Effect of Cord Construction on the Properties of Rubber Composites

Zhi Min Xie; Dong Liang Chai; Si Chi Chen; Zhi Min Wan

doi:10.4028/www.scientific.net/AMM.328.906

Paper Titles

Empirical Regressive Model of Thermal Conductivity Coefficients on a Kind of Compound Rubber Material
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Melt Polycondensation and Analysis of Hydroxyl-Terminated Poly(L-lactic Acid) Using Small Molecular Diols as Terminating Agents
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Effect of Field Strength on Polymer Aggregation in Electrohydrodynamic Spraying of Thermoplastic Polyurethane
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Preparation and Thermal Shock Properties of Al₂O₃p/40Cr Functionally Graded Composites Materials
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Effect of Cord Construction on the Properties of Rubber Composites
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An Experimental Study on Mechanical Properties for High Performance Concrete Using Fly-Ash
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Experimental Research on Surface Roughness and Topography of Aluminum Alloy 7055 under High-Speed Milling
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Experimental Investigation of Downward Flame Spread over RPU Samples
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Load Capacity Finite Element and Optional Design of Scissor Platform
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 328Effect of Cord Construction on the Properties of...

Effect of Cord Construction on the Properties of Rubber Composites

Abstract:

Cord-rubber composites are different from the general rigid-matrix composites because of the twisted nature of cords and the large, nonlinear deformation of rubber material. The study of the effect of cord construction on their mechanical properties is essential to the improvement of the performance characteristics of rubber products. However, little work was concerned with the influence of the number of strands of cord. The present work demonstrated that influence by using nonlinear finite element analyses. The calculated results show that the effective moduli of the twisted cord reinforced composites tend to be closer to that of a single strand of cord reinforced composites when increasing the number of strands with a constant cord volume fraction. For three types of reinforcing cords, the shear stresses have a symmetric distribution and an anti-symmetric distribution in the condition of in-plane shearing and axial loading, respectively. It is also found that the minimum MISS (maximum interfacial shear stress) occurs in the case of a single strand of cord in comparison with the cases of the twisted cords, and the maximum MISS is related to the loading conditions and the number of strands.