我国地面沉降若干问题研究

摘要：地面沉降主要有（1）主要由过量开采地下水引起的和（2）在新构造活动构造沉降的基础上，由开采地下水、油气、地下热水形成的地面沉降两种类型。不仅不同的土层有不同的变形特点，在不同地点的同一层土也有不同的变形特点。同一地点同一层土在不同时期的变形特点也不尽相同。建立数学模型时要根据土层实际变形特点分别建立相应的模型，才能模拟出真实的地面沉降情况。解决耦合问题和垂向、水平向尺度不同带来的困难也是正确模拟必不可少的。     

苏锡常地区地面沉降及其若干问题探讨

地面沉降是苏锡常地区当前面临的最大地质灾害问题。本区的地面沉降具有两个特点:一是在时空上与 地下水开采密切相关;二是其形成主要为含水砂层的压密和顶、底板粘性土层的固结。针对地面沉降的研究多从 其宏观力学特性、水土耦合和建模等方面着手,而对土体在沉降变形过程中的结构变化研究不多,因而对土体在沉 降变形过程中的可逆和不可逆、非线性变形、弱透水层变形等的机理,还存在许多模糊认识。对此文章提出了相关 建议,主要包括:1)应系统地研究苏锡常地区第四纪土体各土层的细观和微观结构,弄清地面沉降区土体结构的演 化规律及其与抽、灌地下水、土体物性指标等之间的关系,建立土体沉降类型与土体结构演化之间的关系;2)应对 第四纪土体中的弱透水层开展系统研究;3)应从土体结构的角度,深入研究土体在排水和回灌过程中的可逆和不 可逆变形。     

江苏省徐州市睢宁县城区地面沉降稳定性分析与评价

根据江苏省徐州市睢宁县城区内可压缩土层的类型、空间分布特点及压缩变形等特征,建立了本区地面沉降计算地质模型。利用该模型计算出城区2013年累计地面沉降量3.08~380.60 mm,平均为162.41 mm,最大沉降量发生在城区西北部,该区域可压缩土层、黏性土的累计厚度大,地下水水位下降幅度较大。根据预测2030年地下水位埋深条件,采用地面沉降地质模型计算得出城区累计地面沉降量,在此基础上对区内地面沉降危险性进行分区,从而为地下水开采总量的控制及地面沉降监测控制提供相关建议措施,以避免城区2030年后地面沉降地质灾害逐步发展为特大型地质灾害。     

华北平原地下水位驱动下的地面沉降现状与研究展望

华北平原年地面沉降量大于50 mm的严重区面积超过全国总量的80%,防治形势严峻,需要开展有针对性的研究,为有效防控地面沉降提供科学依据。华北平原建立了较完善的地面沉降监测网络,基本掌握了地面沉降现状及演化规律,但受华北平原含水层系统影响因素复杂与时空变化大等因素制约,对地下水位变化驱动下的土层变形特征及其机制研究迄今仍比较薄弱,限制了对地面沉降发展趋势的科学研判和预测预警。在总结国内外地面沉降研究进展、基于高时空分辨率监测数据分析华北平原地面沉降现状和发展趋势的基础上,提出了地下水位变化影响下的地面沉降研究方向。目前,华北平原地面沉降出现减缓态势,天津、沧州、衡水等重点城市主城区地面沉降得到有效控制,但华北平原尤其是河北平原地面沉降总体上仍然处于较快发展阶段,主要原因是农业灌区地下水开采得不到有效控制。未来华北平原地面沉降研究应聚焦地面沉降机理和预测预警、地下水位回升驱动下的土层变形规律及其对环境的影响、地面沉降区地下水资源属性及地热开发与地面沉降关系等方面。     

基于DFOS的排灌水条件下土体变形响应模型试验研究

黏土层和砂土层交替变化的多层土体在强烈开采地下水作用下极易产生压密固结而引发地面沉降灾害。本文针对含水层释水引起地面沉降问题,研制了地面沉降试验装置,进行了排灌水条件下含水层系统的沉降及回弹试验。采用分布式光纤感测技术对土体内部应变分布及含水率变化进行耦合监测,并分析了各分层对水位变化的响应特征。结果表明:黏土层和砂土层均表现出了排水压缩和灌水回弹特点,黏土层变形较砂土层明显。各层变形与含水率变化具有良好的对应关系,表现为砂土层变形和含水率变化基本同步,而黏土层变形略微滞后于含水率变化。黏性土压缩曲线具有明显的分段特征,排水时当含水率低于液限后迅速减小,黏土层压缩速率明显加快;回灌时当含水率高于液限后,回弹速率明显加快。试验结果对研究地面沉降机理、评价地面沉降潜力及地下水利用具有重要意义。     

华北平原典型地段地面沉降演化特征与机理研究

华北平原是世界上最大的地下水系统之一,地面沉降问题突出。由于沉积环境变化多样、地质条件差异性显著和人类开采活动强烈,使得该地区地面沉降成因机理复杂。本文采用卫星对地观测技术与传统手段相结合,监测地面沉降灾变过程,分析华北平原地面沉降发展历史和现状。结合应力-应变图解法及土工实验研究地面沉降差异性特征及滞后变形成因机理。取得了以下关键认识:(1)华北平原地面沉降空间分布差异性明显,沉降主要分布在平原区第四纪沉积凹陷,呈现东西分带、南北分段特点。地面沉降空间发展部分受到北东向和北西向构造控制。在沧县隆起区,地面沉降也比较发育,主要原因是沧县隆起在第四纪时期构造运动相对不活跃,沉积了较厚的第四系;存在与构造走向一致的3期古河道,该地区赋存丰富的地下水资源并被大量开采。(2)地面沉降发生发展与地下水开采历史密切相关,沉降主要压缩贡献层随地下水开采层位变化而变化。北京平原100 m以深地层对地面沉降贡献呈增加趋势。天津平原目前地面沉降的主要贡献层来自300 m以下地层。(3)气候干旱导致地下水补给量减少,同时增加了地下水的开采,因而是引起地面沉降的重要间接驱动因素。高层建筑荷载、基坑降排水、地热开采对地面沉降的影响应引起足够重视。(4)地面沉降具有很强的滞后性,最大滞后时间可达25年。除了渗透固结成因以外,土体蠕变是另外一个重要原因。更新世地层在不同荷载下,蠕变特征明显。沧县隆起晚更新世地层次固结可达到总变形28.3%。(5)土的物理性质、地下水位变化模式对土层变形特征具有重要影响。不同埋深地层在地下水位变化条件下的变形特征存在较大的差异(弹性、黏弹性、黏弹塑性)。浅部含水组呈现以弹性为主的变形特征。     

北京平原区现阶段主要沉降层位与土层变形特征

超量开采地下水引发的地面沉降已成为北京平原区最主要的地质灾害之一.精准识别现阶段地面沉降主要贡献层位,查明不同水位变化模式下土层变形特征,对实现地面沉降精准防控,建立合适的地下水-地面沉降模型具有重要意义.本文根据北京市7个地面沉降监测站内分层标和水位近十几年观测资料,对不同深度土层沉降变化特征和主要沉降层位进行了精准...     

基于情景分析的天津市滨海新区地面沉降预测

鉴于地面沉降演化的地质系统渐变性特征,从主要致灾因子考虑建立地面沉降数值模型。设计3种地下水开采情景,编译计算机程序预测地下水位动态变化过程中的地面沉降值。至2020年,在最不利、适中和最理想3种情景下天津市滨海新区最大累计沉降量分别达640 mm、520 mm和150mm;全区平均累计沉降量分别达268 mm、177 mm和95 mm。     

Characterization of land subsidence induced by groundwater withdrawals in Su-Xi-Chang area, China

Su-Xi-Chang area is one of the typical regions in China which suffers from severe land subsidence. Various tools of field monitoring were integrated to study the characteristics and mechanisms of land subsidence in this region. The occurrence and the development of the land subsidence in this region are strongly related to the groundwater pumping both in time and space. The main consolidation layers are the soft mud layers; however, the compressibility of the confined sandy layers should not be ignored. The second and third confined aquifers contributed more than 30% of total subsidence. Meanwhile, irrecoverable deformations were also observed in the sandy layers. Different sandy layers deform diversely under different stress conditions. Some have the elastic feature. But the soil strata, including both sandy layers and clayey layers, located in the center of the groundwater level depression cone exhibited obvious viscous mechanical behavior which caused the common lag phenomenon. The sand composition (mingled with small clay particles or interbeds) and sand rheology are the two main reasons for the lag phenomena in sandy layers. A series of laboratory tests for modeling the effective stress changes due to groundwater withdrawals, were conducted to investigate the mechanism of the lag phenomenon. Based on the test results, the relationship of stress–strain–time for saturated sands is obtained; and it could be expressed as power functions. The results also showed that the compression of the sandy layers was time dependent, and its deformation could be remarkable. When establishing land subsidence model, the deformation for the similar soil formation could be elastic, visco-elastic and even visco-elastic–plastic, because of the different groundwater level fluctuation experienced.     

基坑抽水引起周围地面沉降机理及防治措施

抽水引起周围地面沉降和构筑物地基沉降已成为工程建设中的一个环境灾害问题。根据抽水引起周围地面沉降的机理分析,提出了由抽水引起地下水水头压力变化、含水层颗粒迁移、含水层压缩和水体的膨胀的更具普遍意义的地下水运动方程,该方程可以简化成Biot和Helm的地下水运动方程。在此基础上,通过实例分析和方案对比,提出了抽水引起周围地面沉降的防治措施,并分析了各种措施的适用范围及优缺点。     

北京平原区地面沉降分布特征及影响因素

地面沉降是北京平原区主要地质灾害之一。文中采用永久散射体差分干涉测量(PS-InSAR)技术获取平原区地面沉降空间分布特征,基于GIS空间分析平台,将多种地面沉降影响因素分别与PS-InSAR获取的地面沉降场形变信息进行耦合研究,查明地面沉降与多种影响因素之间的响应关系。研究发现:(1)北京市地面沉降发育较为严重的地区主要出现在平原区东部、北部以及南部等地,存在多个沉降中心,最大沉降速率达到152mm/a,区域不均匀沉降现象明显,并且有连成一片的趋势。(2)地面沉降分布具有明显的构造控制特性,沉降区多位于几大活动断裂交接部位的沉积凹陷地区,与第四纪沉积凹陷十分吻合。地面沉降的发展趋势与活动断裂的走向具有明显的对应关系,在有活动断裂通过的区域,地面沉降剖面线上表现出明显的转折或突变,断裂两侧区域不均匀沉降十分明显。(3)地面沉降分层沉降量与对应层位上黏性土占比呈正比例关系,其空间分布特征及变化趋势与平原区的地层结构及可压缩黏性土层厚度具有很好的一致性,沉降范围整体由北西向的单一结构区向南东方向的多层结构区扩张。沉降速率大于50 mm/a的沉降区大多分布在黏性土层厚度大于100 m的地区,几大沉降中心与黏性土层厚度较大地区吻合较好。(4)第二承压含水层(顶底板埋深100~180 m)地下水开采对地面沉降影响最大,沉降中心与该层位地下水位降落漏斗区高度吻合,是地面沉降的主要贡献层位。     

古潜山热储开发对地面沉降的影响机制研究

古潜山是中国水热型地热的主要富集区,具有分布广、潜力大、开发利用条件好等特点,同时也是中国地面沉降相对严重的地区。廓清古潜山区地面沉降的影响机制是区域地下水资源以及地热资源的合理规划与开发利用的基础。本文从地面沉降的机理出发,以雄安新区为例,从第四系厚度、黏性土含量、水位变化、土体固结性、地下水的越流补给以及地下水开采量6个方面分析了对地面沉降的影响,认为雄安新区地面沉降的发生主要受第四纪地层中地下水的超采和砂岩热储的采灌不均衡两个因素的影响,其中地下水超采是地面沉降的主要因素,砂岩热储层的无序开发是诱发地面沉降的次要因素,碳酸盐岩热储的开发尽管会造成热储压力的下降,但受碳酸盐岩压缩性能的影响储层不会产生明显的压缩变形。研究结果可以为新区地面沉降的防治及能源规划提供支撑。     

天津市地下水开采对地面沉降影响的多元回归分析

地下水的过量开采是天津市引起地面沉降的主要原因。因此天津市提出了“压缩地下水开采量”、“地下水人工回灌”、“调整地下水开采层次”等控制地面沉降的3大技术措施。经过多年的努力,控制地面沉降效果明显。如何解决地下水开发与控制地面沉降的关系,更好的贯彻这3大技术措施,是该文编写的初衷。即在开采同样地下水量的情况下,如何使地面沉降量最小;或在地面沉降量容许的情况下,如何开采最大量的地下水。压缩地下水开采量是治理地面沉降的根本措施,亦即如何压缩采水量或调整开采层次会达到最好效果。论文对天津市某区各个地下水开采层的多年累计开采量、累计沉降量进行数据统计分析,建立了该地区累计沉降量及各个地下水开采层的多元相关方程。在此基础上,分析了各个地下水开采层对地面沉降影响的相关程度。以此为该区控制地面沉降的提供依据。     

The development and control of the land subsidence in the Yangtze Delta,China

Land subsidence in China occurs predominantly in 17 provinces (cities) situated in the eastern and middle regions of the country, including Shanghai, Tianjin and Jiangsu, and Hebei provinces. It is primarily caused by groundwater overpumping. One of the areas most severely affected by land subsidence is the Yangtze Delta, most of which consists of Shanghai City, the Su-Xi-Chang area (Suzhou, Wuxi and Changzhou cities) of Jiangsu Province, and the Hang-Jia-Hu area (Hangzhou, Jiaxing and Huzhou cities) of Zhejiang Province. The excessive exploitation of groundwater forms in a large regional cone of depression and, consequently, land subsidence is also regional, currently centered in the Shanghai and Su-Xi-Chang areas. In 2002, the maximum cumulative subsidence of Shanghai, Su-Xi-Chang and Hang-Jia-Hu were 2.63 m, 2.00 and 1.06 m, respectively. The land subsidence area is continuing to expand throughout the Yangtze Delta. To study the characteristics and the pattern of this land subsidence, the government has implemented a monitoring system involving the placement of 37 groups of extensometers (layers marks) and drilling of more than 1000 observation wells. These provide an invaluable historical record of deformation and pore water pressure and facilitate studies on the special features of soil deformation when the groundwater level changes due to pumping. Several measures have been taken in recent years to control the development of the land subsidence in the different areas; these include groundwater injection, prohibition of pumping deep confined groundwater, and an adjustment of the pumping depth and magnitude of the groundwater withdrawn. At present, although the subsidence area is still increasing slowly, the subsidence rate is controlled.     

苏锡常地区非线性地面沉降耦合模型研究

长期过量开采地下水所引发的地面沉降是一个复杂的非线性变化过程,对其进行数值模拟时,如不考虑沉降发展过程中模型参数的非线性变化,会给预测带来很大误差。本文依据苏锡常地区实际资料,通过典型钻孔土力学试验,确定出土体在不同荷载条件下的弹塑性和蠕变特征方程以及土体渗透系数随孔隙度变化的关系式。在此基础上建立了研究区三维变系数地下水流模型及考虑土体垂向不同变化特征(弹塑变或蠕变)的一维区域沉降模型,并采用多尺度有限单元法对模型进行了真正意义上的耦合求解。     

Dewatering induced subsidence during excavation in a Shanghai soft deposit

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.     

Prediction of Land Subsidence Under Cyclic Pumping Based on Laboratory and Numerical Simulations

In this study subsidence due to groundwater withdrawal was investigated. Kerman Province in Iran is struggling with land subsidence problem due to extensive groundwater withdrawal mainly for farming. The rate and type of groundwater withdrawal has very important impact on settlement rate. In this research, effective parameters on land subsidence caused by groundwater withdrawal were determined by laboratory tests. Sampling had done up to depth of 300 m mainly with remolded specimens from Shams-abad, Nouq plain in Kerman province. Similar to the field preconsolidation pressure was applied on specimens in the laboratory. Rate of applied stress on prepared specimens was similar to effect of oscillation of groundwater level. In order to model the actual soil behavior in the laboratory, one-dimensional consolidation device (odometer) was adopted for testing. In these tests, the effect of loading caused by seasonal oscillation of groundwater table is considered by means of cyclic loading in the testing which has great effect on rate of settlements. The results of tests show that when the water table level periodically increases and decreases the amount of settlement decrease, comparing with the case when the groundwater table drop to a constant level. In order to predict the further effects of groundwater level oscillation and actual field condition on land subsidence, a finite element model based on Biots’ three-dimensional consolidation theory was developed. After calibration of finite element model with laboratory tests, this model was used for prediction the effect of groundwater level oscillation on actual field conditions.     

国际地面沉降研究综述

文章在介绍国际地面沉降会议历史及２０００年第六届国际地面沉隆会议简况的基础上,并根据２０００年第六届国际地面沉降会议论文,对国际地面沉降研究进展情况分成如下六个方面进行了综述。地面沉降地质因素介绍了古代地面沉降、泥炭层沉降、地震砂土液化地面沉降和海平面上升研究状况。地下流体运移地面沉降方面介绍了以地下水开采为主的地面沉降问题及地面塌陷、天然气开采引起的地面沉降、均匀沉降对建筑结构的破坏和欠固结石英     

The state of land subsidence and prediction approaches due to groundwater withdrawal in China

This article gives a general introduction to land subsidence with the prediction approaches due to withdrawal of groundwater in three subsided/subsiding regions in China: the deltaic plain of Yangtse River (YRDP), North China Plain (NCP), and Fenwei Plain (FP). On YRDP, Shanghai is the typical subsided/subsiding city; on NCP Tianjin is the typical subsided/subsiding city, and on FP Taiyuan is the typical subsided/subsiding city. The subsided area with subsidence over 200 mm on YRDP is about 10,000 km² and the maximum subsided value reached 2.9 m at Shanghai; on NCP the subsided area reached 60,000 km² with the maximum subsidence of 3.9 m at Tianjing; on FP the subsided area is relatively smaller than that on the other two plains and is about 1,135 km² with maximum subsidence of 3.7 m at Taiyuan city. In order to protect the civil and industrial facilities, it is necessary to predict the future development of land subsidence based on present state. Many researchers proposed several approaches to predict the land subsidence due to groundwater withdrawal according to different geological conditions and groundwater withdrawal practice. This article classifies these approaches into five categories: (i) statistical methods; (ii) 1D numerical method; (iii) quasi-3D seepage model; (iv) 3D seepage model; (v) fully coupled 3D model. In China, the former four categories are presently employed in the prediction practice and their merits and demerits are discussed. According to the prediction practice, 3D seepage model is the best method presently.     

苏锡常地区孔隙Ⅱ承压水开采条件与水、土应力平衡探讨

基于水、土应力平衡观点，获得了对Ⅱ承压水过量开采发生地面沉降和可开采资源的认识，但平衡条件尚有模糊性，认为承压水一开采就产生水、土应力失衡。其分析研究在含水层弹性释放量上，未分天然状态土体自重压缩和开采至水、土应力失衡互动时含水层压缩弹性释放量，这就导致水、土应力平衡条件认识上的模糊性。通过土体压缩曲线与地面沉降发生曲线变化特征，结合苏州市城市规划区东部郭巷Ⅱ承压水开采过程中水位与地面沉降同步监测资料研究，论述苏锡常地区Ⅱ承压水具高压强，有一个天然动态下水、土应力平衡面，Ⅱ承压水开采其顶板以上土体不同厚度区，按天然状态水、土应力平衡面以上水压力控制开采，不会发生地面沉降。这一问题的深化有助于地面沉降机理研究和承压水可开采资源评价及开采利用条件的认识，为超采区划定和沿江及高水位地区由封井转入按水、土应力平衡开采提供了理论依据。