Application of River Network Hydrodynamic Model in Determining Water Distribution Scale of Haishu Plain

The water distribution network is an important part of the plain water environment improvement system. To make efficient use of the regional water diversion source, scientifically distribute the water diversion flow and improve the water environment carrying capacity of Haishu Plain, the river network hydrodynamic model is used in this paper to simulate the water intake location, reasonable water quantity and influence range of water transfer in Haishu Plain. The simulation results have high accuracy, which can provide a scientific basis for the scale, water transfer mechanism and project layout of water transfer construction in Haishu Plain and show a strong reference value for the study of water diversion and distribution scheme of coastal plain river network.

Water level updating model for flow calculation of river networks

Complex water movement and insufficient observation stations are the unfavorable factors in improving the accuracy of flow calculation of river networks. A water level updating model for river networks was set up based on a three-step method at key nodes, and model correction values were collected from gauge stations. To improve the accuracy of water level and discharge forecasts for the entire network, the discrete coefficients of the Saint-Venant equations for river sections were regarded as the media carrying the correction values from observation locations to other cross-sections of the river network system. To examine the applicability, the updating model was applied to flow calculation of an ideal river network and the Chengtong section of the Yangtze River. Comparison of the forecast results with the observed data demonstrates that this updating model can improve the forecast accuracy in both ideal and real river networks.

平原河网水动力优化调度与水环境改善的响应关系研究

平原河网河道流动性较差是引起水环境污染严重的主要原因,引调水是改善平原河网地区水环境的重要措施之一。本文以佛山市三山围为例,基于实测资料构建了河网水动力水质耦合模型,采用15天的连续水动力水质监测数据对模型进行了验证,并将NSE和RMSE模型评价指标用于模型评价。同时结合地势、潮汐规律和景观水位等设计了4种闸控模式和7种景观控制水位,共28种模拟工况,模拟分析了不同条件下的水动力水质改善与内外江潮位变化、引排水流量及其空间分布、闸控方式和景观水位等综合响应机理。结果表明:构建的模型合理可靠。研究区域受引排水路径的影响,河道流动性差异较为显著。综合考虑河道流量分布、水流路径、分汊河道分流作用和外江污染物浓度等对河道水质的作用效果并有效结合潮汐河网的动态水环境容量和污染源排放的时空分布对水环境的改善作用将非常显著。与低景观控制水位相比,高景观控制水位的内江动态水环境容量相对较大,污染物浓度较低。景观控制水位从0.2 m上升至0.8 m时,不同引调水路径的引水流量上升28.00%~64.70%,断面氨氮浓度削减了0.85~5.50 mg/L,削减比例达到28.89%~67.23%。本研究为平原潮汐河网水环境优化调度研究提供了新的思路,为相关部门对平原河网的水环境改善提供了重要的参考。

考虑水动力条件及水系连通的平原河网圩区畅流活水方案

针对平原河网地区水动力条件不足等问题,以嘉兴市新塍镇为例,探究不同畅流活水方案对河道水质的改善效果。构建MIKE11水动力学水质耦合模型,分析“引水/水系连通—水质”驱动响应规律,以NH3-N浓度为主要指标,分析不同活水方案的水质改善效果,并提出优化调控方案。结果表明,集中引水对区域水质改善影响较小,分散设置多个引水点可明显提高水质;直接对水质较差河道进行补水,污染物消减率在8%~30%之间,水质改善效果较明显;合理的水系连通工程可进一步增加畅流活水方案水质改善效果。

河网地区洪水预报模型开发及在长江下游地区的应用

平原水网地区的洪水预报一直是水文学科的难点问题,尤其受人类活动影响剧烈。为了更好地模拟流域水文循环过程,解决工程实际应用中的挑战,提出了一种新颖的分布式架构水文模型。该模型具有分布式特征,能够根据流域特征和需求灵活选择最合适的水文特征单元进行组合,从而支持对不同水文特征单元精确化、理论化的研究。为了实现实时预报功能,还研发了数据库耦合技术、大型河网实时校正技术及水利工程调度技术。在此基础上,应用分布式架构思想建立了太湖流域模型,对其进行了概化处理,并选取2016年实况数据对模型参数进行了率定。通过对太湖水位1 d、2 d、3 d预见期的实时预报,计算成果基本能够反映平原水网地区太湖流域的水流运动实际状况。综合而言,该分布式架构水文模型方法不仅在科学性上得到验证,而且在实现技术上具有可行性,成功地解决了从理念到现实的应用实践问题,为平原水网地区洪水预报提供了新的思路和方法。

滨湖城市防洪智能调度与“四预”业务系统开发--以江苏无锡市运东大包围为例

信息化技术的革新为水利行业发展提供了重要的机遇,但受限于历史实测资料不足,人工智能算法在滨湖平原河网地区洪涝预报中的应用存在一定困难。以江苏无锡市运东大包围为研究区域,详细阐述了城市洪涝智能预报调度的实现路径,利用水文水动力模型生成调度预案集,分别采用长短期记忆网络模型与卷积网络模型构建城市河网关注点水位智能预报方法与城市内涝风险阈值快速计算方法;以服务“四预”(预报、预警、预演、预案)业务为导向设计防洪智能预报调度系统,开发系统功能,集成专业模型与智能模型服务于业务场景应用,以实践探索为太湖滨湖城市洪涝预报调度一体化、智能化、业务化提供参考。

滨海平原区可能最大洪水计算研究

平原河网区受城市区域空间交错、河湖蓄滞洪区联通、水利工程密布等因素的影响,瞬时单位线、经验公式等传统方法推及可能最大洪水(PMF)存在很大的局限性。为弥补传统方法在平原河网地区的适用性问题,尝试使用水动力洪水演进模型法,并综合考虑水库溃坝、可能最大降雨(PMP)、海洋风暴潮等不同叠加因素的影响,选取典型区域(江苏省连云港市西陬山地区某厂址附近区域)研究多种组合条件下平原河网区域的洪水演进过程,及在特定区域内产生的可能最大洪水,以期为平原河网地区可能最大洪水位的推求及工程设计提供参考。

基于数学模型的感潮河网水环境改善方案研究——以上海市金山区浦南东片为例

平原感潮河网地区水环境改善方案制定是一个多目标、多变量的优化问题,以上海市金山区浦南东片为例,通过建立水动力数学模型,研究不同工程方案和调度方案组合下,区域中小河道水动力条件和水环境质量的改善效果。研究表明,通过增加南排杭州湾口门等工程方案,可扩大研究区域的引排水量,对南部、东部片区河道水动力条件改善效果明显;通过灵活运用水资源调度方案,可进一步实现不同片区中小河道水动力的显著提升。

基于断面水质达标的污水处理厂尾水排放浓度确认研究

我国在建设项目准入中实行“三线一单”生态环境分区管控制度,“环境质量底线”是其重要要素之一。研究以苏中水网地区某工业污水处理厂为例,遵循地表水环境质量底线要求,在满足控制断面(排污口下游2 km)主要水质污染因子浓度达标并预留安全余量的要求下,通过构建一维河网水动力水质耦合模型,建立污染源与水质响应关系,模拟分析丰、枯水期控制断面水质稳定达标时污水处理厂尾水的允许排放浓度,为区域水环境保护和管理工作提供技术支撑。

基于MIKE11的粤港澳大湾区河涌生态补水调度方案评估

为解决粤港澳大湾区跨境河涌鸭涌河生态补水工程与河口水闸联合调度的问题,考虑到外海潮位顶托作用显著,构建了MIKE 11一维河网水动力水质数学模型,并设计不同类型的调度方案,包括天然状态方案、现状调度方案、联合调度方案,评估各方案降低污染物浓度和改善水质的效果。结果表明:在日常补水调度中,若河口水闸调度不与生态补水调度结合,鸭涌河水体更新效率偏低,若河口水闸与生态补水联合调度,在枯水期月份前5 d每天补水2 h的水质改善效果较好,电费较低,综合评价指数最优;而在汛期防洪排涝调度中,不需要进行生态补水调度。此外,水量分析结果表明,不同补水方案的综合评价指数与典型断面的进出水量、进出水量比值的响应规律相反。评估结果可为鸭涌河的水环境质量提升方案提供科学依据。

基于MIKE21模型分析综合治理工程对河道水文情势的影响——以福建金溪工程为例

在流域开展综合治理工程规划建设前,为保护水生态和水环境,需要研究综合治理工程对河道水文情势的影响。本研究利用二维水动力学模型MIKE21,以福建金溪建宁河段为研究案例,模拟研究综合治理工程对该河段水文情势的影响,结果发现河段水位增长幅度在0.1~0.3m之间,流速降低幅度在0.4~0.8m/s之间。该研究可为小流域综合治理工程水生态、水环境影响分析评估提供技术思路与方法,支撑流域和区域经济社会高质量发展。

汉北河流域强人类活动影响下的暴雨洪水模拟方法

为了研究人类活动影响下丘陵到平原区流域洪水模拟的关键问题,包括流域内降雨空间分布不均、丘陵平原产汇流差异大、下垫面受水利工程建设和调度影响等复杂边界条件,并提出相应的解决办法和模型,以汉北河为例,将大流域划分为11个单元,通过分析场次暴雨在各单元的空间分布解决降雨空间不均的问题;各单元根据各自下垫面条件进行API水文模型参数的率定,解决了丘陵平原产汇流差异大的问题,提高了模型参数与实际情况的贴合度。在模型中,将河流改道、水库、蓄滞洪区、水闸、泵站建设和调度、土地利用等人类活动对汇流的影响纳入物理模型和产汇流模拟中,以便构建符合实际调度的下垫面产汇流体系。模拟计算的洪峰的纳什系数NSE均在0.85以上,模拟结果表明洪峰流量、水位及峰现时间与实测值吻合良好。

浦阳江流域感潮河段洪水预报研究

浦阳江流域中上游属感潮河段,易受下游洪水顶托影响,导致预报站水位流量关系不稳定,给洪水预报作业带来难度。以诸暨站以上流域范围为研究对象,选用1990—2021年间具有代表性的20场洪水,建立三水源新安江模型,对诸暨站流量进行预报;基于BP神经网络优良的非线性映射能力,建立以湄池水位、时段降雨量、安华水库下泄流量、诸暨站预报流量等为输入因子的诸暨站水位预报模型,以探究该模型在诸暨洪峰水位预报中的适用性。结果证明2019—2021年的场次洪峰水位预报效果较优,场次水位相对误差均保持在2.5%以内。

宁波陆埠镇平原河网水系结构对水动力影响研究

平原河网的水动力条件对维持区域生态平衡和生物多样性具有关键作用,而水系结构直接关系到河网的连通性和流动性。以宁波陆埠镇河网为例,在概括水系结构现状的基础上,基于浅水方程组理论,构建二维河网水动力模型,通过实测数据对模型进行验证。通过水系连通方式构造3种河网结构,模拟分析2种流动条件下,河网中水体流动的规律。结果表明:洋溪河在流入和流出条件下,流速最小值分别增至0.102 m·s^(-1)和0.154 m·s^(-1),白鹤桥横河、孙家横河、沿西河和周家湾浦的流速也有不同程度的增加,仓前河部分河段出现水体几乎不流动现象,说明水系连通对改善河网水动力有积极的作用,如果水系过度连通,在水流交汇的局部区域就可能出现水体滞留现象。因此,在实施水系连通工程前应该做好评估工作。

基于水文-水动力-水质模型的区域水环境治理改善措施评估——以南方某市区域流域为例

为进一步优化城市水环境治理方案,利用模型模拟的方法研究评估分析区域黑臭水体整治策略与实施方案的效果。基于研究区域内监测与河网等基础数据,采用水文、水动力及水质模型模拟区域内的水文过程、水力调度及污染物迁移转化等过程,研究不同环境整治方案的水质改善评估方法与技术。结果表明,采用控源截污方案对污染削减有更显著的效果,在进一步结合水闸调度、内外江泵站活水等工程措施,整体水环境质量能达到预期的控制目标。通过水力水质模型模拟分析,掌握不同工程方案下研究区域的水质改善效果,可为工程治理提供定量的评价数据和科学依据。

上海市沿海地区排水口门工程规模论证

为科学开展沿海地区多约束条件下排水口门工程规模论证,以浦东新区北横河及其配套泵闸工程为例,基于平原地区数字河网水动力模型,以水闸最大过闸流量作为关键分析指标,评估排水效益变化趋势。基于固定河道断面和排涝泵站规模,分析24 h总排水量、代表断面流速等,综合考量社会经济发展需求,结合选址用地条件、对河势和外侧航道的影响以及泵闸工程设计,对不同规模的设计方案进行比选。结果表明:外延伸段河道河口宽150 m、闸净宽72 m、泵站流量80 m3/s为最优河闸泵规模方案。该方案兼顾沿海地理特性、自然环境条件和社会经济需求,可为今后类似工程设计提供参考。

DEVELOPMENT AND APPLICATION OF A EUTROPHICATION WATER QUALITY MODEL FOR RIVER NETWORKS

The Preissmann implicit scheme was used to discretize the one-dimensional Saint-Venant equations, the river-junction-fiver method was applied to resolve the hydrodynamic and water quality model for river networks, and the key issues on the model were expatiated particularly in this article. This water quality module was designed to compute time dependent concentrations of a series of constituents, which are primarily governed by the processes of advection, dispersion and chemical reactions. Based on the theory of Water Quality Analysis Simulation Program （WASP） water quality model, emphasis was given to the simulation of the biogeochemical transformations that determine the fate of nutrients, in particular, the simulation of the aquatic cycles of nitrogen and phosphorus compounds. This model also includes procedures for the determination of growth and death of phytoplankton. This hydrodynamic and water quality model was applied to calculate two river networks. As illustrated by the numerical examples, the calculated water level and discharge agree with the measured data and the simulated trends and magnitudes of water quality constituents are generally in good agreement with field observations. It is concluded that the presented model is useful in the pollutant control and in the determination of pollutant-related problems for river networks.

Sediment transport following water transfer from Yangtze River to Taihu Basin

To meet the increasing ：need of fresh water and to improve the water quality of Taihu Lake, water transfer from the Yangtze River was initiated in 2002. This study was performed to investigate the sediment distribution along the river course following water transfer. A rainfall-runoff model was first built to calculate the runoff of the Taihu Basin in 2003. Then, the flow patterns of river networks were simulated using a one-dimensional river network hydrodynamic model. Based on the boundary conditions of the flow in tributaries of the Wangyu River and the water level in Taihu Lake, a one-dimensional hydrodynamic and sediment transport numerical model of the Wangyu River was built to analyze the influences of the inflow rate of the water transfer and the suspended sediment concentration （SSC） of inflow on the sediment transport. The results show that the water transfer inflow rate and SSC of inflow have significant effects on the sediment distribution. The higher the inflow rate or SSC of inflow is, the higher the SSC value is at certain cross-sections along the ：river course of water transfer. Higher inflow rate and SSC of inflow contribute to higher sediment deposition per kilometer and sediment thickness. It is also concluded that a sharp decrease of the inflow velocity at the entrance of the Wangyu River on the river course of water transfer induces intense sedimentation at the cross-section near the Changshu hydro-junction. With an increasing distance from the Changshu hydro-junction, the sediment deposition and sedimentation thickness decrease gradually along the river course.

IMPACT OF FUTURE SEA LEVEL RISE ON FLOOD AND WATER LOGGING DISASTERS IN LIXIAHE REGION

Lixiahe region is one of the susceptible area to flood and waterlogging disasters in China due to its low topographic relief and having difficulty in draining floodwater away.The condition will be more serious if sea level rises in the future.The estimated results by some scientists indicate that the sea level could rise probably 20-100 cm by 2050.However,what the effect will future sea level rise exerts on flood drainage and on flood or waterlogging disasters? A hydrological system model has been developed to study the problem in the lower reaches of the Sheyang River basin.Predicted results from the model show that,if sea level rises,drainage capacity of each drainage river will decrease obviously,and the water level will also rise.From the change of drainage capacity of drainage rivers the trends of flood and waterlogging disasters are analyzed in the paper if the severe flood that happened in the past meets with future sea level rise.Some countermeasures for disaster reduction and prevention against sea-level rise are put forward.

汉江上游气象-水文干旱特征变量响应概率研究

为揭示汉江上游气象水文干旱特征变量响应关系,分别选用标准化降水指数、标准化径流指数表征气象干旱和水文干旱,采用线性、非线性函数模型构建气象水文干旱特征变量响应模型,进而构建了基于Copula函数耦合贝叶斯网络概率模型的气象水文干旱特征变量响应概率曲线。结果表明:气象水文干旱历时和烈度的最优响应模型分别为线性函数模型和基于Gumbel Copula函数的非线性模型;干旱历时和烈度的最优联合分布函数分别为Frank Copula函数和Gumbel Copula函数;水文干旱历时、烈度的响应概率随对应的气象干旱特征变量的增加而增加,水文干旱历时响应概率变化速率逐渐减小,最后趋于平缓,水文干旱烈度响应概率变化速率较小。