Flow and transport simulation of Madeira River using three depth-averaged two-equation turbulence closure models

Li-ren YU

doi:10.3882/j.issn.1674-2370.2012.01.002

Volume 5 Issue 1

Mar. 2012

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Li-ren YU. 2012: Flow and transport simulation of Madeira River using three depth-averaged two-equation turbulence closure models. Water Science and Engineering, 5(1): 11-25. doi: 10.3882/j.issn.1674-2370.2012.01.002

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Li-ren YU. 2012: Flow and transport simulation of Madeira River using three depth-averaged two-equation turbulence closure models. Water Science and Engineering, 5(1): 11-25. doi: 10.3882/j.issn.1674-2370.2012.01.002

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Flow and transport simulation of Madeira River using three depth-averaged two-equation turbulence closure models

doi: 10.3882/j.issn.1674-2370.2012.01.002

Li-ren YU^{*1, 2
,}

1.
Environmental Software and Digital Visualization (ESDV), São Carlos 13561-120, Brazil
2.
Association of United Schools-Higher Education Center of São Carlos

Funds: FAPESP (Foundation for Supporting Research in São Paulo State), Brazil, of the PIPE Project (Grant No. 2006/56475-3)

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Corresponding author: Li-ren YU
Received Date: 2011-07-27
Rev Recd Date: 2011-12-15

Abstract

Abstract

This paper describes a numerical simulation in the Amazon water system, aiming to develop a quasi-three-dimensional numerical tool for refined modeling of turbulent flow and passive transport of mass in natural waters. Three depth-averaged two-equation turbulence closure models, , , and , were used to close the non-simplified quasi-three-dimensional hydrodynamic fundamental governing equations. The discretized equations were solved with the advanced multi-grid iterative method using non-orthogonal body-fitted coarse and fine grids with collocated variable arrangement. Except for steady flow computation, the processes of contaminant inpouring and plume development at the beginning of discharge, caused by a side-discharge of a tributary, have also been numerically investigated. The three depth-averaged two-equation closure models are all suitable for modeling strong mixing turbulence. The newly established turbulence models such as the model, with a higher order of magnitude of the turbulence parameter, provide a possibility for improving computational precision.
- river modeling,
- numerical modeling,
- contaminant transport,
- depth-averaged turbulence models,
- multi-grid iterative method,
- connected computational domain

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References(29)

References

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Flow and transport simulation of Madeira River using three depth-averaged two-equation turbulence closure models

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