地下水位变化对透—阻型岩溶塌陷影响的分析

陶小虎; 赵 坚; Xiaoming Wang; Ming Ye; Roger Benito Pacheco Castro

doi:10.11932/karst2017y50

地下水位变化对透—阻型岩溶塌陷影响的分析

doi: 10.11932/karst2017y50

1.
河海大学水利水电学院
2.
Geophysical Fluid Dynamics Institute, Florida State University

基金项目: 国家自然科学基金项目(51279045)；江苏省普通高校研究生科研创新项目（CXZZ12_0246）

计量
- 文章访问数: 2349
- HTML浏览量: 759
- PDF下载量: 765
- 被引次数: 0
出版历程
- 发布日期: 2017-12-25

Analysis of seepage effect on the formation of sinkhole in unconfined aquifer-aquitard system caused by groundwater changes

1.
College of Water Conservancy and Hydropower Engineering, Hohai University
2.
Geophysical Fluid Dynamics Institute, Florida State University

摘要

摘要: 文章从一维地下水运动和渗透力学的角度，分析比较潜水位上升与承压水位下降对岩溶地区透—阻型盖层中阻水层渗透稳定性的影响，重点讨论了承压水位下降速度(降速)与下降深度（降深）对阻水层中渗透坡降的影响，结果表明:地下水位变化（潜水位上升或承压水位下降）产生的非稳定渗流不利于岩溶洞穴开口上方阻水层的稳定，承压水位的下降对岩溶开口附近处阻水层中渗透力的影响远大于潜水位的变化；在承压层水位最大降深确定的条件下，承压水位下降速度愈快，岩溶开口附近处阻水层中向下渗透力愈大。因此，在覆盖型岩溶地区抽取地下水时，为了减缓或避免覆盖型塌陷的发生，应同时控制好最大降深和最大开采速度。
- 透—阻型 /
- 岩溶塌陷 /
- 渗透力 /
- 一维地下水流 /
- 潜水位上升 /
- 承压水位下降 /
- 降速
Abstract: Cover-collapse sinkholes are an extremely complex process that often cause unpredictable geological disaster. They occur abruptly and can lead to catastrophic damages such as human death and injury, property damage, losses of soil and water and environmental problems, as well as may cause secondary disaster. Groundwater is one of the crucial triggering factors for sinkhole development and collapse. To have a better understanding of the mechanical effect of groundwater on sinkhole formation，the force exerted by the groundwater on the soil particles in saturated zone with porous medium was analysed. In this case, the entire hydraulic force acting on the soil particle by groundwater depends on the seepage force or the value of hydraulic gradient which causes the velocity of groundwater movement. A 1D groundwater flow model was simply established, where the unconfined aquifer-aquitard system overlies the confined aquifer, in order to study the hydraulic gradient distribution in the confining unit. The differences between the effects of the phreatic level arising and piezometric level lowering were compared. Moreover, the effects of drawdown rate and drawdown of piezometric level in confined aquifer on the confining unit were mainly discussed. The results show that groundwater movement with variation of the water table or piezometric level in karst area will erode and disintegrate the soil, resulting in the formation of soil cavity and upward propagation of the erosion. The unsteady seepage due to groundwater level fluctuations goes against the stability of the confining layer above the karst opening; the impact of seepage force resulting from piezometric level lowering is greater than that of the phreatic level arising; the size of the soil cavity formed is related to the degree of the decline of piezometric level which is also influenced by the decline rate; under the conditions with the same piezometric level declines in the confined aquifer, the higher the drawdown rate is, the larger the maximum hydraulic gradient will be formed at the bottom. It was demonstrated that under the same drawdown condition, a critical drawdown rate should be made to prevent the soil failure; meanwhile, when a huge drawdown rate is needed, we should shorten the time of continuous drawdown. In other word, a critical drawdown should be proposed to protect the stability. Thus, controlling maximum operating head and maximum drawdown rate is critical in managing the groundwater exploitation in confined aquifer, in order to reduce or avoid the occurrence of cover-collapse sinkhole.
- unconfined aquifer-aquitard system /
- sinkhole /
- seepage force /
- 1D groundwater movement /
- phreatic level arising /
- piezometric level drawdown /
- drawdown rate

HTML

参考文献(20)

[1]	程星, 彭世寿. 岩溶区地下水位下降致塌的数值模拟研究［J］. 地球与环境, 2005, 33(S1): 119-123.
[2]	Waltham T, Bell F G, Culshaw M. Sinkholes and subsidence ［M］. Berlin: Springer, 2005.
[3]	戴建玲, 雷明堂, 蒋小珍. 线性工程岩溶塌陷危险性评价研究［J］. 中国岩溶, 2012, 31(3): 296-302.
[4]	Zalasiewicz J, Williams M, Steffen W, et al. The New World of the Anthropocene ［J］. Environmental Science & Technology, 2010, 44(7): 2228-2231.
[5]	金晓文, 陈植华, 曾斌, 等. 岩溶塌陷机理定量研究的初步思考［J］. 中国岩溶, 2013, 32(4): 437-446.
[6]	李颜贵, 刘子龙, 于孝民, 等. 唐山黄庄岩溶塌陷形成条件和机理分析［J］. 中国岩溶, 2014, 33(3): 299-307.
[7]	林丹, 游省易, 唐小明. 矿坑排水与岩溶地面塌陷的关系［J］. 中国岩溶, 2016, 35(2): 202-210.
[8]	贾连杰. 尼山水库岩溶塌陷机理研究［D］.青岛：中国海洋大学, 2006.
[9]	Peterson R O, James O. Rumbaugh I. Hydrogeologic Impacts Observed During the January 2010 Freeze Event in Dover/Plant City, Hillsborough County, Florida ［M］. Brooksville, Florida: Southwest Florida Water Management District, 2012.
[10]	White C L. Geostatistical Analysis Of Sinkhole Occurrence Due To Increased Groundwater Pumping During Freeze Events In Plant City, Florida ［D］. Tallahassee, Florida： The Florida State University, 2013.
[11]	Tharp T M. Mechanics of upward propagation of cover-collapse sinkholes ［J］. Engineering Geology, 1999, 52(1-2): 23-33.
[12]	雷明堂, 蒋小珍, 李瑜. 唐山市岩溶塌陷模型试验研究［J］. 中国地质灾害与防治学报, 1997, 8(S1): 187-194.
[13]	雷明堂, 蒋小珍, 李瑜. 岩溶塌陷模型试验：以武昌为例［J］. 地质灾害与环境保护, 1993, 4(2): 39-44.
[14]	Lei M, Gao Y, Jiang X, et al. Experimental Study of Physical Models for Sinkhole Collapses in Wuhan, China ［M］//BECK B F. Sinkholes and the Engineering and Environmental Impacts of Karst，2005:91-102.
[15]	万志清, 秦四清, 李志刚, 等. 土洞形成的机理及起始条件［J］. 岩石力学与工程学报, 2003, 22(8): 1377-1382.
[16]	Bear J. Dynamics of fluids in porous media ［M］. New York: Courier Dover Publications, 2013.
[17]	Terzaghi K. Theoretical soil mechanics ［M］. New York: John Wiley & Sons, 1943.
[18]	Fidelibus M D, Gutiérrez F, Spilotro G. Humaninduced hydrogeological changes and sinkholes in the coastal gypsum karst of Lesina Marina area (Foggia Province, Italy) ［J］. Engineering Geology, 2011, 118(1-2): 1-19.
[19]	刘之葵, 梁金城, 周健红. 岩溶区土洞发育机制的分析［J］. 工程地质学报, 2004, 12(1):45-49.
[20]	贾龙, 蒙彦, 管振德. 岩溶土洞演化及其数值模拟分析［J］. 中国岩溶, 2014, 33(3):294-298.