Characteristics of the development, formation mechanism and prevention suggestions of the geological disasters in FAST protected areas
-
摘要: FAST(中国天眼)保护区内地质灾害发育,目前共有在册地质灾害132处,属地质灾害高易发区域,区内地质灾害隐患已对FAST工程的安全运行构成威胁。本文以FAST保护区现有地质灾害为研究对象,采用实地调查、资料收集、数理统计等方法,对保护区内地质灾害的发育特征进行分析,建立地质灾害关联模型,研究区内地质灾害孕灾条件及影响因素之间的耦合关系,并对区内地质灾害成因机理进行分析研究,提出了防治措施及监测预警建议。FAST保护区滑坡地质灾害主要有“牵引式”、“推移式”两种破坏力学模式,其中小型滑坡多呈“牵引式”破坏,中型、大型滑坡多呈“推移式”破坏;区内崩塌危岩体的主要破坏模式有“倾倒式”、“坠落式”、“滑移式”。区内地质灾害主要诱发因素是强降雨和人类工程活动,因此,强降雨前后应做好地质灾害巡查防控,区内开展岩土工程活动前需做好科学评估和规划,避免人为引发地质灾害。Abstract: Geological disasters are development in the FAST (Five-hundred-meter Aperture Spherical radio Telescope) protected area which is geological disasters prone area where 132 registered geological disasters exist. Hidden hazards of geological disasters in this area have posed threats to the safe operation of the FAST project. In this paper, the existing geological disasters in the FAST protected area are taken as the research objects, methods of field investigation, data collection and mathematical statistics are adopted to analyze the development characteristics of geological disasters in the protected area. The correlation model of geological disasters is established to study the coupling relationship between the disaster-breeding conditions and influencing factors of geological disasters, the formation mechanism is analyzed and studied,and the prevention and control measures and monitoring suggestions are also put forward. As a result, the landslide in FAST protected area are mainly divided into two mechanical failure modes, namely, “traction type” and “push type”. Small landslides are mostly “traction type”, and medium and large landslides are mostly “push type”. The main failure modes of dangerous rock mass in the area are “toppling”, “falling” and “sliding”. Heavy rainfall and human engineering activities are the main inducing factors of geological disasters in the area. therefore, geological disaster inspection and prevention should be carried out before and after heavy rainfall. Scientific assessment and planning should be made before carrying out geotechnical engineering activities to avoid man-made geological disasters.
-
-
[1] 朱博勤,严召进,白文胜,等.FAST工程勘察技术理论与实践[M].武汉:湖北科学技术出版社,2021.ZHU Boqin, YAN Zhaojin, BAI Wensheng, et al. Theory and Practice of FAST Engineering Survey Technology[M]. Wuhan: Hubei Science and Technology Press, 2021.
[2] [2] 南仁东.500m球反射面射电望远镜FAST[J].中国科学G辑,2005,35(5):449-466.
Rendong NAN. 500m spherical radio telescope FAST[J]. Science in China Ser G., 2005,35(5):449-466.
[3] [3] 陈垿.贵州省高位隐蔽性地质灾害特征及防治措施探究[J].冶金与材料,2020(5):62.CHEN Xu. Probe into the Characteristics and prevention measures of hidden geological hazards in high-level areas in Guizhou Province[J]. Metallurgy and Materials, 2020(5):62.
[4] [4] 沈志平,孙洪,吴斌,等.岩溶洼地地区典型地质灾害与防治对策建议[J].中国地质灾害与防治学报,2016,27(2):137-144.
SHEN Zhiping, SUN Hong, WU Bin, et al. Study on typical geologic hazard in karst depressions and its countermeasures[J]. The Chinese Journal of Geological Hazard and Control, 2016,27(2):137-144.
[5] [5] 杨志刚.FAST台址岩土工程危岩与崩塌堆积体专项勘察报告[R].贵阳:贵州地质工程勘察设计研究院,2010.YANG Zhigang. Special investigation report on dangerous rock and collapse accumulation body of geotechnical engineering at FAST astronomical site[R]. Guiyang: Guizhou Institute of Geological Engineering Investigation and Design, 2010.
[6] [6] 余永康,李振庆.FAST工程台址区危岩综合治理技术及应用[J].科学技术创新,2019(7):83-85.
YU Yongkang, LI Zhenqing. Comprehensive treatment technology and application of dangerous rock in FAST astronomical site[J]. Science and Technology Innovation,2019(7):83-85.
[7] [7] 黄青能.滑坡、崩塌和危岩地质灾害的发育特征及形成机制[J].中国资源综合利用,2020,38(7):158-165.
HUANG Qingneng. Development characteristics and formation mechanism of landslides, collapses and dangerous rock geological disasters[J]. China Resources Comprehensive Utilization, 2020,38(7):158-165.
[8] [8] 戴传固,王雪华,陈建书,等.中国区域地质志·贵州志[M].北京:地质出版社,2013.DAI Chuangu, WANG Xuehua, CHEN Jianshu. Editorial Board of the Regional Geology of China, Guizhou Province[M]. Beijing: Geological Publishing House, 2013.
[9] [9] 白永健,铁永波,孟铭杰,等.川西地区地质灾害发育特征与时空分布规律[J].沉积与特提斯地质,2022,42(4):666-674.
BAI Yongjian, Yongbo TIE, MENG Mingjie, et al. Characteristics and temporal-spatial distribution of geohazards in westem Sichuan[J]. Sedimentary Geology and Tethyan Geology, 2022,42(4):666-674.
[10] [10] 铁永波,张宪政,龚凌枫,等.西南山区典型地质灾害链成灾模式研究[J].地质力学学报,2022,28(6):1071-1080.
Yongbo TIE, ZHANG Xianzheng, GONG Lingfeng, et al. Research on the pattem of typical geohazard chains in the southwest mountainous region, China[J]. Journal of Geomechanics, 2022,28(6):1071-1080.
[11] [11] 吴瑞安,郭长宝,杜宇本,等.川藏铁路加查—朗县段地质灾害发育特征研究[J].现代地质,2017,31(5):956-964.
WU Ruian, GUO Changbao, DU Yuben, et al. Research on geohazard developing characteristics in Jiacha to Langxian section of Sichuan-Tibet Railway[J]. Geoscience, 2017,31(5):956-964.
[12] [12] 闫金凯,马娟,冯春.FAST台址巨石混合体边坡开挖稳定性分析[J].中国地质灾害与防治学报,2012,23(2):25-29.
YAN Jinkai, MA Juan, FENG Chun. Stability analysis of large rock mixture slope under excavation in FAST location[J]. The Chinese Journal of Geological Hazard and Control, 2012,23(2):25-29.
[13] [13] 邓珊珊,陈洪凯,游来凤.喀斯特山区危岩崩塌形成机制研究——以三峡库区巫溪海螺湾危岩为例[J.重庆师范大学学报(自然科学版),2012,29(6):35-39.
DENG Shanshan, CHEN Hongkai, YOU laifeng. Developing mechanics for perilous in karst area: Taking the Hailuo bay in the Three Gorges as an example[J]. Journal of Chongqing Jiaotong University (Natural Science), 2012,29(6):35-39.
[14] [14] 王林峰,唐红梅,陈洪凯.陡崖上群发性危岩崩塌机理研究[J].武汉理工大学学报,2010,32(6):1-5.
WANG Linfeng, TANG Hongmei, CHEN Hongkai. Research on the mechanism of multiple rocks on the cliff collapse[J]. Journal of Wuhan University of Technology, 2010,32(6):1-5.
[15] [15] 王运生,程万强,刘江伟.川藏铁路廊道泸定段地质灾害孕育过程及成灾机制[J].地球科学,2022,47(3):950-958.
WANG Yunsheng, CHENG Wanqiang, LIU Jiangwei. Forming process and mechanisms of geo-hazards in Luding section of the Sichuan-Tibet Railway[J]. Earth Science, 2022,47(3):950-958.
[16] [16] 李芳,梅红波,王伟森,等.降雨诱发的地质灾害气象风险预警模型:以云南省红河州监测示范区为例[J].地球科学,2017,42(9):1637-1646.
LI Fang, MEI Hongbo, WANG Weisen, et al. Rainfall-induced meteorological early warning of geo-hazards model: Application to the monitoring demonstration area in Honghe prefecture, Yunnan Province[J]. Earth Science, 2017,42(9):1637-1646.
[17] [17] 李海如.福建平和县西环路滑坡防治工程勘察实践与稳定性分析[J].探矿工程(岩土钻掘工程),2020,47(12):72-78.LI Hairu. Site investigation and stability analysis for landslide control along Xihuan Road, Pinghe County, Fujian Province[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2020,47(12):72-78.
[18] [18] 张田田,杨为民,万飞鹏.浑河断裂带地质灾害发育特征及其成因机制[J].吉林大学学报(地球科学版),2022,52(1),149-161.
ZHANG Tiantian, YANG Weimin, WAN Feipeng. Characteristirs and form ation mechanis m of geohnzands in Hunhe Fault Zone[J]. Journal of Jilin University (Earth Science Edition), 2022,52(1):149-161.
[19] [19] 李洪梁,高波,张佳佳,等.内外动力地质作用耦合的崩塌形成机理研究:以藏东昌都地区上三叠统石灰石矿山采场崩塌为例[J].地质力学学报,2022,28(6):995-1011.
LI Hongliang, GAO Bo, ZHANG Jiajia, et al. Mechanism of rock fall coupled with endogenic and exogenic geological processes: A case study in the upper Triassic Limestone mines in the Qamdo area,eastern Tibet[J] . Journal of Geomechanics, 2022,28(6):995-1011.
[20] [20] 叶振南,杨强,李强,等.燕子河流域地质灾害发育特征与危险性评价[J].辽宁工程技术大学学报(自然科学版),2020,39(2):145-151.
YE Zhennan, YANG Qiang, LI Qiang, et al. Landslide characteristics and hazard assessment in Yanzi River Basin[J]. Journal of Liaoning Technical University (Natural Science), 2020,39(2):145-151.
[21] [21] 崔华丽,杨东旭,杨栋,等.狭陡型泥石流成灾特征与防治对策研究——以阿坝州金川县刘家沟泥石流为例[J].钻探工程,2022,49(6):122-129.
CUI Huali, YANG Dongxu, YANG Dong, et al. Disaster characteristics and prevention measures of narrow-steep debris flow—A case study of Liujia gully in Jinchuan County, Aba Prefecture, Sichuan Province[J]. Drilling Engineering, 2022,49(6):122-129.
[22] [22] 许强,董秀军,李为乐.基于天-空-地一体化的重大地质灾害隐患早期识别与监测预警[J].武汉大学学报·信息科学版,2019,44(7):957-966.
XU Qiang, DONG Xiujun, LI Weile. Integrated space-air-ground early detection, monitoring and warning system for potential catastrophic geohazards[J]. Geomatics and Information Science of Wuhan University, 2019,44(7):957-966.
-
计量
- 文章访问数: 199
- PDF下载数: 37
- 施引文献: 0
下载: