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http://dx.doi.org/10.1163/156855109X428808

Biodegradable Starch-Based Resin Reinforced with Continuous Mineral Fibres-Processing, Characterisation and Mechanical Properties  

Wittek, Thomas (Shonan Institute of Technology)
Tanimoto, Toshio (Shonan Institute of Technology)
Publication Information
Advanced Composite Materials / v.18, no.2, 2009 , pp. 167-185 More about this Journal
Abstract
Environmental problems caused by extensive use of polymeric materials arise mainly due to lack of landfill space and depletion of finite natural resources of fossil raw materials like petroleum or natural gas. The substitution of synthetic petroleum-based resins with natural biodegradable resins appears to be one appropriate measure to remedy the above-mentioned situation. This study presents the development of a composite that uses environmentally degradable starch-based resin as matrix and natural mineral basalt fibres as reinforcement, and investigates the fibre's and the composite's mechanical properties. The tensile strength of single basalt fibres was verified by means of single fibre tensile tests and statistically investigated by means of a Weibull analysis. Prepreg sheets were manufactured by means of a modified doctor blade system and hot power press. The sheets were used to manufacture specimens with fibre volume contents ranging from 33% to 61%. Specimens were tested for tensile strength, flexural strength and interlaminar shear strength. Composites manufactured during this study exhibited tensile and flexural strength of up to 517 MPa and 157 MPa, respectively.
Keywords
'Green' composite; basalt fibres; biodegradable resin; processing; mechanical properties;
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  • Reference
1 S. Ochi, H. Takagi and H. Tanaka, Development of High-Strength Cross-Ply 'Green' Composites, Zairyo 52, 857–862 (2003) (in Japanese)
2 T.Wittek and T. Tanimoto, Comparison of tensile properties of starch resin reinforced with natural and synthetic fibres, in: Proc. 4th Int. Workshop on Green Composites (IWGC-4), Tokyo, Japan, pp. 112–115 (2006)
3 N. N. Morozov, V. S. Bakunov, E. N. Morozov, L. G. Aslanova, P. A. Granovskii, V. V. Prokshin and A. A. Zemlyanitsyn, Materials based on basalts from the European North of Russia, Glass and Ceramics 58, 100–104 (2001)   DOI
4 V. V. Gur'ev, E. I. Neproshin and G. E. Mostovoi, The effect of basalt fiber production technology on mechanical properties of fiber, Glass and Ceramics 58, 62–65 (2001)   DOI
5 R. V. Subramanian and H. F. Austin, Silane coupling agents in basalt-reinforced polyester composites, Int. J. Adhesion and Adhesives 1, 50–54 (1980)   DOI   ScienceOn
6 A. Kasuya, H. Hamada and A. Nakai, Molding and mechanical properties of unidirectional natural spun natural fiber-reinforced thermoplastics by spun yarn, in: Proc. Annu. Conf. Japan Society for Composite Materials, Tokyo, Japan, pp. 7–8 (2005) (in Japanese)
7 Available at www.sudaglass.com
8 J. Militky and V. Kovacic, Ultimate mechanical properties of basalt filaments, Textile Research Journal 66, 225–229 (1996)   DOI
9 M. Dauda and M. Yoshiba, Processing and mechanical properties of long maize fiber reinforced polypropylene composites, Trans. MRSJ 26, 1083–1090 (2001)
10 M. Hughes, in: Green Composites: Polymer Composites and the Environment, C. Baille (Ed.), pp. 233–251. Woodhead Publishing, Cambridge (2004)
11 N. G. McCrum, C. P. Buckley and C. B. Bucknall, Principles of Polymer Engineering. Oxford University Press, Oxford (1988)
12 B. S. Chiou, G. M. Glenn, S. H. Imam, M. K. Inglesby, D. H. Wood and W. J. Orts, in: Natural Fibers, Biopolymers and Biocomposites, A. K. Mohanty, M. Misra and L. T. Drzal (Eds), pp. 639–670. Taylor & Francis, Boca Raton, FL (2005)
13 A. Stamboulis, C. Baille and T. Peijs, Effects of environmental conditions on mechanical and physical properties of flax fibers, Composites: Part A 32, 1105–1115 (2001)   DOI   ScienceOn
14 P. Ye, L. Reitz, C. Horan and R. Parnas, Manufacture and biodegradation of wheat gluten/basalt composite material, J. Polymers and the Environment 14, 1–7 (2006)   DOI
15 A. K. Mohanty, M. Misra and G. Hinrichsen, Biofibres, biodegradable polymers and biocomposites: an overview, Macromolecular Materials and Engineering 276/277, 1–24 (2000)   DOI
16 F. M. Kogan and O. V. Nikitina, Solubility of chrysotile asbestos and basalt fibers in relation to their fibrogenic and carcinogenic action, Environmental Health Perspectives 102 Supplement 5, 205–206 (1994)   PUBMED
17 Y. Ozawa, T. Kikuchi andM. Isohata,Mechanical behavior of basalt fiber reinforced polymer composites in temperature conditions, in: Proc. 3rd Intern.Workshop on Green Composites (IWGC-3), Kyoto, Japan, pp. 124–127 (2005)
18 H. Tanaka, Denpun emarujon randi, Engineering Materials 51, 58–62 (2003) (in Japanese)
19 D. Hull, An Introduction to Composite Materials. Cambridge University Press, Cambridge (1981)
20 S.W. Tsai and H. T. Hahn, Introduction to Composite Materials. Technomic Publishing, Westport (1980)
21 A. Gomes, K. Goda and J. Ohgi, Effects of alkali treatment to reinforcement on tensile properties of curaua fiber green composites, JSME International Journal, Series A 47, 541–546 (2004)   DOI   ScienceOn
22 N. Nanjyo, FRP kosei sozai nyumon dai 2 sho: Garasu seni, Journal of the Japan Society for Composite Materials 33, 141–149 (2007) (in Japanese)
23 Q. Liu, M. T. Shaw, R. S. Parnas and A. M. McDonell, Investigation of basalt fiber composite mechanical properties for applications in transportation, Polym. Compos. 27, 41–48 (2006)   DOI   ScienceOn
24 D. Plackett, in: Green Composites: Polymer Composites and the Environment, C. Baille (Ed.), pp. 123–153. Woodhead Publishing, Cambridge (2004)
25 M. Sain and S. Panthapulakkal, in: Green Composites: Polymer Composites and the Environment, C. Baille (Ed.), pp. 181–205. Woodhead Publishing, Cambridge (2004)
26 F. L. Matthews and R. D. Rawlings, Composite Materials: Engineering and Science. Chapman and Hall, London (1994)
27 Q. Liu, M. T. Shaw, R. S. Parnas and A. M. McDonell, Investigation of basalt fiber composite aging behavior for applications in transportation, Polymer Composites 27, 475–483 (2006)
28 T. Tanimoto, Continous-fibre CMC fabrication by using pre-impregnated sheets, Composites: Part A 30, 583–586 (1989)
29 W. Weibull, A statistical distribution function of wide applicability, J. Appl. Mech. 18, 293–297 (1951)
30 M. A. Sokolinskaya, L. K. Zabava, T. M. Tsybulya and A. A. Medvedev, Strength properties of basalt fibers, Glass and Ceramics 48, 435–437 (1991)   DOI
31 T. Uno, N. Suizu, K. Goda and J. Ohgi, Tensile and impact properties of mercerized ramie fiber green composite, in: Proc. 4th Intern. Workshop on Green Composites (IWGC-4), Tokyo, Japan, pp. 147–149 (2006)
32 D. Z. Dzhigiris, M. F. Makhova, V. D. Gorobinskaya and L. N. Bombyr, Continuous basalt fiber, Glass and Ceramics 40, 467–470 (1983)   DOI