Abstract
In recent years, the hybrid composites of cellulosic and synthetic fibres are tailored to yield materials with reduced cost and weight. Prior to the fabrication of the hybrid composite, in most case, the cellulosic fibre needs surface modification for proper bonding. Therefore, this study investigates the effect of sodium bicarbonate treatment on the physical and mechanical properties of the hybrid and nonhybrid laminate composites of sugar palm and glass fibre-reinforced polypropylene. The findings will be compared with the conventional alkali treatment. The laminate composites were fabricated using the film stacking technique and hot compression process. Prior to the fabrication process, the sugar palm fibre in it which is naturally woven mat was treated with 4 wt% and 10 wt% alkali and sodium bicarbonate, respectively. All the laminate composites were investigated by tensile, flexural, and impact test, water absorption, and morphological examination. The tensile strength increased with both alkaline and sodium bicarbonate treatments for the hybrid and nonhybrid composites. The increase was more pronounced with the alkaline-treated SPF composite (L03) which displayed the highest value of 61.75 MPa, while that of the sodium bicarbonate-treated SPF composite (L04) recorded 58.76 MPa against 53.01 MPa for the untreated SPF composite (L02). The same trend was observed for the flexural strength. In overall, the alkaline treatment yielded better performance in comparison with sodium bicarbonate treatment.
Highlights
Nowadays, the synthetic fibre-reinforced polymer (FRP) composite becomes the key material that is fast replacing the conventional material in the field of aerospace and automotive industry
The tensile modulus for the untreated sugar palm fibre (SPF)/PP composite (L02) was low (1.80 GPa) in comparison with alkalinetreated SPF/PP (L03) and sodium bicarbonate-treated SPF/PP (L04) composites which registered 2.28 GPa and 2.06 GPa, respectively, whereas the incorporation of SPF and glass fibre causes brittleness in the PP matrix and the elongation percentage reduced by 52.8%. It is clear based on the tensile test results that alkaline treatment affects the properties of the composite in a more positive way when compared with sodium bicarbonate treatment
A laminate composite based on sugar palm fibre, glass fibre, and polypropylene was manufactured by film stacking technique and hot compression moulding technique
Summary
The synthetic fibre-reinforced polymer (FRP) composite becomes the key material that is fast replacing the conventional material in the field of aerospace and automotive industry. Superior properties and lightweight are the key attributes for the adoption of the FRP. Notwithstanding, these synthetic fibre-reinforced polymer composites are not environmentally friendly, nondegradable, associated health risk, and nonrecyclable, amongst others [1,2,3,4,5]. To reduce the advance effect of FRP to the environment, the hybrid composites of synthetic and natural fibre are becoming an option where strength requirement is not critical. The hybrid is achieved through the incorporation of the natural fibre into the synthetic fibre, leading to the paradigm shift from the FRP to hybrid-reinforced polymer composite system.
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