Vertical two-dimensional non-hydrostatic pressure model with single layer

doi:10.1007/s10483-013-1702-x

Applied Mathematics and Mechanics (English Edition) ›› 2013, Vol. 34 ›› Issue (6): 721-730.doi: https://doi.org/10.1007/s10483-013-1702-x

Vertical two-dimensional non-hydrostatic pressure model with single layer

康玲郭晓明

School of Hydropower and Information Engineering, Huazhong University of Science and Technology, Wuhan 430074, P. R. China

出版日期:2013-06-03 发布日期:2013-06-03
通讯作者: Xiao-ming GUO E-mail:mastergxm@hust.edu.cn

Vertical two-dimensional non-hydrostatic pressure model with single layer

Ling KANG, Xiao-ming GUO

School of Hydropower and Information Engineering, Huazhong University of Science and Technology, Wuhan 430074, P. R. China

Online:2013-06-03 Published:2013-06-03
Contact: Xiao-ming GUO E-mail:mastergxm@hust.edu.cn

摘要/Abstract

摘要： The vertical two-dimensional non-hydrostatic pressure models with multiple layers can make prediction more accurate than those obtained by the hydrostatic pressure assumption. However, they are time-consuming and unstable, which makes them unsuitable for wider application. In this study, an efficient model with a single layer is developed. Decomposing the pressure into the hydrostatic and dynamic components and
integrating the x-momentum equation from the bottom to the free surface can yield a horizontal momentum equation, in which the terms relevant to the dynamic pressure are discretized semi-implicitly. The convective terms in the vertical momentum equation are ignored, and the rest of the equation is approximated with the Keller-box scheme. The velocities expressed as the unknown dynamic pressure are substituted into the continuity
equation, resulting in a tri-diagonal linear system solved by the Thomas algorithm. The validation of solitary and sinusoidal waves indicates that the present model can provide comparable results to the models with multiple layers but at much lower computation cost.

关键词: vertical two-dimensional model, non-hydrostatic pressure, single layer, Thomas algorithm, wave

Abstract: The vertical two-dimensional non-hydrostatic pressure models with multiple layers can make prediction more accurate than those obtained by the hydrostatic pressure assumption. However, they are time-consuming and unstable, which makes them unsuitable for wider application. In this study, an efficient model with a single layer is developed. Decomposing the pressure into the hydrostatic and dynamic components and
integrating the x-momentum equation from the bottom to the free surface can yield a horizontal momentum equation, in which the terms relevant to the dynamic pressure are discretized semi-implicitly. The convective terms in the vertical momentum equation are ignored, and the rest of the equation is approximated with the Keller-box scheme. The velocities expressed as the unknown dynamic pressure are substituted into the continuity
equation, resulting in a tri-diagonal linear system solved by the Thomas algorithm. The validation of solitary and sinusoidal waves indicates that the present model can provide comparable results to the models with multiple layers but at much lower computation cost.

Key words: finite element, geometric nonlinearity, numerical simulation, drill string, vertical two-dimensional model, non-hydrostatic pressure, single layer, Thomas algorithm, wave

中图分类号:

vertical two-dimensional model| non-hydrostatic pressure| single layer|Thomas algorithm| wave

康玲郭晓明. Vertical two-dimensional non-hydrostatic pressure model with single layer[J]. Applied Mathematics and Mechanics (English Edition), 2013, 34(6): 721-730.

Ling KANG;Xiao-ming GUO. Vertical two-dimensional non-hydrostatic pressure model with single layer[J]. Applied Mathematics and Mechanics (English Edition), 2013, 34(6): 721-730.

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Vertical two-dimensional non-hydrostatic pressure model with single layer

Vertical two-dimensional non-hydrostatic pressure model with single layer

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