Banana fibers obtained from the stem of banana plant (Musa sapientum) have been characterised for their diameter variability and their mechanical properties, with a stress on fracture morphology. The nature of representative stress strain curves and fracture at different strain rates have been analysed through SEM.
MukhopadhyayS., VijayG., TalwadeR., DhakeJ.D., PegorettiA, Some Studies on Banana Fibers, International conference on Advances in Fibrous Materials, Nonwoven and Technical Textiles, 7–9 August 2006, Coimbatore, India.
10.
RaoM M., MohanaR. K., Extraction and tensile properties of natural fibers: Vakka, date and bamboo, Composite Structures77, 288–295, (2007).
AndrewsE. H., Developments in Polymer Fracture-1, AndrewsE. H. (ed), Applied Science Publishers, 1979, 1–2
13.
WilliamsJ. G., The Physics of Glassy Polimers, HawardR. N., YoungR. J. (ed), Chapman & Hall, London, second edition 1997, 343
14.
PhilipsD. C., HarrisB., The Strength, Toughness and Fatigue Properties of Polymer Composites, Polymer Engineering Composites, RichardsonM. O. W. (ed), Applied Science Publishers, 1977, 48
15.
ScheirsJ., Compositional and Failure Analysis of Polymers, John Wiley & Sons, England, 2000, 325
SandeepK; VarmaI K., Journal of Macromolecular Science, Part B: Physics, 45, 153–164, (2006).
19.
HornsbyPR, HinrichsenE, TarverdiK.Preparation and properties of polypropylene composites reinforced with wheat and flax straw fibres. Part I Fibre characterization. J Mater Sci; 32: 443–449. (1997).
20.
MukherjeeK.G.; SatyanarayanaK.G.Structure and properties of some vegetable fibres. Part 1: Sisal fiber. Journal of Materials Science, London, v. 19, 3925–3934, 1984.
