深层地下水及其可利用性分析

深层地下水是指地质历史时期特定气候条件下形成的、现代补给来源很少、恢复更新速度极其缓慢的地下水。国内外专家对区域大型沉积盆地中的深层地下水的运移机制存在不同的认识,根本的分歧在于是否存在水力连续性。尽管在学术上存在着主张和反对开采深层地下水的争论,但实际情况却是世界上许多干旱国家和地区正在开采或计划开采深层地下水,并且作为主要的供水水源。深层地下水的开采主要是开采其储存量,其可利用限度取决于是否允许消耗其储存量及允许消耗多少储存量。开采战略要么是选择长期开采要么是选择替代解决办法,如果选择前者,那么分阶段、分层位开采并给予其足够恢复、更新的时间是非常必要的。     

地下水资源特性及其合理开发利用

地下水资源具有以下重要特性:兼具可再生性与不可再生性,发育的系统性,以及随时间的变动性。可再生的补给资源,是理论上可持续利用的地下水资源;除了特定情况外,不可再生的储存资源只能借用而不能耗用。地下水资源发育的系统性,要求以含水系统或水文系统、而不是以含水层为单元进行地下水资源评价。由于土地利用方式的改变,地下水资源是随时间而变化的,需要根据变化情况进行再评价。根据可持续发展的理念,地下水资源评价应当遵循供水永续性和生态环境可承载性原则。地下水资源评价需要采用多种方法,相互校核,以提高其成果的信度。最后以河北平原为例,探讨了深层地下水的资源属性以及合理利用地下水的途径。     

停止开采深层地下水 修复与改善生态环境

沧州市水资源短缺，深层地下水严重超采，已形成大面积区域地下水位降落漏斗，地面沉降已达2m，生态环境严重恶化．为保障经济社会的可持续发展，要积极引调地表水，开发利用地下咸水，加强雨洪控制利用，逐步替代最后终止深层地下水的开采。从根本上修复和改善生态环境。     

衡水地区地裂缝空间发育特征与地下水位降深关系

通过浅层地震法及高密度电阻率法物探对河北衡水地区最近发现的3条地裂缝调查,探明了地裂缝地下发育深度、宽度、倾向等,发现地裂缝在地表与地下发育特征有明显不同：地表以一条地裂缝存在,在地下深处则以裂缝带发育,裂缝带两侧裂缝埋深不同,地下裂缝形态表现为上窄下宽。对该地区深层钻探、水文地质和多年地下水开采等资料分析表明,该地区的地裂缝是地质历史时期地质构造活动产物,开采深层地下水等资源则是促使地裂缝发展的主要原因。通过对不同地点地裂缝发育深度与近36年以来地下水水位降深的关系分析,结果显示：不同地区地裂缝发育深度与相应深层地下水水位降深呈线性关系。研究成果对地裂缝机理研究及预防开采深层地下水对地质环境的影响具有指导作用。     

徐州深层地下水开发利用中存在的环境地质问题及成因分析

徐州深层地下水在开发利用过程中,由于开采布局不合理和存在"三集中"(开采层次集中、开采地段集中、开采时间集中)以及水文环境地质条件脆弱等因素,出现了一系列环境地质问题,如地下水位下降、地面塌陷、水质恶化等.分析徐州市深层地下水开发利用中存在的环境地质问题及成因,对徐州市深层地下水合理开采和保护具有一定的指导意义.     

德州深层地下水降落漏斗相关模型建立及其应用

德州市深层地下水,由于长期大量开采,早已形成降落漏斗。作者从漏斗条件的实际出发,利用１７年的地下水动态观测资料,在地下水资源均衡基础上,进行相关分析,建立了相关模型。利用相关模型直接进行不同开采条件下的地下水位预报和限定地下水位条件下的开采量计算。此外,还利用相关模型进行了含水层（组）弹性释水系数和漏斗补给量计算。     

陇东白垩系盆地地下水赋存特征及水资源属性

陇东盆地能源丰富,水资源短缺。盆地深层白垩系地下水来自古地质历史时期,受地质构造、岩性变化影响和控制地下水具有补给不足,径流、排泄不畅、更新缓慢的特点,地下水资源开采以消耗弹性储存量为主。弹性储存量虽然数量很大,但没有后续性补给量,且受开采和环境条件的限制,不可能大量抽取,否则会引起地质环境恶化。认识好白垩系深层地下水资源的固有属性,有助于合理开发利用深层地下水资源。     

Arsenic Distribution Pattern in Different Sources of Drinking Water and their Geological Background in Guanzhong Basin,Shaanxi, China

To study arsenic(As) content and distribution patterns as well as the genesis of different kinds of water, especially the different sources of drinking water in Guanzhong Basin, Shaanxi province, China, 139 water samples were collected at 62 sampling points from wells of different depths, from hot springs, and rivers. The As content of these samples was measured by the intermittent flowhydride generation atomic fluorescence spectrometry method(HG-AFS). The As concentrations in the drinking water in Guanzhong Basin vary greatly(0.00–68.08 μg/L), and the As concentration of groundwater in southern Guanzhong Basin is different from that in the northern Guanzhong Basin. Even within the same location in southern Guanzhong Basin, the As concentrations at different depths vary greatly. As concentration of groundwater from the shallow wells(50 m deep, 0.56–3.87 μg/L) is much lower than from deep wells(110–360 m deep, 19.34–62.91 μg/L), whereas As concentration in water of any depth in northern Guanzhong Basin is 10 μg/L. Southern Guanzhong Basin is a newly discovered high-As groundwater area in China. The high-As groundwater is mainly distributed in areas between the Qinling Mountains and Weihe River; it has only been found at depths ranging from 110 to 360 m in confined aquifers, which store water in the Lishi and Wucheng Loess(Lower and Middle Pleistocene) in the southern Guanzhong Basin. As concentration of hot spring water is 6.47–11.94 μg/L; that of geothermal water between 1000 and 1500 m deep is 43.68–68.08 μg/L. The high-As well water at depths from 110 to 360 m in southern Guanzhong Basin has a very low fluorine(F) value, which is generally 0.10 mg/L. Otherwise, the hot springs of Lintong and Tangyu and the geothermal water in southern Guanzhong Basin have very high F values(8.07–14.96 mg/L). The results indicate that highAs groundwater in depths from 110 to 360 m is unlikely to have a direct relationship with the geothermal water in the same area. As concentration of all reservoirs and rivers(both contaminated and uncontaminated) in the Guanzhong Basin is 10 μg/L. This shows that pollution in the surface water is not the source of the high-As in the southern Guanzhong Basin. The partition boundaries of the high- and low-As groundwater area corresponds to the partition boundaries of the tectonic units in the Guanzhong Basin. This probably indicates that the high-As groundwater areas can be correlated to their geological underpinning and structural framework. In southern Guanzhong Basin, the main sources of drinking water for villages and small towns today are wells between 110–360 m deep. All of their As contents exceed the limit of the Chinese National Standard and the International Standard(10 μg/L) and so local residents should use other sources of clean water that are 50 m deep, instead of deep groundwater(110 to 360 m) for their drinking water supply.     

鲁北平原深层地下水基本特征与水环境问题

鲁北平原因超量开采地下水而引发了诸多水环境问题.本文对其分布规律和演化趋势进行了分析,并提出了对策建议.     

深层地下水SPD人工补给系统

提出了一种新的深层地下水回灌方法———SPD人工补给系统,并通过室内沙槽模拟试验,对该系统和常规的直接井回灌法作了比较。研究表明,利用该系统补给深层地下水,具有回灌水质要求低、补给速度快、补给量多、不易淤堵等特点,是深层地下水人工补给的一条有效的新途径。