This paper presents a study on the effect of Arenga Pinnata fibre volume fraction on the tensile and compressive properties of Arenga Pinnata fibre reinforced epoxy composite (APREC). The composites were produced using four different Arenga Pinnata fibre volume contents, which were 10vol%, 15vol%, 20vol%, and 25vol%, in unidirectional (UD) fibre alignment. Tensile and compression tests were performed on all APREC specimens in order to investigate the effect of fibre volume fraction on modulus of elasticity, strength and strain to failure. The morphological structure of fractured specimens was observed using scanning electron microscopy (SEM) in order to evaluate the fracture mechanisms involved when the specimens were subjected to tensile or compressive loading. The results indicated that the higher the amount of Arenga Pinnata fibres, the higher the stiffness of the composites. This is shown by the increment of tensile and compressive modulus of the specimens when the fibre volume content was increased. Tensile modulus increased up to 180% when 25vol% Arenga Pinnata fibre was used in APREC compared to Pure Epoxy specimen. It can also be observed that the tensile strength of the specimens increased 28% from 53.820 MPa (for Pure Epoxy) to 68.692 MPa (for Epoxy with 25vol% APREC addition). Meanwhile, compressive modulus and strength increased up to 3.24% and 9.17%, respectively. These results suggest that the addition of Arenga Pinnata fibres significantly improved the tensile and compressive properties of APREC.
This paper investigates the flexural properties of Arenga Pinnata fibre reinforced epoxy composite
(APREC) in relation to its fibre arrangement. The composites were produced using Arenga Pinnata fibre
as the reinforcement material and epoxy resin as the matrix. In this work, two types of Arenga Pinnata
fibre arrangement were under-studied, randomly distributed and unidirectional distributed (UD). Samples
were prepared at 10vol%, 15vol%, 20vol%, and 25vol% of fibres reinforcement to matrix ratio for both
types. Three-point bending configuration flexural tests were performed for both randomly distributed
APREC and UD APREC at 10vol%, 15vol%, 20vol%, and 25vol% respectively. Results indicated that
UD APREC have better flexure modulus and flexure strength for all the fibre loading percentages (vol%)
as compared against the randomly distributed APREC. The 25vol% UD APREC showed the highest
modulus (3.783 GPa) with an increment of 31.0% as compared against the pure epoxy (2.888 GPa).
It was also observed that there was no significant increment on flexure strength for both random and
unidirectional APREC as compared to pure epoxy (61.125 MPa), but the flexure strength value decreased
for randomly distributed fibre orientation for all fibre volume percentages (vol%)