水位下降速率对岩溶土洞塌陷的影响分析

陈学军; 薛明明; 宋宇

doi:10.11932/karst20240409

水位下降速率对岩溶土洞塌陷的影响分析

doi: 10.11932/karst20240409

陈学军^{1, 2,},
薛明明^{1, 2},
宋宇^{1, 2, ,}

1.
桂林理工大学, 广西桂林 541004
2.
广西岩土力学与工程重点试验室, 广西桂林 541004

基金项目: 国家重点研发计划项目（2019YFC507502）；国家自然科学基金（41967037）

详细信息

作者简介:
陈学军（1961－），男, 博士, 教授, 博士生导师, 主要从事灾害地质与岩土工程方面的研究。E-mail：chenxj@glut.edu.cn

通讯作者:
宋宇（1981－），女, 博士, 副教授, 硕士生导师, 主要从事特殊性土的工程特性及致灾机理方面的研究工作。E-mail：songyu119@126.com。

中图分类号: P642.25
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出版历程
- 收稿日期: 2022-11-27
- 录用日期: 2023-07-31
- 修回日期: 2023-06-10
- 刊出日期: 2024-10-31

Influence of water level dropping rates on the collapse of karst soil caves

CHEN Xuejun^{1, 2
,},
XUE Mingming^{1, 2},
SONG Yu^{1, 2
, ,}

1.
Guilin University of Technology, Guilin, Guangxi 541004, China
2.
Guangxi Key Laboratory of Geomechanics andGeotechnical Engineering, Guilin, Guangxi 541004, China

Funds: This research is supported by National Key Research and Development Grogram（Grant No. 2019YFC507502）and the National Natural Science Foundation of China（Grant No. 41967037）.

摘要

摘要: 水位升降引起的水气压力变化会导致岩溶土洞塌陷。通过开展物理模型试验与FLAC3D数值模拟相结合的方式，模拟相同供水速率不同排水速率下的水位升降波动对岩溶土洞的致塌过程，分析了水位升降波动过程中不同排水速率对既有土洞内水气压力的变化、覆盖层土压、变形的影响，建立了排水速率，覆盖层变形、塌陷与水气压力的关系，提出了水位波动对土洞塌陷的作用规律。结果表明：（1）排水速率对水气压力变化的影响规律基本一致但变化程度不同。水气压力的变化程度、响应时间与排水速率呈正相关。（2）覆盖层变形量、土压的变化与水气压力变化呈正相关，但影响程度不同，排水速率只是加快了其变化程度。（3）土洞变形、塌陷程度是综合因素所致。排水速率、水位波动次数对既有土洞中水气压力变化、以及土体变形效应均具有不同程度的影响。（4）数值模拟结果与试验室模型试验所得结论基本吻合。这些规律为进一步研究水动力因素对岩溶塌陷的作用规律提供了重要的理论支撑，为合理防治、预测岩溶塌陷提供了依据。
- 土洞塌陷 /
- 物理模型试验 /
- FLAC3D数值模拟 /
- 排水速率 /
- 水位波动
Abstract: The change of water-gas pressure caused by the rise and fall of water level will lead to the collapse of karst soil caves. In this study, we combined the physical model test and FLAC3D numerical simulation to simulate the soil cave collapse caused by water level fluctuation under the same water supply rate and different drainage rates. Besides, we also analyzed the influence of different drainage rates on the variation of water-gas pressure, soil pressure of the overlying soil layer and deformation of soil caves during the fluctuation. We also established the relationship between water-gas pressure and variables such as drainage rates, overburden deformation and cave, and put forward the action law of water level fluctuations on the collapse of soil cave. The results show as follows. (1) The influence of drainage rates on the variation of water-gas pressure is basically the same, but with different degrees. The change degree and response time of water-gas pressure are positively correlated with the drainage rate. (2) The change of overburden deformation and soil pressure is positively correlated with the change of water-gas pressure, but with different influence degrees. The drainage rate can only accelerate the change degree. (3) Degrees of deformation and collapse of soil caves are caused by comprehensive factors. The speed of the drainage rate and the number of water level fluctuations influence the changes of water-gas pressure in different degrees in soil caves and also influence the soil deformation caused by water level fluctuations. (4) The numerical simulation results are basically consistent with the results of laboratory model test. These results provide important theoretical support for further research on the laws of hydrodynamic factors affecting karst collapse and provide a basis for rational prevention and prediction of karst collapse.
- soil cave collapse /
- physical model test /
- FLAC3D numerical simulation /
- drainage rate /
- water level fluctuation

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图 1 工程地质图

Figure 1. Engineering geology map

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图 2 上覆土层结构类型

Figure 2. Structure types of overlying soil layers

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图 3 模型装置及测量设备图（a）模型装置正面图（b）测量设备图（c）模型装置剖面图

Figure 3. Physical model device and monitoring equipment (a) front view of model device; (b) measurement equipment diagram; (c) profile view of model device

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图 4 岩溶网格模型

Figure 4. Karst grid model

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图 5 水气压力随时间变化图

Figure 5. Variation of water-gas pressure with time

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图 6 既有土洞上覆土体变形量与水气压力关系

Figure 6. Relationship between deformation of overlying soil and water-gas pressure of soil cave

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图 7 排水速率为2.08×10⁻⁴ m·s⁻¹土压随时间变化图

Figure 7. Variation of soil pressures with time at the drainage rate of 2.08×10⁻⁴ m·s⁻¹

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图 8 排水速率为4.17×10⁻⁴ m·s⁻¹土压随时间变化

Figure 8. Variation of soil pressures with time at the drainage rate of 4.17×10⁻⁴ m·s⁻¹

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图 9 排水速率为4.17×10⁻³ m/s土压随时间变化

Figure 9. Variation of soil pressures with time at the drainage rate of 4.17×10⁻³ m·s⁻¹

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图 10 土压与水气压力关系图（水位上升）

Figure 10. Relationship between soil pressures and water-gas pressures when the water level rises

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图 11 土压与水气压力关系图（水位下降）

Figure 11. Relationship between soil pressures and water-gas pressures when the water level drops

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图 12 洞顶累计塌落量随水位波动次数的变化图

Figure 12. Variation of cumulative collapse volumes on the cave roof with the number of water level fluctuations

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图 13 不同排水速率下塌陷口长短半轴长度变化图

Figure 13. Variation of the semi-axis lengths of the collapse opening under different drainage rates

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图 14 排水速率为4.17×10⁻³ m·s⁻¹时塌陷口半轴长度测量图；(a)长半轴测量图 (b)短半轴测量图

Figure 14. Measurement diagram of the semi-axis length of the collapse opening at the drainage rate of 4.17×10⁻³ m·s⁻¹. (a) diagram of major half axis measurement; (b) diagram of short half axis measurement

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图 15 不同排水速率下竖向位移分布图 (a)排水速率为2.08×10⁻⁴ m·s⁻¹; (b)排水速率为2.78×10⁻⁴ m·s⁻¹; (c)排水速率为4.17×10⁻⁴ m·s⁻¹; (d)排水速率为8.34×10⁻⁴ m·s⁻¹ ;(e)排水速率为4.17×10⁻³ m·s⁻¹

Figure 15. Distribution of vertical displacements under different drainage rates (a) at the drainage rate of 2.08×10⁻⁴ m·s⁻¹; (b) at the drainage rate of 2.78×10⁻⁴ m·s⁻¹; (c) 4.17×10⁻⁴ m·s⁻¹; (d) at the drainage rate of 8.34×10⁻⁴ m·s⁻¹; (e) at the drainage rate of 4.17×10⁻³ m·s⁻¹

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图 16 不同排水速率下最大剪应力分布图 (a)排水速率为2.08×10⁻⁴ m·s⁻¹; (b)排水速率为2.78×10⁻⁴ m·s⁻¹; (c)排水速率为4.17×10⁻⁴ m·s⁻¹; (d)排水速率为8.34×10⁻⁴ m·s⁻¹ ; (e)排水速率为4.17×10⁻³ m·s⁻¹

Figure 16. Distribution of maximum shear stresses under different drainage rates (a) at the drainage rate of 2.08×10⁻⁴ m·s⁻¹; (b) at the drainage rate of 2.78×10⁻⁴ m·s⁻¹; (c) at the drainage rate of 4.17×10⁻⁴ m·s⁻¹; (d) at the drainage rate of 8.34×10⁻⁴ m·s⁻¹; (e) at the drainage rate of 4.17×10⁻³ m·s⁻¹

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图 17 不同排水速率下塑性区分布图 (a)排水速率为2.08×10⁻⁴ m·s⁻¹; (b)排水速率为2.78×10⁻⁴ m·s⁻¹; (c)排水速率为4.17×10⁻⁴ m·s⁻¹; (d)排水速率为8.34×10⁻⁴ m·s⁻¹ ; (e)排水速率为4.17×10⁻³ m·s⁻¹

Figure 17. Distribution of plastic zones under different drainage rates (a) at the drainage rate of 2.08×10⁻⁴ m·s⁻¹; (b) at the drainage rate of 2.78×10⁻⁴ m·s⁻¹; (c) at the drainage rate of 4.17×10⁻⁴ m·s⁻¹; (d) at the drainage rate of 8.34×10⁻⁴ m·s⁻¹; (e) at the drainage rate of 4.17×10⁻³ m·s⁻¹

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表 1 土体基本物理、力学参数

Table 1. Basic physical and mechanical parameters of soil

覆盖层类型	密度/g·cm⁻³	孔隙率	剪切模量/kpa	体积模量/kpa	内摩擦角/°	粘聚力/kPa	渗透系数/cm·s⁻¹
红黏土	1.72	0.47	1.354×10⁶	4.22×10⁶	8.8	25.3	3.22×10⁻⁴

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表 2 覆盖层厚度与岩溶塌陷关系统计表

Table 2. Relationship between cover layer thickness and karst collapse

覆盖层厚度/m	<2	2~4	4~6	6~8	8~10	10~12	12~14	合计
塌陷个数/个	97	72	69	56	22	2	1	318
占百分比/%	30.41	22.57	21.63	17.55	6.90	0.63	0.31	100

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表 3 模型试验方案

Table 3. Model test scheme

方案	土洞直径/cm	初始水位位置	初始水位高度/mm	水位上升速率/m·s⁻¹	水位下降速率/m·s⁻¹
1	10	土层表面	100	2.78×10⁻⁴	4.17×10⁻³
2					4.17×10⁻⁴
3					2.08×10⁻⁴

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表 4 不同排水速率下一次水位升降过程中水气压力响应、变化及初始环境温度效应

Table 4. Water-gas pressure response, variation and initial ambient temperature effect during one rise and fall process of water level under different drainage rates

排水速率/m·s⁻¹	试验时环境初始温度/ ℃	既有土洞内初始气压值/kPa	水气压力响应时间/s	水气压力消散历时/s	水气压力降幅/kPa
4.17×10⁻³	20.88	101.083	1 010	10	3.7233
4.17×10⁻⁴	25.85	99.065	1 260	80	1.1202
2.08×10⁻⁴	31.29	98.99	1 510	90	0.8505

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