Title of article
Distribution of the Velocity Profile via Analytical and Three-Dimensional Numerical Vegetation Modeling
Author/Authors
Hussain ، A. A. Department of Mechanical Engineering - Faculty of Engineering and Informatics - University of Bradford , Al-Obaidi ، M. A. Technical Institute of Baquba, Technical Instructor Training Institute - Middle Technical University , Mohammed ، A. S. Civil Engineering Department - College of Engineering - University of Sulaimani , John ، Y. M. Department of Chemical Engineering - Faculty of Engineering and Informatics - University of Bradford , Rashid ، F. L. Petroleum Engineering Department - College of Engineering - University of Kerbala
From page
1792
To page
1805
Abstract
Understanding the ecological conditions of vegetation growth in water sources is vital to appraise the influence of vegetation on river engineering. Based on the experimental information that is accessible, the consequences of vegetation on flow resistance is described as an alteration in the drag coefficient and the planned area. The current study analytically estimates the vertical distribution of stream-wise velocity in open-channel flow while considering rigid and flexible vegetation. The flow is vertically separated into top free water layer and bottom vegetation layer using the projected deflection height of both vegetation. Related momentum calculations for each layer are then derived. Based on the gathered experimental data, a 3D numerical model with various simulation situations is used to model, calibrate, and evaluate the artificial cylinders. A considerable deflection analysis is utilised to calculate the velocity-dependent stem height. This has proven to be more precise compared to formerly deflection investigation. The estimated outcomes show that precise predictions may be made for the vertical contours of vertical Reynolds shear stress based on mean horizontal velocity. The numerical simulations demonstrate that plant flexibility reduces the vertical Reynolds shear stress and prompted flow resistance force of the vegetation.
Keywords
Open , channel flow , Analytical model , Numerical Model , velocity distribution , ANSYS Fluent , 3D Simulation
Journal title
Journal of Applied Fluid Mechanics (JAFM)
Journal title
Journal of Applied Fluid Mechanics (JAFM)
Record number
2766330
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