Abstract
In the framework of a multi-scale approach, we develop numerical models for suspension flows. At the micro scale level, we perform particle-resolved numerical simulations using a Distributed Lagrange Multiplier/Fictitious Domain approach. At the meso scale level, we use a two-way Euler/Lagrange approach with a Gaussian filtering kernel to model fluid-solid momentum transfer. At both the micro and meso scale levels, particles are individually tracked in a Lagrangian way and all inter-particle collisions are computed by a Discrete Element/Soft-sphere method. The previous numerical models have been extended to handle particles of arbitrary shape (non-spherical, angular and even non-convex) as well as to treat heat and mass transfer. All simulation tools are fully-MPI parallel with standard domain decomposition and run on supercomputers with a satisfactory scalability on up to a few thousands of cores. The main asset of multi scale analysis is the ability to extend our comprehension of the dynamics of suspension flows based on the knowledge acquired from the high-fidelity micro scale simulations and to use that knowledge to improve the meso scale model. We illustrate how we can benefit from this strategy for a fluidized bed, where we introduce a stochastic drag force model derived from micro-scale simulations to recover the proper level of particle fluctuations. Conversely, we discuss the limitations of such modelling tools such as their limited ability to capture lubrication forces and boundary layers in highly inertial flows. We suggest ways to overcome these limitations in order to enhance further the capabilities of the numerical models.
Highlights
The understanding of the dynamics of suspension flows is still incomplete, major advances have been achieved over the past 50 years
Advanced numerical models embedded in a multi-scale approach create many opportunities to gain novel physical insight into fluid-grains interactions that govern suspension flows
We have shown an example in which using high-fidelity Particle Resolved Simulation (PRS) data is extremely helpful in identifying and partly curing some defects of meso-scale two-way Euler/Lagrange (TWEL) models
Summary
The understanding of the dynamics of suspension flows is still incomplete, major advances have been achieved over the past 50 years. Meso-scale methods provide a good basis for intermediate size simulations of suspension flows with a relatively wide range of Reynolds number and porosity. They represent an attractive alternative to PRS but the accurate treatment of. Macro-scale models correspond to different variants of the Euler/Euler model as, e.g., the Two Fluid Model (TFM). In this family of models, the solid phase is somehow assumed to behave as a fluid and both phases are solved in an average way based on closure laws for momentum transfer. We discuss the current limitations of the different models and the stages in the development of more advanced models for suspension flows
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