降雨–地下水耦合诱发花岗岩风化料路基边坡渗透破坏超重力模型试验研究

doi:10.3724/1000-6915.jrme.2025.0638

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摘要为揭示花岗岩风化料填方路基边坡在降雨与地下水耦合作用下的渗流–变形破坏机制，开展超重力离心模型试验与有限元数值模拟研究。2组超重力试验均表现为受后缘水位快速抬升引发的渗透破坏，破坏时后缘临界水位均约为12 m，边坡模型内部临界水力梯度约为0.47。经超重力试验验证的有限元模型结果表明，边坡渗透破坏的主因为后缘水位快速增长导致的局部水力梯度激增，其产生的渗透力诱发边坡内部发生侵蚀管涌破坏。此外，当坡脚细粒发生淤堵、渗透性降低时，地下水位升高会显著降低边坡稳定性；当坡脚细粒发生流失、渗透性提高时，地下水位降低会有效提升边坡稳定性。水力梯度由边坡坡面向后缘呈阶梯式降低，这一分布特征与侵蚀管涌破坏由坡面向后缘发展的过程协调一致，直至管涌通道贯通后，边坡前后水力梯度趋于一致。研究结果对同类路基边坡水力破坏的防治设计与工程实践等具有重要借鉴意义。

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	赵宇1
	2*
	闫状1
	詹良通1
	柳景淳1
	张瑞1
	吴逸1

关键词 ：边坡工程, 路基边坡, 超重力试验, 地下水, 渗透破坏, 花岗岩风化料

Abstract：To elucidate the seepage-deformation failure mechanism of subgrade slopes filled with completely decomposed granite (CDG), hypergravity model tests and finite element analyses were conducted to examine the coupled effects of groundwater and rainfall. In both hypergravity tests, seepage failure occurred at the trailing edge due to a rapid rise in the water level. The critical water level at the trailing edge was approximately 12 m, and the critical hydraulic gradient within the slope model was around 0.47 for both tests. The finite element model, validated by the hypergravity tests, indicates that the onset of osmosis failure is primarily attributed to a surge in the local hydraulic gradient resulting from the swift increase in water level at the trailing edge; subsequently, seepage leads to backward piping failure within the slope. Furthermore, as fine particles accumulate and permeability decreases at the slope toe, the stability of the slope diminishes with the rise in groundwater level. Conversely, when fine particles at the slope toe are eroded and permeability increases, the groundwater level decreases, resulting in enhanced slope stability. The hydraulic gradient gradually diminishes from the slope surface to the trailing edge, aligning with the development process of backward piping failure, until the piping channel is fully formed and the hydraulic gradients on both the front and back of the slope become consistent. These findings provide valuable insights for mitigating water-induced failures in similar subgrade slopes.

Key words： slope engineering subgrade slope hypergravity test groundwater seepage failure completely decomposed granite

引用本文:

赵宇1，2*，闫状1，詹良通1，柳景淳1，张瑞1，吴逸1. 降雨–地下水耦合诱发花岗岩风化料路基边坡渗透破坏超重力模型试验研究[J]. 岩石力学与工程学报, 2026, 45(5): 1336-1347.
ZHAO Yu1, 2*, YAN Zhuang1, ZHAN Liangtong1, LIU Jingchun1, ZHANG Rui1, WU Yi1. Hypergravity model tests of rainfall-groundwater coupling induced seepage failure of CDG filled subgrade slope. , 2026, 45(5): 1336-1347.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0638 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I5/1336

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