Micro-Computed Tomography Image Based Numerical Elastic Homogenization of MMCs

Yuriy Sinchuk; Stefan Dietrich; Matthias Merzkirch; Kay André Weidenmann; Romana Piat

doi:10.4028/www.scientific.net/KEM.627.437

Paper Titles

Contact State Investigation of a Three-Point Bend Specimen Using Numerical Methods
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An Experimental Evaluation for Four Multiaxial Fatigue Approaches
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Very High Plastic Strain Zones in 304 Stainless Steel Small Punch Specimen Loaded at RT by Martensite Formation and Recrystallization Technique
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Comparison between Subjective and Objective Measurement of Slipperiness
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Micro-Computed Tomography Image Based Numerical Elastic Homogenization of MMCs
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Fibre Concrete Foundation Slab Experiment and FEM Analysis
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Influence of Cold Weather on Compressive Strength in High Performance with Silica Fume
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The Behavior of Pseudo Strain-Hardening Cementitious Composite (PSH2C) Using Synthetic Fibers under Uniaxial Tensile Loading
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A Boundary Element Method for Structural Reliability
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Micro-Computed Tomography Image Based Numerical Elastic Homogenization of MMCs

Abstract:

Properties of an interpenetrating metal–ceramic composite with freeze-cast preforms are investigated. For the estimation of elastic properties of the composite numerical homogenization approaches for 2D and 3D finite element models are implemented. The FE models are created based on micro-computed tomography (μCT) images. The results of the numerical 2D and 3D modeling coincide and are in good agreement with available experimental measurements of elastic properties.