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- Introduction to forest-based bioeconomy
- Wood products
- Natural fibre products
- Man-made bio-based fibre products
- Bio-based nanomaterials
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- Pulping and biorefining
- Energy and biofuels
- Biomass chemistry and physiology
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Linear polymer behaviour
Man-made bio-based fibre products
- Introduction to man-made bio-based fibre products
- Man-made bio-based fibre products and their end-uses
- Textile fibres, processing and end-uses
- Key aspects of the down-stream conversion processes
- Production of bio-based fibres
- Dissolving pulp as a raw material
- Cellulose esters of organic acids
- Production of viscose fibres
- General description of carbamate processes
- Production of lyocell fibres
- Production of Cupro fibres
- Carbon fibres from regenerated cellulose
- Production of Alginate fibres
- Viscose and lyocell machinery developments
- Processing of silkworm and spider silk protein fibres
- Polylactide fibres
- Polyhydroxyalcohols PHA and poly(caprolactone)
- Scientific principles of polymer fibre forming
- Alternative and emerging processes for bio-based synthetic fibers
- Ionic liquid as direct solvents: Ioncell-F method
- Enzymatic activation of cellulose – Biocelsol method
- Cellulose carbamate process
- Direct spinning of cellulose composite fibre yarn
- Cellulose-lignin blend as carbon fibre raw material
- Bio-based polyolefines — emerging processes
- Bio-based polyesters — emerging processes
- Polyamides from ligno-cellulosics as raw materials
- Industrial development with silkworm and spider silk
Authors & references
Author:
Professor Emeritus, Pertti Nousiainen, Tampere University
References:
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- Meredith, R., The Structure and Properties of Fibres, Textile Progress 7 (1975) 4, 85 p Denny, M., The physical properties of spider´s silk and their role in the design of orbwebs, Journal of Experimental Biology, Vol 65, 1976, pp. 484–486.
- Happey, F. (ed.), Applied Fibre Science, Vol. 3, Academic Press, London 1979, 553 p.
- Perepelkin, K.E., Structural mechanics of polymeric fibres. Reviews and new conceptions. Proceedings of the Textile Institute’s 77-th World Conference, v. 2, p. 19–28, Tampere, (Finland) 1996.
- Sundquist, J., Ed. Luonnonkuidut, Tampere University of Technology, 1981.
- Linde,W.W. and Ossipow, P.A., Die Seide, Fachverlag Leipzig, Leipzig 1954, 526
- Carmichael, S., Viney, C., Molecular order in Spider Major Ampullate Silk (Dragline): Effects of Spinning Rate and Post-Spin Drawing, Journal of Applied Polymer Science, Vol. 72, 895–903 (1999)
- Teule, F., Aube, C., Ellison, M. and Abbott, A., Biomimetic manufacturing of Customized Novel Fiber Proteins for Specialised Applications. Proceed. 3rd Autex Conference, Gdansk, Book I, Technical University of Lodz, June 25–27, 2003, pp. 38–43.
- Happey, F. (ed.), Applied Fibre Science, Vol. 3, Academic Press, London 1979, 553 p.
- Schmidt-Rohr, K, Hu, W. and Zumbylyadis, N., Elucidation of the Chain Conformation in a Glassy Polyester (PET) by Two-Dimensional NMR, Science Vol. 280, 1 May 1998, pp. 714–717.
- Development of PTT fibres and textile application fields, ITB International Textile Bulletin, 3/2002, pp. 42–43.
- Perepelkin. K.E., Theoretical and limited properties of fibres. Fibres with extreme properties. Bulletin of Sankt-Petersburg State University of Technology and Design. St-Pb., SUTD Publ., 1999. p. 26–33
- Perepelkin, K.E., Extreme properties of fibres. Fibres with extreme properties. Theory, practice and perspectives. Book of Abstracts. Conference ENSITM – University of Mulhouse, France. 1997. p. 105–110.
- Perepelkin K.E. Periodic Table of Elements – the Basis for Forecasting Extreme Properties and for the Creation of New High-Performance Oriented Materials (Fibres, Whiskers). (Lecture of 5th International Conference on Frontiers of Polymers and Advanced Materials). Molecular Crystals and Liquid Crystals. 2000, v. 354, p. 275–286.
- K.E. Perepelkin, The theoretical and maximum attainable strength of different one-axially oriented polymers (fibres, films), Mechanics of Polymers. 1966, No. 6, 845–856.
- N.H. Macmillan, The ideal strength of solids in: Atomic fracture, Ed. by R. Latanision, J. R. Pickens. New York, Plenum Press, 1983. – p. 95–164
- G.M. Bartenev, Strength and destruction mechanism of polymers, Moscow: Khimiya Publ., 1984. – 280 p.
- Perepelkin, K.E., Russian aromatic fibres. In book: High-performance fibres. Ed. by J.W.S. Hearle. Woodhead Publ. House. Oxford, 2001 – in press.
- Perepelkin K.E., Matchalaba N.N. Recent achievements in structural ordering and control of properties of para-aramid fibers. (Lecture of 5th International Conference on Frontiers of Polymers and Advanced Materials). Molecular Crystals and Liquid Crystals. 2000, v. 354, p. 331 (920)–345 (933).
- Matchalaba N.N., Perepelkin K.E. Aramid fibre development – today and future. 1st Central European Conference “Fiber-Grade Polymers, Chemical Fibers and Special Textiles. Lodz, 03–04.10.2000. Proceedings. Lodz, Institute of Chemical Fibres. Chapter 14. 2001. P.
- Perepelkin, K.E., Multi-Level Textile Structures. Physical Fundamentals and Metodology of Properties Prognosis. Fibres and Textiles in Eastern Europe.1998, v. 6, No 2, p.39–43.
- Perepelkin, K.E., Structural mechanics of polymeric fibres. Reviews and new conceptions. Proceedings of the Textile Institute’s 77-th World Conference, v. 2, p. 19–28, Tampere, (Finland) 1996.
- Lewin, M. and Preston, J., High Technology Fibers, Part A, Marcel Dekker Inc., 1985, 397 p.
- Warner, S.B., et al. Development of Low Cost, Moderately High Strength, Tough Fibers for Industrial Applications, http://ntc.tx.ncsu.edu.html/reports/NTC.RB-Folder.dev.html, July 14, 1998, 3 p.
- Davis, H. and Singletary, J., Microstructure Organisation in Para-amid Fibres, Textile research Journal 70(11) 2000, pp 945–950.
- Darwin, P.L., et al., Poly(ethylene terephthalate) Copolyesters Derived from (2S,3S)-2,3-Dimethoxy-1,4-Butanediol, Journal of Polymer Science Part A: Polymer Chemistry, Vol. 39, pp. 3250–3262.
- Testa, G., et al., Effects of morphological changes on the oxygen transport properties of poly(ethylene terephthalate)-co-(1,4-cyclohexylene dimethylene terephthalate), Die Angewandte Makromoleculare Chemie 243 (1996) nro 4249, pp. 99–115.
- Lewin, M. and Preston, J., High Technology Fibers, Part A, Marcel Dekker Inc., 1985, 397 p.
- Bruggemann, A., and Tinnemans, A.H.A., Reactive Blending of Poly(ethylene terephthalate) with a Liquid Crystalline Copolyester and Polyhydroxyether. Journal of Applied Polymer Science 71(1999), 1107–1123.
- Hallden, A., et al., Poly(ethylene-graft-ethylene oxide)(PE-PEO) and Poly(ethylene-co-acrylic acid) (PEAA) as Compatibilizers in Blends of LDPE and Polyamide-6, Journal of Applied Polymer Science 78(2000), pp. 2416-–424.
- Takahashi, T., Takimoto, J-I. and Koyama, K., Elongational Viscosity for Mischible and Immischible Polymer Blends. II. Blends with a Small Amaount of UHMW Polymer. Journal of Applied Polymer Science 72(1999), 961–969.
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This page has been updated 13.04.2021