Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province

CUI Fangpeng; LI Bin; YANG Zhongping; WU Lele; LI Ning; PENG Jianquan

doi:10.11932/karst20200408

Volume 39 Issue 4

Aug. 2020

Turn off MathJax

Article Contents

Abstract

References

Article Navigation > CARSOLOGICA SINICA > 2020 > 39(4): 524-534

CUI Fangpeng, LI Bin, YANG Zhongping, WU Lele, LI Ning, PENG Jianquan. Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province[J]. CARSOLOGICA SINICA, 2020, 39(4): 524-534. doi: 10.11932/karst20200408

Citation:

CUI Fangpeng, LI Bin, YANG Zhongping, WU Lele, LI Ning, PENG Jianquan. Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province[J]. CARSOLOGICA SINICA, 2020, 39(4): 524-534. doi: 10.11932/karst20200408

Citation:

CUI Fangpeng, LI Bin, YANG Zhongping, WU Lele, LI Ning, PENG Jianquan. Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province[J]. CARSOLOGICA SINICA, 2020, 39(4): 524-534. doi: 10.11932/karst20200408

PDF( 81352 KB)

Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province

doi: 10.11932/karst20200408

1.
School of Geoscience and Surveying Engineering, China University of Mining and Technology
2.
Institute of Geomechanics, CAGS
3.
School of Civil Engineering, Chongqing University

Publish Date: 2020-08-25

Abstract

Abstract

This paper presents a discrete element modeling using UDEC software to reproduce the dynamic response of the Pusa landslide triggered by the combination of goafs, deep major karst cracks, heavy rainfall and continual blasts during underground coal mining. Based on the reproduction, the dynamic triggering mechanism and the key contributing factors of the landslide are analyzed. The results show that caving, crack and deformation zones that developed in the strata overlying goafs during mining coal seams expand up gradually below the slope. The deformation zone meets the toe of the original slope after mining of the uppermost coal seam. Meanwhile, an obvious progressive deformation zone develops in the original slope containing the deep karst fractures. The deformation behaves as a wholly downward and clockwise movement. On the condition of the heavy rainfall, a continuous progressive deformation zone develops in the slope that has been influenced by the goafs. The deformation continues to behave more downward and clockwise movement as a whole. Finally, while the continual stope blasts, as the key contributing factor for the landslide, during the underground coal mining, the slope that has been influenced by the goafs and the heavy rainfall enters multiple-phase dynamic response stages including further progressive damage deformation, critical collapse, shattering, ejecting and compaction. Simultaneously, the whole slope exhibits a downward, apart break and clockwise rotation. These results modeling would provide a support for control of similar landslides.
- the Pusa landslide,
- dynamic triggering mechanism,
- discrete element modeling,
- goaf,
- heavy rainfall,
- stope blasting

FullText(HTML)

References(23)

References

[1]	郑光，许强，巨袁臻，等. 2017年8月28日贵州纳雍县张家湾镇普洒村崩塌特征与成因机理研［J］. 工程地质学报， 2018， 26（1）： 223-240.
[2]	彭双麒，许强，郑光，等. 碎屑流堆积物粒度分布与运动特性的关系：以贵州纳雍普洒村崩塌为例［J］. 水文地质工程地质， 2018， 45（4）： 129-136.
[3]	许强，邓茂林，李世海，等. 武隆鸡尾山滑坡形成机理数值模拟研究［J］. 岩土工程学报， 2018， 40（11）： 2012-2021.
[4]	高杨，李滨，王国章. 鸡尾山高速远程滑坡运动特征及数值模拟分析［J］. 工程地质学报， 2016， 24（3）： 425-434.
[5]	LI B， FENG Z， Wang G Z， et al. Processes and behaviors of block topple avalanches resulting from carbonate slope failures due to underground mining［J］. Environmental Earth Sciences， 2016， 75（8）：1435-1441.
[6]	李滨，王国章，冯振，等.地下采空诱发陡倾层状岩质斜坡失稳机制研究［J］.岩石力学与工程学报，2015，34（6）：1148-1161.
[7]	许强，黄润秋，殷跃平，等. 2009年“6·5”重庆武隆鸡尾山崩滑灾害基本特征与成因机制初步研究［J］. 工程地质学报，2009，17（4）：432-444.
[8]	殷跃平. 斜倾厚层山体滑坡视向滑动机制研究：以重庆武隆鸡尾山滑坡为例［J］.岩石力学与工程学报，2010，29（2）：217-226.
[9]	YIN Y P，SUN P，ZHANG M，et al. Mechanism on apparent dip sliding of oblique inclined bedding rockslide at Jiweishan，Chongqing， China［J］. Landslides，2011，8（1）：49-65.
[10]	李腾飞，李晓，李守定，等. 地下采掘诱发斜坡失稳破坏机制研究：以武隆鸡尾山崩滑为例［J］. 岩石力学与工程学报， 2012， 31（s2）： 3803-3810.
[11]	FAN X M， XU Q， GIANVITO S， et al. The “long” runout rock avalanche in Pusa， China， on August 28， 2017： a preliminary report［J］. Landslides， 2019， 16：139-154.
[12]	邓茂林，许强，郑光，等. 基于离心模型试验的武隆鸡尾山滑坡形成机制研究［J］. 岩石力学与工程学报， 2016， 35（s1）： 3024-3035.
[13]	李世俊，马昌慧，刘应明，等. 离心模型试验与数值模拟相结合研究采空边坡渐进破坏特性［J］. 岩土力学，2019，40（4）： 1-8.
[14]	冯振，殷跃平，蔡奇鹏，等. 斜倾厚层山体滑坡启动机制的模型试验研究［J］. 岩石力学与工程学报， 2014， 33（s1）： 2600-2604.
[15]	代张音，唐建新，舒国钧，等. 地下采空诱发顺层岩质斜坡变形破坏特征研究［J］. 安全与环境学报，2017，17（4）：1294-1298.
[16]	贺凯，李滨，冯振. 危岩崩塌启动机制离心模型试验研究［J］. 水文地质工程地质，2018，45（1）： 131-136.
[17]	贺凯，高杨，王文沛，等. 陡倾煤层开采条件下上覆山体变形破坏物理模型试验研究［J］. 地质力学学报，2018，24（3）：399-406.
[18]	朱赛楠，殷跃平，李滨.大型层状基岩滑坡软弱夹层演化特征研究：以重庆武隆鸡尾山滑坡为例. 工程地质学报， 2018，26（6）： 233-242.
[19]	殷跃平，刘传正，陈红旗，等. 2013. 2013年1月11日云南镇雄赵家沟特大滑坡灾害研究［J］. 工程地质学报， 2013，21（1）： 6-15.
[20]	王国章，李滨，冯振，等.重庆武隆鸡冠岭岩质崩滑-碎屑流过程模拟［J］. 水文地质工程地质， 2014，41（5）： 101-106.
[21]	谢宏，王茂春.贵州采煤塌陷引发的地质灾害及塌陷区的类型［J］. 贵州大学学报（自然科学版）， 2012，29（3）： 128-131，135.
[22]	肖锐铧，陈红旗，冷洋洋，等.贵州纳雍"8·28"崩塌破坏过程与变形破坏机理初探［J］. 中国地质灾害与防治学报，2018，29（1）：3-9.
[23]	钱鸣高. 矿山压力与岩层控制［M］. 徐州：中国矿业大学出版社，2003.

Relative Articles

[1]	WEI Lei, MEI Hongbo, ZHAO Peng, YANG Yingdong, LUO Zeyang, LIU Bowen. Research on early warning for meteorological risks of rainfall-induced landslide hazards in typical areas of southwest Yunnan[J]. CARSOLOGICA SINICA, 2024, 43(6): 1376-1385. doi: 10.11932/karst20240614
[2]	TANG Lingming, HUANG Xiang, LI Hongming, LI Jiaming, CAO Xianfa, CHEN Xuejun, LU Lixia. Field experiment on the attenuation rule of main frequency for mining blasting vibration in the karst area[J]. CARSOLOGICA SINICA, 2024, 43(2): 454-462. doi: 10.11932/karst2024y014
[3]	ZHAO Zhenhua, LUO Zhenjiang, HUANG Linxian, XING Liting, LI Hongtao, SUN Hongjie. Research on the response mechanism of groundwater level to rainfall in the western suburb of Jinan based on wavelet analysis[J]. CARSOLOGICA SINICA, 2023, 42(5): 931-939. doi: 10.11932/karst20230506
[4]	XUE Mingming, CHEN Xuejun, SONG Yu, GAO Xiaotong, LI Hui, GAN Xiaohui, ZHANG Mingzhi, PAN Zongyuan, TANG Lingming. A study on collapse law of soil cave with different rainfall rates based on FLAC3D[J]. CARSOLOGICA SINICA, 2022, 41(6): 905-914. doi: 10.11932/karst20220605
[5]	SHI Xiao, YANG Yan, LI Yidong, TIAN Ning, Ye Zhimao, LI Jiancang, DUAN Junwei. Analysis of temporal and spatial variations of CO2 migration in the soil cave system in karst critical zone：A case study of Jiguan cave, western Henan[J]. CARSOLOGICA SINICA, 2021, 40(4): 580-591.
[6]	HU Fupeng, OU Yuanchao, FU Maoru. Study on numerical simulation of karst cross-hole resistivity CT exploration at cave with different filling media[J]. CARSOLOGICA SINICA, 2019, 38(5): 766-773. doi: 10.11932/karst20190513
[7]	YU Hongzhang. Discussion on lining strength of railway tunnels in karst areas under instantaneous heavy rainfall: An example of the Yuanbaoshan tunnel of Zhijin-Bijie railway in Guizhou Province[J]. CARSOLOGICA SINICA, 2019, 38(6): 916-923. doi: 10.11932/karst2019y21
[8]	ZHANG Jiantong, CHEN Shunjun, LIU Sumei, LIN Lusheng, XU Lihua. Numerical simulation analysis of interaction of superstructure-foundation-pile foundation under hidden karst condition[J]. CARSOLOGICA SINICA, 2018, 37(5): 792-798. doi: 10.11932/karst20180518
[9]	XU Zhongping, ZHOU Xun, CUI Xiangfei, TA Mingming, WANG Xinyun, ZHANG Ying. Research advances of numerical simulation of groundwater in karst areas[J]. CARSOLOGICA SINICA, 2018, 37(4): 475-483. doi: 10.11932/karst20180401
[10]	SUN Xiliang, CHEN Liangjing, OU Jian, CHEN Wendong. Cause analyses and prevention suggestions for the karst collapse in the Fujia village of Hunan, China[J]. CARSOLOGICA SINICA, 2018, 37(3): 421-426. doi: 10.11932/karst20180313
[11]	JIAO Youjun, PAN Xiaodong, ZENG Jie, REN Kun. Numerical modeling of the influence of karst-conduit structure on variation of spring flow[J]. CARSOLOGICA SINICA, 2017, 36(5): 736-742. doi: 10.11932/karst2017y48
[12]	MAO Liang, YU Qingchun, WANG Jingxia, LI Honghui, ZHAO Shuaiwei, JIA Meilan. Numerical simulation of precipitation impact on fractured karst system evolution[J]. CARSOLOGICA SINICA, 2017, 36(1): 42-48. doi: 10.11932/karst20170105
[13]	JIANG Guang-hui. The research progress and developing tendency of karst water[J]. CARSOLOGICA SINICA, 2016, 35(1): 1-4. doi: 10.11932/karst2016y01
[14]	HUA Shuai. Numerical simulation research on the stability of transmission tower pile foundations in a karst area of Guangdong Province[J]. CARSOLOGICA SINICA, 2014, 33(1): 44-50. doi: 10.3969/j.issn.1001-4810.2014.01.007
[15]	JIA Long, MENG Yan, GUAN Zhen-de. Evolution and numerical simulation of a karst soil cave[J]. CARSOLOGICA SINICA, 2014, 33(3): 294-298.
[16]	LIANG Bing, CHEN Nan, JIANG Li-guo. The numerical simulation to the mineral dissolution-release law in the coal gangue[J]. CARSOLOGICA SINICA, 2011, 30(3): 359-362. doi: 10.3969/j.issn.1001-4810.2011.03.020
[17]	WANG Yun, YU Qing-chun, YU Qing-chun, MA Hao. Numerical simulation for the evolution of the overflow spring in fracture-karst aquifer system[J]. CARSOLOGICA SINICA, 2010, 29(4): 378-384. doi: 10.3969/j.issn.1001-4810.2010.04.005
[18]	HAN Wei, LI Guo-min, LI Ming, LI Guang-he, LI Hong-ming, WU San-san, ZHANG Ying-hua. Numerical analysis to groundwater exploitation in Dawu karst well field[J]. CARSOLOGICA SINICA, 2008, 27(2): 182-188. doi: 10.3969/j.issn.1001-4810.2008.02.014
[19]	BIAN Jin-yu, XUE Yu-qun, CHENG Cheng, ZHU Gui-e, HE Fang. THREE-DIMENSIONAL NUMERICAL SIMULATION OF GROUNDWATER IN PUXI DISTRICT,SHANGHAI[J]. CARSOLOGICA SINICA, 2002, 21(3): 182-187. doi: 10.3969/j.issn.1001-4810.2002.03.006
[20]	Lu Wenxi. NUMERICAL SIMULATION OF SPRING OUTELOW BEHAVIOUR[J]. CARSOLOGICA SINICA, 1992, 11(2): 137-140.

Supplements(0)

Cited By

Proportional views

Proportional views

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

Get Citation

PDF(81352.0KB)

XML

Article Metrics

Article views (1476) PDF downloads(224)

Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province

doi: 10.11932/karst20200408

Abstract

References

Relative Articles

Proportional views

Catalog

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Proportional views

Related

Discrete element modelling on dynamic triggering mechanism of the Pusa landslide in Nayong county, Guizhou Province

doi: 10.11932/karst20200408

Abstract

References

Relative Articles

Proportional views

Catalog

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Proportional views

Related

Export File

Citation

Format

Content