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Rapid Monitoring of River Hydrodynamics and Morphology using Acoustic Holography

Lead Research Organisation: UNIVERSITY COLLEGE LONDON
Department Name: Civil Environmental and Geomatic Eng

Abstract

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Publications

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Xie Z (2020) A Cartesian cut-cell based multiphase flow model for large-eddy simulation of three-dimensional wave-structure interaction in Computers & Fluids

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Xie Z (2022) A conservative and consistent implicit Cartesian cut-cell method for moving geometries with reduced spurious pressure oscillations in Journal of Computational Physics

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Xie Z (2020) A control volume finite element method for three-dimensional three-phase flows in International Journal for Numerical Methods in Fluids

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Xie Z (2020) A three-dimensional Cartesian cut-cell/volume-of-fluid method for two-phase flows with moving bodies in Journal of Computational Physics

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Xie Z (2022) Eulerian and Lagrangian transport by shallow-water breaking waves in Physics of Fluids

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Jalalabadi R (2021) Free surface flow over square bars at different Reynolds numbers in Journal of Hydro-environment Research

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Luo Q (2023) Hydrodynamics and turbulence of free-surface flow over a backward-facing step in Journal of Hydraulic Research

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Jalalabadi R (2023) Large-eddy simulation of free-surface turbulent channel flow over square bars in International Journal of Heat and Fluid Flow

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Xie Z (2021) Large-eddy simulation of turbulent free surface flow over a gravel bed in Journal of Hydraulic Research

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Luo Q (2023) Meandering of instantaneous large-scale structures in open-channel flow over longitudinal ridges in Environmental Fluid Mechanics

 
Description Numerical simulations of turbulent flow over topographic roughness showed significant correlation between the turbulence structure and the water surface deformation. As a result of flow separation near the channel bed water surface waves occur and the wave frequency matches the frequency of the vortex shedding process of flow separation. As a secondary process, the small-scale turbulence of the flow deforms the water surface in more random patters.
Exploitation Route These results can be taken forward to design river monitoring equipment that would record and quantify surface waves, which can provide detailed information of the type of roughness that is found near the bed and can eventually lead to better flow monitoring.
Sectors Environment
 
Title Research Code Enhancements 
Description The open-source code Hydro3D, based on the method of large-eddy simulation, was enahnced by a free-surface algorithm which was validated and applied to open-channel flow over a backward facing step. A Journal of Fluid Mechanics and a Journal of Hydraulic research paper document this development. 
Type Of Material Improvements to research infrastructure 
Year Produced 2021 
Provided To Others? No  
Impact Several journal publications have resulted from this development. 
 
Title Level Set Method 
Description As describd in the Research Environment section, the open source code Hydro3D was enhanced with a Level Set Method algorithm. This method is now standard for all our open-channel flow simulations. 
Type Of Technology New/Improved Technique/Technology 
Year Produced 2021 
Impact The new method resulted in a couple of fundamental research papers and will be used in future research. 
 
Title Simulation of tidal stream turbines using Hydro3D 
Description Hydro3D is an open-source Large-Eddy Simulation based code used for hydraulic engineering applications and has been recently developed to simulate tidal stream turbines. Hydro3D is written in FORTRAN 95 and is parallelised with MPI, both required to be installed prior code compilation. For a more detailed description of Hydro3D, its current development and related publications please visit: http://hydro3dproject.github.io/ Note that the current dataset gathers the input files set to simulate a single horizontal axis tidal stream turbine operating at its maximum performance and with artificial turbulence at the inflow condition. The input files (.cin) used in Hydro3D are: - control.cin - in this file all the flow conditions, numerical schemes and output paramenters are set. - geom.cin - is used to define the properties of any solid body (e.g. tidal turbine) used during the simulation. - mdmap.cin and infodom.cin - these files indicate the division pattern of the computational domain in rectangular blocks together with their assignation to CPUs. 
Type Of Technology Software 
Year Produced 2017 
Impact The code was enhanced by adding free surface algorithms. 
URL https://research-data.cardiff.ac.uk/articles/software/Simulation_of_tidal_stream_turbines_using_Hydr...