Home Physical Sciences Melt Processing of Wood Cellulose Tissue and Ethylene-Acrylic Acid Copolymer Composites
Article
Licensed
Unlicensed Requires Authentication

Melt Processing of Wood Cellulose Tissue and Ethylene-Acrylic Acid Copolymer Composites

  • and
Published/Copyright: September 9, 2013
Become an author with De Gruyter Brill
Submit Manuscript Author Information
International Polymer Processing
From the journal International Polymer Processing Volume 28 Issue 4

Abstract

The difficulty of feeding cellulose fibers together with the polymer into the melt processing equipment is a serious disadvantage for the production of cellulose-containing composites on a large scale. In the present work, a continuous method of feeding cellulose in the form of a tissue into a twin-screw extruder through an opening downstream of the extruder cylinder was studied. With this method, composites with different fiber contents were obtained. The tissues used were one made mainly of softwood fibers and another mainly of hardwood fibers. In order to better understand how to improve the fiber dispersion by melt mixing, a second extrusion was performed with a single screw extruder with a barrier-flighted screw and also with the twin-screw used to compound the tissue with the polymer. The compounds produced were then injection molded into test bars. The test bars containing the softwood tissue exhibited some fiber aggregates also after a second extrusion, whereas no fiber aggregates were observed in samples made with the tissue containing hardwood fibers and two passes through the twin screw. The fiber length was in general reduced by each melt processing stage and the shortest fiber length was observed after two extrusions with the twin-screw and injection molding. The tensile modulus increased with increasing fiber content. A higher stiffness was obtained with more softwood fibers in the tissue whereas more hardwood fibers gave a higher tensile strength and greater elongation at break.

2 Mail address: Ruth Ariño, Department of Materials and Manufacturing Technology, Chalmers University of Technology, SE- 41296 Gothenburg, Sweden E-mail:

References

Ariño, R., Boldizar, A., “Processing and Mechanical Properties of Thermoplastic Composites Based on Cellulose Fibers and Ethylene-Acrylic Acid Copolymer”, Polym. Eng. Sci., 52, 19511957 (2012)10.1002/pen.23134Search in Google Scholar

Askling, C., Wagberg, L. and Rigdahl, M., “The Effect of Additives on the Mechanical Properties of Dry-formed Fibre Networks”, J. Mater. Sci., 33, 19972003 (1998)10.1023/a:1004390313084Search in Google Scholar

Bataille, P., Ricard, L. and Sapieha, S., “Effects of Cellulose Fibers in Polypropylene Composites”, Polym. Compos., 10, 103108 (1989)10.1002/pc.750100207Search in Google Scholar

Bengtsson, M., Baillif, M. L. and Oksman, K., “Extrusion and Mechanical Properties of Highly Filled Cellulose Fibre-polypropylene Composites”, Composites Part A, 38, 19221931 (2007)10.1016/j.compositesa.2007.03.004Search in Google Scholar

Bledzki, A. K., Letman, M., Viksne, A. and Rence, L., “A Comparison of Compounding Processes and Wood Type For Wood Fibre – PP Composites”, Composites Part A, 36, 789797 (2005)10.1016/j.compositesa.2004.10.029Search in Google Scholar

Dalväg, H., Klason, C. and Strömvall, H.-E., “The Efficiency of Cellulosic Fillers in Common Thermoplastics. Part II. Filling with Processing Aids and Coupling Agents”, Int. J. Polym. Mater., 11, 938 (1985)10.1080/00914038508078651Search in Google Scholar

Dufresne, A., “Cellulose-based Composites and Nanocomposites”, in Monomers, Polymers and Composites from Renewable Resources, Mohamed Naceur, B., Alessandro, G. (Eds.), Elsevier, Amsterdam, p. 401418 (2008)10.1016/B978-0-08-045316-3.00019-3Search in Google Scholar

Emsley, A. M., “The kinetics and Mechanisms of Degradation of Cellulosic Insulation in Power Transformers”, Polym. Degrad. Stab., 44, 343349 (1994)10.1016/0141-3910(94)90093-0Search in Google Scholar

Jr.Giles, F.H., WagnerJr., J. R. and Mount III, E. M., “Chapter 4 Plastic Behavior in the Extruder”, in Extrusion. The Definitive Processing Guide and Handbook, William Andrew Publishing, Norwich, p. 3552 (2005)10.1016/B978-081551473-2.50005-2Search in Google Scholar

John, M. J., Anandjiwala, R. D., “Recent Developments in Chemical Modification and Characterization of Natural Fiber-reinforced Composites”, Polym. Compos., 29, 187207 (2008)10.1002/pc.20461Search in Google Scholar

Klason, C., Kubat, J. and Strömvall, H. E., “Efficiency of Cellulosic Fillers in Common Thermoplastics. Part 1. Filling without Processing Aids or Coupling Agents”, Int. J. Polym. Mater., 10, 159187 (1984)10.1080/00914038408080268Search in Google Scholar

Le Baillif, M., Echtermeyer, A., “Effect of the Preparation of Cellulose Pellets on the Dispersion of Cellulose Fibers into Polypropylene Matrix during Extrusion”, J. Appl. Polym. Sci., 115, 27942805 (2009)10.1002/app.30421Search in Google Scholar

Le Baillif, M., Oksman, K., “The Effect of Processing on Fiber Dispersion, Fiber Length, and Thermal Degradation of Bleached Sulfite Cellulose Fiber Polypropylene Composites”, J. Thermoplast. Compos., 22, 115133 (2009)10.1177/0892705708091608Search in Google Scholar

Maillefer, C. E., G.B. Patent 964 428 (1960)Search in Google Scholar

Maillefer, C. E., U.S. Patent 3 358 327 (1967)Search in Google Scholar

Nachtigall, S. M. B., Cerveira, G. S. and Rosa, S. M. L., “New Polymeric-coupling Agent for Polypropylene/Wood-flour Composites”, Polym. Test., 26, 619628 (2007)10.1016/j.polymertesting.2007.03.007Search in Google Scholar

Oksman, K., Skrifvars, M. and Selin, J. F., “Natural Fibres as Reinforcement in Polylactic Acid (PLA) Composites”, Compos. Sci. Technol., 63, 13171324 (2003)10.1016/S0266-3538(03)00103-9Search in Google Scholar

Sain, M., Pervaiz, M., “Chapter 5: Mechanical Properties of Wood Polymer Composites”, in Wood-Polymer Composites, Woodhead Publishing Limited, p. 101117 (2008)10.1533/9781845694579.101Search in Google Scholar

Sapieha, S., Pupo, J. F. and Schreiber, H. P., “Thermal Degradation of Cellulose-containing Composites during Processing”, J. Appl. Polym. Sci., 37, 233240 (1989)10.1002/app.1989.070370118Search in Google Scholar

Sears, K. D., Jacobson, R. E. and Caufield, D. F. J. U., US Patent 6,270,883 B1 (2001)Search in Google Scholar

Sears, K. D., JacobsonR. E.Caufield, D. F. J. U., US Pub. No 2002/0000683 A1 (2002)Search in Google Scholar

Wielage, B., Lampke, T., Utschick, H. and Soergel, F., “Processing of Natural-fibre Reinforced Polymers and the Resulting Dynamic-mechanical Properties”, J. Mater. Process. Tech., 139, 140146 (2003)10.1016/S0924-0136(03)00195-XSearch in Google Scholar

Yam, K. L., Gogoi, B. K., Lai, C. C. and Selke, S. E., “Composites from Compounding Wood Fibers with Recycled High Density Polyethylene”, Polym. Eng. Sci., 30, 693699 (1990)10.1002/pen.760301109Search in Google Scholar

Zadorecki, P., Michell, A. J., “Future Prospects for Wood Cellulose as Reinforcement in Organic Polymer Composites”, Polym. Composite., 10, 6977 (1989)10.1002/pc.750100202Search in Google Scholar

Received: 2013-2-26
Accepted: 2013-5-20
Published Online: 2013-09-09
Published in Print: 2013-08-01

© 2013, Carl Hanser Verlag, Munich

Articles in the same Issue

  1. Contents
  2. Contents
  3. Regular Contributed Articles
  4. Effect of Nanoclay Surface Modifier Chemical Reactivity on Morphology and Rheological Properties of PP/PA6 Blend Nanocomposite
  5. Thermal Mold Design in Consideration of the Temperature Control Fluid Flow
  6. Experimental Assessment of Dispersion Failure of Glass Fiber Reinforced Plastics in a Twin Screw Extruder
  7. Life-stage Analysis of Solvent Induced Fissures under Static Stress in PET Fibers
  8. The Effect of TMPTMA Addition on Electron-beam Irradiated LDPE, EVA and Blend Properties
  9. Flammability and Thermal Characterization of Aluminum Hydroxide Filled with LDPE
  10. The Influence of Vulcanization Agents on Vulcanization Kinetics of Chloride Butyl Rubber
  11. Adhesion Tendency of Polymers to Hard Coatings
  12. Barrier Screw Compounding and Mechanical Properties of EAA Copolymer and Cellulose Fiber Composite
  13. Melt Processing of Wood Cellulose Tissue and Ethylene-Acrylic Acid Copolymer Composites
  14. Experiments and Modelling of Calender Processing for Shear Thinning Thermoplastics between Counter Rotating Rolls with Differential Velocities
  15. PPS News
  16. PPS News
  17. Seikei Kakou Abstracts
  18. Seikei Kakou Abstracts
https://doi.org/10.3139/217.2773

Articles in the same Issue

  1. Contents
  2. Contents
  3. Regular Contributed Articles
  4. Effect of Nanoclay Surface Modifier Chemical Reactivity on Morphology and Rheological Properties of PP/PA6 Blend Nanocomposite
  5. Thermal Mold Design in Consideration of the Temperature Control Fluid Flow
  6. Experimental Assessment of Dispersion Failure of Glass Fiber Reinforced Plastics in a Twin Screw Extruder
  7. Life-stage Analysis of Solvent Induced Fissures under Static Stress in PET Fibers
  8. The Effect of TMPTMA Addition on Electron-beam Irradiated LDPE, EVA and Blend Properties
  9. Flammability and Thermal Characterization of Aluminum Hydroxide Filled with LDPE
  10. The Influence of Vulcanization Agents on Vulcanization Kinetics of Chloride Butyl Rubber
  11. Adhesion Tendency of Polymers to Hard Coatings
  12. Barrier Screw Compounding and Mechanical Properties of EAA Copolymer and Cellulose Fiber Composite
  13. Melt Processing of Wood Cellulose Tissue and Ethylene-Acrylic Acid Copolymer Composites
  14. Experiments and Modelling of Calender Processing for Shear Thinning Thermoplastics between Counter Rotating Rolls with Differential Velocities
  15. PPS News
  16. PPS News
  17. Seikei Kakou Abstracts
  18. Seikei Kakou Abstracts
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Winner of the OpenAthens UX Award 2026
Winner of the OpenAthens UX Award 2026
Have an idea on how to improve our website?
Please write us.
© 2026 De Gruyter Brill
Downloaded on 2.4.2026 from https://www.degruyterbrill.com/document/doi/10.3139/217.2773/html
Scroll to top button