Add to ORKGWe present results of direct numerical simulation of heat transfer in turbulent particle-laden channel flow. We show an enhancement of the heat transfer when heavy inertial particles with a high specific heat are added to the flow. The simulations employ a coupled Eulerian-Lagrangian computational model in which the momentum and energy transfer between the discrete particle - and the continuous fluid phase are fully taken into account. The effect of turbophoresis, resulting in an increased particle concentration near a solid wall due to the heterogeneity of the wall-normal velocity fluctuations, is held responsible for the increased heat transfer. As a result, the transport properties in the region near the walls differ from that in the bul...
We show, by direct numerical simulations, that heavy inertial particles (characterized by Stokes num...
The Euler-Lagrange approach, based on Direct Numerical Simulation (DNS) and Large-Eddy Simulation (L...
Turbulent internal flow in channel and pipe geometry with a diluted second phase of inertial particl...
We present results of direct numerical simulation of heat transfer in turbulent particle-laden chann...
We present results of direct numerical simulation of turbulence modification and heat transfer in tu...
Heat transfer in multiphase flows plays an important role in many industrial applications. For insta...
Transfer of mechanical energy between solid spherical particles and a Newtonian carrier fluid has be...
Turbulent non-isothermal fully developed channel flow with solid particles was investigated through ...
The temperature distribution in particle-laden turbulent flow, in a flume, was investigated both by ...
Abstract. In present work heat transfer in particle-laden wall-bounded turbulent flows has been stud...
In present work heat transfer in particle-laden wall-bounded turbulent flows has been study with the...
Suspensions of solid particles in a viscous fluid are ubiquitous in natural and engineering setti...
A direct numerical simulation of fully-developed, time-dependent, three-dimensional turbulent flow i...
Deposition and resuspension mechanisms in particle-laden turbulent flows are dominated by the cohere...
The distribution of inertial particles in turbulent flows is highly non-uniform and is driven by the...
We show, by direct numerical simulations, that heavy inertial particles (characterized by Stokes num...
The Euler-Lagrange approach, based on Direct Numerical Simulation (DNS) and Large-Eddy Simulation (L...
Turbulent internal flow in channel and pipe geometry with a diluted second phase of inertial particl...
We present results of direct numerical simulation of heat transfer in turbulent particle-laden chann...
We present results of direct numerical simulation of turbulence modification and heat transfer in tu...
Heat transfer in multiphase flows plays an important role in many industrial applications. For insta...
Transfer of mechanical energy between solid spherical particles and a Newtonian carrier fluid has be...
Turbulent non-isothermal fully developed channel flow with solid particles was investigated through ...
The temperature distribution in particle-laden turbulent flow, in a flume, was investigated both by ...
Abstract. In present work heat transfer in particle-laden wall-bounded turbulent flows has been stud...
In present work heat transfer in particle-laden wall-bounded turbulent flows has been study with the...
Suspensions of solid particles in a viscous fluid are ubiquitous in natural and engineering setti...
A direct numerical simulation of fully-developed, time-dependent, three-dimensional turbulent flow i...
Deposition and resuspension mechanisms in particle-laden turbulent flows are dominated by the cohere...
The distribution of inertial particles in turbulent flows is highly non-uniform and is driven by the...
We show, by direct numerical simulations, that heavy inertial particles (characterized by Stokes num...
The Euler-Lagrange approach, based on Direct Numerical Simulation (DNS) and Large-Eddy Simulation (L...
Turbulent internal flow in channel and pipe geometry with a diluted second phase of inertial particl...