Mechanical,wear,water absorption and thermal behavior of rice straw carbon nanomaterial and pineapple fiber epoxy composites

Abstract

This research investigates the development of high-performance epoxy composites reinforced with pineapple fibers and rice straw-derived carbon nanomaterial, targeting enhancements in mechanical strength, tribological behavior, thermal stability, and moisture resistance. Composites were fabricated via the hand lay-up technique, ensuring uniform fiber alignment and optimal carbon nanomaterial dispersion within the matrix. Among the formulations studied, specimen A14 (57 vol. % epoxy, 40 vol. % pineapple fiber, 3 vol. % carbon nanomaterial) exhibited superior mechanical properties, achieving a tensile strength of 166 MPa and flexural strength of 217.8 MPa, attributed to effective fiber-matrix interfacial bonding and crack-bridging by carbon nanomaterial. Conversely, specimen A15 (55 vol. % epoxy, 40 vol. % pineapple fiber, 5 vol. % carbon nanomaterial) demonstrated optimal functional properties, with the lowest specific wear rate of 0.0067 mm³/Nm and coefficient of friction of 0.21, due to the formation of a lubricated protective film from carbon nanomaterial accumulation. Furthermore, A15 achieved the lowest thermal conductivity of 93 W/mK, signifying enhanced thermal resistance, while recording maximum water absorption of 0.042%, primarily due to carbon nanomaterial agglomeration and the intrinsic hydrophilicity of natural fibers. SEM analysis revealed critical microstructural features across the specimens: A11 exhibited a smooth, brittle matrix; A12 showed distinct fiber fracture zones confirming energy dissipation; A13 and A14 evidenced strong matrix-fiber interlocks; and A15 displayed visible carbon nanomaterial clusters that acted as thermal barriers and wear-resistant zones, albeit introducing localized stress concentration. Overall, this study highlights the synergistic integration of bio-based fibers and nanoscale carbon additives to engineer lightweight, structurally robust, and multifunctional composites, paving the way for their utilization in automotive interiors, lightweight panels, and sustainable engineering components.

Keywords

composites natural fiber carbon mechanical properties wear

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