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Leaf fibres

Ramie, Sunn Hemp, (2) Leaf Fibres Sisal, Manila, Phormium, Ibid., 972-84. [Pg.183]

Turner, A. J., Bast and Leaf Fibres—Development and Prospects, 325-38 ... [Pg.183]

Holden, M. A study of enzymes that can break down tobacco-leaf components. 3. Fungal polygalacturonase on leaf fibre Biochem J. 47 (1950) 415 20. 1825. [Pg.1332]

Sisal or sizal, hard leaf fibre from the sisal plant Agave sisalana). [Pg.91]

Ersoy, S. Kucuk, H. (2009). Investigation of industrial tea-leaf-fibre waste materialfor its sound absorption properties. Applied Acoustics, Vol.70, No.l, (January 2009), pp. 215-220, ISSN 0003-682X... [Pg.214]

Banana fibre, Pine apple leaf fibre (PALE) homogenisation by 15 passes through a laboratory homogeniser, operated at 500 bars and 90-95°C TEMPO mediated oxidation Acid treatment coupled with high pressure Banana fibre having 4-5 nm in diameter... [Pg.30]

Cherian et al. [119] also extracted cellulose nanofibres from pineapple leaf fibres using acid-coupled steam treatment. The strucmral and physicochemical properties of the pineapple leaf fibres were studied by environmental scanning electron microscopy (ESEM), AFM and TEM and X-ray diffi action (XRD) techniques. The acid-coupled steam explosion process resulted in the isolation of PALF nanofibres having a diameter range of 5-60 nm. Figure 1.24a and b shows the AFM and TEM images of nano fibres obtained from pineapple leaf fibres. AFM and TEM support the evidence for the isolation of individual nanofibres from PALF. [Pg.34]

Cherian BM, Leao AL, Souza SF, Thomas S, Pothan LA, Kottaisamy M (2010) Isolation of nanocellulose from pineapple leaf fibres by steam explosion. Carbohydr Polym 81 720-725... [Pg.42]

Basu A, Chellamani KP, Kumar PR (2003) Jute and pineapple leaf fibres for the manufacture of technical textiles. Asian Text J 12 94-96... [Pg.339]

Bhaduii SK, Sen SK, Dasgupta PC (1983) Structural studies of an acidic polysaccharide isolated from the leaf fibre of pineapple (Ananas comosus MERR). Carbohydr Res 121 211-220 Bhattacharya TB, Biswas AK, Chatterjee J, Pramnick D (1986) Short pineapple leaf fibre reinforced rubber composites. Plast Rubb Process Appl 6 119-125 Bismarck A, Mishra S, Lampke T (2005) Plant fibers as reinforcement for green composites. In Mohanty AK, Misra M, Drzal LT (eds) Natural fibers, biopolymers and biocomposites. Taylor Francis, EL, Boca Raton... [Pg.340]

George J, Bhagawan SS, Thomas S (1998a) Improved interactions in chemically modified pineapple leaf fibre reinforced polyethylene composites. Cranpos Inlerf 5 201-223 George J, Bhagawan SS, Thomas S (1998b) Effects of environment on the properties of low-density polyethylene composites reinforced with pineapple fibers. Compos Sci Technol 58 1471-1485... [Pg.340]

Ghosh SK, Dey SK, Dey A (1988) Tensile behaviour and processing of bleached yam from pineapple leaf fibre. Indian J Text Res 13 17-20... [Pg.340]

Hayavadana J, Jacob M, Sampath G (2003) Diversified product of pine apple leaf fibres. Man Made Text India 46 301-305... [Pg.341]

Mangal R, Saxena NS, Sreekala MS, Thomas S, Singh K (2003) Thermal propoties of pineapple leaf fiber reinforced composites. Mater Sci Eng A 339 281-285 Mishra S, Misra M, Tripathy SS, Nayak SK, Mohanty AK (2001) Potentially of pineapple leaf fibre as reinforcement in PALF-polyester composite surface modification and mechanical performance. J Reinf Plast Compos 20 322-334... [Pg.341]

Munirah M, Rahmat AR, Hassan A (2007) Characterization and treatment of pineapple leaf fibre thermoplastic composite for constmction application. Research Report, Department of Polymer Engineering, Faculty Chemical and Faculty Natural Resources, Universiti Teknologi Malaysia, pp 1-63... [Pg.342]

Siregar JP, Sapuan SM (2009) Mechanical properties of pineapple leaf fibre (PALF) reinforced high impact polystyrene (HIPS) composites. In Sapuan SM (ed) Research in natural fibre reinforced polymer composites. UPM, Serdang, Selangor, Malaysia... [Pg.343]

Tripathy PC, Misra M, Parija S, Mishra S, Mohanty AK (1999) Studies of Cu(II)-I04 initiated graft copolymerization of methyl methacrylate from defatted pineapple leaf fibres. Polym Int 48 868-872... [Pg.343]

Pineapple leaf fibre (PALF), which is rich in cellulose, relatively inexpensive and abundantly available has the potential for polymer-reinforced composite. PALF at present is a waste product of pineapple cultivation. Hence, without any additional cost input, pineapple fibres can be obtained for industrial purposes. Among various natural fibres, PALFs exhibit excellent mechanical properties. These fibres are multicellular and lignocellulosic. They are extracted from the leaves of the plant Ananus cosomus belonging to the Bromeliaceae family by retting. The main chemical constituents of pineapple fibres are cellulose (70-82%), lignin (5-12%) and ash (1.1%). The superior mechanical properties of PALFs are associated with their high cellulose content. [Pg.671]

Arib RMN, Sapuan SM, Ahmad MMHM et al (2006) Mechanical properties of pineapple leaf fibre reinforced polypropylene composites. Mater Des 27 391-396... [Pg.698]

PA. Sreekumara, K. Joseph, G. Unnikrishnana, and S. Thomas, A comparative study on mechanical properties of sisal-leaf fibre-reinforced polyester composites prepared by resin transfer and compression moulding techniques. Compos. Sci. Technol. 67,453-461 (2007). [Pg.279]

M. Mokhtar, A. Hassan, A. R. Rahmat, and S. Abd Samat, Characterization and treatments of pineapple leaf fibre thermoplastic composite for construction application, Universiti Teknologi Malaysia Institutional Repository. (2005). [Pg.451]

Mussig, Kams, M and Franck, R.R. (2005) Bast and leaf fibre composite materials. Chapter 10, in Bast and Other Plant Fibres (ed. R.R. Franck), Woodhead... [Pg.222]

WOOD FIBRES BAST FIBRES LEAF FIBRES == SEAD AND FRUIT FIBRES 1 WOOL 1... [Pg.126]

Leaf fibres are mainly obtained from agave plants and are called sizal. Sizal is planted on an industrial scale in a few countries - the most important producers are Indonesia, Tanzania and Flaiti. Sizal fibres are chopped or used as continuous fibres up to 1.5 m in length for making non-woven mats. Their maximum strain is 2-4%. Sizal fibres are also used as twine and spun with short chopped fibres and a small amount of steel fibres. Such a hybrid reinforcement has proved to be cheap and efficient (Mwamila 1985). [Pg.128]

Cellulosic fibres from vegetable sources other than cotton and wood are used in a variety of textile and industrial products. These fibres are mostly obtained either from the leaves of tropical plants or from the stems of reed-like plants. Leaf fibres are generally stiff ( hard fibres ) and are used mostly for cordage. Stem fibres (also known as bast fibres) are usually finer ( soft fibres ) and find use in textile applications. The cellulose content of these materials is usually in the range 70—90% (on dry weight). The more important commercial products and their principal usage are shown below. [Pg.248]

See other pages where Leaf fibres is mentioned: [Pg.2]    [Pg.16]    [Pg.194]    [Pg.37]    [Pg.116]    [Pg.252]    [Pg.401]    [Pg.6]    [Pg.17]    [Pg.341]    [Pg.342]    [Pg.343]    [Pg.395]    [Pg.664]    [Pg.664]    [Pg.230]    [Pg.278]    [Pg.359]    [Pg.278]   
See also in sourсe #XX -- [ Pg.6 , Pg.17 , Pg.30 , Pg.34 ]



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