A (k–ε) turbulence closure model for plant canopy flows

A two-equatioo tin'huh, nee model has beeo dereloped for predicting two-p/rose flow. The two equations describe the conservation of turbulem'e kinetic energy and dLs'sipation rate of that em'rgy ./br the incompi'essibk, carrier fhd d ht a two-phase flow. The'continuity, the momenttmr, K and e equat

A new model for turbulent flows in porous media is developed. The spatial-and time fluctuations in this new model are tied together and treated as a single quantity. This novel treatment of the fluctuations leads to a natural construction of the k and e type equations for rigid and isotropic porous

A higher-order closure model was developed to simulate airflow within and above vegetative environments. The model consists of equations for the mean wind, turbulent kinetic energy (TKE) components, tangential stress and simplified equations for the thud-order transport terms that appear in the seco

The applicability of a finite element-differential method to the computation of steady two-dimensional lowspeed, transonic and supersonic turbulent boundary-layer flows is investigated. The turbulence model chosen for the Reynolds shear stress and turbulent heat flux is the k-t. two-equation model.