吉林省白城市地下水数值模拟及其变化趋势

为了给吉林省白城市地下水资源合理开发利用提供科学依据,运用地下水模拟技术对白城市地下水位变化趋势进行预测。首先在分析研究区水文地质条件的基础上建立水文地质概念模型,将含水系统概化为潜水含水层、越流层和承压含水层,并确定了系统的边界条件。运用地下水模型软件(GMS)对研究区地下水流进行了模拟和预测,预测结果表明在扩大开采的情况下,潜水含水层水位总体下降约1~2 m;随着开采量的增加和时间的增长,含水层在洮儿河扇形地、洮南、研究区东北部、镇赉、大安南部等地相继出现疏干现象,最大降幅达5~6 m。承压含水层在大安南部、镇赉北部等地水位下降较大,但是流场整体降幅不大,总体降幅在0.5 m以内。最后提出了地下水合理开发利用建议。     

呼和浩特盆地地下水流系统变异机制及其资源效应

几十年的高强度开采致使呼和浩特盆地地下水流系统发生了很大变化。在对含水系统结构特征分析的基础上,结合地下水流场及水位动态特征,对地下水流系统演化模式进行了分析总结,基本可归纳为3个演化阶段,地下水人工开采及沟谷水利工程的修建是地下流系统变异的主要驱动因子。采用均衡法对现状条件下地下水均衡情况进行了定量计算,通过与历史时期均衡情况对比分析,发现在不同水流系统演化阶段,各含水层地下水补排量差异较大,从而导致地下水资源量发生变化,与历史时期相比,潜水含水层资源量明显减小,承压含水层资源量有所增加,但总资源量一定程度减小,地下流系统变异的资源效应明显。     

新疆和什托洛盖煤田吉力湖西含水层特征研究

以和什托洛盖煤田吉力湖西地下水亚系统为研究对象,对该地下水亚系统的赋存条件、含水层特征、地下水流循环特征以及地下水位动态特征进行了研究。研究结果表明:研究区含水层特征主要包括基岩裂隙水、第四系松散岩类孔隙水和古近系碎屑岩类孔隙水;研究区补给来源主要为山区河道渗漏补给、暴雨洪流入渗补给和降水入渗补给;地下水的排泄主要包括潜水蒸发和侧向径流两种方式。研究区潜水动态类型为蒸发型,年内动态变化曲线呈单峰、单谷型,水位变化幅度在0. 67 m左右。     

新郑市浅层地下水流数值模拟及评价

通过分析新郑市水文地质条件,建立了概念模型,运用GMS软件建立三维地下水流的数值模拟模型,对研究区浅层地下水资源进行现状评价,并对2015年和2020年地下水位进行了预测.结果表明,研究区地下水水位持续下降,到2020年水位将会下降5～10 m,部分地区可能会出现开采漏斗,为了降低地下水位的下降幅度,应该调整产业结构,加强水资源的管理,提高水资源的利用率,从而减少地下水资源的开采.     

挠力河流域三维地下水流数值模拟

在分析概化挠力河流域地质及水文地质条件的基础上,建立了研究区地下水流系统的三维数学模拟模型,运用Visual MODFLOW软件进行求解,并对研究区未来7年的地下水流场进行了预报。模型预报过程中用迭代逼近方法预报二类边界,用频谱分析法预报年降水量和地下水开采量,实现了随机模型与确定性模型相耦合。结果表明,研究区地下水多年平均补给量为20.9×10⁸ m³/a。从预报的等水位线图看出,按照预测的开采量进行开采,研究区的地下水位在预报期间略有下降,每年平均下降0.329 m。     

采煤对榆溪河流域地下水资源的影响研究

榆溪河位于榆阳区境内,全长98 km,流域面积近4 000 km2,根据地形地貌及支流分水岭等整个流域被划分为10个水源地。本文依据流域水文地质条件构建水文地质概念模型,在此基础上基于可视化数值模拟软件(Processing Modflow)建立流域三维地下水流数值模型,模型经识别与校验完成后,加载煤矿矿坑涌水工况,模拟煤矿开采对地下水资源的影响,预测未来30年末的地下水末流场、末埋深场、末降深场、潜水位降深曲线以及地下水补排均衡量,并进行分析评价,得出主要结论为:(1)在地下水及煤矿现状开采条件下,未来30年末水源地地下水处于负均衡状态,负均衡主要为消耗深层侏罗系地下水资源储存量。(2)煤矿开采涌水主要对矿井及其周围的潜水位产生一定的影响,金鸡滩镇附近由于煤矿矿坑疏干地下水会形成一个较大的降落漏斗区域,潜水位最大净降深约3m,影响半径约15 km。(3)流域地下水位呈缓慢平顺的发展态势,没有出现地下水位急剧变化的情况,未来30年地下水位下降一般0.5~2.3 m,煤矿附近最大地下水位下降约3 m。研究成果可为榆溪河流域煤矿开采和水资源利用规划提供依据。     

苏北沿海三市三维地下水流数值模拟

20世纪80年代以来,苏北沿海三市（连云港、盐城和南通）地下水过量开采导致部分地区水位持续大幅下降,引发地面沉降、水质咸化等问题。本文基于研究区大量地质、水文地质资料,以及2005—2013年地下水开采和水位观测数据,经过模型识别、验证,建立了能刻画苏北沿海三市地下水流场演化的三维非均质各向异性地下水流数值模型,模拟了研究区2005—2013年开采量由约2.03亿m³逐渐减少到1.56亿m³条件下深部地下水系统流场（包括第Ⅱ、Ⅲ、Ⅳ承压含水层）的动态演化过程。结果表明,各观测孔的水位实测值与模拟值吻合良好,水位及水均衡模拟结果显示各含水层水位下降得到有效控制,但是该区域地下水仍处于超采状态。为进一步控制水位下降,防治咸水扩散、地面沉降等地质环境灾害,模型预测并比较了现状开采和限制开采2种不同开采方案下2014—2020年苏北沿海三市深层地下水流场的变化趋势。预报结果显示,2种开采方案下,各含水层水位下降速率均减小,尤其是限制开采方案下,第Ⅱ、Ⅲ和Ⅳ承压含水层的区域水位平均下降速率依次为0.15、0.16和0.15 m/a,分别比模拟期减小了46.43%、65.21%和48.28%,在开采强度降至最低的条件下储存量变化速率仍为负值,说明需要进一步加强地下水限制开采的力度。     

基于Visual Modflow的邯郸县地下水位动态研究

根据邯郸县水文地质条件,建立水文地质概念模型和地下水流数学模型,采用可视化标准软件Visu-al Modflow对研究区地下水进行数值模拟计算及预测。通过自动与手动相结合的方式,多次对模型进行调整,实现模拟计算结果与实际观测值的较好拟合;并以调节均衡型开采动态为原则,制定了2015、2020年县域浅层地下水设计开采量方案。模拟结果表明,2011年至2015年地下水位有明显下降趋势,地下水位下降3 m,2015年以后,在限采条件下,控制开采量,地下水位平均降深稳定在3.5 m左右,流场趋于稳定。     

近50 a来新疆孔雀河灌区地下水流系统演变特征

新疆孔雀河灌区面临地下水超采问题,科学认识区域地下水流系统的发育条件和演变特征,是优化地下水资源开发利用方式的基础.通过构建第四系含水层三维地下水稳定流模型,利用流线追踪技术,模拟识别了孔雀河流域19702020年期间地下水流系统的变化特征.结果 表明,不同补给区和排泄区通过流线进行组合,在孔雀河周边形成了交错分布的地下水流系统,其空间分布格局随灌区地下水开采规模而变化.在20世纪70年代的拟天然状态,灌区主要发育自北向南的地下水流系统,其空间分布格局取决于水文地质参数和排泄要素,并可能存在1～4个以孔雀河为排泄带的流动系统.在有强烈地下水开采的现状条件下,灌区地下水流系统转变为从四周流向漏斗中心,截断了从孔雀河上游渗漏到中下游河道排泄的水流系统.近50 a来,以潜水蒸发为排泄方式的地下水流系统投影面积萎缩了29％,而以地下水开采为排泄方式的地下水流系统投影面积从零增加到研究区面积的40％.潜水蒸发对自然生态系统具有重要的支撑作用,灌区地下水开采应有所控制以保障潜水蒸发型地下水流系统的发育条件.     

群矿开采条件下山西潞安矿区的地下水流场变化

煤炭开采导致区域含水层结构破坏,已经严重影响了区域地下水循环演化态势,是煤矿区地下水资源短缺的根本原因。本文以山西长治盆地潞安矿区为例,通过野外调查、相似材料模拟实验和数值模拟手段,分析了群矿开采驱动下含水层结构破坏对地下水流场的影响。通过砂槽模拟试验结果和数值模拟结果进行对比验证,结果表明:1)煤层开采形成采动裂隙发育基本限制在完整基岩内,使得隔水底板黏土岩发生弯曲变形,承压含水层水位下降形成层间疏干区,对第四系潜水含水层流场影响甚微,潜水水位没有明显下降;2)隔水层有效厚度变薄的局部地区,由于采动裂隙切穿隔水层,导致该区潜水含水层消失;3)采煤造成的类似"溯源侵蚀",引发原本隔离的地下水系统间的地下水袭夺现象,矿井水补给量有所增加。     

地下水位变化对透—阻型岩溶塌陷影响的分析

文章从一维地下水运动和渗透力学的角度,分析比较潜水位上升与承压水位下降对岩溶地区透—阻型盖层中阻水层渗透稳定性的影响,重点讨论了承压水位下降速度(降速)与下降深度（降深）对阻水层中渗透坡降的影响,结果表明:地下水位变化（潜水位上升或承压水位下降）产生的非稳定渗流不利于岩溶洞穴开口上方阻水层的稳定,承压水位的下降对岩溶开口附近处阻水层中渗透力的影响远大于潜水位的变化;在承压层水位最大降深确定的条件下,承压水位下降速度愈快,岩溶开口附近处阻水层中向下渗透力愈大。因此,在覆盖型岩溶地区抽取地下水时,为了减缓或避免覆盖型塌陷的发生,应同时控制好最大降深和最大开采速度。      

Reassessing the management of groundwater use from sandy aquifers: acidification and base cation depletion exacerbated by drought and groundwater withdrawal on the Gnangara Mound, Western Australia

The combined effects of low rainfall, groundwater withdrawal in excess of 300 GL/year and reduced recharge in areas covered by pine plantations has caused the water table in a sandy unconfined aquifer on the Gnangara Mound in Western Australia to drop by up to 5 m and aquifer storage to decline by about 500 GL over the last 20 years. Groundwater has become acidic in areas of high drawdown, with pH values typically being less than 5.0 at the water table, and elevated concentrations of SO₄ ^2?, Al, Fe, Zn, Cu, Ni and Pb. Trends of increasing acidity and base cation concentrations in deep water supply wells in the Mirrabooka wellfield indicate that about 0.7 keq/ha/year of base cations are being leached from soil within cones of depression of pumping wells. These results indicate that the assessment of the sustainable yields of aquifers under conditions of low rainfall needs to consider geochemical interactions between groundwater, aquifer sediments, soils and vegetation, and not be just based on aquifer hydraulics and water-balance changes.     

河北省滦县李家屿灰场2#副坝区灰水运动的水文地质评价

韩家哨村位于河北滦县李家屿灰场北部谷地,地势低于灰场,距离约800m。灰场运行期间,该区地下水出现水位升高及水质变差等问题。本文从水文地质条件角度,详细研究灰水的运移途径及其对该区地下水的影响。韩家哨村区域地下水系统分为上层滞水和孔隙一裂隙（溶隙）潜水含水层系统。潜水含水层系统水力传导系数为172．6～203．4m^2／d。地下水补给主要来源于韩家哨村以南坝后地形较高区域及灰水。灰水渗漏优势区韩家哨村南部宽约200m的带状区域。灰场堆灰形成新的地下水分水岭致使灰水在20副坝坝前垂直下渗进入风化带,沿白云岩裂隙（溶隙）补给潜水含水层,并向韩家哨村区域流动补给孔隙含水层,改变后的潜水部分通过民井向外排泄。     

用地下水潮汐效应确定潜水含水层水文地质参数

目前对潜水含水层地下水潮汐效应和水文地质参数求解方法的研究相对较少.通过对福建古雷半岛滨海潜水含水层地下水潮汐效应和海水潮汐动态的观测, 运用Fourier频谱分析方法确定了研究区海水潮汐波动方程(波动特征参数), 并以此作为地下水的边界条件, 推导了潜水含水层地下水潮汐效应的波动方程, 利用最小二乘法以地下水水位波动观测值为目标函数对潜水含水层的渗透系数与重力给水度的比值进行了反演识别, 为类似地区水文地质参数的确定提供了借鉴, 也为该区后续地下水中溶质迁移规律的研究奠定了基础.      

Environmental impact assessment using FORM and groundwater system reliability concept: case study Jining, China

In this paper, fist-order reliability method (FORM) is used to evaluate the impacts of uncertainties posed by traditional deterministic models on the environment in Jining, China. Because of groundwater contamination in shallow aquifer, and an increase in water demand, the new wells target the confined aquifer with constant pumping rate of 5,000 m³/d. Using Theis equation, the groundwater drawdown is analyzed to determine whether the confined aquifer will be contaminated. Although the piezometric level is higher than the phreatic level by 11.0 m, the risk of drawdown is still 19.49% when the pumping rate of 5,000 m³/d is maintained for 2 years. The deterministic model indicates a drawdown of 8.94 m which is lower than the maximum tolerance drawdown of 11.0 m. The sensitivity and uncertainty analysis reveal that the model result is more sensitive to transmissivity than specific yield, while the reliability analysis offers significant information for the decision makers. This approach exposes and minimizes the risk of undesirable consequences such as groundwater contamination.     

Study on the groundwater sustainable problem by numerical simulation in a multi-layered coastal aquifer system of Zhanjiang,China

Assessing sustainability of coastal groundwater is significant for groundwater management as coastal groundwater is vulnerable to over-exploitation and contamination. To address the issues of serious groundwater level drawdown and potential seawater intrusion risk of a multi-layered coastal aquifer system in Zhanjiang, China, this paper presents a numerical modelling study to research groundwater sustainability of this aquifer system. The transient modelling results show that the groundwater budget was negative (\(-3826\times 10^{4}\) to \(-4502\times 10^{4 }\,\hbox {m}^{3}/\hbox {a}\)) during the years 2008–2011, revealing that this aquifer system was over-exploited. Meanwhile, the groundwater sustainability was assessed by evaluating the negative hydraulic pressure area (NHPA) of the unconfined aquifer and the groundwater level dynamic and flow velocity of the offshore boundaries of the confined aquifers. The results demonstrate that the Nansan Island is most influenced by NHPA and that the local groundwater should not be exploited. The results also suggest that, with the current groundwater exploitation scheme, the sustainable yield should be \(1.784\times 10^{8}\, \hbox {m}^{3}/\hbox {a}\) (i.e., decreased by 20% from the current exploitation amount). To satisfy public water demands, the 20% decrease of the exploitation amount can be offset by the groundwater sourced from the Taiping groundwater resource field. These results provide valuable guidance for groundwater management of Zhanjiang.     

Identifying the recharge sources and age of groundwater in the Songnen Plain (Northeast China) using environmental isotopes

The recharge sources and groundwater age in the Songnen Plain, Northeast China, were confirmed using environmental isotopes. The isotopic signatures of the unconfined aquifers in the southeast elevated plain and the north and west piedmont, cluster along local meteoric water lines (LMWLs) with a slope of about 5. The signature of source water was obtained by the intersection of these LMWLs with the regional meteoric water line (RMWL). This finding provides evidence that the recharge water for these areas originate from the Changbai Mountains and the Low and High Hingan Mountains, respectively. Groundwater in the unconfined aquifer in the low plain yields a LMWL with a slope of 4.4; its nitrate concentration indicates the admixture of irrigation return flow. The δ-values of the unconfined aquifer in the east elevated plain plot along the RMWL, reflecting recharge by local precipitation. The mean residence time of groundwater in these aquifers is less than 50?years. However, the ¹⁴C age of the groundwater in the confined Quaternary aquifer ranges from modern to 19,500?years, and in the Tertiary confined aquifer from 3,100 to 24,900?years. Modern groundwater is mainly recharged to the Quaternary confined aquifer on the piedmont by local precipitation and lateral subsurface flow.     

Numerical groundwater-flow modeling to evaluate potential effects of pumping and recharge: implications for sustainable groundwater management in the Mahanadi delta region,India

Process-based groundwater models are useful to understand complex aquifer systems and make predictions about their response to hydrological changes. A conceptual model for evaluating responses to environmental changes is presented, considering the hydrogeologic framework, flow processes, aquifer hydraulic properties, boundary conditions, and sources and sinks of the groundwater system. Based on this conceptual model, a quasi-three-dimensional transient groundwater flow model was designed using MODFLOW to simulate the groundwater system of Mahanadi River delta, eastern India. The model was constructed in the context of an upper unconfined aquifer and lower confined aquifer, separated by an aquitard. Hydraulic heads of 13 shallow wells and 11 deep wells were used to calibrate transient groundwater conditions during 1997–2006, followed by validation (2007–2011). The aquifer and aquitard hydraulic properties were obtained by pumping tests and were calibrated along with the rainfall recharge. The statistical and graphical performance indicators suggested a reasonably good simulation of groundwater flow over the study area. Sensitivity analysis revealed that groundwater level is most sensitive to the hydraulic conductivities of both the aquifers, followed by vertical hydraulic conductivity of the confining layer. The calibrated model was then employed to explore groundwater-flow dynamics in response to changes in pumping and recharge conditions. The simulation results indicate that pumping has a substantial effect on the confined aquifer flow regime as compared to the unconfined aquifer. The results and insights from this study have important implications for other regional groundwater modeling studies, especially in multi-layered aquifer systems.     

Inverse modelling of aquifer parameters in basaltic rock with the help of pumping test method using MODFLOW software

The origin and movement of groundwater are the fundamental questions that address both the temporal and spatial aspects of ground water run and water supply related issues in hydrological systems. As groundwater flows through an aquifer, its composition and temperature may variation dependent on the aquifer condition through which it flows. Thus, hydrologic investigations can also provide useful information about the subsurface geology of a region. But because such studies investigate processes that follow under the Earth's shallow, obtaining the information necessary to answer these questions is not continuously easy. Springs, which discharge groundwater table directly, afford to study subsurface hydrogeological processes.The present study of estimation of aquifer factors such as transmissivity (T) and storativity (S) are vital for the evaluation of groundwater resources. There are several methods to estimate the accurate aquifer parameters (i.e. hydrograph analysis, pumping test, etc.). In initial days, these parameters are projected either by means of in-situ test or execution test on aquifer well samples carried in the laboratory. The simultaneous information on the hydraulic behavior of the well (borehole) that provides on this method, the reservoir and the reservoir boundaries, are important for efficient aquifer and well data management and analysis. The most common in-situ test is pumping test performed on wells, which involves the measurement of the fall and increase of groundwater level with respect to time. The alteration in groundwater level (drawdown/recovery) is caused due to pumping of water from the well. Theis (1935) was first to propose method to evaluate aquifer parameters from the pumping test on a bore well in a confined aquifer. It is essential to know the transmissivity (T = Kb, where b is the aquifer thickness; pumping flow rate, Q = TW (dh/dl) flow through an aquifer) and storativity (confined aquifer: S = bS_s, unconfined: S = S_y), for the characterization of the aquifer parameters in an unknown area so as to predict the rate of drawdown of the groundwater table/potentiometric surface throughout the pumping test of an aquifer. The determination of aquifer's parameters is an important basis for groundwater resources evaluation, numerical simulation, development and protection as well as scientific management. For determining aquifer's parameters, pumping test is a main method. A case study shows that these techniques have been fast speed and high correctness. The results of parameter's determination are optimized so that it has important applied value for scientific research and geology engineering preparation.