网格尺度对三维水动力模型模拟滨海地区潮流特性影响的数值分析

摘要/Abstract

摘要： 构建了三门湾三维水动力模型,将计算结果与实测资料进行对比分析后设置了不同的网格尺度,对三个断面和四个典型点的潮流特性进行了分析。结果表明:当研究水域为港汊较多、地形复杂的海湾时,数值模拟计算值的相对偏差会随着网格尺度增大而增大,当网格尺度增大到一定值时,相对偏差会由于多种误差的正负累积而趋于稳定。地形是影响潮流计算的关键因素,在地形变化剧烈和水深较小的潮间带水域的潮差和流速值相对变化较大,在水深较大的平坦区域则几乎不受网格尺度的影响;流向对网格尺度的敏感程度较低,与网格尺度无明显关系;水平涡粘系数与网格面积呈正相关,且网格面积对流速变形率S_ij较大处影响较大。综合分析,在进行潮流计算时,需要在地形复杂的岸边、水深较小的潮间带以及岛屿间进行网格的加密处理,考虑计算时间、模型计算的稳定收敛以及计算值的精确度等因素,确定合适的计算网格尺度,使得计算结果满足精度要求。

关键词: 三维水动力模型, 网格尺度, 潮流特性, 数值模拟

Abstract: In this paper, a three-dimensional hydrodynamic model of Sanmen Bay is constructed. Different mesh scales are set up after comparing and analyzing the calculation results with the measured data, and the tidal current characteristics of three sections and four typical points are analyzed. The results show that: when the study water is a bay with many harbor branches and complex topography, the relative deviation of the numerical simulation value will increase with the mesh scale. When the mesh scale increases to a certain value, the relative deviation will stabilize due to the accumulation of multiple errors. The topography is a key factor affecting the calculation of tidal currents. The tidal range and current velocity values in the inter-tidal waters with drastic topographic changes and small water depths are relatively large, while in the flat areas with large water depths, they are almost unaffected by the mesh scale. The current direction has a low sensitivity to the mesh scale and has no obvious relationship with the mesh scale. The horizontal vortex viscosity coefficient is positively correlated with the mesh area and the mesh area has a greater effect on the current velocity deformation rate S_ij at the larger places. Comprehensive analysis shows that, in the calculation of tidal currents, it is necessary to encrypt the mesh in the shore with complicated topography, inter-tidal zone with small water depth and islands, and to determine the appropriate mesh scale by considering the factors of calculation time, stable convergence of the model calculation and the accuracy of the calculated values, so as to make the calculation results meet the requirements of accuracy.

Key words: three-dimensional hydrodynamic model, mesh scale, tidal wave characteristics, numerical simulation

中图分类号:

X143

刘姣男, 韩丽娟, 乔建浩, 郝瑞霞. 网格尺度对三维水动力模型模拟滨海地区潮流特性影响的数值分析[J]. 辐射防护, 2024, 44(4): 391-402.

LIU Jiaonan, HAN Lijuan, QIAO Jianhao, HAO Ruixia. Numerical analysis of the effect of mesh scale on the tidal characteristics of coastal areas simulated by 3D hydrodynamic model[J]. RADIATION PROTECTION, 2024, 44(4): 391-402.

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