Drag law for monodisperse gas-solid systems using particle-resolved direct numerical simulation of flow past fixed assemblies of spheres

International Journal of Multiphase Flow

Volumn 37, Issue 9, 2011, Pages 1072-1092

  Tenneti, S ^a   Garg, R ^a   Subramaniam, S ^a  

^a Iowa State University of Science and Technology   (United States)

Author keywords

Drag law; Gas solid flow; Immersed boundary method; Particle resolved direct numerical simulation

Indexed keywords

CFD SIMULATIONS; DRAG CORRELATION; DRAG LAW; FINITE FLUID; FIXED-BED; FLOW BEHAVIORS; FLUID STRESS; FORCE DENSITY; FUNDAMENTAL PROBLEM; GAS-SOLID; GAS-SOLID FLOWS; IMMERSED BOUNDARY METHODS; MEAN FLOW; MONODISPERSE; MONODISPERSE SPHERES; NAVIER-STOKES SOLVER; NUMERICAL CONVERGENCE; PARTICLE ASSEMBLIES; PARTICLE SURFACE; PARTICLE-RESOLVED DIRECT NUMERICAL SIMULATION; PRESSURE FIELD; RELATIVE CONTRIBUTION; SIMULATION APPROACH; SLIP VELOCITY; SOLID VOLUME FRACTION; STOKES NUMBER; TWO-FLUID; TWO-FLUID THEORY; VALIDATION TEST; VISCOUS STRESS;

CONVERGENCE OF NUMERICAL METHODS; DIRECT NUMERICAL SIMULATION; FLOW OF SOLIDS; FLOW SIMULATION; FLUIDIZATION; FLUIDIZED BEDS; GASES; MOMENTUM TRANSFER; REYNOLDS EQUATION; REYNOLDS NUMBER; SPHERES; TITRATION; TURBULENT FLOW;

DRAG;

EID: 80052089690     PISSN: 03019322     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijmultiphaseflow.2011.05.010     Document Type: Article

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