Pullout Capacity Of Cylindrical Block Embedded In Sand

[1]Briaud J.-L. & Kim N.K. (1998). Beem Column Method for Tieback Walls. J. Geotech. Geoenviron. Eng. 124(1), 67-69. 10.1061/(ASCE)1090-0241(1998)124:1(67).BriaudJ.-L.KimN.K.1998Beem Column Method for Tieback WallsJ. Geotech. Geoenviron. Eng.1241676910.1061/(ASCE)1090-0241(1998)124:1(67)Open DOI Search in Google Scholar

[2]Smoltczyk U. (2003). Geotechnical Engineering Handbook, Vol. 1. Fundamentals. Ernest & Sohn, Berlin.SmoltczykU.2003Geotechnical Engineering Handbook1Fundamentals. Ernest & SohnBerlinSearch in Google Scholar

[3]Smith I. (2006). Smith’s Elements of Soil Mechanics. Blackwell Publishing Ltd, Oxford, UK.SmithI.2006Smith’s Elements of Soil Mechanics.Blackwell Publishing LtdOxford, UKSearch in Google Scholar

[4]Briaud J.-L. (2013). Geotechnical Engineering Unsaturated and Saturated Soils. John Wiley & Sons Inc., Hobokan, New Jersey.BriaudJ.-L.2013Geotechnical Engineering Unsaturated and Saturated Soils.John Wiley & Sons Inc.Hobokan, New Jersey10.1002/9781118686195Search in Google Scholar

[5]Zimmermann Th., Truty A., Urbański A. & Podleś K. (2010). Z_Soil. PC 2010 3D user manual, Theory, Tutorials and Benchmarks, Data Preparation. Elmepress Int. & Zace Services Ltd, Switzerland.ZimmermannTh.TrutyA.UrbańskiA.PodleśK.2010Z_Soil. PC 2010 3D user manual, Theory, Tutorials and Benchmarks, Data Preparation.Elmepress Int. & Zace Services LtdSwitzerlandSearch in Google Scholar

[6]Rowe R.K. & Davis E.H. (1982). The behaviour of anchor plates in sand. Géotechnique. 32(1). 25-41. 10.1680/geot.1982.32.1.25.RoweR.K.DavisE.H.1982The behaviour of anchor plates in sandGéotechnique.321254110.1680/geot.1982.32.1.25Open DOI Search in Google Scholar

[7]Murray E.I. & Geddes I.D. (1989). Resistance of passive inclined anchors in cohesionless medium. Géotechnique. 39(3). 417-431.MurrayE.I.GeddesI.D.1989Resistance of passive inclined anchors in cohesionless mediumGéotechnique.39341743110.1680/geot.1989.39.3.417Search in Google Scholar

[8]Kumar I. (2002). Seismic horizontal pullout capacity of vertical anchors in sands. Canadian Geotechnical Journal. 39(4). 982-991. 10.1139/t02-021.KumarI.2002Seismic horizontal pullout capacity of vertical anchors in sandsCanadian Geotechnical Journal.39498299110.1139/t02-021Open DOI Search in Google Scholar

[9]Merifield R.S. & Sloan S.W. (2006). The ultimate pullout capacity of anchors in frictional soils. Canadian Geotechnical Journal. 43(8). 852-868. 10.1139/t06-052.MerifieldR.S.SloanS.W.2006The ultimate pullout capacity of anchors in frictional soilsCanadian Geotechnical Journal.43885286810.1139/t06-052Open DOI Search in Google Scholar

[10]Kame G.S., Dewaikar D.M. & Deepankar Ch. (2012). Pullout Capacity of a Vertical Plate Anchor Embedded in Cohesion-less Soil. Earth Science Research. 1(1). 27-56. 10.5539/esr.v1n1p27.KameG.S.DewaikarD.M.DeepankarCh.2012Pullout Capacity of a Vertical Plate Anchor Embedded in Cohesion-less SoilEarth Science Research.11275610.5539/esr.v1n1p27Open DOI Search in Google Scholar

[11]Bhattacharya P. & Kumar I. (2014). Pullout capacity of inclined plate anchors embedded in sand. Canadian Geotechnical Journal. 51(6). 1365-1370. 10.1139/cgj-2014-0114.BhattacharyaP.KumarI.2014Pullout capacity of inclined plate anchors embedded in sandCanadian Geotechnical Journal.5161365137010.1139/cgj-2014-0114Open DOI Search in Google Scholar

[12]Bhattacharya P. (2016). Pullout capacity of strip plate anchor in cohesive sloping ground under undrained condition, Comp. Geotech. 78. 134–143. 10.1016/j.compgeo.2016.05.006.BhattacharyaP.2016Pullout capacity of strip plate anchor in cohesive sloping ground under undrained conditionComp. Geotech.7813414310.1016/j.compgeo.2016.05.006Open DOI Search in Google Scholar

[13]Nouri H., Biscontin G. & Aubeny C.P. (2017). Numerical prediction of undrained response of plate anchors under combined translation and torsion, Comp. Geotech. 81. 39–48. 10.1016/j.compgeo.2016.07.008.NouriH.BiscontinG.AubenyC.P.2017Numerical prediction of undrained response of plate anchors under combined translation and torsionComp. Geotech.81394810.1016/j.compgeo.2016.07.008Open DOI Search in Google Scholar

[14]Desai Ch.S. & Zaman M. (2014). Advanced Geotechnical Engineering. Soil – Structure Interaction Using Computer and Material Models. Taylor & Francis Group, Boca Raton, FL, USA.DesaiCh.S.ZamanM.2014Advanced Geotechnical Engineering. Soil – Structure Interaction Using Computer and Material ModelsTaylor & Francis GroupBoca Raton, FL, USA10.1201/b15578Search in Google Scholar

[15]Stutz H., Wuttke F. & Benz T. (2014). Extended zero-thickness interface element for accurate soil – pile interaction modelling, In: Numerical Methods in Geotechnical Engineering, Hicks, Brinkgreve & Royce (Eds). Taylor & Francis Group, London, 283-288.StutzH.WuttkeF.BenzT.2014Extended zero-thickness interface element for accurate soil – pile interaction modellingNumerical Methods in Geotechnical Engineering, Hicks, Brinkgreve & RoyceTaylor & Francis GroupLondon28328810.1201/b17017-52Search in Google Scholar

[16]Bond A. & Harris A. (2010). Decoding Eurocode. Taylor and Francis, New York, USA.BondA.HarrisA.2010Decoding Eurocode.Taylor and FrancisNew York, USASearch in Google Scholar

[17]Schofield A. N. & Wroth C. P. (1968). Critical State Soil Mechanics. McGraw-Hill.SchofieldA. N.WrothC. P.1968Critical State Soil Mechanics.McGraw-HillSearch in Google Scholar

[18]Atkinson J.H. (2007). The mechanics of soils and foundations. Taylor & Francis, London and New York.AtkinsonJ.H.2007The mechanics of soils and foundations.Taylor & FrancisLondon and New YorkSearch in Google Scholar

[19]Flora, A. & Modoni G. (1997). Upgrading Equipment and Procedures for Stress Path Triaxial Testing of Coarse-Grained Materials. Geotechnical Testing Journal. Vol. 20., No. 4. 459-469. 10.1520/GTJ10412J.FloraA.ModoniG.1997Upgrading Equipment and Procedures for Stress Path Triaxial Testing of Coarse-Grained MaterialsGeotechnical Testing Journal.20445946910.1520/GTJ10412JOpen DOI Search in Google Scholar

[20]Iolli S., Modoni G., Chiaro G. & Salvatore E. (2015). Predictive correlations for the compaction of clean sands. Transportations Geotechnics. 4. 38-49. 10.1016/j.trgeo.2015.06.004.IolliS.ModoniG.ChiaroG.SalvatoreE.2015Predictive correlations for the compaction of clean sandsTransportations Geotechnics.4384910.1016/j.trgeo.2015.06.004Open DOI Search in Google Scholar

[21]Geotechnnical Engineering Handbook (2011). Edited by Braja M. Das, J. Ross Publishing, Inc., Fort Lauderdale.Geotechnnical Engineering Handbook2011BrajaM. DasJ. Ross Publishing, Inc.Fort LauderdaleSearch in Google Scholar

[22]EN 1997-1. (2004). Eurocode 7: Geotechnical design – Part 1. General rules. Brussels.EN 1997-12004Eurocode 7: Geotechnical design – Part 1General rulesBrusselsSearch in Google Scholar

eISSN:: 2083-831X
Language:: English

Publication timeframe:: 4 times per year
Journal Subjects:: Geosciences, other, Materials Sciences, Composites, Porous Materials, Physics, Mechanics and Fluid Dynamics

Journal RSS Feed

Pullout Capacity Of Cylindrical Block Embedded In Sand

Article Category: Research Article

Published Online: Jun 05, 2018

Page range: 30 - 37

Received: Oct 16, 2017

Accepted: Dec 13, 2017

DOI: https://doi.org/10.2478/sgem-2018-0005

Keywordsblock anchors, pullout capacity, FE analysis, plastic limit analysis

© 2018 Krzysztof Sternik, Katarzyna Dołżyk-Szypcio, published by Sciendo

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

Keywords
block anchors, pullout capacity, FE analysis, plastic limit analysis