长江流域资源与环境 >> 2015, Vol. 24 >> Issue (04): 653-.doi: 10.11870/cjlyzyyhj201504017

• 生态环境 • 上一篇    下一篇

汛前供水期神农溪库湾倒灌异重流特性及其对营养盐分布的影响

吕垚1,刘德富1,2,3*,黄钰铃1,4,杨正健2,纪道斌1,崔玉洁1,3   

  1. 1.三峡大学水利与环境学院,湖北 宜昌 443002;2.湖北工业大学资源与环境学院,湖北 武汉 430068;3.武汉大学水利水电学院,湖北 武汉 430072;4.中国水利水电科学研究院水环境研究所,北京 100038
  • 出版日期:2015-04-20

IMPACTS OF REVERSE DENSITY FLOW ON NUTRIENT DISTRIBUTION IN SHENNONG BAY DURING PREFLOOD WATER SUPPLY PERIOD

LV Yao1, LIU Defu1,2,3, HUANG Yuling1,4, YANG Zhengjian2, JI Daobin1, CUI Yujie1,3   

  1. 1. College of Hydraulic & Environmental Engineering, China Three Gorges University, Yichang 443002, China; 2. College of Resources and Environment, Hubei University of Technology, Wuhan 430072, China;
    3. School of Water Resources & Hydropower Engineering, Wuhan University, Wuhan 430072, China;
    4. Department of Water Environment, China Institute of Water Resources and Hydropower Research, Beijing 100038, China
  • Online:2015-04-20

摘要:

为研究三峡水库神农溪库湾水动力特性及其对营养盐分布的影响,于2013年汛前供水期对神农溪库湾水文、水质及水生态进行空间定点监测与分析。结果表明:2013年汛前供水期三峡水库干流水体依次以底层、中上层和表层倒灌异重流形式潜入神农溪库湾。受干流倒灌异重流影响,库湾营养盐自下游向上游逐渐降低,干流水体对库湾营养盐具有明显补给作用。水位变化过程会影响倒灌异重流的模式和范围,可通过水库调度来解决支流库湾水华和富营养化问题。

Abstract:

Recently, reverse density flow was found in many tributary bays of Three Gorges Reservoir (TGR), such as Xiangxi River and Daning River. Nutrients of high concentration carried by intruding water from TGR are likely to be the main nutrient source of these tributary bays. Due to the multifaceted importance of water quality in the Shennong Bay (SNB), the eutrophication in SNB increasingly draws extensive attention of local government. In addition, the water ecenvironment change of SNB are strongly affected by the regulation of TGR. Therefore, continuous monitoring has been carried out in SNB to study the hydrodynamics and their impacts on nutrient distribution during preflood water supply period. Results of the hydrology, water quality and aquatic ecology of SNB were presented in this paper. According to the water regime information of TGR during the period of monitoring, on the basis of the daily change extent and variation trend of water level, the preflood water supply period of TGR in 2013 can be divided into three stages. The first was February 3 to April 5, which lasted 62 days, the water level changed slowly from 170.07 m to 161.33 m with a total decrease of 8.74 m and by an average daily decline of 0.14 m. The second stage was April 6 to May 10, water level changed from 161.36 m to 160.21 m with an overall decline of 1.15 m. The third stage was May 11 to June 21, water level changed rapidly from 160.15 m to 145.06 m, creating a total decline of 15.09 m with an average daily decline of 0.36 m. It can be seen from the spatial and temporal distribution of flow rate in SNB that flow velocity ranged from -0.249 m/s to 0.246 m/s in the bay, and bidirectional flow phenomena persisted during the period of monitoring as the mainstream water of TGR was intruding into SNB in a form of reverse density flow from varied depths. It again provided a piece of evidence for the universal presence of reverse density flow in tributary bays of TGR. This special flow pattern in SNB provided a hydrodynamic basis for nutrient transport, and nutrient distribution of tributary bays was obviously affected by the mainstream of TGR. Affected by the intrusions from mainstream of TGR, nutrients decreased as the distance from estuary of SNB increased until the end of the bay, the mainstream water of Yangtze River supplied a large number of nutrients to SNB. Form and range of intrusions can be affected by water level management which was proven to have interplays between the algal blooms. At the same time, sustained and steady change of the water level can make a specific type of intrusion so that stable water stratification can form which was proved to be related to algal blooms in tributary bays of TGR. Therefore, algal blooms and eutrophication in tributary bays of TGR can be resolved through reservoir operation.

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