Effect of the Fiber Equivalent Diameter on the Elastic Modulus and Density of Sisal Fibers

"Natural fibers are currently gaining attention as reinforcement of polymer composites for uses in engineering parts for automobile and building construction. In spite of environmental, economical and societal advantages, the natural lignocellulosic fibers are not as uniform in their dimension and properties as compared to synthetic. In recent works it was found that the variation in strength could be correlate to the equivalent diameters for several lignocellulosic fibers including the sisal fibers. In the present work an investigation on a possible correlation of the equivalent diameter with changes in density and elastic modulus was carried out. Precise measurements of the equivalent diameter, conducted in a profile projector, were correlated with the density and the elastic modulus by means of the Weibull statistic analysis. The results showed that an inverse correlation with the diameter also applies for both the density and the elastic modulus with a high degree of precision. SEM observation of the sisal fiber in structure and fracture aspects strongly indicate that defects and microfibril participation could be responsible for the inverse correlation.IntroductionAccording to Kalia [1], cellulose-based fibers are currently being pushed owing to their ""green"" image. Contrary to synthetic glass fiber, extensively used in our modem technology, these lignocellulosic fibers are renewable and can be incinerated at the end of the material's lifetime without adding pollution in the atmosphere moreover, the amount of CO2 released during incineration process is negligible as compared to the corresponding amount taken up by the plant throughout its lifetime. Even if an industrial processing equivalent of C02 release is added, the lignocellulosic fiber is considered neutral with respect to the emission of gases responsible for the global warming [2]."