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The fundamentals of cohesive powder consolidation and flow behaviour using a reasonable combination of particle and continuum mechanics are explained. By means of the model 搒tiff particles with soft contacts? the influ-ence of elastic-plastic repulsion in particle contacts is demonstrated. With this as the physical basis, the stationary yield locus, instantaneous yield loci and consolidation loci, flow function and compression function are presented. The flow properties of a very cohesive titania nanopowder (dS=200 nm) are shown. These models are used to evaluate shear cell test results as constitutive functions for computer aided apparatus design for reliable powder flow.
The fundamentals of cohesive powder consolidation and flow behavior using a reasonable combination of particle and continuum mechanics are explained. By means of the model 搒 tiff particles with soft contacts? The influ-ence of elastic-plastic repulsion in particle contacts is demonstrated. With this the flow properties of a very cohesive titania nanopowder (dS = 200 nm) are shown. These models are used to evaluate shear cell test results as constitutive functions for computer aided apparatus design for reliable powder flow.