Influence of Pumping Drainage during Breach Closure on Embankment Safety in Tuanzhou Township of Dongting Lake

doi:10.11988/ckyyb.20240851

Abstract

Abstract:

Under the background of global climate change, extreme hydrological events with increasing frequency pose severe threat to dam safety. Large floods in the Yangtze River Basin, accompanied by levee breaches, occurred in 2016 and 2020. On July 5, 2024, the embankment of Tuanzhou township in Dongting Lake area, Hunan Province, collapsed, endangering the safety of people’s lives and property. To expedite the return of residents to their homes and prevent secondary disasters, early emergency closure measures are typically implemented post-breach. At this stage, with equalized water levels inside and outside the polder, rapid emergency drainage is conducted under breach closure conditions. The impact of sudden water level drops on the safety of the main embankment and the secondary embankment has attracted significant attention, even constraining emergency rescue operations. To assess the effects of emergency drainage on embankment safety in the Tuanzhou polder of Dongting Lake area and aid in the formulation of emergency response plans, we constructed non-steady seepage and stability analysis model for the main embankment and the Qianlianghu-Tuanzhou interval embankment near the breach with Dongting Lake water level remaining unchanged. The analysis focuses on the seepage stability and slope safety of the embankment under extreme sudden water level drop rates of 0.3 m/d and 0.6 m/d during emergency drainage during breach closure. The results indicate that the maximum seepage gradient and slope stability of the embankment meet the standards for third-level embankment safety under various conditions. Additionally, we propose rapid drainage measures in comprehensive consideration of multiple factors to provide technical support for emergency rescue and shed new insights for safety analysis under similar conditions.

Key words: pumping and drainage, embankment breach closure, non-steady seepage, stability analysis, embankment safety, Dongting Lake, Tuanzhou township

CLC Number:

TV223.4水工建筑物的渗流和防渗

LI Shao-long, FAN Yue, ZHOU Xin-hua, WANG Jin-long, XIAO Li, WANG Yan-li, CUI Hao-dong. Influence of Pumping Drainage during Breach Closure on Embankment Safety in Tuanzhou Township of Dongting Lake[J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(12): 196-201.

Figures/Tables 11

Fig.1 Location of breach in Tuanzhou township of Dongting Lake

Fig.2 Typical cross section of the embankment

Fig.3 Two-dimensional meshes

Table 1 Permeability coefficients of typical levees

分区	渗透系数/(cm·s^-1)	允许渗透坡降	备注
人工填土	5.00×10^-5		—
压浸平台	1.00×10^-3		团洲垸主堤
$Q 4 a l + l$ 粉质壤土	2.75×10^-4	0.40	团洲垸主堤
$Q 4 a l + l$ 粉细砂	2.84×10^-3	0.20	团洲垸主堤
$Q 2 l$ 粉质黏土	3.09×10^-5	0.45	团洲垸主堤
壤土	5.00×10^-5	0.40	钱团隔堤
砂壤土	5.00×10^-4	0.22	钱团隔堤
粉细砂	2.84×10^-3	0.20	钱团隔堤
粉质黏土	3.09×10^-5	0.45	钱团隔堤
粉质壤土	2.75×10^-4	0.40	钱团隔堤

Table 1 Permeability coefficients of typical levees

分区	渗透系数/(cm·s^-1)	允许渗透坡降	备注
人工填土	5.00×10^-5		—
压浸平台	1.00×10^-3		团洲垸主堤
$Q 4 a l + l$ 粉质壤土	2.75×10^-4	0.40	团洲垸主堤
$Q 4 a l + l$ 粉细砂	2.84×10^-3	0.20	团洲垸主堤
$Q 2 l$ 粉质黏土	3.09×10^-5	0.45	团洲垸主堤
壤土	5.00×10^-5	0.40	钱团隔堤
砂壤土	5.00×10^-4	0.22	钱团隔堤
粉细砂	2.84×10^-3	0.20	钱团隔堤
粉质黏土	3.09×10^-5	0.45	钱团隔堤
粉质壤土	2.75×10^-4	0.40	钱团隔堤

Table 2 Unsaturated seepage parameters

分区	进气值参数α/ mm^-1	形状参数 n	饱和含水量θ_s	残余含水量θ_r
人工填土	0.003	1.23	0.38	0.10
压浸平台	0.013	2.40	0.35	0.05

Table 3 Physical and mechanical parameters of embankment

分区	重度γ/(kN·m^-3)		固结快剪
分区	天然	饱和	黏聚力C/kPa	内摩擦角Φ/(°)
堤身填土	18.8	19.1	13	12
壤土	18.9	19.3	12	15
粉质壤土	19	19.5	16	15
砂壤土	19	19.6	15.2	18.5
粉质黏土	19	19.2	17	15.0
粉细砂	19.5	20.0	0	25.0

Table 4 Simulation schemes

方案	计算条件及参数	方案说明
F1-1	团洲垸应急抽水降速0.3 m/d	主堤渗流
F2-1	团洲垸应急抽水降速0.3 m/d	隔堤渗流
F1-2	团洲垸应急抽水降速0.6 m/d	主堤渗流
F2-2	团洲垸应急抽水降速0.6 m/d	隔堤渗流
F3-1	团洲垸应急抽水降速0.6 m/d, 堤顶车载20 kPa	主堤稳定
F4-1	团洲垸应急抽水降速0.6 m/d, 堤顶车载20 kPa	隔堤稳定

Fig.4 Head contours of seepage field

Fig.5 Process of horizontal hydraulic gradient in simulation program F1-2

Table 5 Anti-sliding safety factors in different cases

方案	抗滑安全系数		稳定标准
方案	降速0.6 m/d	稳态	稳定标准
F3-1	1.487	1.602	1.3
F4-1	1.438	1.489	1.3

Fig.6 Position of typical slide arc

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