Comparison of Average Energy Slope Estimation Formulas for One-dimensional Steady Gradually Varied Flow

Q4 Environmental Science

Archives of Hydroengineering and Environmental Mechanics Pub Date : 2014-12-01 DOI:10.1515/heem-2015-0006

W. Artichowicz, Patrycja Mikos-Studnicka

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引用次数: 3

Abstract

Abstract To find the steady flow water surface profile, it is possible to use Bernoulli’s equation, which is a discrete form of the differential energy equation. Such an approach requires the average energy slope between cross-sections to be estimated. In the literature, many methods are proposed for estimating the average energy slope in this case, such as the arithmetic mean, resulting in the standard step method, the harmonic mean and the geometric mean. Also hydraulic averaging by means of conveyance is commonly used. In this study, water surface profiles numerically computed using different formulas for expressing the average slope were compared with exact analytical solutions of the differential energy equation. Maximum relative and mean square errors between numerical and analytical solutions were used as measures of the quality of numerical models. Experiments showed that all methods gave solutions useful for practical engineering purposes. For every method, the numerical solution was very close to the analytical one. However, from the numerical viewpoint, the differences between the methods were significant, as the errors differed up to two orders of magnitude.

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一维稳定渐变流平均能量斜率估算公式的比较

摘要为了求稳流水面剖面，可以使用伯努利方程，它是微分能量方程的一种离散形式。这种方法需要估计截面间的平均能量斜率。在文献中，提出了许多方法来估计这种情况下的平均能量斜率，如算术平均值，从而产生了标准阶跃法、谐波平均值和几何平均值。此外，通常采用水力平均的方式进行输送。本文采用不同的平均斜率表示公式计算水面剖面，并与微分能量方程的精确解析解进行了比较。数值解和解析解之间的最大相对误差和均方误差被用来衡量数值模型的质量。实验结果表明，所有方法都能给出对实际工程有用的解。对于每一种方法，数值解都非常接近解析解。然而，从数值的角度来看，两种方法之间的差异是显著的，因为误差相差高达两个数量级。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Archives of Hydroengineering and Environmental Mechanics Environmental Science-Water Science and Technology

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： Archives of Hydro-Engineering and Environmental Mechanics cover the broad area of disciplines related to hydro-engineering, including: hydrodynamics and hydraulics of inlands and sea waters, hydrology, hydroelasticity, ground-water hydraulics, water contamination, coastal engineering, geotechnical engineering, geomechanics, structural mechanics, etc. The main objective of Archives of Hydro-Engineering and Environmental Mechanics is to provide an up-to-date reference to the engineers and scientists engaged in the applications of mechanics to the analysis of various phenomena appearing in the natural environment.