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01-03-2021 | Technical paper

Experimental study of ground improvement by using encased stone columns

Authors: Ankit Thakur, Saurabh Rawat, Ashok Kumar Gupta

Published in: Innovative Infrastructure Solutions | Issue 1/2021

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Abstract

The application of stone columns increases the stiffness of soft soils which contributes to its load carrying capacity and accelerates the process of consolidation leading to reduction in settlement. However, under external loading, squeezing of adjacent soil into the columns not only compromises the integrity of the columns but also reduces its stiffness, strength and drainage properties. The present study investigates the use of vertically and horizontally reinforced stone columns, as a remedial measure for ordinary unreinforced stone columns. The vertical reinforcement is done by encasing the stone columns in geotextile and horizontally by placing geotextile circular discs within the columns at regular interval. Model tests on group of 3 and 4 unreinforced and reinforced stone columns have been conducted in weak sandy soil. The load–settlement response and failure modes for both reinforced and unreinforced groups have been studied. It is observed that reinforced group of stone columns depict better load bearing capacity as compared to unreinforced group. Moreover, bearing capacity for vertically encased and horizontally reinforced is almost similar, with horizontally reinforced group of 4 stone columns depicting slightly higher (1–2%) bearing capacity for a settlement of 30 mm. The experimental results are also validated with theoretical results and are found to be in good agreement.

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Munfakh GA, Sarkar SK, Castelli RP (1983) Performance of a test embankment founded on stone columns. In: Proceedings of international conference on advances in piling and ground treatment for foundations, London, pp 259–265

Yan J, Ye SL (2001) Simplified method for consolidation rate of stone column reinforced foundations. J Geotech Geoenviron Eng (ASCE) 127(7):597–603CrossRef

Choobbasti AJ, Zahmatkesh A, Noorzad R (2011) Performance of stone columns in soft clay: numerical evaluation. Geotech Geol Eng 29:675–684CrossRef

Elshazly HA, Hafez DA, Mossaad ME (2008) Reliability of conventional settlement evaluation for circular foundations on stone columns. Geotech Geol Eng 26(3):323–334CrossRef

Guetif Z, Bouassida M, Debats JM (2007) Improved clay characteristics due to stone column installation. Comput Geotech 34:104–111CrossRef

Shirazi MR, Zarrin O, Valipourian K (2015) The role of vibro-stone column for enhancing the soft soil properties. Int J Civ Environ Eng 9(5):616–620

Thevanayagam S, Martin GR, Nashed R, Shenthan T, Kanagalingam T, Ecemis N (2006) Liquefaction remediation in silty soils using dynamic compaction and stone columns. Technical Report MCEER-06-0009, August 2006

McKelvey D, Sivakumar V, Bell A, Graham J (2004) Modelling vibrated stone columns in soft clay. Geotech Eng 157(GE3):137–149CrossRef

Zhan Y, Jiang G, Yao H (2014) Dynamic characteristics of saturated silty soil ground treated by stone column composite foundation. Adv Mater Sci Eng, Article ID 745386, 1–7

10.

Luo M (2018) Finite element analysis of gravel pile composite foundation under flexible foundation of Airport Engineering. IOP Conf Ser Earth Environ Sci 113:012093CrossRef

11.

Liu CY, Ku CY, Xiao JE, Huang CC, Hsu SM (2017) Numerical modeling of unsaturated layered soil for rainfall-induced shallow landslides. J Environ Eng Landsc Manag 25(4):329–341CrossRef

12.

Meshkinghalam H, Bonab MH, Azar AK (2017) Numerical investigation of stone columns system for liquefaction and settlement diminution potential. Int J Geo-Eng 8:Article no. 11

13.

Liu W, Hutchinson TC (2018) Numerical investigation of stone columns as a method for improving theperformance of rocking foundation systems. Soil Dyn Earthq Eng 106:60–69CrossRef

14.

Etezad M, Hanna AM, Asce F, Ayadat T (2015) Bearing capacity of a group of stone columns in soft soil. Int J Geomech 15(2):Article ID 04014043 (1–15)

15.

Nehab N, Baba K, Ouadif L, Bahi L (2016) Three-dimensional modeling of a group of stone columns in “Bouregreg Valley” soft ground. ARPN J Eng Appl Sci 11(24):14537–14544

16.

Gueguin M, Hassen G, de Buhan P (2015) Stability analysis of homogenized stone column reinforced foundations using a numerical yield design approach. Comput Geotech 64:10–19CrossRef

17.

Stuedlein AW, Holtz RD (2013) Bearing capacity of spread footings on aggregate pier reinforced clay. J Geotech Geoenviron Eng 139(1):49–58CrossRef

18.

Nassaji F, Asakereh A (2013) Effect of Granular bed on behavior of stone column improved ground. Int J Sci Eng Investig 23(2):67–71

19.

Killeen MM, McCabe BA (2014) Settlement performance of pad footings on soft clay supported by stone columns: a numerical study. Soils Found 54(4):760–776CrossRef

20.

Muir Wood D, Hu W, Nash DFT (2000) Group effects in stone column foundations: model tests. Geotechnique 50(6):689–698CrossRef

21.

Ambily AP, Gandhi SR (2007) Behavior of stone columns based on experimental and FEM analysis. J Geotech Geoenviron Eng 133:405–415CrossRef

22.

Murugesan S, Rajagopal K (2007) Model tests on geosynthetic-encased stone columns. Geosynth Int 14(6):346–354CrossRef

23.

Murugesan S, Rajagopal K (2008) Performance of encased stone columns and design guidelines for construction on soft clay soils. In: Proceedings of the 4th Asian Regional Conference on Geosynthetics, pp 729–734

24.

Murugesan S, Rajagopal K (2010) Studies on the behavior of single and group of geosynthetic encased stone columns. J Geotech Geoenviron Eng 136:129–139CrossRef

25.

Tandel YK, Solanki CH, Desai AK (2012) Reinforced granular column for deep soil stabilization: a review. Int J Civ Struct Eng 2(3):720–730

26.

Nasiri M, Hajiazizi M (2019) An experimental and numerical investigation of reinforced slope using geotextile encased stone column. Int J Geotech Eng. https://doi.org/10.1080/19386362.2019.1651029CrossRef

27.

Ali K, Shahu JT, Sharma KG (2012) Model tests on geosynthetic-reinforced stone columns: a comparative study. Geosynth Int 19(4):292–305CrossRef

28.

Dash SK, Bora MC (2013) Improved performance of soft clay foundations using stone columns and geocell-sand mattress. Geotext Geomembr 41:26–35CrossRef

29.

Ghazavi M, Yamchi AE, Afshar JN (2018) Bearing capacity of horizontally layered geosynthetic reinforced stone columns. Geotext Geomembr 46:312–318CrossRef

30.

Ali K, Shahu JT, Sharma KG (2014) Model tests on single and groups of stone columns with different geosynthetic reinforcement arrangement. Geosynth Int 21(2):103–118CrossRef

31.

Shenthan T, Nashed R, Thevanayagam S, Martin GR (2004) Liquefaction mitigation in silty soils using composite stone columns. Earthq Eng Eng Vib 3(1):39–50CrossRef

32.

Zahmatkesh A, Choobbasti AJ (2010) Settlement evaluation of soft clay reinforced by stone columns, considering the effect of soil compaction. Int J Recent Res Appl Sci 3(2):159–166

33.

Maduro IJ, Molina CR, Castillo LV, Renoud-Lias B, Salvi GJ (2004) The use of stone columns on settlement and liquefaction susceptible soils. In: International conference on case histories in geotechnical engineering, p 6

34.

Chenari RJ, Fard MK, Chenari MJ, Sosahab JS (2019) Physical and numerical modeling of stone column behavior in loose sand. Int J Civ Eng 17:231–244CrossRef

35.

Malarvizhi SN, Ilamparuthi K (2007) Comparative study on the behaviour of encased stone column and conventional stone column. Soils Found 47:873–885CrossRef

36.

Alexiew D, Raithel M (2015) Geotextile-encased columns: case studies over twenty years. In: Embankments with special reference to consolidation and other physical methods. Butterworth-Heinemann, Oxford, pp 451–477

37.

Chen JF, Li LY, Xue JF, Feng SZ (2015) Failure mechanism of geosynthetic-encased stone columns in soft soils under embankment. Geotext Geomembr 43:424–431CrossRef

38.

Elshazly H, Elkasabgy M, Elleboudy A (2008) Effect of inter-column spacing on soil stresses due to vibro-installed stone columns: interesting findings. J Geotech Geol Eng 26:225–236CrossRef

39.

Adam D, Schweiger HF, Markiewicz R, kNabe T (2010) Euro 2008 Stadium Klagenfurt—prediction, monitoring and back calculation of settlement behavior. In: Proceedings of the from research to design in European practice, Bratislava, Slovak Republic, 2–4 June 2010

40.

Shahu JT, Reddy YR (2011) Clayey soil reinforced with stone column group: model tests and analyses. J Geotech Geoenviron Eng 137(12):1265–1274CrossRef

41.

Black JA, Sivakumar V, Bell A (2011) The settlement performance of stone column foundations. Geotechnique 61(11):909–922CrossRef

42.

Mohanty P, Samanta M (2015) Experimental and numerical studies on response of the stone column in layered soil. Int J Geosynth Ground Eng 1(3):27CrossRef

43.

Castro J (2017) Modeling stone columns. Materials 10(7):782. https://doi.org/10.3390/ma10070782.CrossRef

44.

Mehrannia N, Nazariafshar J, Kalantary F (2017) Experimental investigation on the bearing capacity of stone columns with granular blankets. Geotech Geol Eng. https://doi.org/10.1007/s10706-017-0317-6CrossRef

45.

BIS IS 15284-1: 2003 Design and construction for ground improvement—guidelines—part 1: stone columns. Bureau of Indian Standards, ManakBhavan, 9 Bahadur Shah ZafarMarg, New Delhi, India

Title: Experimental study of ground improvement by using encased stone columns
Authors: Ankit Thakur
Saurabh Rawat
Ashok Kumar Gupta
Publication date: 01-03-2021
Publisher: Springer International Publishing
Published in: Innovative Infrastructure Solutions / Issue 1/2021
Print ISSN: 2364-4176
Electronic ISSN: 2364-4184
DOI: https://doi.org/10.1007/s41062-020-00383-y

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