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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 8/2024

01.04.2024 | Original Article

A critical review of rock mass classification systems for assessing the stability condition of rock slopes

verfasst von: Amit Jaiswal, A. K. Verma, T. N. Singh

Erschienen in: Environmental Earth Sciences | Ausgabe 8/2024

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Abstract

In the last few decades, several rock mass classification systems have been proposed to identify rock slope stability conditions, having high probability of failure and accordingly prioritize preventive measures. This paper reviews the various classification systems, highlighting their differences and similarities with regard to the factors involved and the mode of their failures. The advantages and limitations of each classification have also been compared. However, many of these existing systems fail to classify slope cuttings according to their actual vulnerability of failure, as they ignore important triggering factors such as earthquakes or precipitation. For example groundwater is considered as an instability causing factor with limited effect, rather than a triggering factor for failure. It is observed that rock slope should be classified according to their potential of failure, taking into account both their condition and the influence of triggering factors upon stability. It is also observed that it is important to analyse each type of failure separately, since each one is influenced by unique factors of instability. Finally, it provides suggestion for the improvement of existing classifications through incorporation of all the critical factors like slope aspect, mode of excavation, earthquake, and rainfall that would have caused slope instability.
Vorheriger Artikel Improving permeability prediction via Machine Learning in a heterogeneous carbonate reservoir: application to Middle Miocene Nullipore, Ras Fanar field, Gulf of Suez, Egypt
Nächster Artikel Numerical and experimental modeling of geotextile soil reinforcement for optimizing settlement and stability of loaded slopes of irrigation canals

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Literatur
ASTM (2002) Standard test method for determining rock quality designation (RQD) of rock core. ASTM standard D6032–02. ASTM International, West Conshohocken
Bar N, Barton N (2017) The Q-slope method for rock slope engineering. Rock Mech Rock Eng 50:3307–3322CrossRef
Barton N and Bar N, Introducing the Q-slope method and its intended use within civil and mining engineering projects. In ISRM Regional Symposium-EUROCK 2015. One Petro.
Bieniawski ZT (1989) Engineering rock mass classification. Wiley, Chichester
Bieniawski ZT, Rock mass classification in rock engineering. In: Proceeding of the Symposium on Exploration for Rock Engineering (ed. ZT Bieniawski) 1976; pp. 97–106.
Bieniawski ZT, The geomechanics classification in rock engineering applications. In: Proceedings of the 4th international congress on rock mechanics, Montreux. 1979; p. 41–48.
Chen Z (1995) Recent developments in slope stability analysis. Keynote lecture. In: Fujii, T. (Ed), Proc. 8th Int. Cong. Rock Mech. 3, pp 1041–1048
Deere DU, Hendron AJ Jr, Patton FD, Cording EJ (1967) Design of surface and near-surface construction in rock. In: Fairhurst C (ed) Failure and breakage of rock. Society of Mining Engineers of AIME, New York, pp 237–302
Flatland R (1992) Application of the Rockfall Hazard Rating System to the Rock Slopes Adjacent to U.S. 50 and State Route 28 on the East Side of Lake Tahoe, M.S., Thesis, University of Nevada, Reno, 318
Furlani S, Bolla A, Hastewell L, Mantovani M, Devoto S (2022) Integrated geomechanical and digital photogrammetric survey in the study of slope instability processes of a flysch sea cliff (Debeli Rtic Promontory, Slovenia). Land 11:2255CrossRef
Guzzetti F, Peruccacci S, Rossi M, Stark CP (2007) Rainfall thresholds for the initiation of landslides in central and southern Europe. Meteorol Atmos Phys 98:239–267CrossRef
Hack R, Price D, Rengers N (2003) A new approach to rock slope stability–a probability classification (SSPC). Bull Eng Geol Env 62:167–184CrossRef
Hoek E, Brown ET (1997) Practical estimates of rock mass strength. Int J Rock Mech Min Sci 34(8):1165–1186CrossRef
Hoek E, Kaiser PK, Bawden WF (1995) Support of underground excavations in hard rock. Balkema, Rotterdam
Hoek E, Carter TG, Diederichs MS (2013) Quantification of the geological strength index chart. In 47th US rock mechanics/geomechanics symposium. OnePetro.
Hudson JA, Harrison JP (2000) Engineering rock mechanics an introduction to the principles. Elsevier, Amsterdam
ISRM Commission on Standardization of Laboratory and Field Test Suggested Methods for the Rock Characterization, Testing and Monitoring, E.T. Brown (editor), (1981a) Pergamon Press, Oxford, UK, 211p
Lauffer H (1958) Gebirgsklassifizierung fur denstol lenbau. Geologie Und Bauwesen 24(1):46–51
Marinos V, Carter TG (2018) Maintaining geological reality in the application of GSI for the design of engineering structures in rock. Eng Geol 239:282–297CrossRef
Marinos P, Hoek E (2000) GSI: a geologically friendly tool for rock mass strength estimation. In ISRM international symposium. OnePetro.
Mazzoccola DF, Hudson JA (1996) A comprehensive method of rock mass characterization for indicating natural slope instability. Q J Eng Geol 1996(29):37–56CrossRef
McCauley ML, Works BW, Naramore SA (1985) Rockfall mitigation—final report; (FHWA/CA/TL-85/12).Washington: FHWA
Nicholson DT (2002) Identification of deterioration hazard potential for quarried rockslopes. Quarry Manage 29(1):43–52
Nicholson DT (2003) Breakdown mechanisms and morphology for man-made rockslopes in North West England. North West Geogr 3(1):12–26
Nicholson DT (2004) Hazard assessment for progressive weathering-related breakdown of excavated rockslopes. Q J Eng Geol Hydrogeol 37:327–346CrossRef
Nicholson DT, Hencher SR (1997), Assessing the potential for deterioration of engineered rockslopes. In: Proceedings of the IAEG symposium, Athens, p 911–17.
Pantelidis L (2009) Rock slope stability assessment through rock mass classification systems. Int J Rock Mech Min Sci 46(2):315–325CrossRef
Pells PJ, Bieniawski ZT, Hencher SR, Pells SE (2017) Rock quality designation (RQD): time to rest in peace. Can Geotech J 54(6):825–834CrossRef
Revfeim KJA (1978) A simple procedure for estimating global daily radiation on any surface. J Appl Meteor 17:1126–1131CrossRef
Ritter W (1879) Die Statikder Tunnelge wolbe. Springer, Berlin
Robertson AM (1988) Estimating weak rock strength. In: Proceedings of the SME annual meeting, Phoenix, p 1–5
Romana M, New adjustment ratings for application of Bieniawski classification to slopes. In: Proceedings of the international symposium on the role of rock mechanics, Zacatecas, Mexico, 1985; p. 49–53.
Selby MJ (1980) A rock mass strength classification for geomorphic purposes: with tests from Antarctica and New Zealand. Zeit Geomorph 24(1):31–51CrossRef
Sidle RC, Ochiai H (2006) Landslides: processes, prediction, and land use. Water Resources Monograph Series. Volume 18. Washington, American Geophysical Union
Sonmez H, Ulusay R (2002) A discussion on the Hoek-Brown failure criterion and suggested modifications to the criterion verified by slope stability case studies. Yerbilimleri 26:77–99
Taheri A, Tani K (2006) Modified rock mass classification system for preliminary design of rock slopes. In Rock Mechanics in Underground Construction: ISRM International Symposium 2006: 4th Asian Rock Mechanics Symposium, 8–10 November 2006; Singapore (p. 280). World Scientific.
Terzaghi K (1946) Rock defects and loads on tunnel supports. Rock tunneling with steel supports. In: Rock tunneling with steel supports. Vol. 1. Youngstown, Commercial Shearing and Stamping Company, p. 17–99
Terzaghi K (1950) Mechanism of landslides, The Geological Society of America. Engineering Geology (Berkley). 83–123
Tomás R, Delgado J, Serón JB (2007) Modification of slope mass rating (SMR) by continuous functions. Int J Rock Mech Min Sci 44:1062–1069CrossRef
Watters RJ (1998) Modification to the Rockfall Hazard Rating System for successful mitigation in mountainous terrain as a result of climate and slope aspect considerations. Association of Engineering Geologists 41st Annual Meeting, Programs with Abstracts. 41, p. 134.
Wickham GE, Tiedemann H, Skinner EH (1972) Support determination based on geologic predictions. In: Proceedings of the 1st North American rapid excavation tunneling conference, New York, AIME, p. 43–64.
Wieczorek GF, Jager S (1996) Triggering mechanisms and depositional rates of postglacial slope-movement processes in the Yosemite Valley, California. Geomorphology 15:17–31CrossRef
Yang B, Elmo D (2022) Why engineers should not attempt to quantify GSI. Geosciences 12(11):417CrossRef
Metadaten
Titel
A critical review of rock mass classification systems for assessing the stability condition of rock slopes
verfasst von
Amit Jaiswal
A. K. Verma
T. N. Singh
Publikationsdatum
01.04.2024
Verlag
Springer Berlin Heidelberg
Erschienen in
Environmental Earth Sciences / Ausgabe 8/2024
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-024-11532-2

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