水利经济系统运行评价指标的动力学模型

根据最优控制理论,建立了相应于工程动力系统中能量指标的水利经济系统运行效益的动力学评价模型,提出了水利经济系统的“弹性”、“质量”等模态特征量及“动能”、“势能”等系统特征量的表达形式,并应用于江苏水利经济系统的实证分析,计算结果反映了所建能量指标的合理性与可行性.     

三峡工程大江截流龙口与导流明渠水文水力学计算和检验

三峡工程大江截流是世界上截流流量最大,水深最大和抛投强度最大的截流工程。鉴于大江截流及二期围堰的重要性及技术复杂性,对上游围堰龙口,导流明渠进行了水文水力学分析计算,得到了各级坝址流量下明渠分流比,龙口落差,流速等水力要素成果,并进行了实时校验,结果表明计算值与原型观测较为一致。     

基于相关分析的雨量站选择及洪水预报方法

在分析历史降雨资料的基础上,建立流域内各雨量站点雨量与流域平均面雨量的相关关系。结合流域水文站分布图选出与流域面雨量相关性高且有区域代表性的雨量站作为遥测系统的关键测站,保证其稳定运行。利用定点定面关系分析方法,由流域内关键测站的时段雨量推求流域时段面雨量,并带入洪水预报模型进行洪水预报。该方法不依赖流域内全部测站的降雨信息,可有效解决流域内雨量站缺测或数据错误时的洪水预报问题。该方法可为无资料或资料短缺地区及新建水库因资金限制只能建设少量测站时的洪水预报提供参考。     

三峡工程大江截流水文泥沙监测规划

鉴于三峡工程大江截流是一项复杂的系统工程,具有水深大,流量大,抛投量大和截流期不断航等显著特点。水文泥沙监测作为其重要的组成部分,监测导流与截流过程中水流泥沙和水下地形的变化,为截流设计优化,调整施工方案与措施等提供科学的决策依据,同时也为导流明渠分流与通航,围堰度汛,截流水力学试验研究及水文预报,水文分析计算等提供水文原型观测资料。本文介绍了水文泥沙监测的目的、任务和水文数据采集,传输,处理与信     

会商室多媒体展示、会议扩声系统建设与思考

本文简述地震会商会议系统技术需求,提供日常震情会商、地震应急会商,并兼顾各种类型会议的场所与设施;着重阐述了现代化会商室技术系统组成、实现的功能以及系统建设过程及构建系统时应注意的问题,提出了相应的几点建议。结合笔者在福建省防震减灾大楼会商室建设及运行维护中取得的经验对如何更好地建设适合地震震情会商的会议室提出了几点思考。     

宽尾墩联合消能工体型选择及水力特性的研究

通过系统水力试验,给出了宽尾墩附加消能的消能机理与消能过程,以及附加阻力系数Δζ'及其计算式。对宽尾墩改善消力池内的水流结构,缩短水跃长度,减少尾水深度,提高消能率及改善跃后水流状态等进行了分析,并给出了相应计算式。通过对比试验,得出了宽尾墩体型选择参数。     

区域供水系统干旱历时特性综合分析

根据区域供水系统中供水水库(群)的蓄水状态及其运行调度策略在满足区域供水目标方面的重要作用,提出了以水库(群)的时段初始蓄水量与时段内来水量之和,以及时段内供水系统的目标需水量作为主要控制参数,以两者的差值正、负来表达供水系统处于非干旱状态和干旱状态的区域干旱鉴别方法。为了多角度地分析干旱和非干旱历时分布、转移概率以及干旱重现期等干旱历时特性以较全面地掌握区域干旱事件特征,针对一具体区域供水系统,运用模拟统计法和概率解析法两种技术手段来研究区域干旱历时特性,同时针对两种方法的计算结果差异,指出了各种方法的特征以及产生差异的原因。     

唐钢设计院网络系统及安全防护分析

唐钢设计院网络通过千兆交换机在主干网络上提供1 000M的独享带宽,通过中心交换机与各部室的工作站和服务器连结.为防范由单个计算机安全事故引起的系统瘫痪和损失,根据网络结构特点及可操作性原则,从划分网络区域着手,采取了加强网络登陆认证,合理配置防火墙、不同网络安全域的隔离及访问控制、MAC地址绑定等技术与措施,并制定相应管理制度,保障设计院网络安全运行.     

三峡工程大江截流导流明渠冲淤变化分析

根据大江截流期间监测,收集到的成果资料,对长江水全部改由导流明渠下泄、所观测到的大江围堰戗堤进占对导流明渠分流及流速流态的变化,河床冲淤及淤积量纵、横向分面进行了阐述,得到了该河段水流及冲淤变化的一般性规律。     

考虑回水顶托影响的水位预报研究

将有回水顶托影响的河段视为多输入-单输出系统,把水位过程视为时间序列,用时间序列分析最优控制理论,建立了可考虑回水顶托影响的水位过程预报模型。提出了在棱柱形河道情况下,以时段水位涨差作变量时,模型中各参数应满足的物理性约束条件;较好地解决了长江荆江河段中受回水顶托影响的石首站的水位过程预报问题,为水位过程预报提供了一条不同于水文学途径和水力学途径的建模途径。     

Sewer model development under minimum data requirements

Planning, design and operation of urban drainage systems is often based on hydraulic sewer modelling. Sewer models are also increasingly used to quantify pollution loads discharged to aquatic ecosystems (e.g. via combined sewer overflows), which ultimately allows an estimation of the ecological impact emanating from urban drainage systems. The establishment of such network models, however, requires detailed and accurate information about the sewer network structure and the connected surface area. This infrastructure data is often unavailable, confidential or available in ‘paper’ format only. The present paper outlines a novel approach to develop a hydraulic sewer model constrained by a minimum amount of data. The approach combines the application of a surface flow accumulation algorithm to a selectively manipulated Digital Elevation Model (DEM) with a routine for hydraulic network dimensioning to generate a close-to-reality sewer network ready to be implemented in a hydraulic modelling platform. The method is tested for three real-life catchments of which characteristics vary in scale, topography, state of development and network complexity. For all cases the generated network is implemented on the EPA-SWMM platform to allow hydrodynamic simulations. Model performance is assessed by (1) evaluating the spatial match of existing and generated network layout, (2) comparing the estimated hydraulic dimension with real-life infrastructure data and (3) benchmarking simulated runoff with measured data for a defined validation period. The analysis shows that the presented method is capable of reproducing the original network layout, network length and corresponding discharge rates based on little, freely available information. Further research potential is identified to improve the hydraulic dimensioning and the application to complex systems that include control structures. The presented approach is useful to estimate the scope of drainage networks including layout and design (e.g. for preliminary planning in emerging areas) to screen existing networks and to identify critical spots where more precise information is required.     

Influence of hydrate exploitation on stability of submarine slopes

Urban pluvial flash floods have become a matter of widespread concern, as they severely impact people’s lives in urban areas. Hydrological and hydraulic models have been widely used for urban flood management and urban planning. Traditionally, to reduce the complexity of urban flood modelling and simulations, simplification or generalization methods have been used; for example, some models focus on the simulation of overland water flow, and some models focus on the simulation of the water flow in sewer systems. However, the water flow of urban floods includes both overland flow and sewer system flow. The overland flow processes are impacted by many different geographical features in what is an extremely spatially heterogeneous environment. Therefore, this article is based on two widely used models (SWMM and ANUGA) that are coupled to develop a bi-directional method of simulating water flow processes in urban areas. The open source overland flow model uses the unstructured triangular as the spatial discretization scheme. The unstructured triangular-based hydraulic model can be better used to capture the spatial heterogeneity of the urban surfaces. So, the unstructured triangular-based model is an essential condition for heterogeneous feature-based urban flood simulation. The experiments indicate that the proposed coupled model in this article can accurately depict surface waterlogged areas and that the heterogeneous feature-based urban flood model can be used to determine different types of urban flow processes.

     

Logistic regression model for sinkhole susceptibility due to damaged sewer pipes

The occurrence of anthropogenic sinkholes in urban areas can lead to severe socioeconomic losses. A damaged underground sewer pipe is regarded as one of the primary causes of such a phenomenon. This study adopted the best subsets regression method to produce a logistic regression model that evaluates the susceptibility for sinkholes induced by damaged sewer pipes. The model was developed by analyzing the sewer pipe network as well as cases of sinkholes in Seoul, South Korea. Among numerous sewer pipe characteristics tested as explanatory variables, the length, age, elevation, burial depth, size, slope, and materials of the sewer pipe were found to influence the occurrence of sinkhole. The proposed model reasonably estimated the sinkhole susceptibility in the area studied, with an area value under the receiver-operating characteristics curve of 0.753. The proposed methodology will serve as a useful tool that can help local governments to choose a cavity inspection regime, and to prevent sinkholes induced by damaged sewer pipes.     

有限供水条件下水库和田间配水整合优化调度

针对多水源多作物灌区,研究有限供水条件下灌区优化配水问题。模型中既考虑水库优化调度,又考虑田间优化配水。模型思路:根据灌区水土资源分布状况,将全灌区划分为多个子区,每个子区种植有若干种作物。如果把每个子区每种作物所在的田块看作一个土壤水库,则可采用水库群调度的方法研究这类灌区优化配水问题,文中采用的是优化控制方法。为了证明模型的正确性,同时建立了3个模型。模型1:既不考虑水库优化调度又不考虑田间优化配水;模型2:只考虑水库优化调度;模型3:只考虑田间优化配水。实例计算表明,整合调度模型能产生较多的效益(特别在干旱年份),优化控制方法计算性能良好。     

Physical and numerical modelling of infiltration from drainage holes for perforated storm sewer

In cities, the existence of impervious structures, such as road pavements, parking lots, footpaths, sidewalks, and roofs, can limit the magnitude of rainfall infiltration greatly. Stormwater run-off in storm sewer often dominates, which can cause problems of urban flooding easily during heave rainfalls. In rain and sewage diversion, perforated storm sewer is proposed to enable the occurrence of stormwater infiltration into the ground, which can change the prolonged drought-like condition. Model-scale laboratory tests are conducted to assess the infiltration process of water through drainage holes around the sewer circumference. The experimental data are also used to calibrate a numerical model, after which numerical parametric analysis is carried out. It is found that the feature of drainage holes only influences the wetting front in the initial stage of infiltration. In the end, the egg-shaped contour of wetting front with greater influencing zone below the sewer is obtained. The cumulative infiltration with time can be described by an infiltration model, which is positively correlated with the diameter and the number of drainage holes. The optimal opening ratio is recommended as 0.25%, which can provide the most effective drainage capacity.

     

Pathways and timescales associated with nitrogen transport from septic systems in coastal aquifers intersected by canals

Septic systems located near coastal waterways can contribute to nutrients that lead to eutrophication, harmful algal blooms, and high levels of fecal coliforms such as E. coli. This study defines pathways and timescales of nitrogen transport released from septic systems using a groundwater-flow and nitrogen transport model of a coastal subdivision connected to 2,000 septic systems and dissected by a dense network of canals. Lift station effluent data are used as a proxy to quantify average household septic nitrogen and fluid contributions of 11 kg/year and 160 m³/year, respectively. These fluxes are upscaled and applied to five sewer conversion zones, each having a known number of septic systems. Model results provide a basis for assessing nitrogen transport timescales associated with (1) coastal groundwaters for regions with high septic density near the coastline and (2) groundwater–canal interaction. Timescales associated with nitrogen removal by natural groundwater flow in a sandy surficial aquifer, following septic to sewer conversion, are predicted by the model to be on the order of 2–3 years for 50% reduction and 8–10 years for 90% reduction. Both numerical and collected field data indicate that canals significantly influence groundwater flow and have the potential to convey nitrogen to coastal waters at rates several orders of magnitude higher than introduced by submarine discharge along the coast. Pre and post sewer conversion data on nitrate and total nitrogen in shallow groundwater from a nearby field site, obtained post-model development, support the nitrogen concentrations and timescales predicted by the numerical model.

     

略论水资源系统的混合模型

大系统优化的关键在于模型的降维.混合模型可看作为一种降维方法,它通过把整个系统分解为联系比较松散的几个子系统,达到降维目的.从理论上对这类模型的建模原则、优化技术及其分类和特点进行了归纳和总结,说明了在多目标复杂水资源系统和排灌系统中这种混合模型的应用是十分有效的.     

A real-time operation optimization model for flood management in river-reservoir systems

In this paper, a new methodology has been developed for real-time flood management in river-reservoir systems. This methodology is based upon combining a Genetic Algorithm (GA) reservoir operation optimization model for a cascade of two reservoirs, a hydraulic-based flood routing simulation model in downstream river system, a Geographical Information System (GIS) based database, and application of K-Nearest Neighbor (K-NN) algorithm for development of optimal operating rules. The GA optimization model estimates the optimal hourly reservoirs’ releases to minimize the flood damages in the downstream river. GIS tools have also been used for specifying different land-uses and damage functions in the downstream floodplain and it has been linked to the unsteady module of HEC-RAS flood routing model using Hec-GeoRAS module. An innovative approach has also been developed using K-NN algorithm to formulate the optimal operating rules for a system of two cascade reservoirs based on optimal releases obtained from the optimization model. During a flood event, the K-NN algorithm searches through the historical flood hydrographs and optimal reservoir storages determined by the optimization model to find similar situations. The similarity between the hydrographs is quantified based on the slopes of rising and falling limbs of inflow hydrographs and reservoir storages at the beginning of each hourly time step during the flood events for two cascade reservoirs. The developed methodology have been applied to the Bakhtiari and Dez River-Reservoir systems in southwest of Iran. The results show that the proposed models can be effectively used for flood management and real-time operation of cascade river-reservoir systems.     

Ground freezing— the application of the mixed method (brine— liquid nitrogen)

The paper deals with different ground freezing techniques, i.e., open, closed and mixed systems. The main criteria of choice between the various methods are also defined, and some experiments carried out in Italy between 1972 and 1979 employing the mixed system are outlined. In particular, the work carried out in Naples in 1979 is described where the mixed treatment was used to excavate below the water table for a sewer trunk line of 3.40 m diameter in the city centre and beneath existing buildings.     

抽水灌溉系统站库联合优化调度数学模型

为解决我国南方岗地多级抽水灌溉系统灌溉保证率偏低、系统中工程效益发挥差等问题,以一具体灌溉系统为例,用系统分析的方法建立了大系统站库联合优化调度数学模型.模型中将多维动态规划模型与模拟模型等优化技术相结合,巧妙地解决了灌溉水量时、空协调优化调度问题.实例表明:该模型的应用能充分发挥系统中各骨干工程的作用,提高系统的灌溉保证率.模型为提高类似灌溉系统的灌溉效益提供了新的研究途径.