Elmer M. Tory scite author profile

The well-known kinematic sedimentation model by Kynch states that the settling velocity of small equal-sized particles in a viscous fluid is a function of the local solids volume fraction. This assumption converts the one-dimensional solids continuity equation into a scalar, nonlinear conservation law with a nonconvex and local flux. This work deals with a modification of this model, and is based on the assumption that either the solids phase velocity or the solid-fluid relative velocity at a given position and time depends on the concentration in a neighbourhood via convolution with a symmetric kernel function with finite support. This assumption is justified by theoretical arguments arising from stochastic sedimentation models, and leads to a conservation law with a nonlocal flux. The alternatives of velocities for which the nonlocality assumption can be stated lead to different algebraic expressions for the factor that multiplies the nonlocal flux term. In all cases, solutions are in general discontinuous and need to be defined as entropy solutions. An entropy solution concept is introduced, jump conditions are derived and uniqueness of entropy solutions is shown. Existence of entropy solutions is established by proving convergence of a difference-quadrature scheme. It turns out that only for the assumption of nonlocality for the relative velocity it is ensured that solutions of the nonlocal equation assume physically relevant solution values between zero and one. Numerical examples illustrate the behaviour of entropy solutions of the nonlocal equation.

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Model Equations and Instability Regions for the Sedimentation of Polydisperse Suspensions of Spheres

Bürger

Karlsen

Tory

et al. 2002

Z. angew. Math. Mech.

112

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The one‐dimensional kinematical sedimentation theory for suspensions of small spheres of equal size and density is generalized to polydisperse suspensions and several space dimensions. The resulting mathematical model, obtained by introducing constitutive assumptions and performing a dimensional analysis, is a system of first‐order conservation laws for the concentrations of the solids species coupled to a variant of the Stokes system for incompressible flow describing the mixture. Various flux density vectors for the first‐order system have been proposed in the literature. Some of them cause the first‐order system of conservation laws to be non‐hyperbolic, or to be of mixed hyperbolic‐elliptic type in the bidisperse case. The criterion for ellipticity is equivalent to a well‐known instability criterion predicting phenomena like blobs and viscous fingering in bidisperse sedimentation. We show that loss of hyperbolicity, that is the occurrence of complex eigenvalues of the Jacobian of the first‐order system, can be viewed as an instability criterion for arbitrary polydisperse suspensions, and that for tridisperse mixtures this criterion can be evaluated by a convenient calculation of a discriminant. We determine instability regions (or alternatively prove stability) for three different choices of the flux vector of the first‐order system of conservation laws. Consequently, mixed or non‐hyperbolic, rather than hyperbolic, systems of conservation laws are the appropriate general mathematical framework for polydisperse sedimentation. The stability analysis examines a first‐order system of conservation laws, but its predictions are applicable to the full multidimensional system of model equations. The findings are consistent with experimental evidence and are appropriately embedded into the current state of knowledge of non‐hyperbolic systems of conservation laws.

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Sedimentation and Thickening

et al. 1999

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Batch and Continuous Thickening. Basic Theory. Solids Flux for Rigid Spheres

Shannon¹,

Stroupe²,

Tory³

1963

Ind. Eng. Chem. Fund.

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Elmer M. Tory

Computer simulation of close random packing of equal spheres

On nonlocal conservation laws modelling sedimentation

Model Equations and Instability Regions for the Sedimentation of Polydisperse Suspensions of Spheres

Sedimentation and Thickening

Batch and Continuous Thickening. Basic Theory. Solids Flux for Rigid Spheres

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