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Reviews on Finite Element Modeling Practices of Stone Columns for Soft Soil Stabilization Beneath an Embankment Dam

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This article reviews the numerical approach in stone column practices and presents the benefits of stone columns as a ground improvement of soft soil to support an embankment dam. In this article, the methodological approaches to numerically modeling stone columns in both 2D and 3D studies, as well as the selection of an appropriate constitutive model are discussed. The numerical practices for the installation of the stone column and the validation procedures used to ensure the accuracy of the numerical analysis are also explained. In addition to that, the study also presents the benefits of stone columns in improving settlement behavior, slope stability, and decreasing the end time of consolidation. Parameters that influence the performance of the stone column with their respective results are also assessed.
Wydawca
Rocznik
Strony
343--353
Opis fizyczny
Bibliogr. 48 poz., rys., tab.
Twórcy
  • Wroclaw University of Technology: Politechnika Wroclawska, Wroclaw, Poland
  • Wroclaw University of Technology: Politechnika Wroclawska, Wroclaw, Poland
Bibliografia
  • [1] Hughes, J. M. O., and Withers, N. J., (1974). Reinforcing of soft cohesive soils with stone columns. Ground Engineering, 1(3), 42–49.
  • [2] Balaam, N. P., and Booker, J. R., (1981). Analysis of rigid rafts supported by granular piles. International Journal for Numerical and Analytical Methods in Geomechanics, 5(4), 379–403.
  • [3] Sondermann, W., and Wehr, W., (2004). Deep vibro technique. In M. P. Moseley and K. Kirsch (Eds.), Ground Improvement (2nd ed., pp. 57–92). London and New York: Taylor and Francis Group.
  • [4] Eiman Fathi, and Reza Mohatasham, (2016). Numerical analysis of the reinforced stone column by geosynthetic on stability of embankment. Proceedings of World Congress on Civil, Structural and Environmental Engineering.
  • [5] Ayadat, T., and Hanna, A. M., (2005). Encapsulated stone columns as a soil improvement technique for collapsible soil. Ground Improvement, 9(4), 137–147.
  • [6] Gniel, J., and Bouazza, A., (2009). Improvement of soft soils using geogrid encased stone columns. Geotextiles and Geomembranes, 27(3), 167–175.
  • [7] Black, J.A., Sivakumar, V., Madhav, M.R. and McCabe, B. A., Sivakumar, V., Madhav, M. R., and Hamill, G. A., (2007). Reinforced stone columns in weak deposits: laboratory model study. Journal Of Geotechnical and Geoenvironmental Engineering, 133(September), 1154–1161.
  • [8] Sivakumar, V., Boyd, J. L., Black, J. a., and McNeil, J. a., (2010). Effects of granular columns in compacted fills. Proceedings of the ICE - Geotechnical Engineering, 163(4), 189–196.
  • [9] Ali, K., Sgahu, J. T., and Sharma, K. G., (2010). Behavior of reinforced stone columns in soft soils : an experimental study. In Indian Geotechnical Conference, GEOtrendz (pp. 620–628). IGS Mumbai Chapter and IIT Bombay.
  • [10] Lee, D.-Y., and Yoo, C.-S., (2011). Laboratory investigation on construction method of geogrid encased stone column. Journal of the Korean Geotechnical Society, 27(2), 73–80.
  • [11] Iman Hossein Pour Babaei, (2015). Test embankment on geotextile encased granular columns stabilized soft ground, D.Sc. thesis, COPPE/UFRJ, Rio de Janeiro, Brazil.
  • [12] Kousik Deb, and Sunil R. Mohapatra, (2013) Analysis of stone column-supported geosynthetic- reinforced embankments, Applied mathematical modelling 37, 2943–2960.
  • [13] Azhani Zukri and Ramil Nazir (2018) Numerical modelling techniques of soft soil improvement via stone columns: A brief review IOP Conf. Ser.: Mater. Sci. Eng. 342 012002
  • [14] Tandel. Y. k., Solanki, C. H., and Desai, A. K., (2012). Numerical modelling of encapsulated stone column-reinforced ground. International Journal of Civil, Structural, Environmental and Infrastructure Engineering, Vol. 2(1), pp. 82–96.
  • [15] Alexiew. D., Brokemper, D., and Lothspeich, S., (2005). Geotextile encased columns (GEC): load capacity, geotextile selection and pre-design graphs. In Proceedings of Geo-Frontiers (pp. 497–510). Austin, Texas, US.
  • [16] Gniel, J., and Bouazza, A., (2010). Construction of geogrid encased stone columns: A new proposal based on laboratory testing. Geotextiles and Geomembranes, 28(1), 108–118.
  • [17] Guetif M., Bouassida. J., and M. Debats, (2007). Improved soft clay characteristics due to stone column installation. Computers and Geotechnics, 34(2) 104–111.
  • [18] Castro, J., and Karstunen, M., (2010). Numerical simulations of stone column installation. Canadian Geotechnical Journal, 47(10) 1127–1138.
  • [19] Kirsch F., (2006). Vibro stone column installation and its effect on ground improvement. Proc. Geotechnical Engineering for Urban Environment, 2006 - March 24. Taylor and Francis, Bochum, Germany, 115–124.
  • [20] Foray P., Laurent B., Etinne F., Serge L., and Ngoc-T.N., (2009). 3D numerical modeling of stone columns and application. Proc. 17th International Conference on Soil Mechanics and Geotechnical Engineering, 3: 2382–2385.
  • [21] Elshazly H., Elkasabgy M., and Elleboudy A., (2008). Effect of inter-column spacing on soil stresses due to vibro-installed stone columns: Interesting findings. Geotechnical and Geological Engineering, 26(2): 225–236.
  • [22] Elshazly H., and Hafez, D., (2006). Back calculating vibro installation stresses in stone columns reinforced grounds. Journal of Ground Improvement, 10(2) 47–53.
  • [23] D. Egan & W. Scott, (2009). Installation effects of vibro replacement stone columns in soft clay. Geotechnics of Soft Soils – Focus on Ground Improvement, Taylor & Francis Group, London, UK, 23–29.
  • [24] Kessler S., Heibrock G., and Triantafyllidis T., (2006). On prediction of vibro compaction performance using numerical models. Symposium International sur le Vibrofoncage et la Vibrocompaction, Paris, 233–242.
  • [25] Arnold M. and Herle I., (2009). Comparison of vibrocompaction methods by numerical simulations. International Journal For Numerical And Analytical Methods In Geomechanics, 1823–38.
  • [26] Vishal J., Aman P.S, and Khushmeet K., (2013). Finite element method: An overview, Walilak J. Sci and Tech, 10 (1); 1–8.
  • [27] Killen Michel B.E, (2012). Numerical modeling of small groups of stone columns, NUI Galway publisher.
  • [28] Alkhorshid, N.R, (2017). Analysis of geosynthetic encased stone columns in very soft soil. University of Brasilia, Brasilia, DF, 128.
  • [29] Elsawy, M.B.D., (2013). Behavior of soft ground improved by conventional and geogrid-encased stone columns, based on FEM study. Geosynthetics International, 20, No. 4, 276–285.
  • [30] Henok L. Belayneh, (2020). The behavior of ordinary and geosynthetic encased stone columns in collapsible soil: A numerical study. Global Scientific Journal, Vol. 8, Issue 12, 978–1004.
  • [31] Obadie N., (2017). Treatment of collapsible soil using encased stone column. The University of Birmingham.
  • [32] Imad E.D., Mohammed S.R., and Ahmad S., A Rashid., Abubaker S., (2020). Numerical modeling of encased stone columns supporting embankment on sabkha soil. Civil Engineering Journal. Vol. 6, No. 8.
  • [33] Q.S.M. Shafiqu, and F.A.A. Al-Assady, (2015). Analysis of embankment supported by stone columns encased with geosynthetic material. International Journal of Civil Engineering and Technology. Vol. 6, Issue 10.
  • [34] Al-Shammarie H. A., (2013). An experimental and theoretical study on ordinary and encased stone columns underneath embankment. Ph.D. Thesis, Civil Engineering Department, University of Baghdad, Iraq.
  • [35] Sim Yu Sheng, (2017), Performance of floating stone columns installed in soft soils. Swinburne University of Technology, Sarawak Campus, Malaysia.
  • [36] M. R. Kahyaoğlu, and M. Vaníček, (2019): A numerical study of reinforced embankments supported by encased floating columns. Acta Geotechnica Slovenica, P25–38.
  • [37] Shaymaa K., Robert L., and Jie H., (2015). Stability analysis of embankments supported by geosynthetic encased stone columns. Geological Special Publication, 2318–2327.
  • [38] K.S.NG., and Y.M. Chew, (2019). Slope stability analysis of embankment over stone column improved ground. Journal of Engineering Science and Technology Vol. 14, No. 6, 3282–3596.
  • [39] Akhila Shaji M., Rajeswari K. R., and Geethu T., (2016). Stability analysis of soft clay stabilized using stone column. International Conference on Structural Engineering and Construction Management.
  • [40] Amit K.D., and Kousik D., (2019). Response of stone column-improved ground under c-ϕ soil embankment. Soils and Foundations, 59, 617–632.
  • [41] S.R. Mohapatra, and K. Rajapal, (2016). Analysis of failure mechanism of geosynthetic-encased stone column supported embankment. GeoAmericans 2016 The 3rd Pan-American Conference on Geosynthetics.
  • [42] Shaymaa T.K, and Ziad B.F, (2018) Stability analysis of roadway embankments supported by stone columns with the presence of water table under short-term and long-term conditions MATEC Web Conferences 162.
  • [43] Sajjid M., and Huriye B., (2012). Finite element modeling of stone columns in alluvial soils under an embankment. 3rd International conference on New Developments in Soil Mechanics and Geotechnical Engineering.
  • [44] Maryam G., Anuar K., Norinah A., and Jamal A., (2018). Simulation of stone column ground improvement (Comparison between axisymmetric and plane strain). American Journal of Engineering and Applied Sciences.
  • [45] Chungsik Yoo, (2010). Performance of geosynthetic-encased stone columns in embankment construction: Numerical investigation. Journal of Geotechnical and Geoenvironmental Engineering, 1148–1160.
  • [46] Yogendra K.T., Chanderesh H., and Atul K., (2013). 3D FE analysis of an embankment construction on GRSC and proposal of a design method. Hindawi Publishing Corporation.
  • [47] Marta Carreira, Marcio Almeida, and Alexandre Pinto, (2016). A numerical study on the critical height of embankments supported by geotextile encased granular columns. The 3rd International Conference on Transportation Geotechnics, Vol. 143, 1341–1349.
  • [48] Mohammedzein, and Al-shibani, (2011). Performance of an embankment supported on soft soil reinforced by stone columns. Institute of Civil Engineering Publishing, Vol. 164, Issue G 14.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4d723666-02f2-4771-accb-3fa14cdeffa2
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