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1.
深基坑降水引起的地面沉降给工程和周边环境带来很大的危害,以天津地铁 XX站深基坑为例,通过使用有限差分模拟软件Processing Modflow建立三维地下水渗流场与地面沉降耦合模型,利用抽水试验数据反演识别场区的水文地质参数,对基坑降水对周边环境的影响进行预测。结合施工要求,本着在规定时间内用最少的抽水量完成降水要求,并对基坑周围造成的环境影响最小的原则,对基坑降水进行优化设计。 相似文献
2.
长江三角洲地区深基坑降水复杂,且极易引起地面沉降地质灾害问题,传统的基于地下水动力学原理的解析解模型(Theis公式或Dupuit公式)已难以满足降水设计模拟计算的需要,尤其是无法预测降水引起的地面沉降问题,深基坑降水与地面沉降耦合模型将地下水渗流模型和土体应力-应变模型耦合起来,可根据基坑地下水位的控制要求,同时模拟计算出降水井的布局、各井的开采量和地面沉降量。据此确定出的基坑降水方案既能满足地下水位的控制要求,又能对降水引起的地面沉降进行最优化控制。 相似文献
3.
Shujun Ye Yue Luo Jichun Wu Xuexin Yan Hanmei Wang Xun Jiao Pietro Teatini 《Hydrogeology Journal》2016,24(3):695-709
Shanghai, in China, has experienced two periods of rapid land subsidence mainly caused by groundwater exploitation related to economic and population growth. The first period occurred during 1956–1965 and was characterized by an average land subsidence rate of 83 mm/yr, and the second period occurred during 1990–1998 with an average subsidence rate of 16 mm/yr. Owing to the establishment of monitoring networks for groundwater levels and land subsidence, a valuable dataset has been collected since the 1960s and used to develop regional land subsidence models applied to manage groundwater resources and mitigate land subsidence. The previous geomechanical modeling approaches to simulate land subsidence were based on one-dimensional (1D) vertical stress and deformation. In this study, a numerical model of land subsidence is developed to simulate explicitly coupled three-dimensional (3D) groundwater flow and 3D aquifer-system displacements in downtown Shanghai from 30 December 1979 to 30 December 1995. The model is calibrated using piezometric, geodetic-leveling, and borehole extensometer measurements made during the 16-year simulation period. The 3D model satisfactorily reproduces the measured piezometric and deformation observations. For the first time, the capability exists to provide some preliminary estimations on the horizontal displacement field associated with the well-known land subsidence in Shanghai and for which no measurements are available. The simulated horizontal displacements peak at 11 mm, i.e. less than 10 % of the simulated maximum land subsidence, and seems too small to seriously damage infrastructure such as the subways (metro lines) in the center area of Shanghai. 相似文献
4.
In terms of controlling groundwater in deep foundation pit projects, the usual methods include increasing the curtain depth, reducing the amount of pumped groundwater, and implementing integrated control, in order to reduce the drawdown and land subsidence outside pits. In dewatering design for confined water, factors including drawdown requirements, the thickness of aquifers, the depth of dewatering wells and the depth of cutoff curtains have to be considered comprehensively and numerical simulations are generally conducted for calculation and analysis. Longyang Road Station on Shanghai Metro Line 18 is taken as the case study subject in this paper, a groundwater seepage model is developed according to the on-site engineering geological conditions and hydrogeological conditions, the excavation depth of the foundation pit as well as the design depth of the enclosure, hydrogeological parameters are determined via the pumping test, and the foundation pit dewatering is simulated by means of the three-dimensional finite difference method, which produces numerical results that consistent with real monitoring data as to the groundwater table. Besides, the drawdown and the land subsidence both inside and outside the pit caused by foundation pit dewatering are calculated and analyzed for various curtain depths. This study reveals that the drawdown and the land subsidence change faster near the curtain with the increase in the curtain depth, and the gradient of drawdown and land subsidence changes dwindles beyond certain depths. In this project, the curtain depth of 47/49 m is adopted, and a drawdown-land subsidence verification test is completed given hanging curtains before the excavation. The result turns out that the real measurements basically match the calculation results from the numerical simulation, and by increasing the depth of curtains, the land subsidence resulting from dewatering is effectively controlled. 相似文献
5.
In terms of controlling groundwater in deep foundation pit projects, the usual methods include increasing the curtain depth, reducing the amount of pumped groundwater, and implementing integrated control, in order to reduce the drawdown and land subsidence outside pits. In dewatering design for confined water, factors including drawdown requirements, the thickness of aquifers, the depth of dewatering wells and the depth of cutoff curtains have to be considered comprehensively and numerical simulations are generally conducted for calculation and analysis. Longyang Road Station on Shanghai Metro Line 18 is taken as the case study subject in this paper, a groundwater seepage model is developed according to the on-site engineering geological conditions and hydrogeological conditions, the excavation depth of the foundation pit as well as the design depth of the enclosure, hydrogeological parameters are determined via the pumping test, and the foundation pit dewatering is simulated by means of the three-dimensional finite difference method, which produces numerical results that consistent with real monitoring data as to the groundwater table. Besides, the drawdown and the land subsidence both inside and outside the pit caused by foundation pit dewatering are calculated and analyzed for various curtain depths. This study reveals that the drawdown and the land subsidence change faster near the curtain with the increase in the curtain depth, and the gradient of drawdown and land subsidence changes dwindles beyond certain depths. In this project, the curtain depth of 47/49 m is adopted, and a drawdown-land subsidence verification test is completed given hanging curtains before the excavation. The result turns out that the real measurements basically match the calculation results from the numerical simulation, and by increasing the depth of curtains, the land subsidence resulting from dewatering is effectively controlled. 相似文献
6.
Ye-Shuang Xu Huai-Na Wu Bruce Zhi-Feng Wang Tian-Liang Yang 《Environmental Earth Sciences》2017,76(9):351
Foundation dewatering has become a major cause of land subsidence in Shanghai. The burial depth of foundations in relation to geotechnical construction works is less than 75 m, and the corresponding groundwater includes phreatic, low-pressure artesian, and the first confined aquifers. Based on the geological and hydrogeological conditions beneath Shanghai, methods of dewatering may be divided into three modes and further five patterns according to the insertion depth of the dewatering-retaining system. The most common dewatering mode aims to reduce the water pressure in the confined aquifer by setting the dewatering wells inside the pit, whilst the retaining walls are buried in the confined aquifer and partially cut off the confined aquifer layer. To predict the settlement due to foundation dewatering, numerical models are generally adopted, which are similar to those used to predict land subsidence induced by regional groundwater withdrawal; however, since foundation dewatering is conducted along with the setting of retaining walls and foundation pit excavation, which differs from regional groundwater withdrawal, interactions between the retaining wall-dewatering well, the dewatering-excavation, and dewatering-recharge are important factors affecting the analytical model. Since the grading of the shallow soil layers is different, stratified settlement characteristics of the shallow soil strata and seepage erosion, which results in additional deformation, need to be given particular consideration. 相似文献
7.
Nguyen Cao Don Nguyen Thi Minh Hang Hiroyuki Araki Hiroyuki Yamanishi Kenichi Koga 《Environmental Geology》2006,49(4):601-609
A sinking of the land surface due to the pumping of groundwater has long been recognized as an environmental issue in the
Shiroishi plain of Saga, Japan. Land subsidence can have several negative economic and social implications such as changes
in groundwater and surface water flow patterns, restrictions on pumping in land subsidence prone areas, localized flooding,
failure of well casings as well as shearing of structures. To minimize such an environmental effect, groundwater management
should be considered in this area. In this study, a new integrated numerical model that integrates a three-dimensional numerical
groundwater flow model coupled with a one-dimensional soil consolidation model and a groundwater optimization model was developed
to simulate groundwater movement, to predict ground settlement and to search for optimal safe yield of groundwater without
violating physical, environmental and socio-economic constraints. It is found that groundwater levels in the aquifers greatly
vary from season to season in response to the varying climatic and pumping conditions. Consequently, land subsidence has occurred
rapidly throughout the area with the Shiroishi plain being the most prone. The predicted optimal safe yield of the pumping
amount is about 5 million m3. The study also suggests that pumping with this optimal amount will minimize the rate of land subsidence over the entire
area.
An erratum to this article can be found at 相似文献
8.
天津市地下水流-地面沉降耦合模型 总被引:6,自引:0,他引:6
天津市平原区地面沉降主要由地下水大量开采引起,影响范围广、危害大,已成为天津市主要的环境地质问题。分析了研究区的水文地质条件,结合地下水开发利用状况,将研究区概化为6个含水层组,地下水流考虑三维非稳定流,地面沉降选用一维固结压缩模型,运用地下水流模型Modflow 2005和地面沉降模拟模块 Sub,建立了天津市平原区地下水流-地面沉降数值耦合模型,模型面积为1.1×104 km2,利用1998-2008年地下水位等值线、过程线、地面沉降过程线等资料对模型进行了识别。模拟期的地下水均衡分析表明,在多年开采条件下,越流补给、压缩释水、侧向边界流入分别占深层含水层补给量的41.84%、32.15%和24.17%。将调试后的模型应用于南水北调实施后地下水控采条件下的地面沉降趋势预测,显示出停采或减少地下水的开采,有利于减缓地面沉降下降速度,且表现出开采层位越往下,地面沉降恢复难度越大的变化趋势。 相似文献
9.
Nguyen Cao Don Hiroyuki Araki Hiroyuki Yamanishi Kenichi Koga 《Environmental Geology》2005,47(3):361-374
In coastal lowland plains, increased water demand on a limited water resource has resulted in declining groundwater levels, land subsidence and saltwater encroachment. In southwestern Kyushu, Japan, a sinking of the land surface due to over pumping of groundwater has long been recognized as a problem in the Shiroishi lowland plain. In this paper, an integrated model was established for the Shiroishi site using the modular finite difference groundwater flow model, MODFLOW, by McDonald and Harbaugh (1988) and the modular three-dimensional finite difference groundwater solute transport model, MT3D, by Zheng (1990) to simulate groundwater flow hydraulics, land subsidence, and solute transport in the alluvial lowland plain. Firstly, problems associated with these groundwater resources were discussed and then the established model was applied. The simulated results show that subsidence rapidly occurs throughout the area with the central prone in the center part of the plain. Moreover, seawater intrusion would be expected along the coast if the current rates of groundwater exploitation continue. Sensitivity analysis indicates that certain hydrogeologic parameters such as an inelastic storage coefficient of soil layers significantly contribute effects to both the rate and magnitude of consolidation. Monitoring the present salinization process is useful in determining possible threats to fresh groundwater supplies in the near future. In addition, the integrated numerical model is capable of simulating the regional trend of potentiometric levels, land subsidence and salt concentration. The study also suggests that during years of reduced surface-water availability, reduction of demand, increase in irrigation efficiency and the utilization of water exported from nearby basins are thought to be necessary for future development of the region to alleviate the effects due to pumping. 相似文献
10.
由于地裂缝研究及地表变形监测技术(例如GPS,InSAR等)的快速发展,抽取地下水引起的地层水平位移受到关注。传统区域地面沉降模型虽然求解快速但不能模拟水平位移;比奥模型虽然能够模拟土体的三维变形,但模型求解的计算量较大,较少应用于大尺度的区域地面沉降数值模拟。为解决以上问题,推导了解耦三维地面沉降数学模型,模型推导过程显示:比奥模型假设法向总应力和不变,则可简化为解耦三维地面沉降模型;解耦三维地面沉降模型假设土体仅有垂向一维变形,则可简化为传统区域地面沉降模型。同时通过数值试验验证了解耦三维地面沉降模型可以作为比奥模型的替代模型和传统区域地面沉降模型的改进模型,用来模拟抽取地下水引起的三维区域地面沉降。 相似文献
11.
The Characteristics and Causes of Land Subsidence in Tanggu Based on the GPS Survey System and Numerical Simulation 总被引:1,自引:0,他引:1
Land subsidence is a severe hazard threatening Tanggu, a flat lowland area, and evidences of land subsidence can be seen throughout the city. A new reasonable GPS network was set up in this area from 2008 to 2010. The monitoring data show that land subsidence was serious and two main subsidence cones were obviously formed in the region. One emerged at Hujiayuan, with the maximum rate reaching 60 mm/a, and the influence region enlarged prominently from 2005 to 2010. The other one occurred at Kaifaqu, which became obvious only after 2005, and it showed a decreasing tendency with time. To analyze the causes of ground settlement, a correlation between groundwater withdrawal and land subsidence was firstly made. The results confirmed that over-exploitation of groundwater was the major cause for the severe settlement in Hujiayuan. Meanwhile, the subsidence of Kaifaqu was also related to groundwater withdrawal before 2005. However, the relationship became unconspicuous after 2005. To find the cause of this abnormity, a three-dimensional finite element numerical model, coupled with groundwater flow and subsidence, was built. The simulation results indicate that the subsidence induced by high-rise buildings is serious, but the affected range is limited and it also shows a decreasing trend with time, corresponding to the subsidence characteristics at Kaifaqu. Therefore, more attention should be paid to this hazard induced by engineering construction besides groundwater withdrawal, as more high-rise buildings are under construction in Tanggu. 相似文献
12.
Numerical simulation of land subsidence induced by groundwater overexploitation in Su-Xi-Chang area,China 总被引:2,自引:0,他引:2
Ji-Chun Wu Xiao-Qing Shi Shu-Jun Ye Yu-Qun Xue Yun Zhang Jun Yu 《Environmental Geology》2009,57(6):1409-1421
Su-Xi-Chang area is one of the typical regions in China which suffers from severe land subsidence. Various field monitoring
records were integrated to study the characteristics and mechanisms of land subsidence in this region. The development of
the land subsidence in this region shows a tight spatial and temporal correlation with the groundwater pumping. Based on the
analysis of the field data, it is found that the deformation patterns of the hydrogeologic units are greatly related to the
hydrogeologic properties and groundwater level variations. Some have an elastic behavior, others may have an elastic–plastic
rheology. Hence, a 3D finite element numerical model considering the rheological properties of the soil was developed to simulate
the groundwater level and land subsidence. Both hydraulic conductivity and specific storage were expected to vary with the
porosity during the process of consolidation. Multiscale finite element method (MsFEM) was applied to solve the model during
the period from 1996 to 2004. After calibrating the model with the observed groundwater level and subsidence data, the parameters
of the multi-layers system were estimated. The calibrated model outputs fit reasonably well with the observed data. Consequently
the model can be applied to predict groundwater level and land subsidence in future pumping scenarios. The model predictive
results show that land subsidence rate can be controlled and even rebound may occur after the implementation of the groundwater
exploitation prohibition.
Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. 相似文献
13.
苏北沿海三市三维地下水流数值模拟 总被引:1,自引:0,他引:1
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。 相似文献
14.
为了精确模拟预测松散沉积层中深基坑降水引起的地下水渗流场和地面沉降的变化特征,考虑土体孔隙度、渗透系数、储水率随地下水位下降发生的动态变化,建立了深基坑降水三维变参数非稳定渗流与太沙基一维固结理论的地面沉降耦合模型,并采用有限元数值分析方法对模型进行求解。以南京地铁三号线浦珠路站深基坑降水为例进行模拟计算。结果表明:采用15口坑内抽水井,抽水井过滤器埋深为22.0~37.0 m,基坑围护连续墙底部埋深至41.5 m为最优降水方案;不仅使基坑内地下水位满足开挖要求,又使基坑外地面沉降在控制范围内。经验证,所建立的模型合理,计算结果可靠,研究理论用于模拟预测此类地区深基坑降水引起的地下水流场变化具有较高的可信度。 相似文献
15.
Characteristics of groundwater flow field after land creation engineering in the hilly and gully area of the Loess Plateau 总被引:1,自引:0,他引:1
Xiaoxi Yin Luwang Chen Jiandong He Xiaoqing Feng Wen Zeng 《Arabian Journal of Geosciences》2016,9(14):646
In order to study the degree of influence and control mechanism to groundwater flow field caused by land creation engineering in the hilly and gully area of the Loess Plateau, based on the geological and engineering conditions of the first stage project of Yan’an new district in China, numerical simulation of groundwater flow is carried out by the Feflow and GIS technologies. From the simulation, punning measure relatively reduces infiltration recharge and artificial gravel drain increases groundwater seepage. The basic characteristics of groundwater flow field is controlled by the old and new topographies in the whole study area, and artificial gravel drain plays an auxiliary role in accelerating groundwater drawdown upstream and promotes groundwater rise downstream. According to differences of groundwater level and declining percentages of hydraulic gradient in the main and secondary gullies, dewatering of artificial gravel drain in the secondary gully is more effective than that in the main gully, which will yet play an important role in the future. The study results will make contributions to understand groundwater response to land creation engineering and will be beneficial to take necessary measures to prevent collapse of loess and failure of building foundation in the hilly and gully area of the Loess Plateau. 相似文献
16.
Xiaoqing Shi Jichun Wu Shujun Ye Yun Zhang Yuqun Xue Zixin Wei Qinfen Li Jun Yu 《Engineering Geology》2008,100(1-2):27-42
Su-Xi-Chang area and Shanghai City, located in the south of Yangtze Delta, China, has subsided due to groundwater overpumping. Because of the regional scale of the groundwater exploitation, cone of depression and land subsidence at present, Su-Xi-Chang area and Shanghai City are treated as a single area for land subsidence study to avoid the uncertainty of boundary condition due to the regionalism. The characteristics of aquifer system compaction are complex because of the difference in the types, compositions and structures of the soils that the hydrostratigraphic units are composed of, and in the histories of groundwater level change the hydrostratigraphic units have experienced. Considering the fact that different hydrostratigraphic units have different kinds of deformation and that an identical unit may also present different deformation characteristics, such as elasticity, elasto-plasticity, and visco-elasto-plasticity, at different sites of the cone of depression or in different periods, corresponding constitutive laws have been adopted. This avoids the shortcomings of the previous research that the same constitutive law was adopted in all the hydrostratigraphic units during the entire time period. A coupled flow and subsidence model, which includes a three-dimensional flow model with variable coefficients and a one-dimensional (vertical) subsidence model, is built according to the complicated hydrological condition in the region. The simulation model is calibrated using observed data, which include compression of individual strata from groups of extensometers and groundwater levels from observation wells from 1995 to 2002. The model reproduced that the primary subsidence layer in Shanghai shifts from the shallow aquitard to the fourth confined aquifer because of the groundwater yield variations and the change of exploitation aquifers. However the third aquitard was the primary subsidence layer in Su-Xi-Chang area and the compaction deformation of the sandy aquifers was remarkable. The simulation results could provide some reasonable advice about groundwater exploitation in the future. 相似文献
17.
冀东铁矿田赋存在太古界单塔子群白庙子组中,资源量(332+333)为25亿 t,平均品位〉30%,是我国重要的铁矿基地。矿区位于滦河冲洪积扇中上部,矿体上覆第四系砂砾卵石含水层富水性强,水量丰富,属于大水矿床,矿床疏干排水困难,疏干排水将破坏地下水环境。本文在分析矿区水文地质条件的基础上,提出了具有密切水力联系的多层含水层系统的水文地质概念模型,并建立了刻画多层含水层系统的数值仿真模拟模型,基于预留隔水顶板井下充填法采矿,预测矿山开采地下水流场演变,评价了矿山开采对区域地下水环境的影响,提出了环境保护措施,对今后矿山开发过程中的地下水环境影响评价方法、地下水资源开发利用及环保管理决策具有重要意义。 相似文献
18.
基于地面沉降控制的区域性松散沉积层地下水可采资源规划评价 总被引:1,自引:0,他引:1
付延玲 《吉林大学学报(地球科学版)》2012,42(2):476-484
为了满足区域性松散沉积层地区地面沉降的防控要求,规划评价地下水的可采资源量,根据渗流理论和土力学理论,建立了地下水三维非稳定渗流与地面沉降耦合数学模型,并考虑了含水层孔隙度、渗透系数、储水率随含水层发生固结沉降的变化特征。采用三维有限元数值分析方法,以江苏省南通市地下水开采为例,基于地面沉降的控制要求,规划评价出了各乡镇各含水层的地下水可采资源量。结果表明:地下水开采布局科学规划后,总的可采资源量为17 870.56×104 m3/a,较现状开采量10 902.32×104 m3/a有较大幅度的增加。地下水三维变参数非稳定流与地面沉降耦合模型可以更加精确地刻画三维水文地质体的特征,更加符合实际情况。 相似文献
19.
本文在系统分析苏锡常地区地下水开采与地面沉降发展动态及相互关系的基础上,从“区域分解”的思想出发,将研究区按第四纪土层结构进行了合理分区,并分别在各亚区建立地面沉降量与地下水水位相关预测模型。实践表明,该模型符合现阶段苏锡常地区地面沉降研究现状,具有一定的实用价值。 相似文献
20.
针对地下空间开发中深基坑减压降水地面沉降发育特征、沉降机制及防治对策等研究进展,以上海市为例,总结了近年来滨海地区深基坑减压降水地面沉降研究取得的主要成果。建立了深基坑减压降水地面沉降防治综合分区方法,探索了深基坑减压降水地面沉降防治原型试验设计方法,掌握了上海市浅部承压含水层深基坑减压降水地面沉降规律,提出了深基坑减压降水地面沉降-地下水位双控模式及控制指标,提出了深基坑减压降水地面沉降防治措施,构建了深基坑减压降水地面沉降管控体系。这些研究成果在特大型城市安全管理、重大市政工程建设及运营服务中得到应用,对同类地区地面沉降研究和防治工作具有借鉴意义。 相似文献