Causes of Lining Instability of Large Water Diversion Channel and the Effects of Prevention and Control Measures

doi:10.11988/ckyyb.20240986

Abstract

Abstract:

Lining instability is common in excavation sections of large water diversion channels with high groundwater levels during the operation period. Effective seepage control measures are crucial for ensuring channel lining safety. This study addresses the lining instability issue in a canal section of the middle route of the South-to-North Water Diversion Project following the ‘7·20’ heavy rainstorm in Henan in 2021. Based on monitoring data and three-dimensional seepage simulation, the causes of the canal lining plate instability were analyzed, and the effects of additional vertical relief wells and transverse drainage pipes on the canal slope were evaluated using a three-dimensional model. Results show that the permeable strata in the channel foundation provide a seepage pathway for rainfall infiltration and lateral groundwater recharge. The rise in groundwater level due to extreme rainfall is the primary cause of canal lining plate instability. Drainage measures could effectively reduce the uplift pressure beneath the lining plate. These findings offer insights for the risk analysis, regulation, and operational management of similar canal sections.

Key words: water diversion channels, high groundwater level, uplift pressure, lining instability, seepage analysis

CLC Number:

SU Xia, WEI Kai, HAO Ze-jia, LI Shao-long, CUI Hao-dong. Causes of Lining Instability of Large Water Diversion Channel and the Effects of Prevention and Control Measures[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(2): 188-193.

编号	地层	渗透系数/(cm∙s^-1)
1	黄土状重粉质壤土	8.00×10^-5
2	重粉质壤土	3.00×10^-5
3	泥灰岩	2.30×10^-4
4	黏土岩	1.00×10^-5
5	砂岩	2.70×10^-4
6	粗砂垫层	5.00×10^-2
7	土工膜	1.00×10^-10

编号	地层	渗透系数/(cm∙s^-1)
1	黄土状重粉质壤土	8.00×10^-5
2	重粉质壤土	3.00×10^-5
3	泥灰岩	2.30×10^-4
4	黏土岩	1.00×10^-5
5	砂岩	2.70×10^-4
6	粗砂垫层	5.00×10^-2
7	土工膜	1.00×10^-10

方案	地下水位/m	渠道水位/m	渠坡出逸高度/m	衬砌板水压差/m
原设计方案	124.28	98.74	0.32	0.51
增设盲沟和减压井的方案	124.28	98.74	0.12	0.11

方案	地下水位/m	渠道水位/m	渠坡出逸高度/m	衬砌板水压差/m
原设计方案	124.28	98.74	0.32	0.51
增设盲沟和减压井的方案	124.28	98.74	0.12	0.11

设置部位	增设措施	渗控目标
一级马道及过水断面	逆止阀	排出衬砌板下土工膜下的积水
	纵向排水盲沟	降低一级马道以上地下水位
	竖向排水孔、减压井	降低渠坡或渠底地层地下水位
一级马道以上	纵向排水盲沟	将入渗的雨水或上层滞水排出
	水平排水孔	将坡体中水体排出坡面
	排水井	降低渠坡深部地下水位

Causes of Lining Instability of Large Water Diversion Channel and the Effects of Prevention and Control Measures

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 11

Related Articles 11

Recommended Articles 0

Metrics

Comments

[1]	JIA Zhen, YANG Dong-mei, ZHENG Hong. A New Method to Deal with Weak Discontinuous Interface in Seepage Analysis Based on Numerical Manifold Method [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(12): 133-137.
[2]	LI Feng, YANG Yu, WEN Li-feng, LI Yan-long. Sensitivity Analysis of Seepage Control Effect and Drainage Measures in the Water Conveyance System of Pumped Storage Power Stations [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(12): 109-116.
[3]	LIU Kai, CHENG Xi, CUI Hao-dong, WEI Kai, YAN Min, WANG Jin-long. Mechanism and Countermeasures of Instability of Tunnel Lining in Foothill Plain Section of Large-scale Water Diversion Channel [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(10): 119-123.
[4]	SHEN Si-chao, QIU Jin-wei, LIU Jun, TONG Jun, HU Bo. Effect of Hydraulic Conditions of Pond Near Embankment on River Slope Stability [J]. Journal of Changjiang River Scientific Research Institute, 2022, 39(6): 157-162.
[5]	ZHANG Xu, LI Ming-bao, WEI Na, SUN Zhen-guo, YANG Zhong-han, TIAN Dong-hong. A Calculation Model of Pore Water Pressure in Saturated Soil Based on Fractal Theory [J]. Journal of Changjiang River Scientific Research Institute, 2019, 36(6): 88-92.
[6]	LÜ Cong-cong, LI Zong-li, LI Dong-qi. Problems of Applying Seepage Pressure in Coupling Analysis of Seepage and Stress Using ABAQUS [J]. Journal of Changjiang River Scientific Research Institute, 2018, 35(5): 68-72.
[7]	XU Wei, FANG Chun-hui, WANG Xue,ZHU Kai. Uplift Pressure at Dam Base of Concrete Gravity Dam Considering the Nonlinear Environmental Impacts [J]. Journal of Changjiang River Scientific Research Institute, 2016, 33(8): 42-46.
[8]	ZHU Guo-sheng, ZHANG Jia-fa, LIU Xiao-jiang, LI Shao-long. Seepage Control Measures for the Foundation of Xinglong Hydropower Project [J]. Journal of Changjiang River Scientific Research Institute, 2016, 33(5): 145-150.
[9]	BAO Cheng-gang. Technical Advances in Second Stage Cofferdam of TGP and Its Significance for High Cofferdam Construction in China [J]. Journal of Changjiang River Scientific Research Institute, 2014, 31(9): 33-42.
[10]	HUANG Yao-ying,SHEN Zhen-zhong,ZHENG Hong. Method of Applying Uplift Pressure in the Analysis of DeepSliding Stability of Gravity dam [J]. Journal of Changjiang River Scientific Research Institute, 2013, 30(12): 112-117.
[11]	YANG Yu-wen, ZHOU Zhi-li, JIANG Tao,ZHAN Ping. Determining the Self-stability Critical Height of Slope with Steady Seepage [J]. Journal of Changjiang River Scientific Research Institute, 2013, 30(10): 54-57.