某地下空间承压含水层抽水试验及成果分析

由于地下水突涌风险,地下空间在施工作业中有必要通过抽水试验确定承压含水层的水文地质参数。依据勘察报告的初步评价,基坑开挖15.5m时,场地内第⑦1层承压含水层有可能产生突涌,为确保工程安全施工,需开挖前进行承压含水层抽水试验,取得场地承压含水层水文地质参数及降水引起的沉降特征,为地下空间设计和施工提供可靠依据。本次布设抽水井、观测井、分层沉降标组、孔隙水压力观测孔及地面沉降观测点,依据抽水试验技术要求获取渗透系数、抽水影响半径等相关水文地质参数。最后,针对工程场地内承压水情况及特点进行分析,提出基坑开挖时的承压水降压建议方案。     

基于大口径稳定流抽水试验的基坑降水方案设计

正近年来,随着长江沿线城市基础设施建设步伐的不断加快,基坑深度也在不断增加,高水头承压水深基坑问题亟待解决。在勘察过程中,一般采取大口径多井、群井稳定流抽水试验,获取承压含水层准确的水文地质参数,以防止基坑突涌、管涌等事故的发生,这对基坑的安全建设具有重要意义。本文以江阴—靖江过江通道北岸盾构井工程抽水试验为例,开展多井(一抽多观)与群井(多抽多观)承压水稳定流抽水试验,对基坑底部Ⅱ层承压含水层进行研究,     

基于层间位移协调的承压水降压引起土层变形分析

承压水降压引起的地面沉降由含水层、弱透水层和潜水层的变形组成。当承压层降压时间短、弱透水层固结变形较小时,可以假设弱透水层为严格的隔水层。采用层状弹性体系理论,基于位移协调条件分别建立了单井抽水以及第三类基坑工程降水（隔水帷幕插入降水含水层）引起的土层变形分析模型,与数值模拟和现场抽水试验结果的对比,验证了文中方法的正确性。研究结果表明,上覆土层弹性参数变化对地表变形的影响可以忽略;抽水井附近的土层变形呈现“上小下大”特点,一定距离以外含水层与地面沉降大致相等,根据承压含水层降深要求,可估算出基坑外的水位降深。     

不同地连墙插入深度下承压含水层减压降水对既有隧道的影响

当基坑需进行未截断条件下的承压含水层降水时,承压水抽降产生的影响范围远大于基坑开挖的影响范围,其对基坑外既有隧道的影响值得重视。进行了承压层减压降水对既有盾构隧道影响的有限元仿真模拟,并分析了采用地下连续墙插入承压含水层时,不同插入深度对隧道变形的影响,结果表明：随着地下连续墙插入承压含水层深度的增加,直至完全截断承压含水层,既有隧道沉降逐渐减小,但受地下连续墙变形的影响,隧道在水平方向仍存在较大位移。因此,当既有隧道与减压井净距较小时,即使承压含水层被完全截断,也应重视减压降水对隧道水平方向变形造成的影响。此外,长期减压降水将会引起隧道产生可观的沉降。因此,应尽量避免承压含水层未被完全截断条件下进行长期减压降水。     

承压含水层中非完整井附近“非达西-达西”两区渗流模型近似解析解

抽水井附近由于流速过快往往发生非达西流,而远离抽水井随着流速下降又变为达西流.为了描述这些特征,建立了承压含水层中非完整井附近“非达西-达西”两区渗流模型,即距离抽水井较近的区域由于流速较快假设发生非达西渗流,并利用Izbash公式刻画,而距离抽水井较远由于流速较慢假设仍然满足达西定律,含水层中垂向流速较小也利用达西定律描述.通过线性化近似方法结合Laplace变换和有限Fourier余弦变换对模型进行了求解,分析探讨了该两区模型下水位降深曲线特征.结果表明:抽水初期,非达西渗流区域水位降深与全非达西渗流模型结果吻合,而抽水后期两区模型非达西渗流区域的水位降深与全达西模型水位降深基本一致,但大于全非达西渗流模型的水位降深;抽水初期,两区模型中达西渗流区域的水位降深比全达西渗流模型结果大,但比全非达西渗流模型结果小;对不同时间的水位降深随井距变化曲线分析发现非达西渗流区域水位降深随Izbash公式中的幂指数n增大而减小,而在达西渗流区域水位降深基本不受n值的影响.研究成果对非完整井抽水试验参数反演具有重要理论意义.      

悬挂式止水帷幕深基坑减压降水的简化计算方法

采用悬挂式止水帷幕结合坑内减压降水的墙-井系统可有效减小坑内降水量或坑外水头降深。将基坑按面积相等等效为井壁进水的大直径承压水非完整井,幵令流入井内的水量等于止水帷幕内坑底承压水含水层内的竖直向渗流量,以此建立坑内减压抽水量与坑外承压水头降深的关系式。该理论公式计算结果在止水帷幕插入比大于0.6且基坑半径与承压含水层厚度之比小于2.0时与有限元计算结果比较接近。因未考虑渗流方向变化时的水头损失,数值计算结果和工程案例实测数据均表明理论公式计算结果偏大。利用参数分析研究承压含水层渗透系数各向异性、基坑平面面积、止水帷幕插入长度等因素对减压降水的影响规律。坑内减压抽水量或坑外水头降深与墙-井系统三维渗流场有关,渗流场越接近竖向渗流,坑外水头降深越小,水位接近初始状态。相比数值分析,理论公式简便直观,可用于减压降水的初步分析。     

侧向有限越流承压含水层中非完整井非稳定流模型及解析解

工程建设中当距离抽水井r=rb处水位基本没有变化或不受抽水影响时,或当此处存在止水帷幕时,含水层系统视为侧向有限延伸,rb为有限半径。为此,构建更加符合工程实际的侧向有限延伸的典型弱透水层-承压水层系统中非完整井非稳定流计算模型,同时考虑井径和井储效应的影响,应用Laplace变换和分离变量法得到了水位降深在拉氏空间下的解析解,并应用拉氏数值逆变换Stehfest法得到真实空间下的水位降深。新建立的解析解可以进一步退化为诸多已有解,并进一步将其与已知解和有限元数值解进行对比,验证了所得解的正确性和可靠性。基于新建解重点分析了侧向边界和井的完整性对承压水层水位降深的影响。结果表明:含水层系统的侧向有限边界仅对抽水后期的水位降深影响明显,含水层系统侧向无限延伸情况下的水位降深要大于情形1(在r=rb处为定水头边界)且明显小于情形2(在r=rb处为不透水边界)下的水位降深,rb越小,两者之间的误差越大;抽水井的完整性对整个抽水期间不同情形下的水位降深均有明显的影响,承压含水层顶板处的水位降深随着抽水井滤管的长度和埋深的增加而减小。     

根据流体运动的能量变化计算单井稳定流抽水涌水量

在抽水过程中,如果已知某一降深地下水通过井壁周围岩层的孔隙和裂隙流入井内的速度V、过水断面W,可以求出这一降深的涌水量Q=WV。就如图1所示承压井而言,此承压井含水层厚度为M,井半径为v,水位降深为S,抽水前的稳定水位距含水层底板的距离为H_1,抽水后井内的水位距含水层的底板的距离为H_2,设含水断面的有效孔隙率为n_e(即多孔介质     

地下水回灌技术在浅层承压含水层中的实践与探讨

上海地区承压含水层埋深较深,深基坑围护的止水帷幕难以深入到承压含水层底板进行地下水水平向的完全阻隔,减压降水过程势必对周边环境产生一定影响。以上海盛大国际金融中心深基坑回灌试验为依据,表明人工回灌地下水对控制承压水位具有一定效果,并运用数值方法模拟了不同回灌条件下坑外承压水位的变化。     

抽水井周围饱水介质场三维水位动态观测及地下水流运动特征

利用设计建造的抽水试验装置,采取多项潜水及承压水的抽水试验,获得大量的抽水井周围饱水介质场三维动态观测数据。试验发现：无论是潜水还是承压水状态,抽水井附近观测井的水位变化,均具有距抽水井愈远愈高、愈近愈低的漏斗状分布,抽水井附件的地下水位降落漏斗是显著的;同时发现每个观测井不同高度上的观测点的水位,均呈现上高下低的特征,说明地下水具有由上到下的运动分量,地下水由周边的供水边界向抽水井聚集运移时,运动方向是下斜向的,潜水如此,承压水也如此。分析认为,这是水头压力与水体自身重力同时起作用的结果。由此推断,在抽水时,靠近承压水含水层顶板存在强势水流,且越靠近补给源,这种强势水流越强。     

深基坑承压含水层抽水试验及控制运行研究

为降低深基坑工程设计与施工风险,对东门口站现场实际水文地质情况进行不同工况的抽水试验,取得场地准确水文地质参数(承压含水层)。该抽水试验指导进行基坑突涌性评价和实际工况运行控制情况,为降水运行提供依据对类似工程的设计、施工及风险控制具有借鉴意义。     

长江漫滩抽水试验与水文地质参数计算

长江漫滩地区第四系是一个巨厚的复杂含水体,地下水丰富,对深大基坑施工影响极大。南京梅子洲过江通道连接线及青奥轴线地下交通系统工程位于长江下游漫滩,基坑最大开挖深度为27.5 m。为满足基坑降水设计及施工要求,勘察时选择有代表性的地段布置了3组抽水试验井,对潜水含水层及承压水含水层进行抽水试验,根据试验井类型和边界条件,选用潜水完整井稳定流、承压水完整井稳定流及非稳定流、承压水非完整井稳定流及非稳定流等多种地下水计算模型进行参数计算并综合分析,为设计提供水文地质参数,并实地验证了参数的合理性。     

扬中金源时代购物中心基坑降水数值模拟分析

基坑降水的成功与否,将对基坑开挖和周边环境产生重要影响,因此有必要对基坑降水方案进行评估。针对扬中金源时代购物中心基坑降水问题,采用MIDAS/GTS对基坑降水效果进行研究。首先,依据地勘报告中提供的土体渗透系数,结合单井、双井抽水试验结果,反演出MIDAS/GTS中需要的土层渗流系数和边界函数;然后利用反演得到的参数,建立了考虑回灌井补水效应的三维基坑降水效果分析模型,模拟基坑内水位降深与时间的变化关系,并对基坑降水效果进行分析和评估,以期指导土方开挖工程的施工。     

Physical model test of transparent soil on coupling effect of cut-off wall and pumping wells during foundation pit dewatering

Water level is decreased during foundation pit excavation to avoid water inrush under confined water pressure. Cut-off wall is often used as waterproof curtain to partially cut off the dewatered aquifer. When a foundation pit is located in a built-up area and the underlying confined aquifer is not cut off, the drawdown must be minimized outside the pit to avoid land subsidence in buildings and pipelines. The coupling effect of the cut-off wall and pumping well is used to control the drawdown outside the foundation pit. However, the coupling mechanism is not intuitively well understood because of the limitations of existing experimental methods. In this study, transparent soil was introduced to model the coupling mechanism in the physical model test. High-purity fused silica and mixed paraffin oil were used as skeleton and fluid to simulate the confined aquifer and groundwater. Industrial solid dye and paraffin oil were used as tracers. A camera was used to collect flow information. Tests were performed for the combinations of cut-off wall and partially penetrating pumping wells. The insertion depth ratio of the cut-off wall most effectively influenced the drawdown. The layout of the pumping wells in horizontal direction influenced water level distribution and flow rate. The optimal depth of the pumping wells was 1–5 m above the bottom of the cut-off wall, and the optimal horizontal distance between the cut-off wall and the pumping wells was 25% of the pit width. Non-Darcy flow was observed within the range of 0–10 m around the bottom of the cut-off wall. These results were significant in understanding the cut-off wall and pumping well coupling effect on foundation pit dewatering.

     

Field experiments and numerical simulations of whirlpool foundation pit dewatering

A whirlpool foundation pit is a small-diameter, deep circular pit. Because of its depth and small diameter, a large drawdown is required, and a limited number of wells can be installed inside the pit. During excavation, partially penetrating wells inside and outside the foundation pit have to be installed to lower the water level when the aquifer is too thick. However, partially penetrating wells near partially penetrating curtains cannot be treated by analytical methods. Therefore, it is necessary to use numerical methods to predict dewatering during excavation. Field experiments were performed on whirlpool foundation pit 1880 of Baosteel Group, Shanghai, China, to obtain pumping rates and drawdown, pumping with a single well and two wells in the confined aquifer. The results indicate that the drawdown inside the pit induced by pumping wells outside the foundation pit was small, whereas it was large for pumping wells inside the pit. The pumping wells inside and outside the pit had to be combined to lower the water level. A three-dimensional numerical model was developed to simulate the dewatering process. The hydraulic conductivities of the confined aquifers were inversed by using the pumping tests. Operation schedules were simulated with the corrected model for different combinations of wells inside and outside the pit. The results suggest that different schedules and operation conditions affect drawdown. The monitored results during dewatering indicate that the simulation and field measurements were in agreement. The results can be applied to similar situations.     

杭州庆春路过江隧道江南工作井监测分析

为了避免基坑工程设计和施工中因没有处理好承压水影响而产生的基坑工程事故,以杭州庆春路过江隧道江南工作井为例,对墙体水平位移、地表沉降、地下水位及混凝土支撑轴力进行监测分析,并提出高承压水控制和防治对策。基坑开挖过程监测数据表明：墙体水平位移与基坑平面尺寸密切相关,可通过加强中部支撑刚度,将大尺寸基坑“分隔”成数个较小的基坑,以控制墙体水平位移;地表沉降最大点发生在距离围护结构0.5倍开挖深度处;止水帷幕结合减压降水的措施,可较好地处理承压水问题,基坑下层开挖施工期间,必须保证抽水井持续降水,非正常断电会影响基坑施工安全;第1道支撑的轴力逐渐变小,甚至有可能出现拉力     

Study on Deep Well Dewatering Optimization Design in Deep Foundation Pit and Engineering Application

Based on analyses of the theories of groundwater unsteady flow in deep well dewatering in the deep foundation pit,Theis equations are chosen to calculate and analyze the relationship between wa-ter level drawdown of confined aquifer and dewatering duration.In order to reduce engineering cost and diminish detrimental effect on ambient surrounding,optimization design target function based on the control of confined water drawdown and four restriction requisitions based on the control of safe water level,resistance to throwing up from the bottom of foundation pit,avoiding excessively great subsidence and unequal surface subsidence are proposed.Adeep well dewatering project in the deep foundation pit is optimally designed.The calculated results including confined water level drawdown and surface subsid-ence are in close agreement with the measured results,and the optimization design can effectively control both surface subsidence outside foundation pit and unequal subsidence as a result of dewatering.     

高富水、强透水卵石地层深基坑降水设计与实践

以常德沅江过江隧道江南工作井作为工程实例,通过对周边地层、水文特性的了解分析,从抽水试验、井位布设、抗突涌验算、沉降分析、坑外回灌等各方面进行了初步的分析,对降水相关的各项技术措施进行了梳理,通过工程实践对降水方案的可行性进行了论证,对类似高富水、强透水卵石地层条件下的深基坑降水施工具有一定的借鉴意义。