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DETAILED TURBULENCE CALCULATIONS FOR OPEN CHANNEL FLOW
By Faye Beaman School of Civil Engineering University of Nottingham
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CONTENTS Flood prediction and modelling Conveyance estimation
Importance of flood prediction Differences between in-bank and over-bank modelling Conveyance estimation Shiono and Knight method (SKM) advanced by Ervine et al Project aim Computational Fluid Dynamics Reynolds Averaged Navier-Stokes models (RANS) Direct Numerical Simulation (DNS) Large Eddy Simulation (LES) Research Initial trapezoidal channel Compound channels Summary
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FLOOD PREDICTION & MODELLING
Frightening statistics 5 million people & 2 million properties located in flood risk areas in the UK Flood alleviation schemes are the focus of a large amount of engineering work; Prediction of conveyance capacity, and velocity and boundary shear stress distributions is a prerequisite for studies on bank protection and sediment transport Very straightforward for in-bank flows However when in flood it becomes much more difficult due to complex 3D flow structures Example of stage-discharge relationship (rating curve)
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FLOOD PREDICTION & MODELLING
Calculation of river flood conveyance in compound open channels is very complicated; Main channel velocities significantly greater than those in the floodplain Large velocity gradients in the region of the main channel / floodplain interface develop, resulting in momentum transfer Transverse shear layer produced influencing flow, within which large horizontal coherent structures develop Superposition of high lateral shear on bed-generated turbulence and longitudinal secondary flow structures intriguing Compound channel cross section
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FLOOD PREDICTION & MODELLING
Flow structures in a straight two-stage channel (Shiono & Knight)
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TWO STAGE COMPOUND CHANNELS
Top view of compound channel experiment. The large scale coherent structures can be seen from the die injection.
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CONVEYANCE ESTIMATION & SKM
One very popular is that of Shiono and Knight extension by Ervine Based on depth mean averaged form of momentum equation 1D method, incorporating 2D parameters and modelling 3D effects Incorporates empirical calibration constants f, (local friction factor) Γ (secondary flow parameter) λ (dimensionless eddy viscosity coefficient) Cav (Depth average cross flow coefficient)
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COMPUTATIONAL FLUID DYNAMICS (CFD)
Application of full Navier-Stokes equations to environmental problems Reynolds Averaged Navier-Stokes (RANS) models common Other approaches to turbulence simulation include; Direct Numerical Simulation (DNS) Large Eddy Simulation (LES) LES Intermediate approach to RANS and DNS Large 3D unsteady turbulent motions are directly represented and computed exactly Smaller-scale structures are not predicted directly, but their influence upon the rest of the flow is parameterised Schematic of LES
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LARGE EDDY SIMULATION (LES) cont.
Mesh generated forms volumetric filter above which structures computed exactly Filter width delta, Δ = (volume)1/3 Reduced computational power, due to not directly computing small scales
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LARGE EDDY SIMULATION (LES) cont.
COMPUTATIONAL POWER DNS requires data points; Duration of simulation can be approximated as; Therefore computer power; Re ~ 103, several days, Re ~ 104, weeks Ratio of number of points for LES compared to DNS;
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TRAPEZOIDAL CHANNEL Initial case
Re ~ 18,000 300,000 cell mesh Inlet velocity ~ 0.05m/sec Smooth walls Free surface effects included using a symmetry boundary condition Periodic boundary conditions reduce channel length => no of cells Parallel runs Computational time ~ months Physical simulated time ~ 5000sec 4 processors Isosurface of vorticity coloured with pressure Contour plot of streamwise vorticity
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TRAPEZOIDAL CHANNEL MESH
Increased Re case Re ~ 200,000 3 proposed mesh resolutions 0.5mil, 4mil, 30mil Trapezoidal channel awkward to get good skewness and aspect ratio Paved mesh; Non-conformal Throws together a mesh from hex’s or tet’s But still structured where possible Not axisymmetric Cells more isotropic than those of the structured mesh Structured mesh 0.5mil hex Non conformal paved mesh 0.5mil hex
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TRAPEZOIDAL CHANNEL INITIAL RESULTS
Non conformal paved mesh 0.5mil hex Structured mesh 0.5mil hex
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TWO STAGE COMPOUND CHANNEL
Initial runs at Re ~ 150,000 Available FCF data for validation
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SUMMARY Wide variety of channel geometries can be simulated LES
Captures large structures exactly Very computationally demanding Long run times but simulating reasonable results Increased computer power means; more detailed grids higher Reynolds numbers, therefore more realistic flow simulations
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