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Modelling of Flood Waves Based on Wave Propagation ‎Algorithms with Bed Efflux and Influx Including a Coupled ‎Pipe Network Solver

Mahdizadeh, Hossein

[Thesis]. Manchester, UK: The University of Manchester; 2011.

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Layman's Abstract

Abstract of thesis submitted by: Hossein MahdizadehFor the degree of: Doctor of Philosophyand entitled: Modelling of Flood Waves Based on Wave Propagation Algorithms with ‎Bed Efflux and Influx Including a Coupled Pipe Network Solver.‎Flood propagation over urban areas can cause an interaction between the free-surface flow ‎and large underground pipe networks used for storm drainage and sewage, causing ‎outflows and inflows at the bed. The associated waves may collide with each other and the ‎surface waves. In this thesis the shallow water equations are used to model this type of ‎wave interaction over dry or wet beds with bathymetry gradients and friction terms. The ‎proposed shallow water scheme is solved based on finite volume high-resolution Godunov-‎type methods. The solver is well-balanced and can accurately balance the source terms and ‎flux-gradients for the steady-state solutions. The solver also utilises a new type of Riemann ‎wave speed to provide depth-positive results over nearly dry beds and dry states. ‎Additionally a new type of source term is introduced in the continuity equation to model ‎pipe inflow and outflow conditions at bed connections. ‎For the standard one-dimensional shallow water equations the numerical results are ‎validated with analytical solutions or other reference solutions provided in the literature. ‎This includes the incipient Riemann problems for nearly dry and dry-states, steady flow ‎over a hump in a rectangular channel and the wave propagation problem. Eventually, the ‎generation of dry bed in the middle, over discontinuous topography is considered. Close ‎agreement is achieved between the shallow water scheme and analytical or reference ‎solutions for the above test cases. For the shallow water problems with influx/efflux source ‎terms comparisons are made with STAR-CD, a commercial Navier-Stokes solver for ‎general fluid flow prediction. The shallow water model is first used to simulate vertical ‎flows through finite gaps in the bed. Next, the interaction of the vertical flows with a dam-‎break flow is considered for both dry and wet beds. An efflux number, En, is defined based ‎on the vertical efflux velocity and the gap length. A parameter study is undertaken to ‎investigate the effect of the one-dimensional approximation of the present model, for a ‎range of non-dimensional efflux numbers. It is found that the shallow flow model gives ‎sensible predictions at all times provided En<0.5, and for long durations for En>0.5. Dam ‎break flow over an underground connecting pipe is also considered for the one-‎dimensional efflux problems.‎To solve two-dimensional problems the shallow water scheme uses the dimensional-‎splitting method which solves each one-dimensional Riemann problem in the x- and y-‎directions separately. The cross-derivative terms for second-order accuracy are ‎incorporated by solving another Riemann problem in the orthogonal direction. For two-‎dimensional problems first the dam-break problems are considered over wet and dry beds. ‎Then, flood propagation over complex terrain is demonstrated. Next, efflux discharge is ‎modelled in isolation over a dry bed and then with dam-break interaction, comparing with ‎STAR-CD results. Again very good agreement is shown between the two-dimensional ‎shallow water model and STAR-CD for the efflux numbers of En<0.5.‎For modelling the inundation problem over an underground pipe network the solver is ‎coupled with the general underground pipe network solver to calculate the efflux discharge ‎as the flood waves pass through the pipe network. For analysing the pipe network with ‎unknown effluxes an additional set of equations is incorporated into the solution of a ‎general pipe network solver. The shallow water solver coupled to an underground pipe ‎network is then used to simulate dam-break interaction with pipe networks with 9 and 25 ‎nodes to demonstrate the versatility of the method.‎

Bibliographic metadata

Type of resource:
Content type:
Administered thesis
Form of thesis:
Traditional
Type of submission:
Doctoral level ETD - final
Thesis title:
Modelling of Flood Waves Based on Wave Propagation ‎Algorithms with Bed Efflux and Influx Including a Coupled ‎Pipe Network Solver
Degree type:
Doctor of Philosophy
Degree programme:
PhD Civil Engineering
Publication date:
2011-01-11T16:30:14
Institution:
The University of Manchester
Location:
Manchester, UK
Total pages:
170
Layman's abstract:
Abstract of thesis submitted by: Hossein MahdizadehFor the degree of: Doctor of Philosophyand entitled: Modelling of Flood Waves Based on Wave Propagation Algorithms with ‎Bed Efflux and Influx Including a Coupled Pipe Network Solver.‎Flood propagation over urban areas can cause an interaction between the free-surface flow ‎and large underground pipe networks used for storm drainage and sewage, causing ‎outflows and inflows at the bed. The associated waves may collide with each other and the ‎surface waves. In this thesis the shallow water equations are used to model this type of ‎wave interaction over dry or wet beds with bathymetry gradients and friction terms. The ‎proposed shallow water scheme is solved based on finite volume high-resolution Godunov-‎type methods. The solver is well-balanced and can accurately balance the source terms and ‎flux-gradients for the steady-state solutions. The solver also utilises a new type of Riemann ‎wave speed to provide depth-positive results over nearly dry beds and dry states. ‎Additionally a new type of source term is introduced in the continuity equation to model ‎pipe inflow and outflow conditions at bed connections. ‎For the standard one-dimensional shallow water equations the numerical results are ‎validated with analytical solutions or other reference solutions provided in the literature. ‎This includes the incipient Riemann problems for nearly dry and dry-states, steady flow ‎over a hump in a rectangular channel and the wave propagation problem. Eventually, the ‎generation of dry bed in the middle, over discontinuous topography is considered. Close ‎agreement is achieved between the shallow water scheme and analytical or reference ‎solutions for the above test cases. For the shallow water problems with influx/efflux source ‎terms comparisons are made with STAR-CD, a commercial Navier-Stokes solver for ‎general fluid flow prediction. The shallow water model is first used to simulate vertical ‎flows through finite gaps in the bed. Next, the interaction of the vertical flows with a dam-‎break flow is considered for both dry and wet beds. An efflux number, En, is defined based ‎on the vertical efflux velocity and the gap length. A parameter study is undertaken to ‎investigate the effect of the one-dimensional approximation of the present model, for a ‎range of non-dimensional efflux numbers. It is found that the shallow flow model gives ‎sensible predictions at all times provided En<0.5, and for long durations for En>0.5. Dam ‎break flow over an underground connecting pipe is also considered for the one-‎dimensional efflux problems.‎To solve two-dimensional problems the shallow water scheme uses the dimensional-‎splitting method which solves each one-dimensional Riemann problem in the x- and y-‎directions separately. The cross-derivative terms for second-order accuracy are ‎incorporated by solving another Riemann problem in the orthogonal direction. For two-‎dimensional problems first the dam-break problems are considered over wet and dry beds. ‎Then, flood propagation over complex terrain is demonstrated. Next, efflux discharge is ‎modelled in isolation over a dry bed and then with dam-break interaction, comparing with ‎STAR-CD results. Again very good agreement is shown between the two-dimensional ‎shallow water model and STAR-CD for the efflux numbers of En<0.5.‎For modelling the inundation problem over an underground pipe network the solver is ‎coupled with the general underground pipe network solver to calculate the efflux discharge ‎as the flood waves pass through the pipe network. For analysing the pipe network with ‎unknown effluxes an additional set of equations is incorporated into the solution of a ‎general pipe network solver. The shallow water solver coupled to an underground pipe ‎network is then used to simulate dam-break interaction with pipe networks with 9 and 25 ‎nodes to demonstrate the versatility of the method.‎
Keyword(s):
Thesis main supervisor(s):
Degree grantor:
Language:
en

Record metadata

Manchester eScholar ID:
uk-ac-man-scw:105997
Created by:
Mahdizadeh, Hossein
Created:
11th January, 2011, 16:30:14
Last modified by:
Mahdizadeh, Hossein
Last modified:
7th April, 2011, 11:11:39

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