小龙潭水库坝址尾水水位流量关系分析

小龙潭水库坝址的尾水受小龙潭下游伏流的影响,伏流消水洞的排泄能力较差,洪水常形成壅水,不能按常规曼宁公式进行计算坝址尾水的水位与流量关系,根据伏流消水洞的泄流能力按"水库调洪"方法计算绘制小龙潭水库坝址建库后水位流量曲线,确定坝址尾水水位流量关系。结果表明:下游伏流消水洞泄量较小,水库施工期间可能受下河石渣影响。因此,施工过程中要密切注意施工弃渣和弃石,并即时对其进行清理,避免堵塞下游河道。并且下阶段应设立水位、流量监测站,积累资料,即时复核水位流量关系。     

紫坪铺坝下游过饱和溶解气体原型观测研究

在总结国内外关于水电站大坝下游总溶解气体(TDG)过饱和问题的研究现状的基础上,对紫坪铺坝下游河段的过饱和气体进行了原型观测,指出下泄流量与下游TDG饱和度有着较好的相关关系;河道水深是影响过饱和气体消减速率的重要因素;在同样单宽流量下,含沙水体比清水有更高的TDG饱和度。这一研究为更深入的开展高坝下游过饱和溶解气体的产生及消减过程理论研究提供了依据,对高坝下游水生生物保护具有重要作用。     

波浪扰动对太湖底泥磷释放影响模拟

为揭示波浪扰动对湖泊底泥磷释放的影响,在波浪水槽中模拟了不同波高情况下扰动对水体、水土界面、底泥间隙水的磷、溶解氧等的影响.结果显示,在大波扰动下,沉积物大量悬浮,水体总磷随之增加,溶解性磷增加却不显著;波浪扰动显著增加了水体和沉积物界面的溶解氧浓度,并增加了溶解氧在沉积物的侵蚀深度;波浪扰动降低了沉积物表层10 cm内间隙水中的磷浓度,而10 cm以下沉积物中间隙水中磷浓度基本保持不变.研究表明,波浪扰动可迅速增加水体中颗粒态的营养盐,但是对于溶解态营养盐,尤其是水体中活性磷浓度的影响,则受沉积物性质、水-沉积物间隙水磷浓度差,以及水-沉积物中氧含量等多方面因素的影响.     

西津水电站设计水位流量关系曲线的探讨

一、前言在廿年前西津水电站设计时,曾遇到两个水文计算上的问题:第一个问题,西津是低水头河床式电站,厂房设计水位由下游天然水位流量关系曲线控制,但西津历年的水位流量关系曲线均不相同,在设计流量情况下,查上包线和下包线水位相差2     

根據相应流量預报徑流的方法

很久以前就已經在实际工作中,应用了相应水位(流量)的方法。这种方法也随着河流上水文测站網的增长,獲得了特别的發展(1)在这种方法中最容易看出洪水时期水体沿河流移动的規律性的反映,成为这种方法基礎的就是下游断面处的流量和分布在河道徑流匯集的同一等时綫上的上游各断面处流量总数的关系。例如:对于     

洞庭湖中枯水期水情变化及其驱动因素

为揭示洞庭湖中枯水期水情变化特征及其驱动因素,采用长短期记忆神经网络模拟洞庭湖出湖流量及湖区水位,通过情境模拟开展水情变化归因分析。洞庭湖1992—2019年9—10月出湖流量大幅减少,主要受长江流量降低的影响。洞庭湖中枯水期水位主要呈下降趋势,其中9—10月平均水位在西洞庭湖、南洞庭湖降幅约1 m,在东洞庭湖降幅约2 m。地形变化对中枯水期水位主要起拉低作用,长江和流域四水流量变化在9—10月起拉低作用、在12月至次年3月起抬升作用,其中对东洞庭湖水位的影响相对更为显著。研究结果可为洞庭湖中枯水期水资源管理和湿地保护提供参考。     

受多因素影响的水位流量关系单值化整编方法

对受洪水涨落率影响、下游支(干)流洪水顶托影响及人工水利工程影响的水位流量关系，提出了用计算机综合处理的校正因数一落差指数拟合法，较好地解决了水位流量关系单值化的问题，满足现行的《水文资料整编规范》要求，具有一定的推广价值。     

冰塞水位分析

高纬度地区河流冬季常形成冰塞,冰塞堵塞过流断面,使湿周增加,致上游水位升高,常因此产生凌洪灾害,冰塞的解体、溃决又常使下游产生灾害。冰期水位是冰塞演变和发展的重要结果之一,对于防灾减灾具有重要的参考价值。依据实验室资料和黄河河曲段的实测资料,针对直道和弯槽,对比分析了不同冰流量、不同初始水深和流速时模拟冰塞和天然河道冰期水位的变化规律。     

水气混合洞塞泄流溶解氧输移扩散的数值计算

为研究水气二相混合洞塞泄流欠饱和溶解氧输移扩散行为特性,揭示气体体积分数、进口溶解氧浓度、雷诺数等流动特征参数和洞塞尺寸等几何参数对溶解氧浓度恢复的影响规律,开展了水气二相混合洞塞泄流溶解氧输移扩散的室内模型试验,观测流速、压力和溶解氧浓度分布。建立了水气二相混合洞塞泄流溶解氧输移扩散数学模型,并利用物理模型试验数据对数学模型进行了验证。利用验证后的数学模型,分别计算不同进口气体体积分数、溶解氧浓度、雷诺数、洞塞长度和洞塞直径条件下水气二相混合洞塞泄流溶解氧浓度恢复情况。结果发现:气体体积分数越大,进口溶解氧浓度与饱和溶解氧浓度差值越大,雷诺数越小,溶解氧浓度增量越大;洞塞长度越长,洞塞直径越小,溶解氧浓度增量越大。     

神府矿区马家梁村地下水位下降原因分析

分析神府矿区马家梁村一带煤矿开采对地下水径流及水位的影响,认为杨伙盘煤矿开采对该村西部地下水量的增减影响甚微。老张沟煤矿开采造成区内地表径流量减少,地下水位下降。孙营岔一矿开采后对地下水有影响。煤层开采是影响井水、沟流减少不可忽视的因素。爆破采煤将导致原生裂隙、裂纹数量的增加,致部分裂隙穿透上部隔水层,从而造成地下水漏失,水位下降,泉流量减少。     

精细地形下的尾矿坝稳定性及溃坝模拟分析

目前在尾矿坝稳定性和溃坝模拟分析方面,对溃口位置及水砂的流动状态难以做出准确判断。将尾矿坝稳定性和溃坝模拟有机结合,采用FLAC3D计算正常水位、洪水位、漫顶水位三种工况下尾矿坝稳定性,并利用Rhino与Fluent建立尾矿库及下游精细地形,开展尾矿库溃坝水砂在不同时刻及不同地形下的流动状态研究分析。结果表明:（1）浸润线的埋深随尾矿库水位的升高而变小,由正常水位升高至洪水位时浸润线埋深下降5～8 m,漫顶水位时坝顶浸润线沿坡面向下运移约8 m;（2）库水位对剪切带及尾矿坝稳定性有显著影响,从正常水位到洪水位时,剪切带纵向上不断向坝体内部延伸,横向上不断向坝脚延伸,剪切应变率增大为5.78×10?5,尾矿坝稳定系数由1.80下降至1.32;（3）达到坝顶时剪切带急剧缩短,而剪切应变率进一步增大为3.32×10?4,尾矿坝稳定系数由1.32下降到1.18。溃坝水砂的流动状态受地形影响明显,在山谷中表现为范围减小、流速增大的汇聚流动,在平坦农田处表现为范围增大、流速减小的发散流动特点。     

Role of geological structures in seepage from Lar dam reservoir

The main objective of this paper is to estimate the water seepage from Lar dam reservoir based on a combination of the geological structure study results and identification of the flow conduits in the right bank of the reservoir. From the beginning of impounding the dam in 1980, heavy seepage was observed at two karstic springs, Haraz and Galugah, located about 9 km downstream of the dam. During the first impounding, the discharge of the Haraz spring abruptly increased from 0.5 m³/s to around 5 m³/s. The results of piezometers and dye tests indicate that seepage occurs mainly through the right abutment of the dam where there is a structural wedge between the north dipping North Tiz Kuh and the south dipping Lar Valley faults. F1, F2, and F3 faults are the most important faults in vicinity of the structural wedge. Based on the dye test results, the North Tiz Kuh and F3 faults along which caves No. 1 and 2 are formed are regarded as two isolated conduits for seepage and conveyance into Lar Valley Fault at downstream of Lar dam. After identifying the conduits, water seepage from the Lar dam reservoir has been calculated using finite element method. According to the results of numerical method, when the reservoir water level is at 2485 m a.s.l, the average of water seepage is around 8.51 m³/s (this amount of water is related to the seepage along the Lar Valley Fault). The average discharge of springs downstream of the dam has been used to verify the numerical method. The results show a very close relation between estimated and observed discharge.     

Measurement of seasonal variability of hydro-environmental characteristics of Kuwait Bay

To fill in the large existing data gap, this study presents results of a comprehensive data set from Kuwait Bay (KB), showing the horizontal and vertical distribution of its prominent hydrodynamic variables (i.e., water temperature, seawater salinity, seawater density) and water quality variables (i.e., chlorophyll-a concentration, turbidity, dissolved oxygen (DO) concentration, DO saturation, apparent oxygen utilization, photosynthetic active radiation). Field measurements were carried out between 11 September 2014 and 17 August 2015 covering number of monitoring stations in the entire bay. The results revealed significant seasonal variations and apparent three-dimensional features of the measured variables exemplifying the necessity of not considering the bay as a well-mixed water body in the future oceanographic studies anytime of the year. However, well-mixed conditions (with the Brunt-Vaisala frequency of about 0.0002 s^?1) were existent only in the winter. Bay’s water column began stratifying in late spring, and these were significantly intensified (with the Brunt-Vaisala frequency of about 0.0008 s^?1) during the summer and early autumn. The stratification, together with the increase oxygen demand for decomposition processes and decrease in DO solubility in summer, led to the formation of a lower DO water mass (daytime DO concentration <4.2 mg l^?1) at the lower layers. Results also suggested that the water of the KB is more transparent (indicated by lower turbidity) compared to the adjacent sea water. Measurement of light intensity along the water column indicated that the light extincts rapidly (i.e., the light reduced to approximately 10 % of the surface values at water depth of 2–6 m) in KB and many times absent at the water near the seabed. This study also suggested that the KB can be classified at a year-round negative, hypersaline, inverse, and hyperpycnal estuary.     

The study of the hydrogeological setting of the Chamshir Dam site with special emphasis on the cause of water salinity in the Zohreh River downstream from the Chamshir Dam (southwest of Iran)

Dissolution of evaporite formations, emergence of salty water springs, and intrusion of deep saline waters are important causes in changing the quality of surface water. The study area is part of the reservoir and downstream of Chamshir Dam, which is located in watershed of the Zohreh River 20?km southeast of Gachsaran City (southwest Iran). To construct powerhouse and related structures for supplying water to agricultural lands located in downstream of dam, water quality of Zohreh River was studied by eight sampling stations in the study area. Early studies showed that water quality of the Zohreh River decreases severely downstream of the Chamshir Dam. Spatial variations diagram of major ions, Piper and composition diagrams of water samples in selected stations mark the presence of two slight and major contaminating zones at sampling station R₄ and R₅. In these zones, concentration of Ca, SO₄ and Na, Cl ions increase suddenly. Results of hydrogeological, hydrochemical, lithological and tectonics studies showed that even though there are several low discharges springs in the contaminated zone they cannot be related to surface dissolution of evaporate layers by Zohreh River. There is an important fault zone including Chamshir faults I and II in the contamination zones through which intrusion of sulfate brackish and chloride brine waters occur along the fault zone and then enter Zohreh River below its base level. In the absence of any surface evidence, the fault zone is the main cause of salinity. Evaluation of water balance salinity in contaminated zones shows that the discharge rate of saline waters to the river is not low and cannot be separated. These findings show that there are serious restrictions upon the purposes of the project.     

周边采煤活动对岳城水库库区大坝和坝基的渗流影响研究

岳城水库属于国家重点水库,同时库区及周边地下是典型的富煤区域,蕴藏着大量优质煤炭资源。为研究周边采煤活动对岳城水库库区大坝和坝基的渗流影响,文中以坝体作为研究对象,在上游建立一条安全限,通过控制大坝和坝基的有效保护边界来控制开采对浅地表造成的影响深度和影响远度。通过数值模拟,结果表明在上游水位159.1 m和下游水位105.0 m的作用下,只要开采影响范围距离岳城水库大坝2 000 m,开采就不会对大坝和坝基的渗透性变化产生影响;同时,也不会对坝肩的渗透性产生影响。     

大通河流域水能水资源开发对河流水文过程和环境的影响

根据水文观测和引水与水电开发资料,分析了大通河流域水能水资源开发利用现状及其对河流水文过程与生态环境的影响.结果表明：由于区域用水和跨流域引水,使大通河中下游河道的水量减少,水环境容量减小,其中,青石嘴、天堂、连城(二)站3-11月平均流量分别减少0.6%~9.6%、0.5%~3.8%、1.7%~52.9%. 自1994年引大入秦工程建成跨流域引水后,连城(二)站年径流量开始减少,1994-2010年平均径流量比1977-1993年减少了5.7%;引大济湟工程建成通水后,加上引大入秦和引硫济金工程,引水总量将达到12.33×10⁸ m³,占大通河多年平均径流量28.16×10⁸ m³的43.8%,对河川径流的影响十分显著. 至2011年,大通河上已建成梯级电站34座,洪水期电站同时泄水会瞬间加大河道流量,枯水期蓄引水又使减水河段水量减少. 梯级水电站群无序蓄放水使洪水过程由天然的平稳状态转变为人工干预的剧烈变化状态,上下游洪峰不对应,对下游地区的防洪安全产生极大威胁. 过度的水能水资源开发,使大通河中下游部分自然河段出现淹没、断流,水生物和两岸的植物萎缩,水环境污染加重,对生态环境产生负面影响. 建议实行流域水资源统一管理,对梯级电站下泄水量统一调度,在减水河段预留必须的生态基流,确保河道内外生态用水;加强河道水位、流量、泥沙、水环境、水生物监测,为流域防汛、水资源管理、生态环境保护等提供决策依据.     

清水冲刷条件下长江中游沙卵石河段局部卵石淤积成因

为探究三峡水库持续下泄清水条件下长江中游沙卵过渡段内卵石局部冲刷、搬运和淤积现象的成因，采用近期水文、泥沙和地形观测资料，结合河道平面二维水动力模型，计算了研究河段内各级流量下的泥沙起动粒径分布，分析了上游来流、下游水位变化的影响，辨析了河床冲淤的成因。结果表明:① 45 000 m3/s以上流量时，粒径大于30 mm的卵石可沿洪水主流带连续搬运；流量低于15 000 m3/s时，大粒径卵石只能沿枯期主流在浅滩河段局部搬运；流量介于两者之间时，水流对大粒径卵石的输移动力相对较弱。②三峡建库后，洪水量级削减而枯水天数增多，不利于卵石长距离下移，而水位下降不断溯源传递，促使枯水流路上原本稳定的区域开始冲刷。③局部淤积现象由枯期水动力增强所导致，与长江中游沙卵过渡段特殊的地貌和沉积环境有关。卵石局部冲淤调整可能在河段内多个位置长期存在，需引起关注。     

三峡水库蓄水后长江中游水沙时空变化的定量评估

定量评价三峡蓄水后长江中游流域水文情势的时空变化,为长江中游生态保护和区域水资源管理提供科学依据。采用变化范围法分析了长江干流5个水文站的流量、含沙量日均数据,定量评估了三峡工程蓄水后,长江中游水沙变化度最大的江段和水文指标类别,及其对应的生态影响。研究结果表明三峡蓄水后,下游河道含沙量的变化度远大于流量,除城陵矶站外,含沙量较蓄水前有了大幅度下降,宜昌站的含沙量下降幅度达到了一个数量级,洞庭湖对长江干流含沙量有明显的调蓄作用。流量的变化度随着与大坝距离的增加而减小,且在7~11月流量下降幅度明显。这些水文节律的变化将影响下游鱼类产卵栖息地以及滞洪区水生生物与周边植被的生长。     

Effects of discharge of municipal waste on water quality of the lower Mississippi River

The effects of discharge of municipal wastes on water quality within the lower Mississippi River below Old River have been reevaluated using published water quality data in the Louisiana reach of the river for the water years 1974–1984. A novel graphical technique has facilitated the evaluation of upriver controls on water quality and the identification of sources and sinks along the lower Mississippi. Comparison of calculated annual fluxes at different downstream monitoring stations has simplified some of the problems inherent in evaluating analyses of samples collected from different water masses during a typical sampling run. The absolute concentrations of chloride, nitrite plus nitrate, total phosphorous, dissolved oxygen, BOD, and COD are all strongly dependent on processes occurring upriver. Nonpoint influx of materials from agricultural wastes and natural plant debris may be the dominant upstream sources of N, P, BOD, and COD. Increases in chloride and phosphorous downstream within the Lower Mississippi appear to be caused by discharge of industrial wastes. Nitrogen fluxes decrease downriver, except where there is local discharge of high-N, high-P industrial waste water, possibly from fertilizer plants. Removal of N and increases in BOD may be due in part to biological uptake. High river discharge rates and efficient, natural processes of reaeration maintain high oxygen saturation levels. With the exception of an increase in bacterial count, the discharge of municipal waste into the Mississippi River in Louisiana appears to have had no significant effect on water quality, a finding consistent with the earlier U.S. Geological Survey study of Wells (1980). It would be highly desirable for future mass balance studies if existing water quality programs on the Mississippi River were to adopt a Lagrangian sampling approach.     

Quantitative dam break analysis on a reservoir earth dam

Mathematical simulations on dam break or failure using BOSS DAMBRK hydrodynamic flood routing dam break model were carried out to determine the extent of flooding downstream, flood travel times, flood water velocities and impacts on downstream affected residences, properties and environmental sensitive areas due to floodwaters released by failure of the dam structure. Computer simulations for one of the worse case scenarios on dam failure using BOSS DAMBRK software accounted for dam failure, storage effects, floodplains, over bank flow and flood wave attenuation. The simulated results reviewed a maximum flow velocity of 2.40 m/s with a discharge of approximately 242 mз /s occurred at 1.00 km downstream. The maximum discharge increased from 244 m³/s (flow velocity = 1.74 m/s occurred at 8^th. km) to 263 m³/s (flow velocity = 1.37 m/s occurred at 12^th. km); about a 39% drop in flow velocity over a distance of 4.00 km downstream. If the entire dam gives way instantly, some spots stretching from 0.00 km (at dam site) to approximately 3.40 km downstream of the dam may be categorized as “danger zone”, while downstream hazard and economic loss beyond 3.40 km downstream can be classified as “low” or “minimal” zones.