Formation mechanism and risk assessment of unstable rock mass at the Yumenkou tunnel entrance, Shanxi province, China

With the slope unstable rock masses of a stope in Longsi mine, Jiaozuo City, China as the target, we computed and analyzed the stability of unstable rock masses using a limit equilibrium method (LEM) and a discrete element strength reduction method (SRM). Results show that the unstable rock masses are currently stable. Under the external actions of natural weathering, rainfall and earthquake, unstable rock mass 1 was manifested as a shear slip failure mode, and its stability was controlled jointly by bedding-plane and posterior-margin steep inclined joints. In comparison, unstable rock mass 2 was manifested as a tensile-crack toppling failure mode, and its stability was controlled by the perforation of posterior-margin joints. From the results of the 2 methods we find the safety factor determined from SRM is larger, but not significantly, than that from LEM, and SRM can simulate the progressive failure process of unstable rock masses. SRM also provides information about forces and deformation (e.g. stress-strain, and displacement) and more efficiently visualizes the parts at the slope that are susceptible to instability, suggesting SRM can be used as a supplementation of LEM.

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Chasing a hidden fracture using seismic refraction tomography: case study Preonzo, Switzerland

10.5194/egusphere-egu2020-9701 ◽

2020 ◽

Author(s):

Mauro Häusler ◽

Franziska Glüer ◽

Jan Burjánek ◽

Donat Fäh

Keyword(s):

Rock Mass ◽

Seismic Refraction ◽

Slope Instability ◽

Mode Analysis ◽

Mode Shapes ◽

Small Aperture ◽

Higher Modes ◽

Refraction Tomography ◽

Tension Cracks ◽

Unstable Rock

<p>The Preonzo rock slope instability in southern Switzerland partly collapsed in 2012, releasing a volume of ~210&#8217;000 m3 and leaving behind an unstable rock mass of about 140&#8217;000 m3. Shortly after the collapse, a small-aperture seismic array measurement was performed on the remaining unstable volume. The analysis of these data showed a fundamental resonance frequency of about 3.5 Hz and strong wavefield amplifications with factors of more than 30 in direction perpendicular to open tension cracks. Normal mode analysis by frequency domain decomposition using the fundamental and several higher modes allowed for mapping the fracture network of the instability.<br>However, the observed amplification factors and mode shapes could not be explained solely by the open tension cracks visible at the surface. Strong amplifications, especially at frequencies of higher modes, were observed on the uphill part of the rear fracture, which was supposed to be outside the presumed unstable area. The zone where amplifications rapidly decreased in the uphill direction coincides roughly with a geomorphological lineament in the field, interpreted as an additional, but hidden, rear fracture.&#160;<br>We performed active seismic refraction tomography across this lineament and discovered distinct low velocity anomalies in the transition zone from high to low amplifications, supporting the interpretation of an additional fracture. Considering this new finding, the volume of the unstable rock mass increases by about 40 %.&#160;</p>

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Mud Volcanism near the Nabetachiyama Tunnel and the Formation Mechanism of Swelling Rock Mass

Journal of Geography (Chigaku Zasshi) ◽

10.5026/jgeography.118.499 ◽

2009 ◽

Vol 118 (3) ◽

pp. 499-510 ◽

Cited By ~ 5

Author(s):

Kazuhiro TANAKA ◽

Tomokazu ISHIHARA

Keyword(s):

Rock Mass ◽

Formation Mechanism ◽

Mud Volcanism ◽

Swelling Rock

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Analysis of Development Characteristics and Formation Mechanism of Geo-hazards in Youyu County,Shanxi Province

Proceedings of the 2015 International Forum on Energy, Environment Science and Materials ◽

10.2991/ifeesm-15.2015.125 ◽

2015 ◽

Author(s):

Feng Ding ◽

Dongdong Wang ◽

Shihong Cen

Keyword(s):

Formation Mechanism ◽

Shanxi Province

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Study on the Deformation Mechanism of the Wangxia Unstable Rock Mass in the Three Gorges Reservoir

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.926-930.635 ◽

2014 ◽

Vol 926-930 ◽

pp. 635-639

Author(s):

Qi Lang Le ◽

You Long Gao ◽

Zhong Lin Zhang ◽

Ning Guo

Keyword(s):

Rock Mass ◽

Three Gorges Reservoir ◽

Gradual Change ◽

Three Gorges ◽

Monitoring Methods ◽

Local Resident ◽

The Three Gorges Reservoir ◽

The Three Gorges ◽

Gradual Process ◽

Unstable Rock

Twice serious deformation occurred in the Wangxia unstable rock mass in 2010 and 2011 in Wushan country in the Three Gorges Reservoir. It formed a large dangerous factor for the local resident and channel safety. Based on the detailed investigation of the new cracks, deformation history, GPS observations, total station monitoring and crack displacement monitoring data analysis, analyzed comprehensively the deformation and reasons of the unstable rock. The researches show that the deformation type of the unstable rock mass contains gradual change and mutation, should adopt the corresponding monitoring methods and monitoring frequency in different deformation stages based on the geological survey and monitoring the key parts of the unstable rock mass. The destruction of the Wangxia unstable rock was a gradual process, controlled by 5 key cracks, which were crack T11, T12, T13, T16, and T10, consider the Wangxia unstable rock was subsided extrusion type collapse.

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Formation Mechanism and Treatment of the Mudstone Landslide of Xi'an-Baoji Expressway, China

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1079-1080.156 ◽

2014 ◽

Vol 1079-1080 ◽

pp. 156-159

Author(s):

Zhi Bing Wang

Keyword(s):

Slope Stability ◽

Formation Mechanism ◽

Engineering Geology ◽

Shanxi Province ◽

Natural State ◽

Comprehensive Treatment ◽

Saturated State ◽

Hydrogeological Characteristics ◽

Is Design

There is a mudstone landslide that poses threat to ramp bridge of Xishan interchange of Xi'an-Baoji Expressway located in Shanxi province, China. This article analyzes the engineering geology and hydrogeological characteristics at first; and then find out that construction loading in the upper of the slope is the main reason for this landslide. Meantime, rainfall and the special geologic conditions of the slope are also two significant contributors to the slide. Landslide thrusts are calculated under natural state (123 kN/m) and saturated state (1645 kN/m) respectively, and used in the analysis of slope stability. A comprehensive treatment with slope cutting, anti-slide pile and drainage is design for the landslide.

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