重庆小南海滑坡原始地形恢复及滑坡体体积计算

doi:10.3969/j.issn.0253-4967.2020.04.011

摘要/Abstract

摘要： 重庆黔江小南海崩塌滑坡发生于1856年, 属于历史地震诱发滑坡。由于无法获取震前的遥感影像及DEM数据, 只能依据相邻地区地貌类比、数值模拟等推测滑坡发生前的原始地貌形态。文中通过野外实地调查和无人机航拍、水域密集人工测深等方法获取了小南海崩塌滑坡体及相邻地区的高精度DOM影像(数字正射影像图)和DEM数据。选取相邻地区未发生崩塌滑坡的2类地貌形态作为参考, 利用MATLAB软件进行高程曲面拟合, 对崩塌滑坡的原始形态进行恢复; 采用Geostudio软件判断在地震动作用下2类山体原始形态的边坡稳定性, 推测崩塌滑坡前山体的原始形态为高耸陡立、坡度为70°~80°的陡坡; 并收集整理小南海堰塞坝2条测线、 11个钻孔的钻井资料, 通过钻井资料显示的谷底地形对恢复的河谷原始地形的可信度进行验证。最后, 对拟合恢复的小南海山体原始DEM数据与滑坡后当前DEM数据进行填挖方计算, 以估算崩塌滑坡体的体积, 并对分析结果进行探讨, 最终认为挖方计算的结果较为可信, 滑坡体的体积为4.3×10⁷m³。

关键词: 重庆小南海, 山体崩塌滑坡, 高程曲面拟合, 滑坡体积计算

Abstract: As documented in history, an M6¼ earthquake occurred between Qianjiang, Chongqing and Xianfeng, Hubei(also named the Daluba event)in 1856. This earthquake caused serious geological hazards, including a lot of landslides at Xiaonanhai, Wangdahai, Zhangshangjie and other places. Among them, the Xiaonanhai landslide is a gigantic one, which buried a village and blocked the river, creating a quake lake that has been preserved to this day. As the Xiaonanhai landslide is a historical earthquake-induced landslide, it is impossible to obtain the remote sensing image and DEM data before the earthquake, which brings certain difficulties to the estimation of landslide volume and the establishment of numerical simulation model. In this paper, the original topography before the earthquake is inferred by the methods of geomorphic analogy in adjacent areas and numerical simulation, and the volume of the Xiaonanhai landslide body is calculated. Firstly, the principle and application of UAV aerial photography are introduced. We employed an unmanned airplane to take pictures of the Xiaonanhai landslide and adjacent areas, yielding high-precision DOM images(digital orthophoto graph)and DEM data which permit generating terrain contours with a 25m interval. We also used the method of intensive manual depth measurement in waters to obtain the DEM data of bottom topography of Xiaonanhai quake lake. Based on field investigations, and combining terrain contours and DOM images, we described the sizes and forms of each slump mass in detail. Secondly, considering that the internal and external dynamic geological processes of shaping landforms in the same place are basically the same, the landforms such as ridges and valleys are also basically similar. Therefore, combining with the surrounding topography and landform of the Xiaonanhai area, we used MATLAB software to reconstruct two possible original landform models before the landslide. The original topography presented by model A is a relatively gentle slope, with a slope of 40°~50°, and the original topography presented by model B is a very high and steep slope, with a slope of 70°~80°. Thirdly, Geostudio software is used to conduct numerical simulation analysis on the slope stability. The safety factor of slope stability and the scale of landslide are analyzed under the conditions of static stability, seismic dynamic response and seismic dynamic response considering topographic amplification effect. The results show that large landslide is more likely to occur in model B, which is more consistent with the reality. In order to verify the credibility of recovered DEM data of valley bottom topography, we visited the government of Qianjiang District, collected the drilling data of 11 boreholes in two survey lines of Xiaonanhai weir dam. It is verified that the recovered valley bottom elevation is basically consistent with that revealed by the borehole data. Finally, according to the two kinds of topographic data before and after the landslide, the volume of the landslide is calculated by using the filling and excavation analysis function of ArcGIS software. There is a gap between the calculation results of filling and excavation, the filling data is 3×10⁶m³ larger than the excavation data. The reasons are mainly as follows: 1)Due to the disorderly accumulation of collapse blocks, the porosity of the accumulation body became larger, causing the volume of the fill to expand; 2)It has been more than 150a since the Xiaonanhai earthquake, and the landslide accumulation has been seriously reconstructed, therefore, there are some errors in the filling data; 3)The accumulation body in Xiaonanhai quake lake might be subject to erosion and siltation, this may affect the accuracy of the filling data. In conclusion, it is considered that the calculated results of the excavation are relatively reliable, with a volume of 4.3×10⁷m³.

Key words: Xiaonanhai in Chongqing, landslide, elevation surface fitting, volume calculation of landslide

中图分类号:

P642.27

周鑫, 周庆, 高帅坡, 李晓峰. 重庆小南海滑坡原始地形恢复及滑坡体体积计算[J]. 地震地质, 2020, 42(4): 936-954.

ZHOU Xin, ZHOU Qing, GAO Shuai-po, LI Xiao-feng. RESTORATION OF THE ORIGINAL TOPOGRAPHY OF THE XIAONANHAI LANDSLIDE IN CHONGQING AND CALCULATION OF ITS VOLUME[J]. SEISMOLOGY AND GEOLOGY, 2020, 42(4): 936-954.

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