用于模拟波浪-船只-漂浮相互作用的分区函数分解方案

IF 4.6 2区 工程技术 Q1 ENGINEERING, CIVIL Ocean Engineering Pub Date : 2024-11-07 DOI:10.1016/j.oceaneng.2024.119715
Jiawei Yu , Chaobang Yao , Guohua Dong , Fanchen Zhang , Zhiguo Zhang , Dakui Feng
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引用次数: 0

摘要

提出并验证了一种新颖的分区函数分解法,用于准确有效地解决具有荡波效应的波浪与船舶之间的相互作用。该方案采用混合函数分解法,同时利用势流和粘性流精确有效地求解外域中的波浪与船舶相互作用,同时采用原始粘性法模拟内域中的荡波。为了进一步提高计算效率,采用了单相 Level-set 方法。首先,通过应用质量校正方法解决了水平集模型中的非守恒问题。此外,根据质量守恒原理,对自由表面运动的边界条件进行了修改。因此,开发出了一种改进的单相水平集方法,该方法结合了跳跃条件修正和质量修正。通过涉及线性和非线性自由表面、冲击压力、水箱上的整体力的模拟,以及与实验数据的比较,可以观察到所提出的 Level-set 方法有效地解决了内部域的荡流问题,而传统的单相 Level-set 方法往往无法解决这一问题。随后,通过采用多块网格技术标记水槽和非水槽网格块,并将改进的单相 Level-set 方法与 SWENSE 模型相结合,建立了一种分区函数分解方法来处理波浪中具有荡波效应的船舶运动。研究发现,使用传统的隐式和显式运动求解方法同时求解内部和外部流动问题具有一定的挑战性。因此,提出了一种隐式-内迭代求解方法。通过将所提出的运动求解方法与分区函数分解模型相结合,波浪-船舶-荡波相互作用取得了令人满意的结果。
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A partitioned functional-decomposition scheme for modelling wave-ship-sloshing interaction
A novel partitioned function decomposition method is proposed and validated for accurately and effectively solving the interaction between waves and ships with sloshing effect. This scheme employs a hybrid functional-decomposition method that utilizes both potential and viscous flows to accurately and efficiently solve the wave-ship interaction in the external domain, while employing the original viscous method for simulating sloshing in the internal domain. To further enhance computational efficiency, a single-phase Level-set method is employed. Firstly, the issue of non-conservation in the level-set model is addressed through the application of a mass correction method. Additionally, based on the principle of mass conservation, modifications are made to the boundary conditions for free surface motion. As a result, an improved single-phase Level-set method is developed, which combines jump condition correction and mass correction. Through simulations involving linear and nonlinear free surfaces, impulsive pressures, overall forces on the tank, as well as comparisons with experimental data, it is observed that the proposed Level-set method effectively solves the sloshing in the internal domain, a problem for which the traditional single-phase Level-set method often fails to tackle with. Subsequently, by adopting a multi-block grid technique to mark tank and non-tank grid blocks and integrating the improved single-phase Level-set method with the SWENSE model, a partitioned function decomposition method is established to handle ship motions with sloshing effect in waves. It is found that simultaneously solving the internal and external flow problems using traditional implicit and explicit motion-solving methods poses certain challenges. Therefore, an implicit-inner-iteration solution method is proposed. By combining the proposed motion-solving method with the partitioned function decomposition model, satisfactory results are achieved for the wave-ship-sloshing interaction.
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来源期刊
Ocean Engineering
Ocean Engineering 工程技术-工程:大洋
CiteScore
7.30
自引率
34.00%
发文量
2379
审稿时长
8.1 months
期刊介绍: Ocean Engineering provides a medium for the publication of original research and development work in the field of ocean engineering. Ocean Engineering seeks papers in the following topics.
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