The bio-hill chart of a Kaplan turbine

IF 4.6 Q2 ENVIRONMENTAL SCIENCES
P. Romero-Gomez, M. Lång, S. Weissenberger
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引用次数: 0

Abstract

Abstract The construction, rehabilitation and re-licensing of hydropower stations must nowadays fulfill strict demands for fish protection, particularly those related to enhanced turbine passage survival rates of downstream migratory species. In an analogy to the efficiency curves of a water turbine represented on a hill chart, the bio-hill chart introduced herein depicts the relationships between the operating conditions (i.e., discharge and head) and the potential survival rate of migratory fish passing through the turbine. The bio-hill chart applies over the entire operating range of the machine, which is a step forward with respect to previous works that determined hydraulic-biological evaluations for only a few operating points. The elaboration of a bio-hill chart involves two steps: (i) the calculation of turbine flows for each operating point and (ii) the corresponding evaluation of fish friendliness. The flow conditions are determined via computational fluid dynamics simulations. The calculation of fish friendliness relies on modelling approaches to determine mortality risks associated with collision on rotating blades and rapid decompression. We thoroughly describe the process to elaborate the bio-hill chart for juvenile salmonid species, as well as its implementation in a Kaplan turbine. The bio-hill chart represents a first approximation for determining those operating conditions that may mitigate fish mortality risks (i.e., maximize fish friendliness) and for quantitatively establishing the inevitable trade-off that exists between the hydraulic and environmental demands of hydropower generation.
卡普兰涡轮的生物山图
目前,水电站的建设、修复和重新许可必须满足对鱼类保护的严格要求,特别是对提高下游洄游物种的水轮机通道存活率的要求。本文介绍的生物山图,与水轮机效率曲线用山图表示类似,描述了运行工况(即流量和水头)与通过水轮机的洄游鱼类潜在存活率之间的关系。生物山图适用于机器的整个工作范围,这是一个进步,相对于以前的工作,确定水力-生物评价仅为几个工作点。生物山图的制作包括两个步骤:(i)计算每个工作点的涡轮流量和(ii)相应的鱼类友好性评估。通过计算流体动力学模拟确定了流动条件。鱼类友好度的计算依赖于建模方法,以确定与旋转叶片碰撞和快速减压相关的死亡风险。我们详尽地描述了制作幼鲑鱼物种的生物丘图的过程,以及它在卡普兰涡轮中的实施。生物山图代表了确定那些可能减轻鱼类死亡风险的操作条件(即最大限度地提高鱼类友好度)和定量地确定水力发电的水力和环境需求之间不可避免的权衡的第一个近似。
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
CiteScore
7.10
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