大型部分深度导流墙在多尔多涅河tuiliires大坝下游大西洋鲑鱼幼鱼的导流效果

IF 1.6 3区环境科学与生态学 Q3 FISHERIES

Knowledge and Management of Aquatic Ecosystems Pub Date : 2020-01-01 DOI:10.1051/kmae/2020010

M. Larinier, Lionel Dumond, T. Lagarrigue, Aurélien Frey, F. Travade

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引用次数: 7

摘要

2010年至2016年，在法国西南部的多多涅河(Dordogne River)上的tuiliires发电厂，对与三条地表旁路相关的部分深度导流墙的性能进行了评估，以确保大西洋鲑鱼幼鱼的安全下游迁移。在这项研究中，使用无线电遥测技术对603只小海豚进行了监测，目的是:(i)确定它们的逃逸率(通过涡轮机以外的路线)，(ii)分析它们面对结构的行为，(iii)评估导流壁的渗透率作为涡轮机和溢出流的函数。通过地面旁通路线的擒纵率从大约15%到85%不等。涡轮流动是影响导壁面效率的主要因素。二次旁通对低流量的贡献虽然显著，但随着涡轮流量的增加而迅速下降。绝大多数鱼到达了壁的两个下游海湾或直接到达主旁路区域，随着涡轮流量的增加，导壁的引导作用变得不那么明显。2014年对导流壁深度的修改略微提高了其效率(5-10%)，用于低涡轮流量。采用Logistic回归模型描述了设施效率随涡轮流量的变化规律，以及通道下直接通过的概率随通道下平均流速的变化规律。

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Performance of a large partial-depth guide wall to divert downstream migrating Atlantic salmon smolts at Tuilières dam, Dordogne River

From 2010 to 2016, an evaluation of the performance of a partial-depth guide wall associated with three surface bypasses to ensure the safe downstream migration of Atlantic salmon smolts was conducted at the Tuilières power plant on the Dordogne River in southwestern France. The objectives of this study, during which 603 smolts were monitored using radio telemetry, were (i) to determine their escapement rate (passage through routes other than turbines), (ii) to analyse their behaviour faced with the structure and (iii) to assess the permeability of the guide wall as a function of turbine and spilling flows. The rate of escapement through the surface bypass routes varied from approximately 15% to 85%. The turbine flow was the main factor influencing the guide wall efficiency. The contribution of secondary bypasses, while significant for low flows, decreased rapidly with the increase in turbine flows. The vast majority of fish arrived on the two downstream bays of the wall or directly in the area of the main bypass, with the guiding effect of the guide wall becoming less noticeable with the increase of turbine flow. A modification of the depth of the guide wall in 2014 slightly improved its efficiency (by 5–10%) for low turbine flows. Logistic regression models were used to describe the evolution of the efficiency of the facilty as a function of the turbine flow and the probability of direct passage under a bay as a function of average velocity under this bay.

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来源期刊

Knowledge and Management of Aquatic Ecosystems 环境科学-海洋与淡水生物学

CiteScore

3.70

自引率

5.60%

发文量

审稿时长

>12 weeks

期刊介绍： Knowledge and Management of Aquatic Ecosystems (KMAE-Bulletin Français de la Pêche et de la Pisciculture since 1928) serves as a foundation for scientific advice across the broad spectrum of management and conservation issues related to freshwater ecosystems. The journal publishes articles, short communications, reviews, comments and replies that contribute to a scientific understanding of freshwater ecosystems and the impact of human activities upon these systems. Its scope includes economic, social, and public administration studies, in so far as they are directly concerned with the management of freshwater ecosystems (e.g. European Water Framework Directive, USA Clean Water Act, Canadian Water Quality Guidelines, …) and prove of general interest to freshwater specialists. Papers on insular freshwater ecosystems and on transitional waters are welcome. KMAE is not a preferred journal for taxonomical, physiological, biological, toxicological studies, unless a clear link to ecological aspects can be established. Articles with a very descriptive content can be accepted if they are part of a broader ecological context.