数学模拟好氧颗粒污泥的形成及水力剪切强度对颗粒粒径的影响

以生物膜数学模型和活性污泥数学模型为基础,建立好氧颗粒污泥一维数学模型,并模拟营养物质的去除、颗粒粒径变化、反应器周期表现以及好氧颗粒污泥内DO和菌群分布.模拟有机物SS浓度和出水NH4+-N浓度逐渐降低,在大约50 d左右达到稳定,50 d后模拟出水浓度分别<25 mg.L-1和<1.5 mg.L-1.模拟出水NO3--N浓度随着粒径的增加呈现降低趋势.当颗粒粒径由模拟30 d时的1.1 mm增加到100 d时的2.5 mm,颗粒污泥缺氧区面积相应增加,总氮(TN)的去除率由不到10%增加到91%左右,最终模拟出水NO3--N浓度降低到<3 mg.L-1.在好氧颗粒污泥系统内,由于氧气传质阻力,模拟颗粒污泥外层DO浓度高而内层浓度低,颗粒内可以发生同时硝化反硝化,且好氧颗粒污泥内DO特征随时间而发生变化.在好氧初期,好氧颗粒污泥代谢活性高,模拟DO传质深度大约为100～200μm;而在好氧末期,模拟DO传质深度为800μm.模拟自养菌主要分布在DO浓度高的颗粒外层,异养菌分布在整个颗粒.当水力剪切系数kde由0.25(m.d)-1逐渐增加到5(m.d)-1时,模拟颗粒平衡粒径依次由3.5 mm左右减小到大约1.8 mm.在不同水力剪切强度下模拟颗粒污泥生长特征相似,其平衡状态下粒径随曝气强度的增加而减小,可以通过控制曝气强度来控制好氧颗粒污泥的平衡粒径.     

气升流速变化对SBR污泥颗粒化的作用及机理

采用两个相同的SBR反应器:R1保持恒定气升流速3.0 cm·s~(-1),R2气升流速由3.0 cm·s~(-1)逐渐降低至1.0 cm·s~(-1),对比研究了气升流速变化对絮体污泥凝聚和颗粒化的作用.结果表明:R1中35 d后絮体污泥全部转变成均值粒径为564.59μm的颗粒污泥;R2中24 d后絮体污泥全部转变成均值粒径978.71μm的颗粒污泥.R2气升流速由3.0 cm·s~(-1)逐渐降至2.0 cm·s~(-1)时,污泥的分形维数(D2)增大;气升流速由2.0cm·s~(-1)逐渐降到1.6 cm·s~(-1)时,D2先下降后上升,污泥粒径比增长率为0.16±0.01,微生物颗粒表面所受的剪切解吸附率随粒径的增长由调整前的1.35×10~(-2)mg·cm~(-2)·d~(-1)(以VSS计,下同)略微降低后升高至1.88×10~(-2)mg·cm~(-2)·d~(-1),颗粒结构变得更加致密;气升流速小于1.6 cm·s~(-1)之后,旋涡尺度作用减弱,D2持续减小.总体上,当气升流速递减后,R2中污泥混合液流变特性发生了变化,形成的漩涡尺度大于R1,促使更多体积分数的污泥分布在漩涡尺度的耗散范围内,加剧耗散对应范围粒径大小的污泥剪切凝聚,加快了污泥颗粒化进程.     

滇池湖泊生态系统水动力学模拟

针对滇池富营养化状况,依据滇池生态环境建设规划,在以前研究工作的基础上,综合考虑湿地植物、底泥、水域条件变化,根据水动力学原理建立了垂向平均的二维生态系统水动力学模型,模拟了滇池现有水体、拆除防浪堤水域扩展后水体和滇池湿地建成后总水体3种情况的流场和浓度场,以及入滇河道达标排放后的水质浓度场,分析了湿地植物和水域扩展对滇池流场的影响,以及水域扩展、湿地植物、入湖河流达标排放对滇池水质的影响。结果表明,水域拓展对滇池流场的影响是局部的,湿地植物对滇池流场的影响主要发生在湿地区域。水域拓展对滇池水质具有一定影响,TN、TP平均质量浓度由2.08和0.19 mg.L-1(现有水体)降至1.69和0.16 mg.L-1;人工湿地建设对滇池水体TN、TP浓度影响较大,湿地建成后平均质量浓度降至0.76和0.05 mg.L-1,基本达到GB 3838—2002《地表水环境质量标准》Ⅲ类水质标准;人工湿地建设完成并且入滇池河流达标排放后,TN、TP平均质量浓度分别降至0.17和0.01 mg.L-1,水质明显改善。因此,人工湿地建设及入滇池河流的达标排放对滇池生态环境的改善具有重要作用。     

强降雨在滑坡发育中的关键控制机理及典型实例分析

通过构建水动力作用模型,对降雨的激发控制作用进行分析,得出水动力控制机理的结论:强降雨控制滑坡发育,集中表现在改变土体的静水压力、动水压力与浮托力的作用三方面.选取重庆市黔江流水湾滑坡为典型实例,对强降雨的激发控制作用进行验证,强降雨的水动力作用过程分为坡体剪切、滑动开始、剧烈滑动三个不同阶段.最后,提出久旱过后强降雨...     

River environmental decision support system development for Suzhou Creek in Shanghai

The Suzhou Creek Rehabilitation Project (SCRP) is one of the largest water-related environmental rehabilitation schemes ever undertaken in the vicinity of Shanghai, China. This paper details the development and application of a River Environmental Decision Support System (REDSS) for scientific planning and decision-making on the Suzhou Creek project, and illustrates the flexibility of the REDSS framework. We developed the following components: (1) a GIS-based analysis employing Component technology; (2) a "data mart" for multi-dimensional, multi-level, integrated, dynamic, and flexible data querying; and (3) a set of hydrodynamic and water quality models which can simulate complex tidal river networks. In addition, we detail how a water quality assessment model is embedded into the REDSS by employing an Identification Index Method. With the REDSS, all GIS and non-GIS components are integrated seamlessly and data from different sources can be queried simultaneously. This allows for various scenarios to be simulated and analyzed in advance to predict and assess the effects of proposed engineering and management measures. Generated information can thus support effective decisions. All operations of the REDSS can be implemented conveniently through user-friendly interfaces. The function of the REDSS framework is demonstrated through an application to Suzhou Creek. Because the REDSS characteristics are quite general, it may be applied in different geographic regions.     

湖泊流域系统水文水动力联合模拟研究进展综述

湖泊流域水文水动力联合模拟对综合管理湖泊流域水资源具有重要的理论和实践意义。通过水文水动力联合模拟研究进展的综述,可深入了解湖泊流域联合模型发展和演变过程,把握国际研究主流趋势和前沿手段。传统湖泊流域联合模拟方法主要通过流域水文模型结合湖泊水量平衡模型来计算湖泊流域水均衡组分,但水量平衡方法仅是对湖泊过程的一般性描述,难以切实反映水位空间差异显著的湖泊系统有着显著的水动力特性。基于流域水文模型与湖泊水动力模型的联合系统克服了大尺度湖泊流域系统难以切实描述和完整模拟的难点,在湖泊流域系统水资源管理与调控中发挥了重要作用。系统概述了国内外不同尺度湖泊流域系统水文水动力联合模拟研究,归纳总结了基于外部耦合、内部耦合与全耦合技术的联合模型的优势和不足。从学科发展趋势和应用需求的角度出发,概述了湖泊流域系统联合模拟的难点和今后发展趋势     

HYDRODYNAMIC MODELS OF HUMAN STABILITY IN A FLOOD1

ABSTRACT: Major loss of life can occur in a flood when people are toppled by floodwater currents. Three approximate mechanical models and two empirical models of the hydrodynamics of toppling are presented and calibrated to align with available experimental observations to assist the analysis of the risk of life loss. The mechanical models consider circular cylindrical, square cylindrical and cylindrical composite, heavy bodies assembled to represent a human immersed in a flow field and subject to drag and buoyancy forces. The models can account for the height and weight of the exposed persons, and the velocity and depth of the flow. The models are in good mutual agreement and, when calibrated, yield failure functions that can be used to calculate the probability of loss of stability.     

HYDRODYNAMIC SIMULATIONS OF A CONSTRUCTED WETLAND IN SOUTH FLORIDA1

ABSTRACT: This paper describes the application of the SHEET2D model to the Florida's Everglades Nutrient Removal (ENR) Project. The ENR Project is a 3815 acre (1545 ha) pilot project, located in Palm Beach County. The operation of the treatment system will be used to demonstrate the performance of larger scale constructed wetland systems for removal of phosphorus from Everglades Agricultural Area (EAA) stormwater runoff. It is currently the largest stormwater wetland treatment system in the world. The SHEET2D model was used to analyze the performance of the ENR Project. SHEET2D is a two-dimensional, depth-averaged hydrodynamic model that is applicable to shallow water flow conditions. Subsequently, results from SHEET2D simulations were used to develop the ENEMOD model. ENRMOD is a lumped parameter box water quality model that can be used to analyze the long term performance of the ENR project with respect to hydrology and phosphorus uptake. Localized short-circuiting in the agricultural ditches within the project area was analyzed by using the RBFVM-2D model, which is a finite volume hydrodynamic model that is also applicable to shallow water flow conditions. The SHEET2D model was employed to simulate the hydraulics of the structures between cells and the hydrodynamics of the sheet-flow moving across the buffer cell and treatment cells. Collection, distribution, and larger discharge canals within the project were simulated by means of the MultiBasin Routing (MBR) model features that are built into the SHEET2D model. Constant inflows (75 to 600 cfs [2.1 to 17 m³/s]) were used in all runs to simulate the discharge of the ENR Project based on the proposed operating schedule for the outflow pump station. The model simulated 30 days to reach steady state conditions. Under steady state conditions, the hydraulic retention times were computed for the project and the split of flow between the two treatment trains of the entire project from the common buffer cell. Additionally, design components such as height of the levees, capacity of the structures, and hydrographs at specified grids were obtained.     

Evaluating the Applicability of a Two‐dimensional Flow Model of a Highly Heterogeneous Domain to Flow and Environmental Management

Two‐dimensional simulation of highly heterogeneous domains, especially those with disparate length scales, roughness conditions, and geometries, often leads to challenges such as long computation times and numerical instability. Simulation of challenging domains is often needed to guide flood management and environmental regulation agencies in operation and potential domain modifications. This work evaluates the ability of a two‐dimensional unsteady hydrodynamic model to represent long‐duration transient flows over a domain with highly heterogeneous roughness, geometric characteristics, and length scales through bed roughness representation. The domain includes 13 km of Cache Creek and the 14.5 km² Cache Creek Settling Basin, which traps both sediment and mercury. Calibration under different bed roughness methods, validation, and modeling results of bathymetric modification scenarios are presented. The modeling approach's performance supports its application as a tool for management of similar domains, such as settling basins, leveed floodplains, and reservoirs. Accurate representation of flow dynamics can also inform environmental management that involves transport of sediments, nutrients, and heavy metals. This study found that a two‐dimensional unsteady flow model can accurately represent long‐duration transient flow in a large settling basin with highly heterogeneous characteristics without parsing of the domain or flow events simulated.     

昆仑山隧道渗(漏)水水力联系及水动力参数试验研究

隧道施工过程中经常发生隧道涌(漏)水现象,对施工或运营安全可能造成较大影响。为了从根本上治理隧道渗漏水害,首先必须详细准确了解水害的根源,即渗漏水点与地表水源之间的水力联系。对于岩溶管道水比较有效的研究方法是开展连通试验,而对于渗透性能差、水力联系复杂的基岩裂隙水地区开展连通试验是不多的, 尤其是在高纬度、高海拔、以及多年冻土地区开展隧道渗漏水水力联系试验研究尚属首次,值得进一步深入探讨研究。本文针对青藏铁路昆仑山隧道渗漏水情况,在详细调查研究基础上,采用多种形式的连通试验,对昆仑山隧道渗漏水的径流条件和围岩渗透性能进行分析,并进行渗漏水的主要水动力参数计算,为该隧道渗漏水害的治理提供了科学依据。