含水层厚度突变型地裂缝控制因子敏感性分析

doi:10.16108/j.issn1006-7493.2023041

高校地质学报 ›› 2024, Vol. 30 ›› Issue (04): 442-450.DOI: 10.16108/j.issn1006-7493.2023041

含水层厚度突变型地裂缝控制因子敏感性分析

张火链¹，贺圣淋¹，张永伟²，于德杰²，龚绪龙³，叶淑君^1*

1. 南京大学地球科学与工程学院，自然资源部地裂缝地质灾害重点实验室，南京 210023；
2. 山东省国土空间生态修复中心，济南 250014；
3. 江苏省地质调查研究院，自然资源部地裂缝地质灾害重点实验室，南京 210049

出版日期:2024-08-20 发布日期:2024-08-20

Sensitivity Analysis of Controlling Factors for Earth Fissures in Aquifer Systems with Abrupt Thickness Changes

ZHANG Huolian¹，HE Shenlin¹，ZHANG Yongwei²，YU Dejie²，GONG Xulong³，YE Shujun^1*

1. Key Laboratory of Earth Fissures Geological Disaster, Ministry of Natural Resources, School of Earth Science and Engineering,
Nanjing University, Nanjing 210023, China；
2. Shandong Provincial Territorial Spatial Ecological Restoration Center, Jinan 250014, China；
3. Key Laboratory of Earth Fissures Geological Disaster, Ministry of Natural Resources, Geological Survey of Jiangsu Province, Nanjing 210049, China

Online:2024-08-20 Published:2024-08-20

摘要/Abstract

摘要： 过量开采地下水引发的 “采水型”地裂缝灾害在国内外广泛存在。采水型地裂缝的发育是过量开采地下水与复杂的地质、水文地质条件共同作用的结果。含水层厚度突变型地裂缝是常见的一类采水型地裂缝。为了深入理解含水层厚度突变型地裂缝发育机制，文章基于这类地裂缝的概念模型设计了一个理想的地裂缝发育数值试验算例，应用有限元方法计算含水层连续性介质的应力应变分布，应用界面元方法计算非连续裂缝的发育。在此理想算例基础上，进一步应用Sobol全局敏感性分析方法评估含水层厚度比、孔隙水压力变化、压缩系数以及内聚力四个控制因子对地裂缝发育深度的影响。研究结果表明：开采地下水过程中，由于孔隙水压力降低，差异性沉降和剪切应力在含水层厚度突变处集中并不断增大，导致地面产生地裂缝，并进一步向下扩展。含水层厚度比是地裂缝发育最敏感的控制因子，孔隙水压力变化的敏感性次之，压缩系数敏感性弱，内聚力是不敏感控制因子。含水层厚度比和孔隙水压力变化之间有明显的交互作用，含水层厚度差异越大且孔隙水压力降低越大则地裂缝发育越深。

关键词: 地裂缝, 厚度突变, 敏感性分析, Sobol方法, 数值模拟

Abstract: The “groundwater pumping type” earth fissure disasters caused by excessive exploitation of groundwater widely occur worldwide. Their developments are contributed by both excessive exploitation of groundwater and complex geological and
hydrogeological conditions. The type of earth fissure in aquifer system with abrupt thickness change is a general type of earth fissures. In order to achieve a deeper understanding of the mechanism of this type of earth fissures, the paper designs a numerical experimental test in which earth fissure developes in an aquifer system with abrupt thickness change. Firstly, the finite element method is used to calculate the stress-strain distribution of the aquifer system, and the interface element method is used to calculate rupture development. Then the Sobol global sensitivity analysis method is applied to quantify the impact of four control factors, including aquifer thicknesses ratio, changes in pore water pressure, compression coefficient, and cohesion, on the depth of earth fissure development. The results of numerical test indicate that during the process of pumping groundwater, due to the decrease of pore water pressure, differential compaction and shear stress concentrate continuously increase at the location with abrupt changes in aquifer thickness, which leads to the formation of earth fissure on the ground and further downward expansion. The sensitivity analysis results indicate that the aquifer thicknesses ratio is the most sensitive control factor for the development of earth fissures, the sensitivity of pore water pressure changes is second, the sensitivity of compression coefficient is weak, and cohesion is an insensitive control factor. There is an obvious collaboration between the thicknesses ratio and the changes in pore water pressure. The greater the difference in thickness between aquifers, combined with the greater decrease in pore water pressure, the deeper the development of earth fissures.

Key words: Earth fissure, abrupt thickness change, sensitivity analysis, Sobol method, numerical simulation

中图分类号:

P641

张火链, 贺圣淋, 张永伟, 于德杰, 龚绪龙, 叶淑君. 含水层厚度突变型地裂缝控制因子敏感性分析[J]. 高校地质学报, 2024, 30(04): 442-450.

ZHANG Huolian, HE Shenlin, ZHANG Yongwei, YU Dejie, GONG Xulong, YE Shujun. Sensitivity Analysis of Controlling Factors for Earth Fissures in Aquifer Systems with Abrupt Thickness Changes[J]. Geological Journal of China Universities, 2024, 30(04): 442-450.

[1]	李中源, 吴本君. 俯冲板块粘度对双板片相向俯冲动力学过程的影响：数值模拟[J]. 高校地质学报, 2023, 29(5): 735-742.
[2]	张宸玮, 刘春, 耿焕, 刘辉. 碎石堆小行星自旋演化过程的离散元数值模拟[J]. 高校地质学报, 2023, 29(5): 743-755.
[3]	尹书郭, 杨国栋, 冯涛, 马鑫, 曹伟, 黄冕, 郭天晴. 页岩储层物性参数对CO₂ 不同封存机制及封存量的影响[J]. 高校地质学报, 2023, 29(1): 37-46.
[4]	张利伟, 刘春, 李济琛, 寇玉冬. 浅层地温场连续监测和高精度模拟时空误差研究[J]. 高校地质学报, 2022, 28(1): 104-111.
[5]	邬忠虎, 刘贵川, 龚锦玉琼, 余小越, 李浩. 渗流应力耦合下含裂缝页岩力学特性和破坏模式研究[J]. 高校地质学报, 2022, 28(1): 112-118.
[6]	马新雨, 王俊, 周欣, 张云, 徐永福. 考虑隧道降水和开挖施工过程的三维地面沉降模拟[J]. 高校地质学报, 2021, 27(2): 229-239.
[7]	朱致远, 吴本君. 俯冲板块的动力学性质对平板俯冲的影响：数值模拟[J]. 高校地质学报, 2021, 27(2): 240-248.
[8]	冯建伟，孙致学，王焰东，佘姣凤. 塔里木盆地和田河气田奥陶系裂缝应力敏感性研究[J]. 高校地质学报, 2019, 25(2): 276-.
[9]	董健，曾献奎*，吴吉春. 不同类型海岸带海水入侵数值模拟研究进展[J]. 高校地质学报, 2018, 24(3): 442-.
[10]	朱晨光，刘春*，施斌，汤强. 边坡稳定性温度效应数值模拟研究[J]. 高校地质学报, 2018, 24(1): 122-.
[11]	程　详，赵光明，李英明，孟祥瑞，董春亮. 轴对称单轴压缩岩石材料应变局部化剪切带数值模拟研究[J]. 高校地质学报, 2017, 23(3): 555-.
[12]	王艺伟，叶淑君，于军，龚绪龙. 中国“采水型”地裂缝特征和成因分析[J]. J4, 2016, 22(4): 741-.
[13]	莫龙庭，乔文静，章艳红，叶淑君*，吴吉春. 数值模拟方法验证光透法监测流体饱和度的有效性:以非均质孔隙介质中的水/气两相流为例[J]. J4, 2016, 22(3): 572-.
[14]	禇程程 . 奥陶系石灰岩推覆体含水层下煤层开采覆岩破坏特征研究[J]. J4, 2015, 21(3): 569-.
[15]	商琳,戴俊生,杨学君,夏瑞杰. 柴北缘东段构造应力场数值模拟及构造演化模式探讨[J]. J4, 2014, 20(2): 260-.

含水层厚度突变型地裂缝控制因子敏感性分析

Sensitivity Analysis of Controlling Factors for Earth Fissures in Aquifer Systems with Abrupt Thickness Changes

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics