Bulk drag coefficient of a subaquatic vegetation subjected to irregular waves: Influence of Reynolds and Keulegan-Carpenter numbers

IF 0.8 Q4 Environmental Science

Houille Blanche-Revue Internationale De L Eau Pub Date : 2020-04-01 DOI:10.1051/lhb/2020015

Thibault Chastel, Kevin Botten, N. Durand, N. Goutal

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引用次数: 7

Abstract

Seagrass meadows are essential for protection of coastal erosion by damping wave and stabilizing the seabed. Seagrass are considered as a source of water resistance which modifies strongly the wave dynamics. As a part of EDF R & D seagrass restoration project in the Berre lagoon, we quantify the wave attenuation due to artificial vegetation distributed in a flume. Experiments have been conducted at Saint-Venant Hydraulics Laboratory wave flume (Chatou, France). We measure the wave damping with 13 resistive waves gauges along a distance L = 22.5 m for the “low” density and L = 12.15 m for the “high” density of vegetation mimics. A JONSWAP spectrum is used for the generation of irregular waves with significant wave height Hs ranging from 0.10 to 0.23 m and peak period Tp ranging from 1 to 3 s. Artificial vegetation is a model of Posidonia oceanica seagrass species represented by slightly flexible polypropylene shoots with 8 artificial leaves of 0.28 and 0.16 m height. Different hydrodynamics conditions (Hs, Tp, water depth hw) and geometrical parameters (submergence ratio α, shoot density N) have been tested to see their influence on wave attenuation. For a high submergence ratio (typically 0.7), the wave attenuation can reach 67% of the incident wave height whereas for a low submergence ratio (< 0.2) the wave attenuation is negligible. From each experiment, a bulk drag coefficient has been extracted following the energy dissipation model for irregular non-breaking waves developed by Mendez and Losada (2004). This model, based on the assumption that the energy loss over the species meadow is essentially due to the drag force, takes into account both wave and vegetation parameter. Finally, we found an empirical relationship for Cd depending on 2 dimensionless parameters: the Reynolds and Keulegan-Carpenter numbers. These relationships are compared with other similar studies.

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水下植被在不规则波浪作用下的体积阻力系数:Reynolds数和Keulegan-Carpenter数的影响

海草草地对于通过阻尼波浪和稳定海床来保护海岸侵蚀至关重要。海草被认为是水阻力的来源，它强烈地改变了波浪动力学。作为EDF R的一部分 & D Berre泻湖的海草恢复项目，我们量化了水槽中分布的人工植被造成的波浪衰减。实验在圣维南水力学实验室波浪水槽（法国查图）进行。我们用13测量波浪阻尼沿距离L的电阻波片 = 22.5 m表示“低”密度，L = 12.15 m表示植被模拟的“高”密度。JONSWAP谱用于产生有效波高Hs在0.10至0.23范围内的不规则波 m和范围从1到3的峰值周期Tp s.人工植被是海洋Posidonia海草物种的一个模型，以具有8个 0.28和0.16的人造叶片 m高。试验了不同的水动力学条件（Hs、Tp、水深hw）和几何参数（淹没比α、射密度N）对波浪衰减的影响。对于高淹没比（通常为0.7），波浪衰减可以达到入射波高的67%，而对于低淹没比(< 0.2），波的衰减可以忽略不计。根据Mendez和Losada（2004）开发的不规则非破碎波的能量耗散模型，从每个实验中提取了体积阻力系数。该模型基于物种草地上的能量损失基本上是由阻力引起的假设，同时考虑了波浪和植被参数。最后，我们发现Cd依赖于2的经验关系无量纲参数：Reynolds和Keulegan-Capenter数。将这些关系与其他类似研究进行比较。

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

Houille Blanche-Revue Internationale De L Eau 环境科学-水资源

CiteScore

0.40

自引率

0.00%

发文量

审稿时长

>36 weeks

期刊介绍： La Houille Blanche, revue internationale de l ''eau/International Water Journal, is the only almost all French-written journal of Water science. It promotes the dissemination of research and innovative practices in the field of water, as a key resource for everyday use for human needs, agriculture, energy and transport, and hydraulic public works. This includes environmental and risk assessment and management issues related to hydrology, meteorology, flood, low flows and drought, as well as issues in the field of fluid mechanics, hydraulics machinery, multiphase flows, microfluidics... La Houille Blanche, International Water Journal, is cited by Science Citation Index Expanded of Institute for Scientific Information (I.S.I) in USA, and by CNRS in France; since 1902, the journal publishes high-standard relevant peer-reviewed research papers. La Houille Blanche also provides more general information and recent news about the water world, and the SHF association and its members life: scientific events, book review, R & D advancements, … Six issues per year. Thematical journal for original articles and reviews mostly in French.