Sisal Fiber/Natural Rubber Composites: Effect of Fiber Content and Interfacial Modification

Wittawat Wongsorat; Nitinat Suppakarn; Kasama Jarukumjorn

doi:10.4028/www.scientific.net/AMR.410.63

Paper Titles

Flame Retardancy, Thermal Stability, and Mechanical Properties of Sisal Fiber/Organoclay/Polypropylene Composites
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Poly(lactic acid)/Poly(butylene adipate-co-terephthalate) Blend and its Composite: Effect of Maleic Anhydride Grafted Poly(lactic acid) as a Compatibilizer
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Crystallization Behavior of Vetiver Grass Fiber-Polylactic Acid Composite
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Comparison between Mechanical and Thermal Properties of Polylactic Acid and Natural Rubber Blend Using Calcium Carbonate and Vetiver Grass Fiber as Fillers
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Sisal Fiber/Natural Rubber Composites: Effect of Fiber Content and Interfacial Modification
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Effect of Wood Flour on Structural and Thermal Properties and Antibacterial Activity of PLA Filled with Triclosan
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Effect of Heat Treatment on Chemical Structure of a Bio-Filler from Vetiver Grass
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Anti-Fungal and Anti-Algal Performances of Biocides Filled PVC and Wood/PVC Composites
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Modulation of Behaviours of Cultured Cells on Polycaprolactone/Chitosan Blended Biomaterials
p.79

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 410Sisal Fiber/Natural Rubber Composites: Effect of...

Sisal Fiber/Natural Rubber Composites: Effect of Fiber Content and Interfacial Modification

Abstract:

Sisal fiber/natural rubber (NR) composites were prepared by the incorporation of sisal fiber into NR at contents of 10-30 phr. Fiber treatment (alkalization) and adding maleic anhydride grafted natural rubber (NR-g-MA) were used to improve interfacial adhesion between sisal fiber and NR matrix. Mechanical properties, morphologies, and cure characteristics of the composites were studied. With increasing fiber content, modulus at 100% strain (M100), modulus at 300% strain (M300), and hardness of the composites increased whereas tensile strength and elongation at break decreased. Cure time of the composites decreased with increasing fiber content but scorch time was not much affected by fiber content. Alkali treated sisal fiber/NR composite exhibited higher tensile properties and hardness than untreated sisal fiber/NR composite at all fiber content due to the improved adhesion between fiber and NR matrix through the mechanical interlocking mechanism. Alkalization showed no effect on scorch time and cure time of the composites. The addition of NR-g-MA into the composites increased M100, M300, tensile strength, and hardness but prolonged scorch time and cure time. NR-g-MA provided more effective improvement of the mechanical properties of the composites when compared to fiber alkalization.