Effective Elastic Properties of 3D Composites with Short Curvilinear Fibers: Numerical Simulation and Experimental Validation

Victor V. Mykhas'kiv; Bohdan M. Stasyuk

doi:10.4028/www.scientific.net/SSP.258.452

Paper Titles

On the Preparation of Advanced Materials via Pulsed Electric Current Sintering Procedures
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Microstructure Similarities between Phases F and U in Al-Pd-Co Alloys
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AFM Study of Microstructure Role in the Cyclic Plasticity of Martensitic Steel
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Measurement of the Porosity of Additive-Manufactured Al-Cu Alloy Using X-Ray Computed Tomography
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Effective Elastic Properties of 3D Composites with Short Curvilinear Fibers: Numerical Simulation and Experimental Validation
p.452

Magneto-Mechanical Behavior of Iron during Monotonic and Cyclic Loading
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Field Measurement of Natural Electromagnetic Emissions near the Active Tectonic and Mass-Movement Fractures in Caves
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Influence of Carbon Admixtures to the Electrical Conductivity of Slag Mortars
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Investigation of Defects at Cu(In,Ga)Se₂ Flexible Solar Cells on Macroscopic and Microscopic Level and their Influence on Solar Cell Performance
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Effective Elastic Properties of 3D Composites with Short Curvilinear Fibers: Numerical Simulation and Experimental Validation

Abstract:

Theoretical and experimental estimation of elastic properties of two-phase composites containing matrix material and arc-shaped cylindrical fibers is given. Theoretical aspect consists in hybrid micro-macro formulation of problem with consideration of two associated subproblems –numerical simulation of fiber influence on the representative volume element and effective strain-stress field approximation by the averaging procedures. Boundary element method is applied for the solution of micro-level subproblem as well as Mori-Tanaka model is adopted for the overall description of composite properties at the macro-level. Then interfacial displacements are involved into solution scheme only. The effective elastic moduli of arc-fiber-reinforced composites are analyzed for the different materials combinations and fiber fractions. For the validation of numerical results, the prismatic concrete specimen filled by the curvilinear shaped cylindrical steel fibers under compression is investigated experimentally. Comparison of theoretical and experimental data is made.