Horizontal Sigma Coordinate System for River-Flow Models
Publication: Journal of Hydraulic Engineering
Volume 134, Issue 11
Abstract
Because of complicated channel geometry, horizontal coordinates are important in accurate and efficient computations of river flow. We propose a simplified horizontal coordinate system for river-flow simulation, referred to here as a horizontal sigma coordinate system that uses boundary-fitted grids along river channels like a generalized curvilinear coordinate system, without losing the simplicity of Cartesian or orthogonal curvilinear coordinate systems. The proposed approach is based on a sigma coordinate system. The depth-averaged continuity and momentum equations for horizontal two-dimensional fluid motion in the Cartesian and orthogonal curvilinear coordinate systems are transformed to those in the horizontal sigma coordinate system. The form of the transformed continuity and momentum equations in the proposed system is a fairly minor modification of the form of the equations for the Cartesian and orthogonal curvilinear coordinate systems. Computational results for a straight open-channel flow with a narrow pass indicate that the horizontal sigma coordinate system is as numerically accurate as the generalized curvilinear coordinate system and that the CPU times required to calculate the horizontal sigma and Cartesian coordinate systems are comparable. We also computed flood flow in an actual river using the numerical models based on the horizontal sigma, orthogonal curvilinear, and generalized curvilinear coordinate systems. The results show that the horizontal sigma coordinate system may dramatically reduce the numerical error generated in the orthogonal curvilinear coordinate system. These facts demonstrate that the horizontal sigma coordinate system is a promising tool for numerical approximation of flow in the horizontal direction that is computationally efficient and numerically accurate.
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References
Bates, P. D., Lane, S. N., and Ferguson, R. I. (2005). Computational fluid dynamics applications in environmental hydraulics, Wiley, New York, 1–531.
Begnudelli, L., and Sanders, B. F. (2006). “Unstructured grid finite-volume algorithm for shallow-water flow and scalar transport with wetting and drying.” J. Hydraul. Eng., 132(2), 371–384.
Biron, P. M., Ramamurthy, A. S., and Han, S. (2004). “Three-dimensional numerical modeling of mixing at river confluences.” J. Hydraul. Eng., 130(3), 243–253.
Blumberg, A. F., and Mellor, G. L. (1983). “Diagnostic and prognostic numerical circulation studies of the South Atlantic Bight.” J. Geophys. Res., 88, 4579–4592.
Bradbrook, K. F., Biron, P. M., Lane, S. N., Richards, K. S., and Roy, A. G. (1998). “Investigation of controls on secondary circulation in a simple confluence geometry using a three-dimensional numerical model.” Hydrolog. Process., 12, 1371–1396.
Chau, K. W., and Jiang., Y. W. (2001). “3D numerical model for Pearl River estuary.” J. Hydraul. Eng., 127(1), 72–82.
Haney, R. L. (1991). “On the pressure gradient force over steep topography in sigma coordinate ocean models.” J. Phys. Oceanogr. 21, 610–619.
Hodges, B. R., and Imberger, J. (2001). “Simple curvilinear method for numerical methods of open channels.” J. Hydraul. Eng., 127(11), 949–958.
Huang, J. Weber, L. J., and Lai, Y. J. (2002). “Three-dimensional numerical study of flows in open-channel junctions.” J. Hydraul. Eng., 128(3), 268–280.
Kawamura, T., Takami, H., and Kuwahara, K. (1986). “Computation of high Reynolds number flow around a circular cylinder with surface roughness.” Fluid Dyn. Res., 1, 145–162.
Lien, H. C., Hsieh, T. Y., Yang, J. C., and Yeh, K. C. (1999). “Bend-flow simulation using 2D depth-averaged model.” J. Hydraul. Eng., 125(10), 1097–1108.
Mellor, G. L., and Blumberg, A. F. (1985). “Modeling vertical and horizontal diffusivities with the sigma coordinate system.” Mon. Weather Rev., 113, 1379–1383.
Nagata, N., Hosoda, T., and Muramoto, Y. (2000). “Numerical analysis of river channel process with bank erosion.” J. Hydraul. Eng., 126(4), 243–252.
Phillips, N. A. (1957). “A coordinate system having some special advantages for numerical forecasting.” J. Meteorol., 14, 184–185.
Stelling, G. S., and Van Kester, J. A. TH. M. (1994). “On the approximation of horizontal gradients in sigma coordinates for bathymetry with steep bottom slopes.” Int. J. Numer. Methods Fluids, 18, 915–935.
Information & Authors
Information
Published In
Journal of Hydraulic Engineering
Volume 134 • Issue 11 • November 2008
Pages: 1611 - 1619
Copyright
© 2008 ASCE.
History
Received: Sep 25, 2007
Accepted: Apr 25, 2008
Published online: Nov 1, 2008
Published in print: Nov 2008
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