甘肃南部典型小流域泥石流灾变链预测研究
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摘要
基于前人对灾害链的研究及实地勘察,分析山地灾害链的发育类型与结构,采用SINMAP斜坡稳定性分析模型,进行小流域斜坡稳定性数值模拟,分析流域内不稳定区域分布特征。利用多重灾种链式演化模式中的聚焦型模型,分析典型小流域泥石流沟汉林沟链首地质灾害发育特征,结果表明其链首灾种为地裂缝、崩塌、滑坡、坡面泥石流及沟谷泥石流。由于汉林沟沟口相对狭窄,沟道的排导能力较弱,在极端降雨或其他地球外营力下形成的大型沟谷泥石流,极易形成堰塞湖,堰塞湖坝体在无法承受巨大的泥石流体冲击时,极易发生坝体溃决,形成大型山洪灾害,因此汉林沟流域发生泥石流灾害后最终形成的灾害链为山洪灾变链。
Based on previous research and field investigation of the hazards chain,this paper analyzed the development type and structure of mountain hazards chain,using SINMAP slope stability analysis model to do numerical simulation of small watershed slope stability and analyze the regional distribution characteristics of instability in the basin. Using the focused model in the multiple hazards chain evolution model,it analyzed the development characteristics of geological hazards chain in the typical debris flow gully of small watershed—the Hanlin gully.The results show that the hazard types of chain head are ground fissure,collapse,landslide,slope debris flow and gully debris flow. Due to the relatively narrow opening of Hanlin gully and the channel drainage capacity is weak,large-scale gully debris flow is formed by extreme rainfall or other extrasolar forces,so a barrier lake is easily formed. Once barrier lake dam can't withstand the impact of huge debris flow,dam collapse is very likely to form major mountain flood disasters. Therefore,the mountain flood hazards chain forms the finally hazards chain after the debris flow hazard occurred in the Hanlin gully.
Based on previous research and field investigation of the hazards chain,this paper analyzed the development type and structure of mountain hazards chain,using SINMAP slope stability analysis model to do numerical simulation of small watershed slope stability and analyze the regional distribution characteristics of instability in the basin. Using the focused model in the multiple hazards chain evolution model,it analyzed the development characteristics of geological hazards chain in the typical debris flow gully of small watershed—the Hanlin gully.The results show that the hazard types of chain head are ground fissure,collapse,landslide,slope debris flow and gully debris flow. Due to the relatively narrow opening of Hanlin gully and the channel drainage capacity is weak,large-scale gully debris flow is formed by extreme rainfall or other extrasolar forces,so a barrier lake is easily formed. Once barrier lake dam can't withstand the impact of huge debris flow,dam collapse is very likely to form major mountain flood disasters. Therefore,the mountain flood hazards chain forms the finally hazards chain after the debris flow hazard occurred in the Hanlin gully.
引文
[1]王建秀,邹宝平,陈学军.泗顶铅锌矿塌陷地生态环境灾变链式机制及灾害环境整治[J].自然灾害学报,2013,22(1):60-66.
[2]文传甲.论大气灾害链[J].灾害学,1994,9(3):1-6.
[3]文传甲.广义灾害、灾害链及其防治探讨[J].灾害学,2000,15(4):14-19.
[4]李明,唐红梅,叶四桥.典型地质灾害链式机理研究[J].灾害学,2008,23(1):1-5.
[5]宋志,邓荣贵,陈泽硕.典型泥石流堵河案例运动过程与堆积区特征分析:以四川石棉熊家沟泥石流为例[J].自然灾害学报,2016,25(1):74-80.
[6]韩金良,吴树仁,汪华斌.地质灾害链[J].地质前缘,2007,14(6):11-21.
[7]吴瑾冰,郭安红.华北及邻近地区的巨灾链[J].自然灾害学报,2001,10(1):12-16.
[8]肖盛燮.生态环境灾变链式理论原创结构梗概[J].岩石力学与工程学报,2006,25(增刊1):2593-2602.
[9]徐梦珍,王兆印,漆力健.汶川地震引发的次生灾害链[J].山地学报,2012,30(4):502-512.
[10]王土革,钟敦伦,张小刚,等.山地灾害及防灾减灾基本知识[M].成都:四川大学出版杜,2005:58-60.
[11]崔云,孔纪名,田述军,等.强降水在山地灾害链成灾演化中的关键作用控制[J].山地学报,2011,29(1):87-94.
[12]范海军,肖盛燮,郝艳广,等.自然灾害链式效应结构关系及其复杂性规律研究[J].岩石力学与工程学报,2006,25(增刊1):2603-2610.
[13]钟敦伦,谢洪,韦方强,等.论山地灾害链[J].山地学报,2013,31(3):314-326.
[14] ZHANG Peng,MA Jinzhu,SHU Heping,et al. Simulating Debris Flow Deposition Using a Two-Dimensional Finite Model and Soil Conservation Service-Curve Number Approach for Hanlin Gully of Southern Gansu(China)[J]. Environmental Earth Sciences,2015,73(10):6417-6426.
[15] MONTGOMERY D R,DIETRICH W E. A PhysicallyBased Model for the Topographic Control on Shallow Landsliding[J]. Water Resources Research,1994,30(4):1153-1171.
[16] PACK R,TARBOTON D,GOOGWIN C,et al. SINMAP2.0 for Arc GIS:A Stability Index Approach to Terrain Stability Hazard Mapping,User’s Manual[M]. Logan,Utah State,USA:Utah State University,2005:15-20.
[17]肖盛燮.灾变链式演化跟踪技术[M].北京:科学出版社,2011:12-15.
[18]崔云,孔纪名,吴文平.汶川地震次生山地灾害链成灾特点与防治对策[J].自然灾害学报,2012,21(1):109-116.
[2]文传甲.论大气灾害链[J].灾害学,1994,9(3):1-6.
[3]文传甲.广义灾害、灾害链及其防治探讨[J].灾害学,2000,15(4):14-19.
[4]李明,唐红梅,叶四桥.典型地质灾害链式机理研究[J].灾害学,2008,23(1):1-5.
[5]宋志,邓荣贵,陈泽硕.典型泥石流堵河案例运动过程与堆积区特征分析:以四川石棉熊家沟泥石流为例[J].自然灾害学报,2016,25(1):74-80.
[6]韩金良,吴树仁,汪华斌.地质灾害链[J].地质前缘,2007,14(6):11-21.
[7]吴瑾冰,郭安红.华北及邻近地区的巨灾链[J].自然灾害学报,2001,10(1):12-16.
[8]肖盛燮.生态环境灾变链式理论原创结构梗概[J].岩石力学与工程学报,2006,25(增刊1):2593-2602.
[9]徐梦珍,王兆印,漆力健.汶川地震引发的次生灾害链[J].山地学报,2012,30(4):502-512.
[10]王土革,钟敦伦,张小刚,等.山地灾害及防灾减灾基本知识[M].成都:四川大学出版杜,2005:58-60.
[11]崔云,孔纪名,田述军,等.强降水在山地灾害链成灾演化中的关键作用控制[J].山地学报,2011,29(1):87-94.
[12]范海军,肖盛燮,郝艳广,等.自然灾害链式效应结构关系及其复杂性规律研究[J].岩石力学与工程学报,2006,25(增刊1):2603-2610.
[13]钟敦伦,谢洪,韦方强,等.论山地灾害链[J].山地学报,2013,31(3):314-326.
[14] ZHANG Peng,MA Jinzhu,SHU Heping,et al. Simulating Debris Flow Deposition Using a Two-Dimensional Finite Model and Soil Conservation Service-Curve Number Approach for Hanlin Gully of Southern Gansu(China)[J]. Environmental Earth Sciences,2015,73(10):6417-6426.
[15] MONTGOMERY D R,DIETRICH W E. A PhysicallyBased Model for the Topographic Control on Shallow Landsliding[J]. Water Resources Research,1994,30(4):1153-1171.
[16] PACK R,TARBOTON D,GOOGWIN C,et al. SINMAP2.0 for Arc GIS:A Stability Index Approach to Terrain Stability Hazard Mapping,User’s Manual[M]. Logan,Utah State,USA:Utah State University,2005:15-20.
[17]肖盛燮.灾变链式演化跟踪技术[M].北京:科学出版社,2011:12-15.
[18]崔云,孔纪名,吴文平.汶川地震次生山地灾害链成灾特点与防治对策[J].自然灾害学报,2012,21(1):109-116.
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