土坝加高堆石坝工程防渗安全性分析

doi:10.11988/ckyyb.20240843

摘要/Abstract

摘要：

老旧水库大坝加高工程的整体防渗安全性需要重点关注。以某在建水库加高工程为研究对象,采用有限元法对土坝加高堆石坝开展三维渗流场计算,获得特征水位下加高后大坝的等水头线分布、渗流量、渗透坡降等渗流要素,并分析新建防渗系统的渗控效果;进一步针对周边缝止水局部失效、防渗墙局部开裂问题,分析不同失效宽度对大坝渗流特性的影响。计算表明:正常运行条件下,在新防渗系统的作用下,坝体内渗流自由面很低,大坝总渗流量为22.05 L/s;坝体、坝基及防渗系统均不会渗透破坏。当周边缝止水出现局部失效后,流经坝体的渗流量增加明显,与止水失效宽度近似成正比,且相应部位特殊垫层的渗透坡降显著增大,存在颗粒局部迁移调整的可能。当防渗墙底部出现局部开裂时,局部渗漏对大坝部分等水头线分布影响很小,但坝基河床部位渗流量显著增加,且与裂缝宽度呈较好的正相关性。计算成果为土坝加高堆石坝工程的安全建设和渗流稳定提供了理论依据。

关键词: 老坝加高工程, 水头分布, 渗流量, 渗透坡降, 止水失效, 防渗安全性

Abstract:

[Objective] A large number of aging earth and rockfill dams in China needs to be heightened due to seepage risks and insufficient flood control capacity. This study aims to reveal the seepage patterns of heightened dams, quantitatively evaluate the effectiveness of anti-seepage systems, and investigate the effects of two typical defects—waterstop failure at peripheral joints and cracking in cutoff walls—on seepage safety. [Methods] With a reservoir heightening project under construction as a case study, a three-dimensional finite element seepage model was established, incorporating the old dam, heightened concrete-faced rockfill dam, concrete cutoff wall, and curtain grouting system. Based on actual geological conditions and material permeability parameters, the seepage field distribution under four operating conditions—normal water level, dead water level, design flood level, and check flood level—was simulated. Defect-induced seepage was also simulated by setting different waterstop failure widths to analyze the sensitivity of these defects to seepage discharge, hydraulic head distribution, and seepage gradient. [Results] Under normal operation, the combined action of the new impermeable system effectively controlled seepage flow in the heightened dam. The free surface of seepage in the dam body remained low, with most areas in a drained state, while seepage flow primarily concentrated in the foundation; the total seepage discharge was 22.05 L/s. The hydraulic gradients of the face slab, cutoff wall, and curtain grouting were all below allowable thresholds, indicating that the anti-seepage system is reliable. When local waterstop failure occurred at the peripheral joint, reservoir water flew into the dam body through failure areas, forming a “bulging” saturation zone in the total hydraulic head contours. As the failure width increased, this zone expanded, reflecting local concentrated seepage. When local cracking occurred at the base of the cutoff wall, seepage discharge through the foundation riverbed increased markedly. As the cracking width increased, the riverbed seepage discharge rose correspondingly. However, this local leakage at the base of the cutoff wall had minimal impact on the hydraulic head distribution in the dam body and posed no threat to overall seepage safety. [Conclusion] The findings provide a theoretical basis for optimizing seepage control design in rockfill-based earth dam heightening project and offer important guidance for advancing scientific and precise anti-seepage design in old reservoir heightening projects in China.

Key words: old dam heightening project, hydraulic head distribution, seepage discharge, hydraulic gradient, waterstop failure, seepage safety

中图分类号:

TV641土石坝(当地材料坝、填筑坝)

岑威钧, 郑小雨, 邓成发, 曹艺凡. 土坝加高堆石坝工程防渗安全性分析[J]. raybet体育在线院报, 2025, 42(6): 147-153.

CEN Wei-jun, ZHENG Xiao-yu, DENG Cheng-fa, CAO Yi-fan. Seepage Safety of a Rockfill-based Earth Dam Heightening Project[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(6): 147-153.

图/表 12

图1 大坝加高后典型断面示意图

Fig.1 Typical cross-section of dam after heightening

图2 大坝三维渗流场有限元计算网格

Fig.2 Finite element mesh of three-dimensional seepage field of dam

表1 大坝各分区渗透系数

Table 1 Permeability coefficients of different dam zones

序号	名称	渗透系数/ (cm·s^-1)	序号	名称	渗透系数/ (cm·s^-1)
1	混凝土(面板、趾板等)	1.00×10^-7	7	含碎石黏土	1.00×10^-4
1	混凝土(面板、趾板等)	1.00×10^-7	8	混凝土防渗墙	1.00×10^-7
2	垫层	1.00×10^-3	9	基岩帷幕灌浆	5.00×10^-5
3	过渡层	1.00×10^-2	10	5 Lu等值线以上岩体	3.00×10^-4
4	上游堆石区	5.00×10^-2	10	5 Lu等值线以上岩体	3.00×10^-4
5	下游堆石区	1.00×10^-1	11	5 Lu等值线以下岩体	3.00×10^-5
6	黏土	1.00×10^-5	11	5 Lu等值线以下岩体	3.00×10^-5

图3 正常蓄水位下加高后大坝典型剖面等水头线分布

Fig.3 Distribution of hydraulic head contours of typical dam cross-section after heightening under normal water level

表2 不同特征水位下大坝及坝基渗流量

Table 2 Seepage discharge of dam and dam foundation under different characteristic water levels L/s

工况	不同分区渗流量						总渗流量
工况	老坝加高坝体	右岸延伸段坝体	左岸混凝土坝坝体	河床	左岸	右岸	总渗流量
正常蓄水位	0.07	0.05	0.002	7.14	3.55	11.24	22.05
死水位	—	—	—	3.16	—	0.33	3.49
设计洪水位	0.08	0.07	0.002	7.57	4.53	12.34	24.59
校核洪水位	0.09	0.07	0.002	7.65	4.69	12.52	25.02

表3 不同特征水位下大坝各部位最大渗透坡降

Table 3 Maximum seepage gradient of different parts of dam under different characteristic water levels

工况	面板	垫层	过渡层	堆石区	黏土心墙	老坝坝壳	帷幕	防渗墙
正常蓄水位	100.25	0.44	0.19	0.08	0.56	0.33	11.87	25.60
死水位	—	—	—	0.01	0.30	0.03	2.67	9.13
设计洪水位	104.96	0.48	0.20	0.08	0.58	0.34	12.15	26.92
校核洪水位	105.76	0.49	0.20	0.08	0.59	0.34	12.84	27.16
允许渗透坡降	200.00	0.90	0.60	0.35	0.65	0.50	20.00	80.00

图4 大坝面板周边缝变形最大位置

Fig.4 Location of maximum deformation at peripheral joint of dam panel

图5 周边缝局部失效宽度8 cm时典型剖面(坝0+85.00)等水头线分布

Fig.5 Distribution of hydraulic head contours at typical cross-section (dam 0+85.00) with 8 cm local failure width of peripheral joint

表4 周边缝止水局部失效时坝体及坝基渗流量

Table 4 Seepage discharge of dam and dam foundation under local waterstop failure at peripheral joint

周边缝失效宽度/ cm	不同分区渗流量/(L·s^-1)						总渗流量/ (L·s^-1)
周边缝失效宽度/ cm	老坝加高坝体	右岸延伸段坝体	左岸混凝土坝坝体	河床	左岸	右岸	总渗流量/ (L·s^-1)
2	2.38	0.05	0.002	7.74	3.54	11.29	25.00
4	3.36	0.05	0.002	8.13	3.53	11.33	26.40
8	4.34	0.05	0.002	8.52	3.52	11.38	27.81

图6 防渗墙拉应力峰值区

Fig.6 Peak tensile stress area of cutoff wall

图7 防渗墙局部开裂8 cm时典型剖面等水头线分布

Fig.7 Distribution of hydraulic head contours in typical cross-section with 8 cm local cracking in cutoff wall

表5 防渗墙局部开裂时坝体及坝基渗流量

Table 5 Seepage discharge of dam and dam foundation with local cracking in cutoff wall

防渗墙开裂宽度/cm	不同分区渗流量/(L·s^-1)						总渗流量/ (L·s^-1)
防渗墙开裂宽度/cm	老坝加高坝体	右岸延伸段坝体	左岸混凝土坝坝体	河床	左岸	右岸	总渗流量/ (L·s^-1)
2	0.07	0.05	0.002	11.30	3.74	11.27	26.43
4	0.07	0.05	0.002	13.44	3.81	11.29	28.66
8	0.07	0.05	0.002	14.94	3.85	11.31	30.22

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