地下水水位及水温在查明矿区岩溶水补给条件中的应用——以福建马坑铁矿为例

综合利用马坑矿区积累的水位、水温资料,结合前期对矿区水文地质条件的认识,查明了矿区岩溶水在疏干条件下的补给的变化特征。矿区岩溶含水层以石炭系船山组至二叠系栖霞组灰岩为主,大气降水为其主要补给来源。矿区开采过程中由于矿山采石场开采灰岩造成的溶洞出露地表、采空塌陷裂隙、第四系扰动及沟谷堵塞等使大气降水入渗补给量增大;断层破碎带使分布于灰岩含水层上部的二叠系文笔山组泥质砂岩地层具有了良好的含水性及导水性,致使其上部加福组砂岩裂隙水通过小娘坑断层及F3断层等破碎带补给岩溶水;溪马河河水沿河床与F1断层交汇段渗漏补给岩溶水;深部花岗岩低温热水也沿F1及F10断层破碎带进入矿坑。      

贵州盘县马依西二井田水文地质特征及充水因素研究

矿井水文地质类型划分是矿井防治水宏观决策的主要依据,是矿井水文地质工作的一项重要内容。本文以贵州盘县马依西二井田为研究对象,通过井田地下水的补给、迳流、排泄条件和水文地质特征分析,显示该井田水文地质类型主要以大气降水为主要补给来源,以顶板直接进水的裂隙充水矿床,水文地质条件中等。井田地表水通过冒落裂隙带及断层易构成充水导水通道,井田内的地表水体,与矿坑或充水岩层具有水力联系时,可成为矿坑充水水源,在地表水体附近开采时,由于开采形成的采空区可引起冒落带、地表开裂和塌陷,从而沟通地表水体,导致地表水溃入巷道。通过井田水文地质特征以及充水因素分析,为井田今后矿井突水指出方向,同时为水文地质相似矿井充水、突水灾害起到指导作用。     

安徽泥河铁矿矿坑充水因素研究

安徽泥河铁矿矿区水文地质条件较复杂,矿体埋深大,在综合分析矿区水文地质条件、地表水、地下水相互水力联系的基础上,从岩层性质、地下水赋存及补给条件,确定了影响矿床充水的各因素,结果可知:泥河铁矿矿体埋藏深度大,顶底板围岩为隔水层,次生石英岩含水层为矿坑充水的主要间接补给源,其多位于矿体顶板之上50 m,受矿体上部导水性极弱的闪长玢岩层的限制,补给量微弱,对矿区大部分矿坑充水影响不大。但在矿区东北部和中部地段,受开采时冒落带以及导水裂隙带的影响,对该区域矿坑充水的影响较大。此次研究填补了该矿区深层地下水含水系统研究的空白,为准确预测矿坑涌水量提供理论依据,具有重要的参考价值和现实意义。     

东胜煤田乌拉素矿区水文地质特征及充水因素研究

近年不断发生的突水事故,给煤矿安全生产带来严重威胁,研究矿区水文地质特征,分析矿井充水因素有重要现实意义。根据东胜煤田乌拉素矿区地质勘探和水文地质资料,对煤层开采导水裂隙带高度进行计算,结果表明:直罗组底部、含煤系地层的裂隙承压水含水层和上部煤层采空区内的积水,是煤层开采时矿井涌水的主要充水水源,矿井充水通道有断层裂隙带、封闭不良钻孔、采动导水裂隙带;其中导水裂隙带会将上部煤层采空区积水导通,使充水强度增大,矿坑涌水量增加。建议开采过程中要做到边探边采,探采结合,预防突水问题。     

东刘家金矿矿区地下水动态与均衡分析

东刘家金矿矿区位于海阳市郭城镇,主要发育3组NE向断裂裂隙,含水岩组主要为第四系冲洪积、坡积孔隙含水岩组,碎屑岩类孔隙裂隙含水岩组,碳酸盐岩类岩溶裂隙含水岩组及基岩风化带裂隙含水岩组。文中在查清水文地质条件的情况下,详细分析了矿区含水层的富水性,地下水补给、径流、排泄及动态特征,矿区地下水开发利用现状。在此基础上,进行了地下水均衡计算,地下水补给来源主要为大气降水入渗和农灌入渗补给,补给方式为地表直接下渗补给、断裂带导水补给以及上覆松散层下渗补给,主要排泄方式为人工开采、矿坑涌水和蒸发,总体上矿区处于地下水均衡状态。研究成果为矿区在今后的开采过程中控制地下水,合理防治与排水,维持区域地下水自然动态等提供了科学的依据。。     

基于地下水TDS空间分布特征对矿区涌水来源的识别

滇东北昭通地区某铅锌矿为白云岩溶隙裂隙充水型矿床且紧邻洛泽河,水文地质条件复杂。通过对矿区各个区域地下水电导率检测、分析、识别,结合矿区水文地质特征,得出栖霞茅口组地下水为矿坑涌水主要的水源补给区。矿区地下水主要由北往南大竖井径流排泄,而上部水既有北部来水也有少部分南部的补给,上部水和下部水在北东部石炭系和大竖井一带存在越流补给,帷幕线下部承压水来源可能不同。     

河南朝川矿一井突水因素分析

河南省汝州市朝川矿一井主采煤层二1煤底板隔水层薄、分布不稳定,底板灰岩承压含水层富水性强、水头压力高、补给来源丰富,开采至今已发生数十起突水事故,造成严重的经济损失。研究认为：矿井的主要充水水源为寒武系含水层,导水通道是断层、构造裂隙及采动裂隙,二1煤层底板隔水层仅在局部地段能起到隔水作用;矿井的充水方式主要是大气降水、地表水体通过石炭系和寒武系灰岩露头区渗漏补给,在煤层底板形成水头压力大的承压水而威胁矿井安全的。最后指出,在矿井生产中一定要严格遵守＂预测预报,有采必探,边探边掘,先治后采＂防治水方针。     

奥陶系石灰岩推覆体含水层下煤层开采覆岩破坏特征研究

采用相似模型试验和数值模拟相结合的方式,分析了奥陶系石灰岩推覆体含水层下煤层开采的覆岩破坏及地表沉陷 特征。经验公式计算,相似模型试验和数值模拟的对比分析表明：该特殊地质条件下,不考虑渗流场影响时,垮落带高度 为采厚的2.2~4.5倍,导水裂隙带高度为采厚的14.0~19.1倍;渗流场的存在使导水裂隙带及垮落带高度增加,此时垮采比为 4.8,裂采比为20.6。因此,从偏安全的角度考虑,煤层的实际开采过程应考虑渗流场的影响,以渗流场-应力场耦合作用 下的导水裂隙带高度作为安全煤（岩）柱合理留设的依据。     

云南镇沅浪泥塘金矿水文地质特征

狼泥塘金矿区附近无较大地表水体,岩层富水性弱,地表水对矿坑充水无较大影响.矿区内水位、涌水量变幅较大,区内两条重要容矿构造为导水断层,开拓时应严加防范.     

龙口北皂矿海域下H2106综放面井下导高观测

水体下采煤需要观测采场覆岩导水裂缝带高度(简称导高)。龙口北皂矿海域H2106综放面地表为海水,为了解决地表海水区难以施工导高观测钻孔的技术难题,在井下采用仰斜钻孔与井下导高观测仪进行了导高观测,该方法钻孔工程量小且观测精度高。在H2106综放面共设置3个观测剖面,施工了4个采前对比观测钻孔和8个采后导高观测钻孔,并利用顶板覆岩中泥灰岩含水层开采前后其含水量的变化判断导水裂缝带上限。实测得出H2106综放面导高值为38.8m,导高与采厚比为9.5。对于龙口矿区软弱岩层,导高观测的最佳时段为采后10~20d。      

主成分分析法在判定新立矿井海水渗入中的应用

为了判定新立矿井海水渗入情况,在详细的水文地质调查、取样测试的基础上,应用主成分分析法将7个水质测试指标进行了降维处理,分析了主成分的实际意义,并根据综合主成分指标进行了水样的分类。结果表明,7个指标可以综合为两个主成分,Cl^-,Mg^2＋,Na^＋和SO4^2-四个变量在第一主成分上具有类似的、较高的载荷值,反映海水的浓缩效应,K^＋在第二主成分上显示较高的载荷值,反映离子交换吸附效应;矿坑涌水中K^＋、Na^＋等指标即可反映海水渗入的物理、化学特征,通过涌水水质的监测可以判定海水渗入情况。     

海底金矿矿坑涌水水源判识及演化研究

为查明新立海底金矿浅部裂隙涌水在开采条件下的演化规律,从水文地球化学的角度出发,提出采用主成分分析法和最大似然概率法对裂隙涌水水源及其混合比进行判识和计算,并采用数值模拟法间接验证计算结果的可靠性。研究表明:该方法能够有效识别矿山涌水水端元的组合模型及其变化,计算出可能性最大的端元混合比;新立金矿浅部裂隙涌水端元模型经历了由Ⅰ类基岩水+海底地下水到Ⅰ类基岩水+海底地下水+现代海水的演化过程;海底地下水和现代海水易从采空区两侧肩部进入矿坑,且涌水中海水含量呈现先增加后减小的变化规律。     

Seawater inrush assessment based on hydrochemical analysis enhanced by hierarchy clustering in an undersea goldmine pit,China

Seawater inrush is deadly to undersea mine and it is very important to accurately assess the connectivity between seawater and the mine pit. With Xinli gold mine area as a case study, following the analysis of geological setting, a detailed hydrogeological survey and sampling were conducted and conservative ions test of mine water samples was carried out in the laboratory. Furthermore, the physical significances of ion concentration and ion ratios, such as Cl^?, γSO₄ ^2?/γCl^? and γNa⁺/γCl^?, were checked. The test data analysis, enhanced by the physical significance check and hierarchy clustering analysis, was used to assess the overlying seawater inrush into the mine pit. It was determined that the undersea rock masses in the Xinli mine area bear high-mineralization brine water. The ore-controlling fault gouge and a thin layer of clay in Quaternary block the seepage of overlying seawater into the undersea mine pit to a great extent. The mine water from surrounding rock of the northeast gopher drift is closer to seawater in hydrogeochemical features, which indicates that the connectivity between the northeast of footwall of the ore-controlling fault and seawater is relatively good and should be closely monitored in future production. The mine water from the southwest gopher drift and crosscuts is similar to the brine (salty) water in chemical features, drains the net reserves of brine (salty) water in bedrock fissures and will impose few impacts on production in the near future. This approach is feasible and cost-effective.     

Study of the hydrogeological characteristics and permeability of the Xinli Seabed Gold Mine in Laizhou Bay,Jiaodong Peninsula,China

This paper presents a case study investigation into the hydrogeological characteristics and permeability of rock mass in a seabed mine. Following an introduction to the geology and hydrogeological conditions in the Xinli mine area, we reveal the features of the preferred structural planes, dynamic characteristics of mine water seepage, and the permeability of the fractured rock mass in the pit. The permeability of the pit rock mass shows varied characteristics at different geotectonic locations because of the different degrees to which the structural planes developed. The fractured rock mass generally shows low permeability, and the main composition of water seepage is high-salinity brine. Future large-scale undersea mining may induce rock mass movement, destroy water-resistant layers, and enhance water transmissibility and the probability of water gushing into the pit. Thus, strengthening the quality of the filling mass, protecting the stope roof and the water-resistant layers, as well as regular monitoring of water seepage discharge and identification of water sources are critical to work safety and the prevention of seawater gushing in the mine.     

黄河三角洲浅层地下水盐分来源及咸化过程研究

黄河三角洲地下水咸化已成为区域最突出的生态环境问题之一。识别地下水补给及盐分来源是有效控制和改善地下水咸化问题的关键。本研究采集了研究区浅层地下水、地表水和海水等不同类型水样,利用离子比、Piper三线图、吉布斯图等方法对八大离子浓度、δD和δ¹⁸O 组成、Br和Sr 浓度等进行地下水补给研究与盐分来源辨析。结果表明:(1)黄河三角洲浅层地下水以总溶解性固体(TDS)为338 g/L的咸水为主,地下水水化学类型较为单一,主要为Cl-Na型。(2)三角洲区域地下水以大气降水补给为主,并且在补给过程中经历了不同程度的蒸发作用的影响,黄河现行流路区域地下水主要来源于河水侧渗补给,但浅层地下水含水层水平渗透性较差限制了黄河侧渗补给范围。(3)海洋是黄河三角洲浅层地下水盐分的主要来源,黄河现行流路区域及近岸地下水盐分来源于海水混合,三角洲北部刁口河等古河道区域地下水盐分主要来源于海相蒸发盐淋滤溶解。     

Hydrochemical and isotopic characterisation of groundwaters to define aquifer type and connectivity in a subtropical coastal setting,Fraser Coast,Queensland

Physico-chemical parameters, major ion chemistry and isotope composition of surface and groundwaters were determined in forested coastal catchments and adjacent coastal plains. Results showed obvious characterisation related to physical and hydrological setting, and highly variable spatial differences reflecting the complexities of these areas. All these coastal waters are dominated by Na–Cl and fall on a common dilution line; hydrochemical grouping is largely due to anionic differences (Cl, SO₄ and HCO₃), although Na and Mg ratios also vary. Six major hydrochemical facies were determined. For groundwaters, compositional differences are largely related to aquifer material and level of confinement; for coastal groundwaters important are tidal effects and proximity to the shoreline. Differentiation for surface waters is mainly by drainage morphology, flow regime plus proximity to the coast. Connectivity between water bodies is reflected by minor base flow to catchment streams, including with flood plain wetlands, but mostly occurs in low-lying zones where there is mixing of fresh and saline water within surface water and subterranean estuaries, or by seawater intrusion enhanced by overuse. Oxygen and hydrogen isotopic data for confined and semi-confined groundwaters along the coast indicates local recharge; fresh surface waters in the elevated catchments are shown to be sourced further inland plus have experienced evaporation.     

Cation exchange in a temporally fluctuating thin freshwater lens on top of saline groundwater

In coastal-zone fields with a high groundwater level and sufficient rainfall, freshwater lenses are formed on top of saline or brackish groundwater. The fresh and the saline water meet at shallow depth, where a transition zone is found. This study investigates the mixing zone that is characterized by this salinity change, as well as by cation exchange processes, and which is forced by seepage and by rainfall which varies as a function of time. The processes are first investigated for a one-dimensional (1D) stream tube perpendicular to the interface concerning salt and major cation composition changes. The complex sequence of changes is explained with basic cation exchange theory. It is also possible to show that the sequence of changes is maintained when a two-dimensional field is considered where the upward saline seepage flows to drains. This illustrates that for cation exchange, the horizontal component (dominant for flow of water) has a small impact on the chemical changes in the vertical direction. The flow’s horizontal orientation, parallel to the interface, leads to changes in concentration that are insignificant compared with those that are found perpendicular to the interface, and are accounted for in the 1D flow tube. Near the drains, differences with the 1D considerations are visible, especially in the longer term, exceeding 100 years. The simulations are compared with field data from the Netherlands which reveal similar patterns.     

Groundwater regimes and isotopic studies,Ranger mine area,Northern Territory

Three types of groundwater occur in the area of the Ranger mine. Type A groundwater occurs in the loose sands and gravels occupying the present day stream channels, Type B in the weathering profile and Type C occurs in relatively fresh fractured bedrock occupying open fractures and other cavities. The three types of groundwater can be distinguished both chemically and isotopically. Light stable isotope data suggest that most early rains are lost by evapotranspiration and have no imprint on the groundwater. Later in the wet season, the ground is saturated and groundwater recharge occurs on a regional scale. This younger groundwater sits on the older waters. Mixing is probably minimal as before any large scale mixing could occur, most younger waters are lost by evapotranspiration. Stable isotope data suggest that Type B groundwater in certain areas has some connection with evaporated surface water bodies. Stable isotope measurements for the pollution monitoring bores around the tailings dam do not indicate any connection with the polluted pond waters at the time of sample collection.     

Numerical investigations of fault-induced seawater circulation in the Seferihisar-Bal?ova Geothermal system, western Turkey

The Seferihisar-Bal?ova Geothermal system (SBG), Turkey, is characterized by temperature and hydrochemical anomalies along the faults: thermal waters in northern Bal?ova are heated meteoric freshwater, whereas the hot springs of the southern Seferihisar region have a strong seawater contribution. Previous numerical simulations of fluid flow and heat transport indicated that focused upsurge of hot water in faults induces a convective-like flow motion in surrounding units. Salt transport is fully coupled to thermally driven flow to study whether fault-induced convection cells could be responsible for seawater encroachment in the SBG. Isotope data are presented to support the numerical findings. The results show that fault-induced convection cells generate seawater plumes that extend from the seafloor toward the faults. At fault intersections, seawater mixes with rising hot thermal waters. The resulting saline fluids ascend to the surface along the fault, driven by buoyant forces. In Bal?ova, thick alluvium, minor faults and regional flow prevent ascending salty water from spreading at the surface, whereas the weak recharge flow in the thin alluvium of the southern SBG is not sufficient to flush the ascending hot salty waters. These mechanisms could develop in any faulted geothermal system, with implications for minerals and energy migration in sedimentary basins.     

Br/Cl ratios and O, H, C, and B isotopic constraints on the origin of saline waters from eastern Canada

Saline groundwaters were recovered from undisturbed (Restigouche deposit) and active (Brunswick #12 mine) Zn-Pb volcanogenic massive sulfide deposits in the Bathurst Mining Camp (BMC), northern New Brunswick, Canada. These groundwaters, along with fresh to brackish meteoric ground and surface waters from the BMC, have been analyzed to determine their major, trace element and stable isotopic (O, H, C, and B) compositions. Saline groundwaters (total dissolved solids = 22-45 g/L) are characterized by relatively high Na/Ca ratios compared to brines from the Canadian Shield and low Na/Cl_molar and δ¹¹B isotopic compositions (−2.5‰ to 11.1‰) compared to seawater. Although saline waters from the Canadian Shield commonly have oxygen and hydrogen isotopic compositions that plot to the left of the global meteoric water line, those from the BMC fall close to the water line. Fracture and vein carbonate minerals at the Restigouche deposit have restricted carbon isotopic compositions of around −5‰ to −6‰. The carbon isotopic compositions of the saline waters at the Restigouche deposit (+12‰ δ¹³C_DIC) are the result of fractionation of dissolved inorganic carbon by methanogenesis. We suggest that, unlike previous models for shield brines, the composition of saline waters in the BMC is best explained by prolonged water-rock reaction, with no requirement of precursor seawater. We suggest that elevated Br/Cl ratios of saline waters compared to seawater may be explained by differential uptake of Br and Cl during groundwater evolution through water-rock reaction.