周进周出辐流式沉淀池三维数值模拟与PIV实验对比研究

沉淀池是污水处理工艺流程中的重要环节,池内水流流态对沉淀池的处理效果有着较大的影响。利用计算流体力学(CFD)中常用的FLUENT软件,采用重整化RNG k-ε2方程模型对周进周出辐流式沉淀池内的湍流情况进行了数值模拟,同时利用粒子成像测速(PIV)技术对沉淀池中的流速进行了实测,研究结果表明,沉淀池顶部和底部区域流速较大,而中部区域流速相对较小,形成了一个较大的回流区。计算模拟值与实测数据吻合良好,证明了CFD数学模型能准确地模拟沉淀池内的流速分布及流场沿程变化情况,此模型可以应用于沉淀池内部流场模拟。     

垂直流人工湿地水力学特性研究

通过示踪剂实验从停留时间分布（RTD）曲线及其统计特征值等方面对垂直流人工湿地的水力学特性进行了定性和定量的分析。研究表明水流在垂直流人工湿地中的流动是一种非理想的不均匀流动，存在一定的死区和水流的扩散；垂直流人工湿地较大的死区率与其表面布水的不均匀性有关，这也可能是其死区率大于表流人工湿地的最主要的原因。实验还表明，进水流量对垂直流人工湿地停留时间分布影响较大，随着进水流量的增加，平均停留时间减小，但标准平均停留时间增大，死区率减小；当进水流量为15L／h（水力负荷为620mm／d）时，水流在湿地中的散度最大，水流更接近全混流，不利于污染物的降解。     

机械絮凝池内部流场数值模拟和絮凝效果分析

通过对机械絮凝池内不同进水流量和不同桨板转速的流场分别进行数值模拟,计算得到湍动能k和湍动耗散率ε等水力参数,并结合混凝实验分析水流对絮凝效果的影响。结果表明:湍动能k和湍动耗散率ε可以作为评价絮凝是否充分的标准;机械絮凝池最佳水力停留时间为18 min;平均k值为0.00613～0.00212 m2/s2,平均ε值为0.00869～0.00199 m2/s3时,机械絮凝池装置的絮凝效果比较理想。     

微电场-零价铁强化厌氧水解酸化性能

通过投加零价铁和增加微电场提高水解酸化的效果,改善混合工业废水的可生化性。实验在4个反应器中同步进行:微电场-零价铁厌氧反应器(R1)、微电场厌氧反应器(R2)、零价铁厌氧反应器(R3)及普通厌氧反应器(R4)。结果表明,微电场-零价铁对水解酸化具有明显的促进作用,在水力停留时间(HRT)为81 h时,TOC去除率达70%,BOD5/COD由0.15增至0.41,废水的可生化性显著提高。     

内循环厌氧反应器多相流流场的三维数值分析简

利用数值模拟的方法，引入欧拉双流体多相流模型及标准k-ε紊流模型，模拟计算内循环厌氧反应器的三相流三维流场，并通过改变污泥颗粒密度及进水流量，针对固相流速及固含率的变化情况，分析条件的改变对流场的影响。研究结果表明，应用数值模拟方法可以获得内循环厌氧反应器内的流场特征；污泥颗粒密度及进水流量的改变对于反应器内污泥颗粒的流速及分布的均匀性有较为明显的影响。模拟结果对反应器的应用及优化设计具有一定的参考价值。     

以剩余污泥水解酸化液为外加碳源的污水生物脱氮

为解决低碳氮比污水生物脱氮过程反硝化碳源不足的问题，利用剩余污泥水解酸化液为外加碳源，通过具有曝气段与非曝气段的一体化曝气生物滤池（BAF），研究低碳氮比污水生物脱氮的性能与工艺条件。实验结果表明，预处理后的水解酸化液VFAs为3134．9～5251．4mg／L、ThODVFAs／COD为59．87％～91．85％，适合作为生物脱氮的外加碳源；水解酸化液的投配量、进水TN浓度对系统生物脱氮效果的影响较大，气水比、曝气段与非曝气段比例对系统的硝化和反硝化性能有重要的影响；在温度为25±1℃，水解酸化液COD平均为7555．1mg／L，进水TN、NH4-N和COD分别平均为43．88mg／L、39．04mg／L和56．8mg／L，碳源与污水投配的流量比为1：75的条件下，当BAF水力停留时间（HRT）为8h、曝气段与非曝气段比例为3：3、气水比为10：1、回流比为2：1时，NH4-N和TN的去除率分别超过98％和75％，出水COD平均为28．6mg／L。研究指出，剩余污泥水解酸化液经过预处理后可用作低碳氮比污水生物脱氮的外加碳源，有效地提高了反硝化效果，并不会造成二次污染，同时又可以实现剩余污泥的减量化和资源化。     

A2O氧化沟缺氧区三维流场模拟及结构形式优化

以FLUENT软件为工具，选用三维RNG k-ε紊流数学模型对重庆井口污水厂A²O氧化沟缺氧区内的流场进行模拟，分析了缺氧区内流场分布不均匀及沉泥的原因，提出了水下推进器的合理设置位置与导流墙的合理设置方式，并对优化后的缺氧区进行了模拟计算。通过优化后模拟的结果可见，在相同的功率密度下，缺氧区内的流场得到了较均匀的分布，流速从原来的0.131 m/s提升到0.204 m/s，减少了能量的损失。底部的流速也从原来的0.140 m/s提升到0.226 m/s，有效的防止或减少了沟中的污泥沉积。优化的结果对实际工程的设计也有一定的指导意义。     

挥发性污染物苯在水气界面耦合扩散的浓度分布

为研究苯水体泄漏后水气污染的浓度时空分布，利用挥发性污染物水气耦合扩散模型进行预测计算，预测结果与水槽实验相结合，准确地描述了苯在水气界面耦合扩散的浓度分布规律：沿水流方向（x轴）浓度随时间向前推移，距离投放点越远，浓度峰值越小，出现时刻越晚；沿水流深度方向（y轴）浓度分布关于投放点z=0.20 m纵断面对称，在水气界面和空间变化界面（水槽边缘）浓度出现极小值，随着挥发量的增加，浓度峰值出现的位置由水中推移至大气中；沿水流宽度方向（z轴）浓度由投放点向两侧推移。分析了亨利常数、水流速度及风速对苯耦合扩散浓度分布的影响。     

逆流湍动床生物膜反应器液相混合特性的研究

研究了实验室规模逆流湍动床的水力学特性。以亚硝酸钠作为示踪剂，采用刺激响应技术，通过测定停留时间分布(RTD)，考察了反应器的内部流动状况。考察了不同固含率（0～0.3）、表观气速（1.1～8.8 mm/s）和表观液速（0.66～1.7 mm/s）对RTD的影响。研究表明，表观气速增大、固含率减小和适当提高表观液速都会使反应器返混增强，更接近CSTR。反应器死区百分率低，结构性能良好；死区百分率与表观气速和液速相关性不强，而与固含率负相关。逆流湍动床的RTD可用轴向扩散模型、等体积多釜串联模型和不同体积2釜串联模型来模拟，这些模型的特征参数Pe、N和α分别为1.25～1.79、1.46～1.67和0.74～0.90。     

猪场废水厌氧发酵液循环脱氮工艺

研究了水解酸化与生物接触氧化组合循环工艺处理猪养殖场废水厌氧发酵液的脱氮特性,重点考察了组合工艺的最佳运行工况和参数,同时讨论了组合工艺低温运行的性能。结果表明,水力停留时间24 h和污水循环比1∶3为最佳运行工况,此时出水氨氮浓度为2.16～8.20 mg/L。溶解氧(DO)浓度2～3 mg/L和有机负荷3 g/L以下为最佳运行参数,出水氨氮浓度稳定在10 mg/L以下。在春季低温条件下(8～12℃),组合工艺也能较好运行,水解酸化池内小分子有机酸产生总量为114.50～244.22 mg/L。组合工艺连续运行3个月以上,污染物去除效果稳定。     

潜流式湿地系统停留时间分布实验结果分析

鉴于水力停留时间对人工湿地系统处理效果和构建设计的重要性,通过示踪实验测定了潜流式湿地系统的停留时间分布,结合反应器理论,对实验测定的不同进水流量范围的停留时间响应结果,分别以多釜串联模型以及移位正态分布函数进行拟合,并进一步对系统的水力平均停留时间、系统的流动形态以及非理想性进行了分析和讨论,为湿地系统的水力学优化设计和实际运行提供理论基础和技术参数.     

Laboratory-scale in situ chemical oxidation of a perchloroethylene pool using permanganate

In situ chemical oxidation (ISCO) is an emerging technology for the destruction of some chlorinated solvents present in subsurface environments. A laboratory investigation using a physical model was designed to assess the effectiveness of using permanganate as an oxidant to reduce the mass of a perchloroethylene (PCE) pool. The physical model was filled with silica sand overlying a silica flour base, simulating a two-dimensional saturated sand zone overlying a capillary barrier. PCE was introduced into the model so that it rested on top of the silica flour base, forming a dense nonaqueous phase liquid pool. The experimental methodology involved flushing the model with a permanganate solution for 146 days. During this period, measurements of chloride were used to assess the extent of pool oxidation. Before and after the oxidant flush, the quasi-steady state dissolution from the PCE pool was evaluated. Additionally, tracer studies were completed to assess changes in the flow field due to the oxidation process. At the termination of the experiment nine soil cores extracted from the model were used to detect the presence of MnO2 deposits and to quantify the mass of PCE remaining in the system. Excavation of the remaining material in the model revealed that the MnO2 distribution throughout the model was consistent with that observed in the cores. The oxidant flush was concluded before all of the pure phase PCE had been completely oxidized; however, approximately 45% of the PCE mass was removed, resulting in a fourfold decrease in the quasi-steady state aqueous phase mass loading of PCE from the pool. Measurements of chloride during the oxidant flush and of PCE in the soil cores suggested that the oxidation reaction occurred primarily at the upgradient edge of the PCE pool. MnO2 deposits within the model aquifer decreased the velocity of water directly above the pool, and the overall mass transfer from the remaining PCE pool. The results of this experimental study indicate that ISCO using permanganate is capable of removing substantial mass from a DNAPL pool; however, the performance of ISCO as a pool removal technology will be limited by the formation and precipitation of hydrous MnO2 that occurs during the oxidation process.     

水力旋流器速度场的PDPA测试研究

应用相位多普勒粒子分析仪(PDPA)对液液水力旋流器模型的内部流场进行了测试,分析了旋流器内部速度场的特点。通过进口流量的变化,测试了该模型的不同截面上的速度场分布情况。测试结果表明:随着流量的增大,旋流器轴截面上的速度都增大,旋流变大,有利于连续相和分散相的分离;旋流器中连续相和分散相速度分布趋势相同,但在管芯处,两者速度滑移明显。     

SMBR内气液两相流三维CFD模拟

应用CFD软件Fluent对浸没式膜生物反应器(submerged membrane bioreactor,SMBR)内气液两相流进行数值模拟研究,重点考查曝气系统的改变对气液两相流态的影响,并结合PIV实验验证模拟结果,从而为反应器的优化设计及膜污染的控制提供理论依据。模拟结果表明,SMBR内曝气强化了气液两相紊动,膜表面液相速度沿反应器高度增加且形成循环流动,有利于膜面污染物的脱落;反应器内气含率分布不均匀,出现死区,不利于微生物的生长;经实验验证,模拟结果吻合良好。     

Pulsed pumping process optimization using a potential flow model

A computational model is applied to the optimization of pulsed pumping systems for efficient in situ remediation of groundwater contaminants. In the pulsed pumping mode of operation, periodic rather than continuous pumping is used. During the pump-off or trapping phase, natural gradient flow transports contaminated groundwater into a treatment zone surrounding a line of injection and extraction wells that transect the contaminant plume. Prior to breakthrough of the contaminated water from the treatment zone, the wells are activated and the pump-on or treatment phase ensues, wherein extracted water is augmented to stimulate pollutant degradation and recirculated for a sufficient period of time to achieve mandated levels of contaminant removal. An important design consideration in pulsed pumping groundwater remediation systems is the pumping schedule adopted to best minimize operational costs for the well grid while still satisfying treatment requirements. Using an analytic two-dimensional potential flow model, optimal pumping frequencies and pumping event durations have been investigated for a set of model aquifer-well systems with different well spacings and well-line lengths, and varying aquifer physical properties. The results for homogeneous systems with greater than five wells and moderate to high pumping rates are reduced to a single, dimensionless correlation. Results for heterogeneous systems are presented graphically in terms of dimensionless parameters to serve as an efficient tool for initial design and selection of the pumping regimen best suited for pulsed pumping operation for a particular well configuration and extraction rate. In the absence of significant retardation or degradation during the pump-off phase, average pumping rates for pulsed operation were found to be greater than the continuous pumping rate required to prevent contaminant breakthrough.     

Uncertainty in Nonpoint Source Pollution Models and Associated Risks

The usefulness of water quality simulation models for environmental management is explored with a focus on prediction uncertainty. The specific objective is to demonstrate how the usability of a flow and transport model (here: MACRO) can be enhanced by developing and analyzing its output probability distributions based on input variability. This infiltration-based model was designed to investigate preferential flow effects on pollutant transport. A statistical sensitivity analysis is used to identify the most uncertain input parameters based on model outputs. Probability distribution functions of input variables were determined based on field-measured data obtained under alternative tillage treatments. Uncertainty of model outputs is investigated using a Latin hypercube sampling scheme (LHS) with restricted pairing for model input sampling. Probability density functions (pdfs) are constructed for water flow rate, atrazine leaching rate, total accumulated leaching, and atrazine concentration in percolation water. Results indicate that consideration of input parameter uncertainty produces a 20% higher mean flow rate along with two to three times larger atrazine leaching rate, accumulated leachate, and concentration than that obtained using mean input parameters. Uncertainty in predicted flow rate is small but that in solute transport is an order of magnitude larger than that of corresponding input parameters. Macropore flow is observed to contribute to the variability of atrazine transport results. Overall, the analysis provides a quantification of prediction uncertainty that is found to enhance a user's ability to assess risk levels associated with model predictions.     

Uncertainty in Nonpoint Source Pollution Models and Associated Risks

The usefulness of water quality simulation models for environmental management is explored with a focus on prediction uncertainty. The specific objective is to demonstrate how the usability of a flow and transport model (here: MACRO) can be enhanced by developing and analyzing its output probability distributions based on input variability. This infiltration-based model was designed to investigate preferential flow effects on pollutant transport. A statistical sensitivity analysis is used to identify the most uncertain input parameters based on model outputs. Probability distribution functions of input variables were determined based on field-measured data obtained under alternative tillage treatments. Uncertainty of model outputs is investigated using a Latin hypercube sampling scheme (LHS) with restricted pairing for model input sampling. Probability density functions (pdfs) are constructed for water flow rate, atrazine leaching rate, total accumulated leaching, and atrazine concentration in percolation water. Results indicate that consideration of input parameter uncertainty produces a 20% higher mean flow rate along with two to three times larger atrazine leaching rate, accumulated leachate, and concentration than that obtained using mean input parameters. Uncertainty in predicted flow rate is small but that in solute transport is an order of magnitude larger than that of corresponding input parameters. Macropore flow is observed to contribute to the variability of atrazine transport results. Overall, the analysis provides a quantification of prediction uncertainty that is found to enhance a user's ability to assess risk levels associated with model predictions.     

喷嘴角度对脱硫塔内气液两相流场的影响

提出了采用数值模拟的方法研究喷嘴角度对脱硫塔内部气液两相流场的影响。由于实际脱硫塔尺寸庞大,给实验研究带来困难且成本很高,在数值模拟平台上,分别模拟了45°、75°和-30°3种喷嘴角度布置下脱硫塔内部速度场、温度场变化以及湍流强度的分布情况。结果表明,在角度为-30°布置时速度场变化不是很剧烈,脱硫塔进出口温差比较理想,湍流强度在脱硫塔底部较大随着塔高的增加缓慢降低,这样有助于气液两相均匀混合,并控制出口烟温,有利于提高脱硫效率。     

内循环厌氧反应器多相流流场的三维数值分析

利用数值模拟的方法，引入欧拉双流体多相流模型及标准k-s紊流模型，模拟计算内循环厌氧反应器的三相流三维流场，并通过改变污泥颗粒密度及进水流量，针对固相流速及固含率的变化情况，分析条件的改变对流场的影响。研究结果表明，应用数值模拟方法可以获得内循环厌氧反应器内的流场特征；污泥颗粒密度及进水流量的改变对于反应器内污泥颗粒的流速及分布的均匀性有较为明显的影响。模拟结果对反应器的应用及优化设计具有一定的参考价值。     

A2O氧化沟缺氧区三维流场模拟及结构形式优化

以FLUENT软件为工具,选用三维RNG k-ε紊流数学模型对重庆井口污水厂A2O氧化沟缺氧区内的流场进行模拟,分析了缺氧区内流场分布不均匀及沉泥的原因,提出了水下推进器的合理设置位置与导流墙的合理设置方式,并对优化后的缺氧区进行了模拟计算。通过优化后模拟的结果可见,在相同的功率密度下,缺氧区内的流场得到了较均匀的分布,流速从原来的0.131 m/s提升到0.204 m/s,减少了能量的损失。底部的流速也从原来的0.140 m/s提升到0.226 m/s,有效的防止或减少了沟中的污泥沉积。优化的结果对实际工程的设计也有一定的指导意义。