单向风波相互作用演化的实验设计与分析

IF 5.3 2区工程技术 Q1 ENGINEERING, CIVIL

IEEE Journal of Oceanic Engineering Pub Date : 2025-06-24 DOI:10.1109/JOE.2025.3549967

Zitan Zhang;Tianning Tang;Wentao Xu;Xiaobo Zheng;Lijun Zhang;Jung-hoon Lee;Jason P. Monty;Ye Li

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引用次数: 0

摘要

对海上浮式结构的最大威胁是极端气象条件下形成的巨浪。然而，由于缺乏系统的大型海气相互作用研究设施，制约了风浪相互作用研究的进一步发展。为此，我们设计并研制了一种具有风强迫的极端波浪实验装置。为了研究风对波浪的影响，我们进行了单向随机波浪实验。结果表明，风对波高分布的影响是显著的。Rayleigh分布不能很好地描述波高分布，特别是在Benjamin-Feir指数（BFI）较大的情况下。值得注意的是，实验中BFI最大的情况并没有像预期的那样随着风的强迫而增加。我们试图通过了解设备规格之间的差异，为这个问题提供一个可能的解释。我们认为水槽的无因次长度和湍流风的质量对波浪的演变，特别是极端事件的概率有显著的影响。

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Experimental Design and Analysis of the Evolution of Unidirectional Wind Wave Interaction

The greatest threat to floating structures at sea is the huge waves formed with extreme meteorological conditions. However, the lack of a systematic large-scale facility for sea–air interaction limits the further development of wind–wave interaction. Therefore, we have designed and developed an extreme wave experimental facility with wind forcing. We performed unidirectional random wave experiments to investigate the wind impact on waves. The results suggest that the effect of wind on wave height distribution is significant. The wave height distribution cannot be well described by the Rayleigh distribution, especially in cases with a large Benjamin–Feir index (BFI). It is worth noting that the case with the largest BFI in the experiment did not increase with the wind forcing as expected. We attempt to provide a possible explanation for this issue by understanding the differences between the facility specification. We consider that the dimensionless length of the tank and the quality of turbulent wind can have a significant impact on wave evolution, especially the probability of extreme events.

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来源期刊

IEEE Journal of Oceanic Engineering 工程技术-工程：大洋

CiteScore

9.60

自引率

12.20%

发文量

审稿时长

12 months

期刊介绍： The IEEE Journal of Oceanic Engineering (ISSN 0364-9059) is the online-only quarterly publication of the IEEE Oceanic Engineering Society (IEEE OES). The scope of the Journal is the field of interest of the IEEE OES, which encompasses all aspects of science, engineering, and technology that address research, development, and operations pertaining to all bodies of water. This includes the creation of new capabilities and technologies from concept design through prototypes, testing, and operational systems to sense, explore, understand, develop, use, and responsibly manage natural resources.