关于一般形式的两层高层格林-纳格迪模型

IF 2.5 3区 工程技术 Journal of Hydrodynamics Pub Date : 2024-04-11 DOI:10.1007/s42241-024-0012-z
Bin-bin Zhao, Tian-yu Zhang, Zhan Wang, Wen-yang Duan, Alexander Chesnokov, Natalia Shmakova
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引用次数: 0

摘要

传统的高阶格林-纳格迪(HLGN)模型使用多项式作为形状函数来逼近各流体层沿垂直方向的水平速度分量和垂直速度分量的变化,对于浅层构造(h2 /λ ≪ 1, h1 /λ ≪ 1)可以精确描述双层系统中的大振幅内波。然而,对于深配置(h2 / λ ≪ 1, h1 / λ = O(1))的情况,需要用高阶多项式来逼近下流体层沿垂直方向的速度分量变化。然而,这会引入额外的未知数,导致计算时间大幅增加。本文首次推导出双层流体系统 HLGN 模型的一般形式,在推导过程中使用了形状函数的一般形式。在得到两层 HLGN 方程的一般形式后,通过确定合理的形状函数就可以得到相应的解。利用两种不同的 HLGN 模型研究了深构造中的大振幅内孤波。对两种 HLGN 模型的比较表明,上流体层的形状函数采用多项式,下流体层的形状函数采用指数和多项式的组合是一种很好的选择。通过与欧拉解法和实验室测量结果的比较,验证了双层 HLGN 模型的准确性。
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On the two-layer high-level Green-Naghdi model in a general form

The traditional high-level Green-Naghdi (HLGN) model, which uses the polynomial as the shape function to approximate the variation of the horizontal- and vertical-velocity components along the vertical direction for each-fluid layer, can accurately describe the large-amplitude internal waves in a two-layer system for the shallow configuration (h2 / λ 1, h1 / λ 1). However, for the cases of the deep configuration (h2 / λ 1, h1 / λ = O(1)), higher-order polynomial is needed to approximate the variation of the velocity components along the vertical direction for the lower-fluid layer. This, however, introduces additional unknowns, leading to a significant increase in computational time. This paper, for the first time, derives a general form of the HLGN model for a two-layer fluid system, where the general form of the shape function is used during the derivation. After obtaining the general form of the two-layer HLGN equations, corresponding solutions can be obtained by determining the reasonable shape function. Large-amplitude internal solitary waves in a deep configuration are studied by use of two different HLGN models. Comparison of the two HLGN models shows that the polynomial as the shape function for the upper-fluid layer and the production of exponential and polynomial as the shape function for the lower-fluid layer is a good choice. By comparing with Euler’s solutions and the laboratory measurements, the accuracy of the two-layer HLGN model is verified.

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来源期刊
自引率
12.00%
发文量
2374
审稿时长
4.6 months
期刊介绍: Journal of Hydrodynamics is devoted to the publication of original theoretical, computational and experimental contributions to the all aspects of hydrodynamics. It covers advances in the naval architecture and ocean engineering, marine and ocean engineering, environmental engineering, water conservancy and hydropower engineering, energy exploration, chemical engineering, biological and biomedical engineering etc.
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