TY - JOUR
T1 - Turbulence modeling for flow in a distribution manifold
AU - Chen, Andrew
AU - Sparrow, Ephraim M.
PY - 2009/2
Y1 - 2009/2
N2 - An investigation of candidate turbulence models for application to the flow in a distribution manifold has been performed by a synergistic combination of numerical simulation and laboratory experiments. The investigated manifold was a cylindrical chamber fitted with an array of discharge slots deployed axially and uniformly along the length of the chamber. Three turbulence models were considered for the numerical simulations: standard k-ε{lunate}, renormalized group k-ε{lunate} (RNG), and realizable k-ε{lunate} (REAL). The numerical predictions obtained from the application of these models were compared with the experimental results, and the REAL model was found to provide the best representation of the data. Special attention was given to the pressure variation along the length of the manifold, the per-exit-slot mass discharge, and the angle at which the exiting mass leaves the manifold. The departure angle is related to the axial momentum carried by the exiting flow. As confirmed by both the numerical simulations and the experiments, the departure angles varied from 68 to 90° from the upstream end to the downstream end of the manifold (90° is perpendicular to the axis). An in-depth study of numerical accuracy was performed encompassing number of nodes, deployment of nodes, and positioning of the solution domain.
AB - An investigation of candidate turbulence models for application to the flow in a distribution manifold has been performed by a synergistic combination of numerical simulation and laboratory experiments. The investigated manifold was a cylindrical chamber fitted with an array of discharge slots deployed axially and uniformly along the length of the chamber. Three turbulence models were considered for the numerical simulations: standard k-ε{lunate}, renormalized group k-ε{lunate} (RNG), and realizable k-ε{lunate} (REAL). The numerical predictions obtained from the application of these models were compared with the experimental results, and the REAL model was found to provide the best representation of the data. Special attention was given to the pressure variation along the length of the manifold, the per-exit-slot mass discharge, and the angle at which the exiting mass leaves the manifold. The departure angle is related to the axial momentum carried by the exiting flow. As confirmed by both the numerical simulations and the experiments, the departure angles varied from 68 to 90° from the upstream end to the downstream end of the manifold (90° is perpendicular to the axis). An in-depth study of numerical accuracy was performed encompassing number of nodes, deployment of nodes, and positioning of the solution domain.
KW - CFD
KW - Distribution manifolds
KW - Exit port array
KW - Numerical simulation
KW - Pipe flow
KW - Turbulence model
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U2 - 10.1016/j.ijheatmasstransfer.2008.08.006
DO - 10.1016/j.ijheatmasstransfer.2008.08.006
M3 - Article
AN - SCOPUS:58149398450
SN - 0017-9310
VL - 52
SP - 1573
EP - 1581
JO - International Journal of Heat and Mass Transfer
JF - International Journal of Heat and Mass Transfer
IS - 5-6
ER -