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Numerical study of reinforced natural slope by retaining wall with prestressed anchor

  • Said, Nouri (Laboratory of Structures, Geotechnical and Risks (LSGR), University of Hassiba Benboual) ;
  • Amar, Nechnech (Laboratory of Environment, Water Geomechanics and works (LEWGW), University for Science and Technology)
  • Received : 2019.12.26
  • Accepted : 2021.03.17
  • Published : 2021.06.25

Abstract

The slope design under geological and hydraulic conditions has always been a different geotechnics problem. There have been potential main landslide and an undisturbed thin layer of saturated clays soil under the slopes in urban construction development area of Miliana city province of Algeria; its terrain is mountains. The landslide was framed by gravity creeping of thin layer of alluvium and mares cracks along steep clays. The favorable sliding surface larger than 2500 m2 had destroyed the foundation of the building. In order to learn from the comparison between stabilized and non-stabilized slopes with different improvement, the authors also investigated the slopes reinforced by retaining wall with prestressed anchor and discussed their behavior parameters. Based on finite element method, the analysis of slope stability under natural conditions is discussed first, then the support structure of retaining wall and anchor reinforced and their effect of slope stability are analyzed, and also the slope stability of each case is able to be compared. The results show that the stability of slope was significantly improved after reinforcement, and anchor reinforced with retaining wall has obvious reverse anchoring effect on soil. By comparing the factor of safety, stress level and displacement field before and after slope reinforcement, it is found that better reinforcement results can be achieved if strong reinforcement is applied upon the regions with high sliding surface. Furthermore, the increase in stress level at the zone dangerous is more favorable of improving the safety of the critical region.

Keywords

Acknowledgement

I would like to acknowledge people who work at National Center for Research on Earthquake Engineering of Algeria (CGS-Algiers) and Central Laboratory of Public Works (LCTP-Algiers) for their wonderful collaboration, whose expertise was invaluable in formulating of the research topic. The author would like to acknowledge the urban planning and construction engineer Moulai Souiga Hadj Belmehel (Relizane, Algeria) for his contribution regarding numerical implementation issues, those numerical analyses were performed with Plaxis code.

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