Interface Bonding Property Finite Element Simulation of Mo Fiber-Reinforced Polymer Concrete

Xiu Hua Ren; Jian Hua Zhang; Wen Qiang Wang; Ji Cai Yin

doi:10.4028/www.scientific.net/AMR.1120-1121.1501

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Performance of Ultra-High Strength Concrete Containing Different Types of Fibers
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Load Transfer Behavior of Cracking for Cement Concrete Pavement
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Centre of Panel Thermal Conductivity Performance Analysis of Aerocor-Centrifugal Hybrid Ultrafine Glass Fiber VIP Core Materials
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Mechanical Properties of Semi-Rigid Steel Frame-Braced Steel Plate Shear Wall
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Seismic Behavior of Steel Plate Shear Walls-Steel Frame
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Interface Bonding Property Finite Element Simulation of Mo Fiber-Reinforced Polymer Concrete

Abstract:

Interface bonding property of Mo-fiber reinforced polymer concrete not only depends on its material properties of components but also on microstructure characteristics of fibers including surface state, fiber content, fiber shape, bonding state between fiber and matrix, and so on. Interface bonding mechanism was firstly analyzed in the paper, and finite element simulation was employed to study the influence of fiber surface state, fiber number, bonding state between fiber and resin on interface property respectively. Research results show that the addition of Mo fibers can effectively restrain deformation of matrix, and scrap Mo fibers used as tool electrode material in Wire Electrical Discharge Machining before can improve interface bonding strength better than new smooth Mo fibers. With the increase of fiber number, deformation of the composite is decreasing. When fiber number is identical, maximum deformation of new and scrap Mo fiber-reinforced matrix in complete bonding state is respectively decreased by 12.6% and 14.5% on average compared with in complete debonding state.