A CFD model to assess lower Granite Dam operations under stratified conditions

IF 1.4 Q4 WATER RESOURCES

Journal of Applied Water Engineering and Research Pub Date : 2020-10-01 DOI:10.1080/23249676.2020.1831973

M. Politano, R. Laughery

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引用次数: 1

Abstract

Elevated water temperature has deleterious effects on cold-water fish. Lower Granite (LWG) is a run-of-the river dam in the Pacific Northwest, USA. LWG impounds a reservoir, with capacity of 5.7×108 m3, that often become stratified. This paper presents a numerical model to assess LWG selective withdrawal operations to minimize thermal effects on fish. The model accounts for buoyancy forces, which are dominant at low river flowrates. The thermal model was validated against forebay temperature profiles and tailrace temperature on 3 July 2015. Twenty-six simulations were performed under different dam operations, stratification intensities and river flowrates. Numerical results indicate that the thermal stratification has a strong effect on the withdrawal region. Under stratified conditions, a high velocity layer at the intake elevation impacts the hydrodynamics and thermal capacity of the reservoir. According to the simulations, flow uniformly distributed across odd numbered powerhouse units is the best configuration to reduce downstream temperature.

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在分层条件下评估花岗岩坝下游运行的CFD模型

水温升高对冷水鱼有有害影响。下花岗岩(LWG)是一个奔流河大坝在太平洋西北，美国。LWG蓄水池的容量为5.7×108 m3，通常形成分层。本文提出了一个数值模型来评估LWG选择性退出操作，以尽量减少对鱼的热效应。该模型考虑了浮力，这在低河水流量时起主导作用。2015年7月3日，根据前湾温度曲线和尾流温度对热模型进行了验证。在不同的大坝运行方式、分层强度和河流流速下进行了26次模拟。数值结果表明，热分层对回撤区有很强的影响。在分层条件下，进水口高程处的高速层会影响水库的水动力和热容量。模拟结果表明，奇数机组间流量均匀分布是降低下游温度的最佳配置。

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来源期刊

Journal of Applied Water Engineering and Research WATER RESOURCES-

CiteScore

2.90

自引率

16.70%

发文量

期刊介绍： JAWER’s paradigm-changing (online only) articles provide directly applicable solutions to water engineering problems within the whole hydrosphere (rivers, lakes groundwater, estuaries, coastal and marine waters) covering areas such as: integrated water resources management and catchment hydraulics hydraulic machinery and structures hydraulics applied to water supply, treatment and drainage systems (including outfalls) water quality, security and governance in an engineering context environmental monitoring maritime hydraulics ecohydraulics flood risk modelling and management water related hazards desalination and re-use.