new plant fiber and its application [J]. China Fiber Inspection, 2006 (5): 32-34.
24. Jiang Fanchang, Shao Kuan. GB / T5889-1986 quantitative analysis of chemical composition of wheat straw [S]. Beijing: China Standard Press, 2000.
25. Yao Mu, et al. Papermaking materials [M]. Beijing: China Paper Publishing House, 2004,10: 322.
26. Chen Xue. Paper Materials Science [EB/OL] .http: //user.qzone.qq.eom/764313038,2009.6.5
27. Mu Guangzhao. Practical solvent manual [M]. Shanghai: Shanghai Science and Technology Press, 1990: 451.
28. Wei Peng Yue, Yang Yanfei. GB / T2677.6-94 paper raw materials, organic matter content determination [5]. Beijing: China Standard Press, 1995..