基于FEFLOW和GIS技术的矿区地下水动态模拟及预测

矿区地下水动态研究是山西亟待解决的重大需求问题。针对山西矿区水资源短缺与水环境恶化等现状,通过分析气象、水文、地质地貌、开采现状等监测数据资料,以FEFLOW模型和GIS技术为平台,构建山西矿区三维地下水数值模型,进行地下水动态研究,模拟并预测了4种不同情境下矿区地下水动态过程,从而定量分析采矿活动对地下水动态的影响,揭示矿区开采对地下水系统的作用机制。结果表明：当矿区开采强度提高10%、30%、50%时,地下水整体流场和运动趋势没有大的变化,但在矿区南部地下水流场发生突变,等值线形变,且在东南部形成一个水位变化剧烈的低水位带,迫使地下水流向发生偏转。水位分析表明采矿活动会造成地下水位整体下降,下降幅度与开采强度呈正相关关系。地下水系统均衡分析表明,当开采强度保持现状或提高10%,地下水系统仍然处于正均衡,补给量大于排泄量,当开采强度提高30%、50%时,系统转为负均衡状态,补给量小于排泄量,地下水水量大幅度减少。研究成果可为矿区制定合理的开采方案,保护矿区地下水资源提供参考依据,为有效遏制矿区水环境恶化、确保矿区水安全提供科技支撑。     

Comparison of two modeling approaches for groundwater–surface water interactions

An assessment of interactions between groundwater and surface water was carried out by applying two different modeling approaches to a small‐scale study area in the municipality of Havelock, Quebec. The first approach involved a commonly used sequential procedure that consists in determining the daily recharge rate using a quasi 2D infiltration model (HELP), applied in the next step as an imposed flux to a 3D finite‐element groundwater flow model. The flow model was calibrated under steady‐state and transient conditions against measured water levels. The second approach was based on a recently developed physically based, 3D fully coupled groundwater–surface water flow model (CATHY) applied to the entire flow domain in an integrated manner. Implementation, calibration, and results of the simulations for both approaches are presented and discussed. For equal annual precipitation (1038 mm/y) and evapotranspiration (556 mm/y), the second approach computed a recharge rate of 233 mm/y (8.9% higher than the first approach) and a net upward flow from the fractured aquifer (the first approach predicted a net downward flow to the rock). The simulated annual discharge was similar for the two approaches (9.6% difference). Both approaches were found to be useful in understanding the interactions between groundwater and surface water, although limitations are apparent in the sequential procedure's inability to account for surface–subsurface feedbacks, for instance near stream reaches where groundwater discharge is prevalent. The decoupled, two‐model approach provides disaggregated surface, vadose, and aquifer flows, and a simple aperçu at the different components of total discharge. The fully coupled model accounts for continuous water exchanges between the land surface, subsurface, and stream channel in a more complex manner, and produces a better match against observed data. Copyright © 2012 John Wiley & Sons, Ltd.     

Deuterium composition and flow path analysis as additional calibration targets to calibrate groundwater flow simulation in a coastal wetlands system

A conceptual model of the Lake Warden coastal wetlands system, Western Australia, was developed using hydraulic, chemical and stable isotopic data, and formed the basis for a groundwater flow model using the finite element numerical code (FEFLOW). The system to be modeled is complex. The surface water and groundwater within the wetlands system show varying salinity and isotopic composition over short distances and time frames. As a first step, the flow model was calibrated to observed groundwater levels measured since 2001 for both steady state and transient stresses. Particle tracking analysis was conducted to test the source areas of water discharging to the lakes within the wetlands system. The analysis was able to delineate the connectivity between the lakes in the wetland and the flow path. Enrichment of isotopic concentration is evident along a NE–SW transect and the data set provides a means for calibrating a detailed transport model. The study incorporates the varying deuterium composition of the water bodies directly into a transport model and a good match between observed and simulated temporal variations along the transect indicates that the model closely simulated the dynamics of water exchange between the lakes and groundwater within the system.     

共和盆地干热岩体人工裂隙带结构的控热机理与产能优化

人工压裂是获取干热岩型地热资源的关键环节,压裂后的人工裂隙带结构对开采条件下水热传递过程具有重要控制作用。结合我国共和盆地干热岩储层地质条件,采用数值模拟方法着重分析干热岩不同产状人工裂隙带的渗透率与宽度对热储中水热传递过程的影响机理,明确不同人工裂隙结构条件下水热产出能力,进而优化井间距。结果表明:当人工裂隙带渗透率较小时（小于5 D）,裂隙带规模越大,开采井温度越高;当渗透率较大时（大于10 D）,在水平裂隙带中,随着裂隙带规模的增加,由于注入冷水的快速扩散导致整体低温区域增加,开采井温度反而降低。在水平裂隙带中注入冷水主要为水平向流动,随着渗透率的增加,开采井温度更易受注入冷水的影响而降低;但在垂直裂隙带及倾斜裂隙带中,随着渗透率的增加,垂向自由对流增强,注入冷水更易于向储层底部高温区域流动,经加热后到达开采井,使得开采温度提升。综合比较,同一井间距条件下,低渗水平裂隙带以及高渗垂直裂隙带的产热能力较其他裂隙带更强。     

黑河下游地下水波动带地下水时空分布模拟研究-FEFLLOW模型应用

从黑河下游地下水波动带水文循环出发,确定影响地下水变化的重要补给排泄项,根据水文地质结构对研究区水力传导系数和给水度进行确定,并获得研究区参数分区.通过运行FEFL-LOW模型,得到任意时段研究区地下水水头的空间分布.利用观测数据对模拟结果验证并进行参数调整.结果表明:(1)15个观测点平均误差约为0.59 m,最小平均误差为0.18 m,最大平均误差1.09 m;(2)地下水的空间变化为以东西河为中心向两侧加深,研究区南部岩石山地和北部东西居延海之间地下水位较深,其它区域地下水位在1～4 m之间;(3)从模拟初始(1990年),研究区每年水量都处于一种负均衡状态,2000年之后略有改观,2003年出现了正均衡.但不同区域地下水年际变化的趋势不同,研究区内上下游的水位有上升趋势,而中游绿洲区水位以下降趋势为主.     

Modelling study on the impact of deep building foundations on the groundwater system

Coastal areas are usually the preferred place of habitation for human beings. Anthropogenic activities such as the construction of high‐rise buildings and underground transport systems usually require extensive deep foundations and ground engineering works, which may unintentionally modify the coastal groundwater system because the construction materials of foundations are usually of low hydraulic conductivity. In this paper, the impact of these building foundations on the groundwater regime is studied using hypothetical flow and transport models. Various possible realizations of foundation distributions are generated using stochastic parameters derived from a topographical map of an actual coastal area in Hong Kong. The effective hydraulic conductivity is first calculated for different realizations and the results show that the effective hydraulic conductivity can be reduced significantly. Then a hypothetical numerical model based on FEFLOW is set up to study the change of hydraulic head, groundwater discharge, and saltwater‐fresh water interface. The groundwater level and flow are modified to various degrees, depending on the foundations percentage and the distribution pattern of the buildings. When the foundations percentage is high and the building foundations are aggregated, the hydraulic head is raised significantly and the originally one‐dimensional groundwater flow field becomes complicated. Seaward groundwater discharge will be reduced and some groundwater may become seepage through the ground surface. The transport model shows that, after foundations are added, overall the seawater and fresh groundwater interface moves landward, so extensive foundations may induce seawater intrusion. It is believed that the modification of the coastal groundwater system by building foundations may have engineering and environmental implications, such as submarine groundwater discharge, foundation corrosion, and slope stability. Copyright © 2007 John Wiley & Sons, Ltd.     

Development of a conjunctive use model to evaluate alternative management options for surface and groundwater resources

A conjunctive use model has been developed to evaluate alternative management options for surface and groundwater resources. A simple water balance approach was used to estimate net recharge to the aquifer. The groundwater model FEFLOW takes net recharge as an input for the water balance calculation and simulates flow in the groundwater under all boundary stresses. The developed model was applied to an irrigated area in the Indus Basin, Pakistan, to predict groundwater levels up to 2010 in response to the possible need for intervention in irrigation and/or agricultural practices. A geographical information system (GIS) was used to assemble various types of spatial data. The study revealed that an increase in pumpage from the present rate would further strain the scarce water resources. Lining of watercourses and adjustment in cropping pattern could be adopted as alternatives for better management of surface and groundwater resources.

我国地下水数值模拟软件应用进展

随着地下水模拟软件的不断更新完善,以Visual MODFLOW、GMS和FEFLOW为代表的一批标准化软件在我国的应用更加广泛,为提高国内的地下水模拟技术水平有巨大帮助。在介绍国外模拟技术发展的基础上,重点介绍了上述软件在我国的应用进展情况。     

FEFLOW在区域地下水流场演化数值模拟中的应用

首先建立了洛阳龙门地区水文地质模型,然后运用FEFLOW软件对研究区寒武系地下水进行了数值模拟计算,得出了影响景区泉群正常出流的可能原因,主要有降雨量小,煤矿的开采,居民,企业,农业用水的增加等。     

基于FEFLOW的岩溶管道模型构建方法探讨

岩溶管道流模型的刻画一直是岩溶区开展地下水数值模拟研究中的难点所在,基于此,文章以贵州六枝特区某项目为例进行地下水数值模拟研究,探索了在FEFLOW离散特性功能模块下岩溶管道流模型的刻画方式与方法。在详细分析研究区地质及水文地质条件的基础上,对研究区范围、边界、含水层结构等概化,建立了研究区的水文地质概念模型;以ArcGIS软件为辅助,基于有限元法的FEFLOW软件为操作平台,利用区内钻孔资料及野外测算结果,通过软件公式编辑、插值等功能分别获得各层顶底板高程属性,将数据输入FEFLOW后,对模拟区平面三角剖分进而空间离散构建了研究区的三维地质模型;并利用FEFLOW软件的离散特性功能模块,将研究区灰场南部岩溶洼地与岩脚泉间划定为特定区域,建立缓冲区并给予其高特异性,耦合哈根-泊肃叶流体流动公式,在模型中刻画了岩溶管道流模型;最后探讨了特殊地质构造与岩溶管道模型的刻画方式与方法刻画出了符合案例区的三维向斜褶皱地质模型和岩溶管道流模型。