Euler-Lagrange (EL) simulations are an extremely important tool for academia and industry to better understand gas-particle flows. We present simulation results for various gas-particle flow configurations using a variety of Lagrangian-to-Euler coupling schemes. Specifically, we have combined the idea of smoothing the exchange fields (as proposed by Pirker et al. (2011), as well as Capecelatro and Desjardins (2013)) to design a new generation of robust mapping schemes that allow implicit, explicit or a hybrid implicit/explicit time marching. Our schemes enable EL simulations of highly loaded gas-particle flows in which particles have a broad size distribution. We demonstrate the performance of our mapping schemes for the case of (i) a bubbl...
This thesis presents a numerical framework for simulating advection-dominated flows which reconciles...
The coexistence of large particles (such as biomass or coal particles) and fine particles in gas-sol...
In the context of unsteady 3D simulations of particle-laden flows, a new double-constraint load bala...
Euler-Lagrange method is powerful for studying dense gas-solid flow, where the Eulerian grid is typi...
A critical comparison of a hard-sphere discrete particle model, a two-fluid model with kinetic theor...
The large-scale hydrodynamic behavior of relatively dense dispersed multiphase flows, such as encoun...
Dense gas-particle flows are encountered in a variety of industrially important processes for large ...
Particle-laden flows occur in industrial applications ranging from droplets in gas turbines tofluidi...
Dispersed two-phase flows are ubiquitous in many natural phenomena (cloud formation, volcanic erupti...
International audienceA new Eulerian-Lagrangian coupling on a staggered fluid mesh is proposed to si...
Eulerian-Lagrangian simulations often require a two-way coupling, where the discrete phase affects t...
The Eulerian-Lagrangian point-particle method has become a leading paradigm in the study of disperse...
An Eulerian two-fluid numerical solver with kinetic-frictional theory for granular flows has been im...
Les écoulements gaz-particules sont présents dans de nombreux phénomènes naturels (formation des nua...
This thesis presents a numerical framework for simulating advection-dominated flows which reconciles...
The coexistence of large particles (such as biomass or coal particles) and fine particles in gas-sol...
In the context of unsteady 3D simulations of particle-laden flows, a new double-constraint load bala...
Euler-Lagrange method is powerful for studying dense gas-solid flow, where the Eulerian grid is typi...
A critical comparison of a hard-sphere discrete particle model, a two-fluid model with kinetic theor...
The large-scale hydrodynamic behavior of relatively dense dispersed multiphase flows, such as encoun...
Dense gas-particle flows are encountered in a variety of industrially important processes for large ...
Particle-laden flows occur in industrial applications ranging from droplets in gas turbines tofluidi...
Dispersed two-phase flows are ubiquitous in many natural phenomena (cloud formation, volcanic erupti...
International audienceA new Eulerian-Lagrangian coupling on a staggered fluid mesh is proposed to si...
Eulerian-Lagrangian simulations often require a two-way coupling, where the discrete phase affects t...
The Eulerian-Lagrangian point-particle method has become a leading paradigm in the study of disperse...
An Eulerian two-fluid numerical solver with kinetic-frictional theory for granular flows has been im...
Les écoulements gaz-particules sont présents dans de nombreux phénomènes naturels (formation des nua...
This thesis presents a numerical framework for simulating advection-dominated flows which reconciles...
The coexistence of large particles (such as biomass or coal particles) and fine particles in gas-sol...
In the context of unsteady 3D simulations of particle-laden flows, a new double-constraint load bala...