地球科学进展

地球科学进展 ›› 2015, Vol. 30 ›› Issue (1): 26 -36. doi: 10.11867/j.issn.1001-8166.2015.01.0026

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黄土滑塌研究进展
唐亚明 1, 2( ), 冯卫 1, 2, 李政国 1, 2   
  1. 1.中国地质调查局西安地质调查中心, 陕西 西安 710054
    2.国土资源部黄土地质灾害重点实验室, 陕西 西安 710054
  • 收稿日期:2014-09-24 修回日期:2014-12-06 出版日期:2015-03-05
  • 基金资助:
    中国地质调查局项目“延安宝塔区地质灾害监测预警示范”(编号:1212010740907);国家自然科学基金项目“陕北砂性黄土滑塌变形破坏机制研究”(编号:41202256)资助

A Review of the Study of Loess Slump

Yaming Tang 1, 2( ), Wei Feng 1, 2, Zhengguo Li 1, 2   

  1. 1. Xi’an Center of China Geology Survey, Xi’an 710054, China
    2. Key Laboratory for Geo-hazards in Loess Area, China Ministry of Land and Resources, Xi’an 710054, China
  • Received:2014-09-24 Revised:2014-12-06 Online:2015-03-05 Published:2015-01-20
全文 ( 3 ) 下载PDF ( 869 )

黄土高原北部的黄土由于含砂量高, 广泛发育一种既不同于黄土滑坡、又不同于黄土崩塌的独立地质灾害类型——黄土滑塌。由于砂黄土的弱胶结性使得黄土滑塌呈现出某些不同于典型黄土滑坡的特点。从分布区域上看, 它位于黄土高原的I带, 即砂黄土带;从发育的典型地质环境看, 受制于当地特殊的土地资源和居住条件;从风险特征看, 有“坍窑不坍掌”的特点;从诱发因素看, 是降雨、冻融、冻胀、人工开挖等各种因素的综合作用。关于其变形破坏机制, 不同的学者提出了不同的见解, 有先塌后滑式、先滑后塌式、中部向两头延伸式和整体错落式, 最新的研究表明其符合下部剪切破坏上部拉张倒塌模式, 至于其微观机理方面的研究还很少。今后的研究应进一步查明诱发因素, 总结该类滑坡变形破坏特征, 综合运用数值和物理模拟手段, 建立不同诱发因素影响下的地质力学模型, 基于应力—应变关系, 定量分析黄土滑塌的变形破坏机制, 阐明其微观机理。

关键词: 地质灾害, 黄土滑塌, 砂黄土, 诱发因素, 变形破坏

There has widely developed a specific kind of landslide-loess slump in the north of loess plateau in China, which is different from loess slide or loess fall because of the high sandy ingredient in loess. Due to the weak cement of sandy loess, the slump shows some other features than “typical” loess landslide. In distribution scopes, it often occurres in sandy loess belt, beyond that there are clay loess belt and silty clay loess belt. Due to the extreme shortage of land resources, the local people often choose the concave banks of valley as the cave dwellings sites whereas the convex banks are kept to develop agriculture. Generally, the concave banks have already been eroded much by rivers which makes the level stress of the slope release. However, the excavation for constructions reduces the level stress furthermore. Therefore, it causes the shear stress increase at the feet of the slope. The equilibrium state of the slope is destroyed, and then the failure occurres. The triggering factors of loess slump include rainfall, freeze thawing, freeze swelling, excavation, etc. In fact, these factors often comprehensively affect the slumps. In terms of their deformation and failure mechanism, scientists put forward different views, which include falling firstly and sliding secondly, sliding firstly and fall secondly, from middle parts rupture extending to top and bottom, and integrated sliding and falling. The nearest research implies that the failure mechanism be the bottom shearing failure and then the top tension failure. Referring to the failure mechanism at a micro level, few researches have been done to this kind of landslide. Future studies should investigate the triggering factors widely and deeply, summarize the characteristics of the deformation and failure, apply the numerical and physical simulation methods comprehensively, build up the geological-mechanic model, analyze and clarify the deformation and failure mechanisms quantitatively on the basis of strain and stress relationship, and study the failure mechanisms on a micro level.

Key words: Geo-hazards, Loess slump, Sandy loess, Triggering factor, Deformation and failure.

中图分类号: 

图1 陕西榆林子洲石沟2010年3月10日大型黄土滑塌
Fig.1 The large loess slump occurred at Shannxi Yulin Zizhou Shigou on March 10th, 2010
表1 黄土滑坡、崩塌、滑塌的不同特点
Table.1 The different features of loess slide, loess fall and loess slump
特点 黄土滑坡 黄土崩塌 黄土滑塌
特点 黄土滑坡 黄土崩塌 黄土滑塌
易发层位 黄土与基岩或古土壤接触面 纯黄土地层 纯黄土地层
体积 体积较大 体积较小 体积居中
发生部位 剪出口位于斜坡下部 崩塌体位于斜坡上部 破坏面在斜坡中部
运动形式 滑动式 崩落式 坐落式
破坏机制 剪切滑动 拉裂坠落 下部剪切上部拉张
图2 陕北砂性黄土滑塌分布范围图 [ 8 ]
Fig.2 The scope of sandy loess slumps in north of Shaanxi Province [ 8 ]
图3 黄土滑塌发育的典型地质环境
Fig.2 The typical geological environment where loess slumps occurred
图4 黄土滑塌对窑洞的破坏特征(“坍窑不坍掌”)
Fig.4 “The front destroyed whereas the rear intacted” when loess slump fall down the cave dwelling
图5 先塌后滑的破坏模式 [ 4 ]
Fig.5 Loess slump’s failure mode of falling firstly and sliding secondly [ 4 ]
图6 先滑后塌的破坏模式 [ 23 ]
Fig.6 Loess slump’s failure mode of sliding firstly and falling secondly [ 23 ]
图7 中部向两头延伸的破坏模式 [ 25 ]
Fig.7 Loess slump’s failure mode of from middle parts extending to top and bottom [ 25 ]
图8 整体错落的破坏模式 [ 27 ]
Fig.8 Loess slump’s failure mode of integrated sliding and falling [ 27 ]
图9 黄土滑塌与黄土崩塌的对比示意图
Fig.9 Illustration for the contrast of loess slump and fall
图10 扫描电镜影像显示砂黄土的弱胶结性
Fig.10 SEM image showing the existence of weakly cemented materials
表2 不同类型黄土物理力学指标
Table 2 Physical and mechanics index of different loess
测试项目

黄土类型		 干密度
/(g/cm3)		 孔隙比 液限
/%		 塑限
/%		 湿陷系数(p=200) 压缩系数(0.1~0.2)
/MPa-1		 黏聚力
/kPa		 摩擦角
 取样
地点
晚更新世 砂黄土 1.34 1.02 25.1 15.9 0.055 0.12 32 26.4 子洲县
黏粉质黄土 1.44 0.94 27.1 17.2 0.075 0.19 34 24.1 宝塔区
黏黄土 1.39 0.95 26.5 18.2 0.037 / 25 25.1 富县
中更新世 砂黄土 1.50 0.80 25.2 16.0 0.009 0.08 58 29.4 子洲县
黏粉质黄土 1.63 0.70 29.1 17.5 0.013 0.13 45 29.8 宝塔区
黏黄土 1.41 0.92 25.3 17.6 0.018 / 34 31.0 富县
早更新世 砂黄土 1.56 0.73 24.6 15.6 0.010 0.09 79 30.5 子洲县
黏粉质黄土 1.86 0.52 29.0 18.9 0.003 0.08 / 32.4 宝塔区
黏黄土 1.57 0.73 29.2 18.5 0.006 / 45 32.8 富县
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