Complex Geodetic and Photogrammetric Monitoring of the Kral’ovany Rock Slide

To conduct optical fiber monitoring rock slide model test and optical fiber monitoring of steel concrete interface slip model test, the large triaxial shear test of geotechnical engineering was used. First, the data of sliding distance and optical loss and their dynamic range were obtained. Second, the slide distance and fiber loss relation curve and the fitting equation were worked out. Finally, the typical applications of optical fiber sensing technology in Rock Engineering (high slope engineering, rock foundation of Dam Engineering) slope stability and geological disaster monitoring were put forward.The results showed that optical fiber sensing was very sensitive, and the loss value was 30 to 50dB. The dynamic range of rock slide monitoring fiber was 3 to 3.5mm, and the dynamic range of the interface slip monitoring fiber was 1.6mm. Thus, the sensing system can detect the sliding process of the interface between the concrete and the steel plate. It provides some reference for the sliding monitoring of the composite materials.

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Rockslides on limestone cliffs with sub-horizontal bedding in the southwestern calcareous area, China

Natural Hazards and Earth System Sciences Discussions ◽

10.5194/nhessd-2-4299-2014 ◽

2014 ◽

Vol 2 (6) ◽

pp. 4299-4330

Author(s):

Z. Feng ◽

B. Li ◽

Y. P. Yin ◽

K. He

Keyword(s):

Rock Mass ◽

Hard Rock ◽

Compression Fracture ◽

Field Observations ◽

Rock Slide ◽

Mountainous Areas ◽

Hard Rocks ◽

Rupture Plane ◽

Rock Collapse ◽

Cliff Retreat

Abstract. Calcareous mountainous areas are highly prone to geohazards, and rockslides play an important role in cliff retreat. This study presents three examples of failures of limestone cliffs with sub-horizontal bedding in the southwestern calcareous area of China. Field observations and numerical modeling of Yudong Escarpment, Zengzi Cliff, and Wangxia Cliff showed that pre-existing vertical joints passing through thick limestone and the alternation of competent and incompetent layers are the most significant features for rockslides. A "hard on soft" cliff made of hard rocks superimposed of soft rocks is prone to rock slump, characterized by shearing through the underlying weak strata along a curved surface and backward tilting. When a slope contains weak interlayers rather than a soft basal layers, a rock collapse could occur from the compression fracture and tensile split of the rock mass near the interfaces. A rock slide might shear through a hard rock mass if no discontinuities are exposed in the cliff slope, and sliding may occur along a moderately inclined rupture plane. The "toe breakout" mechanism mainly depends on the strength characteristics of the rock mass.

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Slip surface estimation of rock-slide on Miocene bedrock :

Journal of the Japan Landslide Society ◽

10.3313/jls.53.134 ◽

2016 ◽

Vol 53 (4) ◽

pp. 134-140

Author(s):

Naoki KATAYAMA

Keyword(s):

Slip Surface ◽

Rock Slide ◽

Surface Estimation

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THE GREAT ROCK SLIDE AT FRANK

Harm's Way ◽

10.2307/j.ctv6cfq7n.7 ◽

2018 ◽

pp. 69-96

Author(s):

Lorry W. Felske

Keyword(s):

Rock Slide

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NEMETON: Decision Support System for Rockfall and Rock Slide Hazard Mitigation

Landslide Science and Practice ◽

10.1007/978-3-642-31313-4_28 ◽

2013 ◽

pp. 217-221

Author(s):

Jan Klimeš ◽

Stanislav Štábl ◽

Josef Stemberk ◽

Dušan Dufka

Keyword(s):

Decision Support ◽

Decision Support System ◽

Support System ◽

Hazard Mitigation ◽

Rock Slide

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An active large rock slide in the Andean paraglacial environment: the Yerba Loca landslide, central Chile

Landslides ◽

10.1007/s10346-020-01564-7 ◽

2020 ◽

Cited By ~ 1

Author(s):

Sergio A. Sepúlveda ◽

Alejandro Alfaro ◽

Marisol Lara ◽

Javiera Carrasco ◽

Paula Olea-Encina ◽

...

Keyword(s):

Rock Slide ◽

Central Chile

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Back-calculation of the 2017 Piz Cengalo-Bondo landslide cascade with r.avaflow

10.5194/nhess-2019-204 ◽

2019 ◽

Cited By ~ 2

Author(s):

Martin Mergili ◽

Michel Jaboyedoff ◽

José Pullarello ◽

Shiva P. Pudasaini

Keyword(s):

Debris Flow ◽

Flow Model ◽

Rock Avalanche ◽

Simulation Software ◽

Process Models ◽

Rock Fall ◽

Model Parameters ◽

Rock Slide ◽

Glacier Ice ◽

Initial Rock

Abstract. In the morning of 23 August 2017, around 3 million m3 of granitoid rock broke off from the east face of Piz Cengalo, SE Switzerland. The initial rock slide-rock fall entrained 0.6 million m3 of a glacier and continued as a rock(-ice) avalanche, before evolving into a channelized debris flow that reached the village of Bondo at a distance of 6.5 km after a couple of minutes. Subsequent debris flow surges followed in the next hours and days. The event resulted in eight fatalities along its path and severely damaged Bondo. The most likely candidates for the water causing the transformation of the rock avalanche into a long-runout debris flow are the entrained glacier ice and water originating from the debris beneath the rock avalanche. In the present work we try to reconstruct conceptually and numerically the cascade from the initial rock slide-rock fall to the first debris flow surge and thereby consider two scenarios in terms of qualitative conceptual process models: (i) entrainment of most of the glacier ice by the frontal part of the initial rock slide-rock fall and/or injection of water from the basal sediments due to sudden rise in pore pressure, leading to a frontal debris flow, with the rear part largely remaining dry and depositing mid-valley; and (ii) most of the entrained glacier ice remaining beneath/behind the frontal rock avalanche, and developing into an avalanching flow of ice and water, part of which overtops and partially entrains the rock avalanche deposit, resulting in a debris flow. Both scenarios can be numerically reproduced with the two-phase mass flow model implemented with the simulation software r.avaflow, based on plausible assumptions of the model parameters. However, these simulation results do not allow to conclude on which of the two scenarios is the more likely one. Future work will be directed towards the application of a three-phase flow model (rock, ice, fluid) including phase transitions, in order to better represent the melting of glacier ice, and a more appropriate consideration of deposition of debris flow material along the channel.

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