Welcome- Themes
- Introduction to forest-based bioeconomy
- Wood products
- Natural fibre products
- Man-made bio-based fibre products
- Bio-based nanomaterials
- Recycled fibre
- Pulping and biorefining
- Energy and biofuels
- Biomass chemistry and physiology
- Material testing and product properties
- Forests and other biomass resources
- Supply chain
- Process control and automation
- Asset management
- Business and investment planning
- Environmental control and management
- Learning paths
- Other resources
- Tools
- Contact
- Profile
General theories of fibre spinning
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:
Pertti Nousiainen
References:
- Mortimer, S.A., Peguy, A.A. and Ball, R.C., ‘Influence of the physical process parameterson the structure formation of lyocell fibers’, Cellulose Chemistry and Technology,Vol. 30; Number 3/4251–266, 1996.
- Mortimer, S.A. and Peguy, A., ‘Spinning of fibres through the N-methylmorpholine-Noxideprocess’, 8th International cellucon conference, Cellulose and cellulose derivatives: physico-chemical aspects and industrial applications, Woodhead Publishing, 561–567, 1995.
- Mortimer, S.A. and Peguy, A.A., ‘Methods for Reducing the Tendency of Lyocell Fibresto Fibrillate’, J. App. Pol. Sci., 60, 305–316, 1996.
- Mortimer, S.A. and Peguy, A.A., ‘The influence of air gap conditions on the structureformation of lyocell fibres’, J. App. Pol. Sci., 60, 1747–56, 1996.
- Coulsey, H.A. and Smith, S.B., ‘The formation and structure of a new cellulosic fibre’,Dornbirn Conference, Austria, 1995.
- P White, M Hayhurst, J Taylos and A Slater, Lyocell fibres, in: Biodegradable and sustainable fibres, ed. R. S. Blackburn, CRC Press Boca Raton Boston New York Washington, DC, Woodhead Publishing Ltd, Cambridge England, 2005, pp. 157–190.
- Nomura, S., et al., Regenerated Cellulose Fibers Spun from N-methylmorpholine-N-oxide solution, Proceedings of the ISF´94, 26–28 October 1994, Yokohama, Japan, p. 49.
- Bredereck, K., et al., Alkali- und Flüssigammoniak-Behandlung von Lyocellfasern, Melliand textilberichte 1–2/2003, 58–64.
- Bang, Y.H., et al., Effect of Coagulation conditions on Fine structure of Regenerated Cellulosic Films Made from Cellulose /N-methylmorpholine-N-oxide/H2O Systems, Journal of Applied Polymer Science 73 (1999), 2681–2690.
- Liu, R., Shao, H., and Hu, X., Studies on coagulation process of lyocell fibres, Chemical Fibres International, Vol. 51(Dec 2001), 432–441.
- Jianchin, Z. , Meiwu, S., Hua, Z., and Kan, L., Study of the skin-core structure of lyocell staple fibres, Chemical Fibres International, Vol 49 (Dec 1999), 494–500.
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This page has been updated 13.04.2021