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2020 | OriginalPaper | Buchkapitel

Chemical, Physical and Biological Treatments of Pineapple Leaf Fibres

verfasst von : F. N. M. Padzil, Z. M. A. Ainun, Naziratulasikin Abu Kassim, S. H. Lee, C. H. Lee, Hidayah Ariffin, Edi Syams Zainudin

Erschienen in: Pineapple Leaf Fibers

Verlag: Springer Singapore

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Abstract

Pineapple leaves are known as organic wastes that left behind after pineapple fruit have been harvested. In Malaysia, waste management of these leaves is improving time to time, whereby the leaves are collected and consigned for research and industry utilization. Based on studies, pineapple leaf contains an amount of 2.5–3.5% of fibres that layered by hydrophobic waxy substances. The fibres of pineapple leaf (PALF) are extracted and beneficial in textile industry since eighteenth century. In order to optimised the usage of the PALF in high technology application which not only in textile industry, thus, numerous chemicals, physicals and biological or even combination of fibre treatments are applied by researchers and industrial players. For instance, the PALF is recognized as suitable candidates as reinforcing agent in polymeric matrices due to its high specific strength and sustainability. It is proved that attributable to inexpensive, abundant and good mechanical strength obtained by controlling the treatment methods has positioned the PALF as popular fibres in the development of functionalized smart and intelligent products.

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Vorheriges Kapitel Improving the Properties of Pineapple Leaf Fibres by Chemical Treatments

Nächstes Kapitel Physical, Morphological, Structural, Thermal and Mechanical Properties of Pineapple Leaf Fibers

Ab Halim N (2016) Policy intervention for the development of the pineapple industry in Malaysia. Agricult Mark Policy. http://ap.fftc.agnet.org/ap_db.php?id=716&print=1 Accessed 13 Feb 2019

Abd Razak SI, Ahmad Sharif NF, Mat Nayan NH et al (2015) Impregnation of poly (lactic acid) on biologically pulped pineapple leaf fiber for packaging materials. BioRes 10(3):4350–4359CrossRef

Araujo R, Casal M, Cavaco-Paulo (2008) Application of enzymes for textile fibres processing. Biocatal Biotransform 26(5):332–349

Aremu MO, Rafiu MA, Adedeji KK (2015) Pulp and paper production from nigerian pineapple leaves and corn straw as substitute to wood source. Int Res J Eng Technol 2(4)

Asim M, Jawaid M, Abdan K et al (2018) Effect of alkali treatment on physical and mechanical strength of pineapple leaf fibres. IOP Conf Ser: Mater Sci Eng 290:012030CrossRef

Asim M, Khalina Abdan M, Jawaid M et al (2015) A review on pineapple leaves fibre and its composites. Int J Polym Sci 1–16

Bachtiar D, Sapuan SM, Hamdan MM (2008) The effect of alkaline treatment on tensile properties of sugar palm fibre reinforced epoxy composites. Mater Des 29(7):1285–1290CrossRef

Banerjee R, Chintagunta AD, Ray S (2019) Laccase mediated delignification of pineapple leaf waste: an ecofriendly sustainable attempt towards valorization. BMC Chem 13:58CrossRef

Banik S, Nag D, Debnath S (2011) Utilization of pineapple leaf agro-waste for extraction of fibre and the residual biomass for vermicomposting. Ind J Fibre Text Res 36:172–177

10.

Buana MSAS, Pasbaskhsh P, Goh KL et al (2013) Elasticity, microstructure and thermal stability of foliage and fruit fibres from four tropical crops. Fibers Polym 14(4):623–629CrossRef

11.

Buchert J, Pere J, Puolakka A et al (2000) Scouring of cotton with pectinases, proteases, and lipases. Textile Chem Colorist Am Dyestuff Report 32(5)

12.

Buschle-Diller G, Fanter C, Loth F (1999) Structural changes in hemp fibers as a result of enzymatic hydrolysis with mixed enzyme systems. Text Res J 69:244–251CrossRef

13.

Cherian BM, Leão AL, de Souza SF et al (2010) Isolation of nanocellulose from pineapple leaf fibres by steam explosion. Carbohydr Polym 81(3):720–725CrossRef

14.

Cordeiro N, Gouveia C, John MJ (2011) Investigation of surface properties of physico-chemically modified natural fibres using inverse gas chromatography. Indust Crops Prod 33:108–115CrossRef

15.

DOA (2017) Fruit crops statistics 2017. Department of Agriculture Malaysia

16.

Das PK, Nag D, Debnath S et al (2010) Machinery for extraction and traditional spinning of plant fibres. Indian J Tradit Knowl 9(2):386–393

17.

Debnath S (2016) Pineapple leaf fibre—a sustainable luxury and industrial textiles. In: Muthu S, Gardetti M (eds) Handbook of sustainable luxury textiles and fashion. Environmental footprints and eco-design of products and processes. Springer, Singapore

18.

Dey SK, Nag D, Das PK (2009) New dimensions of pineapple leaf fibre—an agrowaste for textile application. In: Shukla JP (ed) New technologies for rural development having potential of commercialisation. Allied Publishers Private Limited, Delhi, pp 115–127

19.

Doraiswami I, Chellamani P (1993) Pineapple leaf fibres. Text Prog 24(1):1–37CrossRef

20.

Dutta S, Bhattacharyya D (2013) Enzymatic, antimicrobial and toxicity studies of the aqueous extract of Ananascomosus (pineapple) crown leaf. J Ethnopharmacol 150:451–457CrossRef

21.

Ghosh SK, Sinha MK (1977) Assessing textile values of pineapple fibre. Indian Text J 88(111–115):8

22.

Ghosh SK, Sinha MK, Dey SK et al (1982) Processing of pineapple leaf fibre (PALF) in cotton machinery. Text Trends 24:49–53

23.

Hansen CM, Björkman A (1998) The ultra-structure of wood from a solubility parameter point of view. Holzforschung 52:335–344CrossRef

24.

Hartzell MM, Hsieh YL (1998) Enzymatic scouring to improve cotton fabric wettability. Text Res J 68(4):233–241CrossRef

25.

John JM, Thomas S (2008) Biofibers and biocomposites. Carbohydr Polym 71:343–364CrossRef

26.

Jose S, Salim R, Ammayappa L (2016) An overview on production, properties, and value addition of pineapple leaf fibres (PALF). J Nat Fibres 13(3):362–373CrossRef

27.

Kengkhetkit N, Amornsakchai T (2012) Utilisation of pineapple leaf waste for plastic reinforcement: 1. A novel extraction method for short pineapple leaf fiber. Indust Crops Prod 40:55–61CrossRef

28.

Leao AL, Souza SF, Cherian BM et al (2010) Pineapple leaf fibres for composites and cellulose. Mol Cryst Liq Crystals 522(1):36–41

29.

Leao AL, Cherian BM, Narine S et al (2015) The use of pineapple leaf fibres (PALSs) as reinforcement in composites. Biofibre Reinf Compos Mater 211–235

30.

Li Y, Hardin ZR (1997) Enzymatic scouring of cotton: effects on structure and properties. Cellulose 94(88):96

31.

Li X, Tabil LG, Panigrahi S (2007) Chemical treatments of natural fibre for use in natural fibre-reinforced composites: a review. J Polym Environ 15(1):25–33CrossRef

32.

Misra M, Hinrichsen G (2004) A review on pineapple leaf fibers, sisal fibers and their biocomposites. Macromol Mater Eng 289:955–974CrossRef

33.

Mohanty AK, Misra M, Hinrichsen G (2000) Biofibres biodegradable polymers and biocomposites: an overview. Macromol Mater Eng 276–277(1):1–24CrossRef

34.

Moya R, Berrocal A, Rodríguez-Zúñiga A et al (2016) Biopulp from pineapple leaf fiber produced by colonization with two white-rot fungi: Trametes versicolor and Pleurotus ostreatus. BioRes 11(4):8756–8776CrossRef

35.

Munawar SS, Umemura K, Tanaka F et al (2008) Effects of alkali, mild steam, and chitosan treatments on the properties of pineapple, ramie, and sansevieria fiber bundles. J Wood Sci 54:28–35CrossRef

36.

Mwaikambo LY (2006) Review of the history, properties and application of plant fibres. African J Sci Technol Sci Eng Ser 7:120–133

37.

Nayan NHM, Razak SIA, Rahman WAWA et al (2013) Effects of mercerization on the properties of paper produced from Malaysian pineapple leaf fiber. Inter J Eng Technol 13(4):1–6

38.

Nayan NHM, Razak SIA, Rahman WAWA (2014) Biopulping by Ceriporiopsis subvermispora towards pineapple leaf fiber (PALF) paper properties. Adv Mater Res 1043:180183

39.

Nikmatin S, Rudwiyanti JR, Prasetyo KW et al (2015) Mechanical and optical characterization of bio-nanocomposite from pineapple leaf fibre material for food packaging. In: International seminar on photonics, optics and its applications (ISPhOA2014), vol 9444, pp 1–6

40.

Othman MH, Buang L, Mohd Khairuzamri MS (2011) Rejuvenating the Malaysia pineapple industry. Acta Horti 902

41.

Panagiotopoulos IA, Lignos GD, Bakker RR et al (2012) Effect of low severity dilute-acid pretreatment of barley straw and decreased enzyme loading hydrolysis on the production of fermentable substrates and the release of inhibitory compounds. J Clean Prod 32:45–51CrossRef

42.

Pandey SN (2007) Ramie fibre: Part II. Physical fibre properties. A critical appreciation of recent developments. Text Prog 39:189–268CrossRef

43.

Panyasart K, Chaiyut N, Amornsakchai T et al (2014) Effect of surface treatment on the properties of pineapple leaf fibers reinforced polyamide 6 composites. Energy Procedia 56:406–413CrossRef

44.

Paster M, Pellegrino JL, Carole TM (2003) Industrial bioproducts: today and tomorrow. Report prepared for the US Department of Energy, Washington, DC

45.

Payae Y, Lopattananon N (2009) Adhesion of pineapple-leaf fiber to epoxy matrix: the role of surface treatments. Songklanakarin J Sci Technol 31:189–194

46.

Porzi GF, Prussi M, Chiaramonti D et al (2012) Modelling lignocellulosic bioethanol from poplar: estimation of the level of process integration, yield and potential for co-products. J Clean Prod 34:66–75CrossRef

47.

Rajesh Bapu TN, Kumaragurubaran SB, Venkataramanan R et al (2015) A review on effect of chemical treatment of natural fibres on mechanical properties. Inter J of Applied Engin Research 10(19):14703–14714

48.

Ramli SNR, Fadzullah S, Mustafa Z (2016) Mechanical performance of pineapple leaf fiber reinforced poly lactic acid (PLA) biocomposites. Proc Mech Eng Res 131–132

49.

Rana S, Pichandi S, Parveen S et al (2014) Natural plant fibres: production, processing, properties and their sustainability parameters (Chap. 1). In: Roadmap to sustainable textiles and clothing. Textile science and clothing technology. Springer, Berlin, pp 1–35

50.

Rout J, Misra M, Tripathy SS et al (2001) The influence of fibre treatment on the performance of coir-polyester composites. Compos Sci Technol 61(9):1303–1310CrossRef

51.

Sarkar PB, Chatterjee H (1948) The bleaching of jute with chlorite. J Text Inst 39:74–81

52.

Sedelnik N (2004) Properties of hemp fibre cottonised by biological modification of hemp hackling noils. Fibres Text East Eur 12(1):58–60

53.

Siakeng R, Jawaid M, Ariffin H et al (2018) Physical properties of coir and pineapple leaf fibre reinforced polylactic acid hybrid composites. IOP Conf Ser Mater Sci Eng 290:012031CrossRef

54.

Sibaly S, Jeetah P (2017) Production of paper from pineapple leaves. J Environ Chem Eng 5:5978–5986CrossRef

55.

Singhal A, Jaiswal PK, Thakur IS (2015) Biopulping of bagasse by Cryptococcus albidus under partially sterilized conditions. Inter Biodeter Biodegrad 97:143–150CrossRef

56.

Sricharussin W, Ree-iam P, Phanomchoeng W et al (2009) Effect of enzymatic treatment on the dyeing of pineapple leaf fibres with natural dyes. Sci Asia 35(1):31–36CrossRef

57.

Threepopnatkul P, Teppinta W, Sombatsompop N (2011) Effect of co-monomer ratio in ABS and wood content on processing and properties in wood/ABS composites. Fibers Polym 12:1007–1013CrossRef

58.

Threepopnatkul P, Krachang T, Teerawattanan W et al (2012) Study of surface treatment of pineapple leaf fiber (PALF) on performance of PALF/ABS composites. In: 15th European conference on composite materials, Venice, Italy, pp 1–7

59.

Yang Y, Sharma-Shivappa R, Burns JC, Cheng JJ (2009) Dilute acid pretreatment of oven-dried switchgrass germplasms for bioethanol production. Energy Fuels 23:3759–3766CrossRef

60.

Yusof Y, Ahmad MR, Wahab MS et al (2012) Producing paper using pineapple leaf fiber. Adv Mater Res 383:3382–3386

61.

Zahari MAKM, Abdullah SSS, Roslan AM et al (2014) Efficient utilization of oil palm frond for bio-based products and biorefinery. J Clean Prod 65:252–260CrossRef

62.

Zin MH, Abdan K, Mazlan N et al (2018) The effect of alkali treatment on the mechanical and chemical properties of pineapple leaf fibres (PALF) and adhesion to epoxy resin. IOP Conf Ser: Mater Sci and Engin 368:012035

63.

Zwane PE, Masarirambi MT, Thwala JM et al (2014) Enzymatic processing of plant fibres for diversified uses. In: RUFORUM fourth biennial conference, Maputo, Mozambique, 19–25 July 2014, pp 391–392

Titel: Chemical, Physical and Biological Treatments of Pineapple Leaf Fibres
verfasst von: F. N. M. Padzil
Z. M. A. Ainun
Naziratulasikin Abu Kassim
S. H. Lee
C. H. Lee
Hidayah Ariffin
Edi Syams Zainudin
Verlag: Springer Singapore
Buch: Pineapple Leaf Fibers
Print ISBN: 978-981-15-1415-9

Electronic ISBN: 978-981-15-1416-6

Copyright-Jahr: 2020
DOI: https://doi.org/10.1007/978-981-15-1416-6_5

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