INTRODUCTIONThe substitution of met

INTRODUCTION

The substitution of metallic materials by polymeric materials is a growing trend, partly resulting from the fact that in many industrial applications these materials have advantages over metallic materials, especially when increased resistance to corrosion, low thermal and electric conductivity, and low density are required.

With a view towards the changing needs of the market, the research and development of new materials, including thermofixed resin composites, has been the objective of many scientific studies.

A composite is a material developed by combining two or more components, one of which is a structural component (glass fibre, carbon fibre, vegetable fibres etc.) and the other a matrix component (resin), to obtain specific characteristics and properties (Mano, 1991). Recent years have witnessed rapid growth in the use of polymeric composites reinforced with fibre, producing a combination of high performance, great versatility, and other advantages at a favourable cost. One of the fibres used for these polymeric products, cellulose fibre, has become an important class of strengthening materials (Joly et al., 1996; Beshay and Hoa, 1992).

Plant fibres have characteristics of great interest in the area of polymeric composites; these include low density, low cost, biodegradability, flexibility in processing, and little need for treatment equipment. (Agrawal et al., 2000; Canché-Escamilla et al., 1999). Plant fibres are becoming an economic and ecological alternative as reinforcement and bulk agents in plastics, since these fibres can gradually substitute for the synthetic fibres regarded as traditional materials (for example, glass fibre), thus opening up new market possibilities for agricultural countries (Nothenberg, 1996).

Phenolic resins are some of the principal thermofixed synthetic polymers, the third most important polymeric matrix for composites (Lubin, 1969), and are also known for their high temperature resistance (Knop and Pilato, 1985; Kopf and Little, 1991). Pure phenolic resin can be obtained through the condensation reaction between phenol (C6H5OH) and formaldehyde (CH2O), producing methylene bridges between the phenol molecules (Figure 1).