Abstract
This paper describes the site investigation and engineering geological characterization of steep engineered rock slopes at the site of a major 280 m single span arch bridge. The rock slopes comprised predominantly carbonaceous limestone with reduced rock mass quality due to the influence of faulting and shearing. The carbonaceous limestone occurs as lenticular bodies with smooth, tectonically disturbed, variably dipping (37°–57°) bedding planes. The rock slope was excavated to a total height of 90 m, including a bridge foundation excavation depth of 30 m and a final permanent engineered slope height of 60 m. The engineered rock slope was excavated at 60°–90° and the natural rock slope is between 50° and 70°. Construction of the bridge foundation required the excavation of three rock slopes, two perpendicular to bedding and one parallel to the strike of the bedding. In the two rock slopes excavated perpendicular to bedding, one exhibited potential bedding plane controlled failure and the other potential toppling instability. The intact rock properties were characterized using laboratory testing and selected discontinuities tested in direct shear. Using the derived properties and the results of the engineering geological mapping numerical modelling was undertaken using a discontinuum model, (UDEC). The deformation of the rock mass during the stages of excavation was simulated and the results used to develop plans for safe construction and reinforcement of the rock slopes.
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References
Cruden DE (2000) Some forms of mountain peaks in the Canadian Rockies controlled by their rock structure. Quaternary Int 68–71:59–65
Cruden DE (2003) The shapes of cold, high mountains in sedimentary rocks. Geomorphology 55:249–261
Liu YR, Tang HM (1999) Rock mass mechanics. China University of Geosciences Press, Wuhan. ISBN 7-5625-1429-1
Ren W, Jin Y, Feng G, Li J (2010) Probing into assessment system of landslide/slope stability. Rock Soil Mech 31(7):2129–2134
Stead D, Coggan J (2012) Numerical modelling of rock slope stability, Chapter 13. In: Clague J, Stead D (eds) Landslide: types, mechanisms and modelling. Cambridge University Press, Cambridge, pp 144–158
Stead D, Eberhardt E, Coggan JS (2006) Developments in the characterization of complex rock slope deformation and failure using numerical modeling techniques. Eng Geol 83:217–235
Xu K, Pan W, Lin J (1991) Engineering geological study on texture of rock mass and weak interrelations in Lianzi Cliff dangerous rock body of Sanxia Gorge on Changjiang (Yangtze) river. Chin J Geol Hazard Cont 2(8):43–53
Acknowledgments
The authors acknowledge funding received from China Railway Major Bridge Engineering Group, Ltd, in the Ensi-Qianjiang expressway of Hubei, China. We also thank the Construction Project Management Department for assistance with field engineering geological investigation for the Longqiao arch bridge. The authors also acknowledge China Scholarship Council (CSC) which has supplied funding for us to undertake collaborative research on this paper. The authors also acknowledge the reviewer for his constructive comments.
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© 2014 Springer International Publishing Switzerland
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Hu, X., Stead, D., Zhai, L., Jin, H., Kong, D. (2014). Engineering Geology and Numerical Modelling of a Steep Rock Slope for the Ensi-Qianjiang Expressway, China. In: Sassa, K., Canuti, P., Yin, Y. (eds) Landslide Science for a Safer Geoenvironment. Springer, Cham. https://doi.org/10.1007/978-3-319-05050-8_40
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DOI: https://doi.org/10.1007/978-3-319-05050-8_40
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