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1.
重非水相(DNAPLs)是地下水常见的有机污染物,理解其运移机制对于污染物修复具有重要意义。为解释实验中多孔介质润湿性对DNAPL的流动速度及残余饱和度的影响,使用多相流相场法,在构造的二维孔隙中模拟DNAPL液滴的下落过程。结果表明:模拟能准确刻画多相流界面的不稳定性,重现与实验室尺度相似的现象。文章提出的双界面模型相较于以往的微观模型能够更好的解释介质润湿性对DNAPL运移的影响。DNAPL的下落速度受前后界面共同影响,而饱和度主要由后界面决定。同时,润湿性对运移的影响大小受制于多孔介质的非均质性。 相似文献
2.
重非水相液体(dense nonaqueous phase liquid,DNAPL)污染土壤和地下水的问题已引起广泛关注,研究其在不同粒径多孔介质及其界面的运移特征形态是确定污染区域、修复治理土壤和地下水环境的前提。文章通过室内试验研究多孔介质界面对DNAPL运移与分布特性的影响。首先在二维砂槽上进行DNAPL污染物的入渗试验,试验过程中用数码相机拍照,将DNAPL扩散过程以图像的形式记录下来;然后用AutoCAD对图片进行处理,绘制出DNAPL迁移过程的锋面变化图。结果表明:DNAPL入渗过程中,迁移主要受到重力作用与毛细作用的控制,毛细作用力随着介质粒径的增大逐层减小,重力作用逐渐起主导作用使污染物入渗速度逐层增大;介质结构影响DNAPL的迁移形态,介质粒径逐层增大,DNAPL污染物的渗流面与指进扩散宽度逐层减小,扩散方式由面状变为指状;在不同粒径介质界面介质结构发生突变时,DNAPL迁移锋面线曲率也相应变大,此时DNAPL的迁移呈现“凸”型特征,另外,不同的界面横向扩散的滞留宽度不同,随着介质粒径的增大,界面的横向扩散宽度相对变短。 相似文献
3.
重非水相污染物(DNAPL)在地下介质中运移和分布受多种因素控制,包括DNAPL本身的物理化学性质,土的性质,泄漏条件等等。由于介质的非均质性,使得多相流运移行为更为复杂。基于地下水随机理论构建渗透率随机场,采用蒙特卡罗方法探讨泄漏速率对非均质饱和介质中DNAPL运移的影响。数值结果表明,在泄漏总量一定的情况下,泄漏速率越低,介质非均质性对DNAPL运移的影响程度越高。反之,DNAPL的渗漏速率越高,小尺度地层的非均质性影响越低。由于DNAPL运移过程中在垂直方向受重力的影响,污染羽在空间上的质心位置(一阶矩)以及展布范围(二阶矩)在垂直方向上的变异程度要高于水平方向。 相似文献
4.
地下水中非水相液体(Non-aqueous Phase Liquid,NAPL)的流动及其曝气修复技术是典型的两相流问题。基于实际地下水含水介质的普遍非均质性,本文应用光透法对非均质孔隙介质中两相流进行了定量试验研究,设计了两组砂箱实验,研究气体和重非水相液体(DNAPL)在非均质孔隙介质中的迁移规律,应用了水/气两相和水/NAPL两相饱和度计算模型。实验结果表明:气体主要由不规则通道向上运动,遇到低渗透性透镜体时在其下方堆积,并开始横向运动,绕过透镜体后继续向上运动,最终在砂箱顶部形成连续气体分布,注气速度越大,气体运移范围越宽;DNAPL在自身重力作用下克服毛管压力向下迁移至低渗透性透镜体,DNAPL无法克服该介质的毛管压力,停止垂向入渗,并在其表面堆积,开始横向运移,绕过透镜体后继续向下运动,最终在砂箱底部形成连续DNAPL污染池。均质介质中建立的计算流体饱和度的水/气模型及水/NAPL模型与实验结果较吻合,可用于非均质多孔介质中水/气相和水/NAPL相饱和度的计算。 相似文献
5.
重非水相液体(DNPALs)在地下环境中的运移分布与残余捕获受多种因素控制。选择四氯乙烯(PCE)作为DNAPLs特征污染物,通过二维砂箱实验探究介质非均质性对PCE运移及污染源区结构特征的影响。采用透射光法监测PCE在砂箱内的运移过程,定量测量PCE的饱和度。采用空间矩分析PCE污染体的平均运移行为随时间的变化,并采用离散状与池状PCE体积比(GTP)定量表征污染源区结构特征。结果表明,由于无法克服毛细压力,PCE在细砂透镜体上方聚积并侧向扩散,水平扩散范围显著增大。随机非均质介质中,PCE绕开细砂透镜体,沿着粗砂透镜体构成的优势通道运移,运移路径的不规则性及饱和度分布的空间变异性增强。PCE的捕获主要为毛细屏障和拉断效应两种形式。运移路径延长,路径上残留的离散状PCE增多,低饱和度的比例与GTP增大。非均质性显著影响PCE的运移路径、捕获及空间分布。 相似文献
6.
文章选用四氯乙烯(PCE)为代表性重非水相液体(DNAPL),采用透射光法监测PCE在单裂隙介质中的运移过程和形态分布,探究流速及裂隙面倾斜度对PCE运移分布行为的影响。结果表明,单裂隙介质中PCE呈团块状脱离注样针,并在运移过程中呈近椭圆状。地下水流速越大,初始面积Fs越大,近椭圆的PCE离心率e越小;裂隙面倾斜度越大,初始面积Fs越小,近椭圆的PCE离心率e越小。不同流速或倾斜度条件下,入渗稳定后的PCE团块面积与离心率均明显下降。地下水流速及裂隙面倾斜度的增大对于PCE纵向运移具有促进作用,使PCE污染物前端锋面运移速率增大,在相同时间内更快运移到裂隙底部。PCE入渗停止后,流速增大促使污染源区PCE饱和度降低,使饱和度峰值随水流速度增大而减小;倾斜度增大抑制污染源区PCE饱和度降低,使饱和度峰值随倾斜度增大而增大。 相似文献
7.
韩智颖王锦国崔孜铭杨蕴 《地质灾害与环境保护》2022,(3):71-77
选定氯苯为典型DNAPL建立理想的地表污染泄漏多相流运移模型,利用TOUGH系列软件TMVOC模块进行数值模拟,探讨地下水动力、介质非均质性及两种因素协同作用时对DNAPLs运移和分布的影响。研究结果表明:(1)水力梯度增大了DNAPL水平和垂向运移速率;当水平向水力梯度过大时,反而导致垂向速率减小。(2)透镜体主要发挥阻滞作用,绕过透镜体后,下游侧污染指入渗深度明显大于上游侧;水力梯度的存在进一步增强介质非均质性的影响,产生更多集聚和绕流,形成不规则的污染指和污染池交替组合形态。 相似文献
8.
重非水相液体(Dense Non-Aqueous Phase Liquid,DNAPL)与水相的界面面积是影响DNAPL在地下水中溶解速率的关键参数。通过设计二维砂箱实验,运用界面分配示踪法测定DNAPL残余饱和态下的界面面积。为量化分析保守示踪剂Br~-的存在对实验结果的影响,共进行两组实验,Br~-和界面分配示踪剂的注入方式分别为依次注入和同时注入。结果表明:(1)两组实验测定的固液相分配系数K_d值分别为0.079 m L/g和0.142 m L/g,表明Br~-的存在增大了介质对界面分配示踪剂的吸附作用;(2)两组实验测定的单位体积多孔介质中界面面积值分别为215 cm~2和237 cm~2,表明Br~-的存在增大了DNAPL与水相交界面对界面分配示踪剂的吸附作用;(3)在本实验范围内(Br~-浓度C_(Br)≤200mg/L),K_d值与Br~-浓度呈良好的线性关系(K_d=0.00032C_(Br)+0.0798),可用于对砂介质的K_d值进行估算和验证。 相似文献
9.
非均质介质的空间维度变化对重非水相流体(DNAPL) 的运移具有重要的影响。在充分考虑地质体的空间连续
性、不对称性以及各向异性等特征的基础上,采用基于马尔可夫链的转移概率(transition probability) 模型来构建非均质
随机场。该文通过TMVOC-MP软件来模拟DNAPL在非均质介质中的运移规律,探讨非均质随机场的水平空间连续性、
空间维度变化以及侧向运移过程对DNAPL运移的影响。结果表明,介质的水平空间连续性越好,DNAPL在水平方向的
迁移范围越大,在垂向的迁移范围越小;相比于三维模型,二维模型中DNAPL在水平方向的展布更大、在透镜体上的蓄
积量更多,在实际应用中以二维模型代替三维模型会加大模拟结果与实际污染情况之间的误差;侧向运移过程削弱了单
个平面的非均质性对DNAPL运移的控制,当存在侧向运移时,DNAPL绕过透镜体所运移的距离以及在透镜体上的蓄积
量会相应减小。 相似文献
10.
多孔介质中重非水相液体(Dense Non Aqueous Phase Liquid,DNAPL)与水相的界面面积是影响DNAPL在地下水中溶解速率的关键参数。本文通过二维均质砂箱实验,运用界面分配示踪法和体积分配示踪法分别测定DNAPL与水相的界面面积(单位介质体积内的面积,Anw)和DNAPL饱和度(Sn),并研究两者之间的相关关系。使用C18H29NaO3S(SDBS)作为界面分配示踪剂,Alcohol(2,4 Dimethyl 3 Pentanol)作为体积分配示踪剂,CaBr2作为保守示踪剂。利用Fe2+催化的Na2S2O8对DNAPL进行原位氧化修复,改变Anw和Sn。结果表明,通过定量(用孔隙体积数PV值衡量)加入Na2S2O8,Anw由206 cm2逐渐降为37 cm2,下降速率约为14 cm2/PV;Sn由1.34%逐渐降为0.33%,下降速率约为0.1%/PV;Anw和Sn之间具有良好的线性关系(Anw=146×Sn,R2=0.987)。此关系可用于估算多孔介质中DNAPL与水相之间的界面面积。对实验影响因素的分析表明,孔隙度的增大(变化率为20.7%)使示踪剂穿透曲线出现肩现象和拖尾现象,导致保守示踪剂的保留时间增加5.6%,界面面积减小6.8%。 相似文献
11.
Following the accidental subsurface release of dense nonaqueous phase liquids (DNAPLs), spatial variability of physical and chemical soil/contaminant properties can exert a controlling influence on infiltration pathways and organic entrapment. DNAPL spreading, fingering, and pooling typically result in source zones characterized by irregular contaminated regions with complex boundaries. Spatial variability in aquifer properties also influences subsequent DNAPL dissolution and aqueous transport dynamics. An increasing number of studies have investigated the effects of subsurface heterogeneity on the fate of DNAPL; however, previous work was limited to the examination of the behavior of single-component DNAPL in systems with simple and well-defined aqueous and solid surface chemistry. From a DNAPL remediation point of view, such an idealized assumption will bring a large discrepancy between the designs based on the model simulation and the reality. The research undertaken in this study seeks to stochastically explore the influence of spatially variable porous media on DNAPL entrapment and dissolution profiles in the saturated groundwater aquifer. A 3D, multicomponent, multiphase, compositional model, UTCHEM, was used to simulate natural gradient water flooding processes in spatially variable soils. Porosity was assumed to be uniform or simulated using sequential Gaussian simulation (SGS) and sequential indicator simulation (SIS). Soil permeability was treated as a spatially random variable and modeled independently of porosity, and a geostatistical method was used to generate random distributions of soil permeability using SGS and SIS (derived from measured grain size distribution curves). Equally possible 3D ensembles of aquifer realizations with spatially variable permeability accounting of physical heterogeneity could be generated. Tetrachloroethene (PCE) was selected as a DNAPL representative as it was frequently discovered at many contaminated groundwater sites worldwide, including Thailand. The randomly generated permeability fields were incorporated into UTCHEM to simulate DNAPL source zone architecture under 96-L hypothetical PCE spill in heterogeneous media and stochastic analysis was conducted based on the simulated results. Simulations revealed considerable variations in the predicted PCE source zone architecture with a similar degree of heterogeneity, and complex initial PCE source zone distribution profoundly affected PCE recovery time in heterogeneous media when subject to natural gradient water flush. The necessary time to lower PCE concentrations below Thai groundwater quality standard ranged from 39 years to more than 55 years, suggesting that spatial variability of subsurface formation significantly affected the dissolution behavior of entrapped PCE. The temporal distributions of PCE saturation were significantly altered owing to natural gradient water flush. Therefore, soil heterogeneity is a critical factor to design strategies for characterization and remediation of DNAPL contaminated sites. The systematic and comprehensive design algorithm developed and described herein perhaps serves as a template for application at other DNAPL sites in Thailand. 相似文献
12.
Solute transport experiments were conducted in a one-dimensional saturated column using dissolved methoxy-nonafluorobutane (HFE-7100), a Novec engineered fluid developed by the 3M Corporation, as the solute. Novec engineered fluids are considered dense non-aqueous phase liquids (DNAPLs) because they are immiscible with water and have a specific gravity greater than one. The HFE-7100 fluid is safer and environmentally friendlier than common DNAPL contaminants such as tetrachloroethylene (PCE) or trichloroethylene (TCE); thus, it is an ideal substitute DNAPL for laboratory groundwater contamination research. Three sets of solute transport experiments were conducted. The first set of experiments was conducted in a glass-bead-packed column using dissolved HFE-7100 as the solute. The second set of experiments was conducted in a sand-packed column using dissolved HFE-7100 as the solute. The third set of experiments was conducted in a sand-packed column using dissolved PCE as the solute. The dissolved HFE-7100 column breakthrough concentrations were compared with dissolved PCE breakthrough concentrations. Results show that the one-dimensional solute transport equation was successful in describing the transport behavior of dissolved HFE-7100. This study demonstrates that the HFE-7100 fluid can be used as a safer substitute DNAPL for groundwater contaminant dissolution and transport research. 相似文献
13.
在二维均质饱和孔隙介质中利用光透法与高密度电阻率法定量监测重非水相液体(DNAPL)的运移过程与饱和度。 将光透法与高密度电阻率法相结合,进行高密度电阻率法对 DNAPL 在饱和多孔介质中渗流过程的定量监测。在二维砂箱 中进行 DNAPL 的入渗试验,应用光透法与高密度电阻率法进行动态监测,分别利用 CCD 相机、LCR 数字电桥采集数据。 光透法的数据处理采用“水-DNAPL”两相中 DNAPL 饱和度的计算公式。而高密度电阻率法的数据处理是将获得的电阻值 数据转化为电阻率值,然后利用 Archie 公式获得重非水相液体的饱和度空间分布。Archie 公式中参数β值本文采用与光透法 相结合的新方法来获取,克服了传统方法获取β值时存在的困难。根据不同时刻的饱和度空间分布可以估算注入砂箱内的 DNAPL 总量,并将其与实测的入渗量进行对比。结果表明,与光透法结合后的高密度电阻率成像法能定量监测饱和孔隙介 质中 DNAPL 的入渗过程,且估算的 DNAPL 入渗量与实测值比较吻合,提出的基于光透法计算β值的新方法是有效且可行的。 相似文献
14.
William G. Harrar Lawrence C. Murdoch Bertel Nilsson Knud Erik S. Klint 《Hydrogeology Journal》2007,15(8):1473-1488
A study of the fracture distribution, hydraulic properties, groundwater levels and the transport of bromide was conducted to characterize vertical transport in the oxidized and reduced zones of a fractured glacial till. Detailed vertical profiles of groundwater levels and solute concentrations were obtained over a 4.5-year period. Vertical migration occurred at several time scales, as a low concentration front was rapidly transported at rates of 100–500 m/year ahead of a slower moving main plume, which advanced at rates of 0.2–0.8 m/year. Concentrations in the leading edge of the plume displayed a high degree of spatial variability over short vertical distances through day 1,000. Late in the test, the influence of matrix diffusion became apparent as concentration patterns developed from being irregular to more uniform distributions. Calculations show that the mass within the low concentration plume front accounts for less than 1% of the total solute mass. Simulation of the breakthrough curves using a simple one-dimensional advection-dispersion model of transport in porous media indicates that vertical transport is dominated by advection. Furthermore, the results indicate that vertical transport of solutes in oxidized and reduced zones of the till can be adequately simulated using an equivalent porous media. 相似文献
15.
Simulation of DNAPL infiltration and spreading behaviour in the saturated zone at varying flow velocities and alternating subsurface geometries 总被引:3,自引:1,他引:2
Katharina Erning Sibylle Grandel Andreas Dahmke Dirk Schäfer 《Environmental Earth Sciences》2012,65(4):1119-1131
The influence of varying groundwater flow velocities on DNAPL infiltration and spreading behaviour was investigated by multiphase
modelling using TMVOC and PetraSim. The multiphase models were calibrated by results of previously conducted laboratory experiments
for the complete spatio-temporal range of the experiments. The small scale 2D scenario modelling was applied to qualify and
quantify changes in position, architecture, geometry and dissolution of a TCE body in a fully saturated homogeneous sandy
medium. The applied flow velocities ranging from 0.05 up to 40.00 m/day exhibited that the DNAPL TCE is affected even at the
lowest flow velocity in its position, its size and its architecture. Additionally, several impermeable lenses with simple
geometry were assumed in the model, to investigate the influence of stratified subsoil. In the experimental set-ups, the DNAPL
body reacts more sensitive to the applied groundwater flow velocities than to the geometrical set-up of the scenarios. A possible
consequence can be the transportation and displacement of a DNAPL pool due to natural or anthropogenic induced high groundwater
flow velocities, as by Pump and Treat facilities, complicating site investigation process and planning of remediation activities. 相似文献