The drag length is key to quantifying tree canopy drag
Abstract
The effects of trees on urban flows are often determined using computational fluid dynamics approaches which typically use a quadratic drag formulation based on the leaf-area density a and a volumetric drag coefficient CdV to model vegetation. In this paper, we develop an analytical model for the flow within a vegetation canopy and identify that the drag length d = (a CdV)-1 is the key metric to describe the local tree drag characteristics. A detailed study of the literature suggests that the median d observed in field experiments is 21 m for trees and 0.7 m for low vegetation (crops). A total of 168 large-eddy simulations are conducted to obtain a closed form of the analytical model. The model allows determining a and CdV from wind-tunnel experiments that typically present the drag characteristics in terms of the classical drag coefficient Cd and the aerodynamic porosity αL. We show that geometric scaling of d is the appropriate scaling of trees in wind tunnels. Evaluation of d for numerical simulations and wind-tunnel experiments (assuming geometric scaling 1:100) in literature shows that the median d in both these cases is about 5 m, suggesting possible overestimation of vegetative drag.
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