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Geotechnical and Geological Engineering
Erschienen in: Geotechnical and Geological Engineering 4/2017

10.03.2017 | State-of-the-Art Review

The Deep Mixing Method: Bearing Capacity Studies

verfasst von: Ahmad Safuan A Rashid, Aliff Ridzuan Bunawan, Khairun Nissa Mat Said

Erschienen in: Geotechnical and Geological Engineering | Ausgabe 4/2017

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Abstract

Nowadays, several techniques are employed to improve the problem of carrying out construction in soft soils by increasing the strength of the soil foundation and reducing the settlement of the soil. Among these stabilizing techniques, the deep mixing method is regarded as the most popular. The deep mixing method is a soil modification method where the soil is mixed in situ with stabilizing agents, commonly soil–cement columns. It increases the strength of the soil, providing bearing resistance and improved settlement performance. Deep mixing is carried out in situ using a machine equipped with mixing blades mounted at the end of a tube that has a nozzle at the lower end. The stabilizer agent is injected into the soil via the nozzle using a pumping system so that it mixes with the soil as the blades are rotated. Throughout this paper, previous works by numerous researchers on deep mixing including laboratory work, full-scale field tests, analytical and numerical analyses related to bearing capacity are reviewed. The techniques and results used are discussed with the help of figures depicting charts, failure modes, and the model configuration setup. It was found that the deep mixing method is suitable for use with any type of soil and provides a better alternative to the existing method of improving soft clay ground, especially with regard to the soil bearing capacity. In addition, future research is needed to improve the use of the method for soil improvement in the construction industry.
Nächster Artikel Assessment of Relationship Between Grouted Values and Calculated Values in the Bazoft Dam Site

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Literatur
Al-Tabbaa A, Evans C (2003) Geoenvironmental research and applications of deep soil mixing in the UK. In: International workshop on deep mixing, Tokyo, pp 288–307
Ahnberg H, Holm G, Holmqvist L, Ljungkrantz C (1994) The use of different additives in deep stabilisation of soft soils. In: Proceedings of the 13th international conference on soil mechanics and foundation engineering, vol 2, pp 1191–1194
Babasaki R, Terashi M, Suzuki T, Maekawa A, Kawamura M, Fukazawa E (1996) Japanese Geotechnical Society Technical Committee report—factors influencing the strength of improved soil. In: Proceeding of the 2nd international conference on ground improvement geosystems, vol 2, Tokyo, pp 913–918
Bergado DT, Anderson LR, Miura N, Balasubramaniam AS (1994) Lime/cement deep mixing method. Improvement techniques of soft ground in subsiding and lowland environments. A.A. Balkelma, Rotterdam, pp 99–130
Bergado DT, Ruenkrairergsa T, Taesiri Y, Balasubramaniam AS (1999) Deep soil mixing used to reduce embankment settlement. Ground Improv 3:145–162CrossRef
Black JA (2007) The settlement performance of a footing supported on soft clay reinforced with vibrated stone columns. PhD thesis, Queen’s University, Belfast
Bouassida M, Porbaha A (2004a) Ultimate bearing capacity of soft clays reinforced by a group of columns—application to a deep mixing technique. Soils Found 44(3):91–101CrossRef
Bouassida M, Porbaha A (2004b) Bearing capacity of foundations resting on soft ground improved by soil cement columns. In: International conference on geotechnical engineering (ICGE 2004), pp 173–180
Bouassida M, de Buhan P, Dormieux L (1995) Bearing capacity of a foundation resting on a soil reinforced by a group of columns. Geotechnique 45(1):25–34CrossRef
Bouassida M, Jelali B, Porbaha A (2008) Limit analysis of rigid foundations on floating columns. In: Innovative geotechnical engineering, international conference on geotechnical engineering, pp 105–115
Bouassida M, Jelali B, Porbaha A (2009) Limit analysis of rigid foundations on floating columns. Int J Geomech 9(3):89–101CrossRef
Broms BB (1999) Keynote lecture: design of lime, lime/cement and cement columns. In: Proceeding of the international conference on dry mix methods for deep soil stabilization, pp 125–153
Broms BB (2000) Lime and lime/columns. Summary and visions. In: Proceedings of 4th international conference on ground improvement geosystems, vol 1, pp 43–93
Broms BB (2001) Discussion—centrifuge model tests on failure envelope of column type deep mixing method improved ground. Soils Found 41(4):103–107
Broms BB (2002) Stabilization of soil with lime columns. Foundation engineering handbook. Kluwer, Dordrecht
Broms BB (2004) Lime and lime/cement columns Ground improvement. Spon Press, New York, pp 252–330
Broms BB, Boman P (1979) Stabilisation of soil with lime columns. Ground Eng 12(4):23–32
Bruce DA, Bruce ME (2001) Practitioner’s guide to the deep mixing method. Ground Improv 5(3):95–100CrossRef
Chai JC, Liu SY, Du YJ (2002) Field properties and settlement calculation of soil–cement column improved soft subsoil—a case study. Lowland Technology International 4(2):51–58
Chew SH, Kamruzzaman AHM, Lee FH (2004) Physico-chemical and engineering behaviour of cement-treated clays. J Geotech Geoenviron Eng ASCE 130(7):696–706CrossRef
Coastal Development Institute of Technology (2002) The deep mixing method—principle—design and construction. A.A. Balkelma, Rotterdam
EuroSoilStab (2002) Development of design and construction methods to stabilise soft organic soils: design guide soft soil stabilisation. CT97-0351. Project no. BE 96-3177, Industrial & Materials Technologies Programme (Brite-EuRam III), European Commission
Fang Z (2006) Physical and numerical modelling of the soft soil ground improved by deep cement mixing method. PhD thesis, The Hong Kong Polytechnic University
Flodin N, Broms B (1981) Historical development of civil engineering in soft clay. In: Brand EW, Branner RP (eds) Soft clay engineering, chap 1. Elsevier, Amsterdam, pp 27–133
Gilbert M, Smith C, Haslam I, Pritchard T (2010) Application of discontinuity layout optimisation to geotechnical limit. In: Proceedings of the 7th European conference on numerical methods in geotechnical engineering
Horpibulsuk S, Miura N, Koga H, Nagaraj TS (2004) Analysis of strength development in deep mixing: a field study. Ground Improv J 8(2):59–68CrossRef
Inagaki M, Abe T, Yamamoto M, Nozu M, Yanagawa Y, Li L (2002) Behavior of cement deep mixing columns under road embankment. In: Proceedings of the 5th international conference on physical modelling in geotechnics: ICPMG, pp 967–972
Iskander MG, Liu J, Sadek S (2002) Optical measurement of deformation under foundations using a transparent soil model. In: Phillips R, Guo PJ, Popescu R (eds) Physical modelling in geotechnics: proceedings of the international conference ICPGM’02, 10–12 July, St. John’s, Newfoundland, Canada, pp 155–159
Kempert HG (2003) Ground improvement methods with special emphasis on column-type techniques. In: Vermeer, Schweiger, Karstunen, Cudny (eds) International workshop on geotechnics of soft soils—theory and practice
Kitazume M (2005) State of practice report—field and laboratory investigations, properties of binders and stabilised soil. In: Proceedings of international conference on deep mixing—best practice and recent advance, pp 660–684
Kitazume M (2006) Application of physical modelling for investigating ground failure pattern. In: Proceedings of the 6th international conference on physical modelling in geotechnics: ICPMG, pp 63–74
Kitazume M, Maruyama K (2005) Collapse failure of group column type deep mixing improved ground under embankment. In: Proceedings of international conference on deep mixing—best practice and recent advance, pp 245–254
Kitazume M, Maruyama K (2006) External stability of column type deep mixing improved ground under embankment loading. Soils Found 46(3):323–340CrossRef
Kitazume M, Maruyama K (2007a) Internal stability of group column type deep mixing improved ground under embankment loading. Soils Found 47(3):437–455CrossRef
Kitazume M, Maruyama K (2007b) Centrifuge model tests on failure pattern of group column type deep mixing improved ground. In: Proceedings of the 17th international offshore and polar engineering conference, pp 1293–1300
Kitazume M, Ikeda T, Miyajima S, Karastanev D (1996) Bearing capacity of improved ground with column type DMM. In: Proceedings of the 2nd international conference on ground improvement geosystems, vol 1, pp 503–508
Kitazume M, Miyake M, Omine K, Fujisawa H (1996) JGS TC report: Japanese design procedures and recent activities of DMM. In: Yonekura R, Terashi M, Shibazaki M (eds) Proceedings of IS-Tokyo’96, second international conference on ground improvement geosystems “Grouting and deep mixing”. Balkema, Tokyo, pp 925–930
Kitazume M, Yamamoto M, Udaka Y (1999) Vertical bearing capacity of column type DMM ground with low improvement ratio. In: Proceedings of the international conference on dry mix methods for deep soil stabilization, pp 245–250
Kitazume M, Okano K, Miyajima S (2000) Centrifuge model tests on failure envelope of column type deep mixing method improved ground. Soils Found 40:43–55CrossRef
Kivelo M, Broms BB (1999) Mechanical behaviour and shear resistance of lime/cement columns. In: Proceedings of the international conference on dry mix methods for deep soil stabilization, pp 193–200
Lin KQ, Wong IH (1999) Use of deep cement mixing to reduce settlements at bridge approaches. ASCE J Geotech Geoenviron Eng 125(4):309–320CrossRef
Massarsch KR, Topolnicki M (2005) Regional report: European practice of soil mixing technology. In: Proceedings of international conference on deep mixing—best practice and recent advance, pp R19–R45
Ni Q, Hird CC, Guymer I (2010) Physical modelling of pile penetration in clay using transparent soil and particle image velocimetry. Géotechnique 60(2):121–132CrossRef
Okumura T (1996) Deep mixing method of Japan. In: Grouting and deep mixing, proceedings of the 2nd international conference on ground improvement geosystems. Balkema, Rotterdam, pp 879–887
Omine K, Ochiai H, Bolton MD (1999) Homogenization method for numerical analysis of improved ground with cement-treated soil columns. In: Proceedings of the international conference on dry mix methods for deep soil stabilization, pp 161–168
Porbaha A (1998) State of the art in deep mixing technology: part I. Basic concepts and overview. Ground Improv 2(2):81–92CrossRef
Porbaha A (2000) State of the art in deep mixing technology: part IV. Design considerations. Ground Improv 3:111–125CrossRef
Porbaha A (2006) Recent advances in deep mixing research and development in the USA. In: Proceedings of sessions of GeoShanghai, pp 45–50
Prandtl L (1921) Uber Die Eindringungsfestigkeit (Harte) Plastischer Baustoffe Und DieFestigkeit Von Schneiden. Zeitschrift fur angewandte Mathematik und Mechanik. vol 1, No 1, pp 15–20
Public Works Research Centre (1999) Deep mixing method design and execution manual for land works, pp 92–99
Raju VR (2003) Ground treatment using dry deep soil mixing for a railway embankment in Malaysia. In: Proceedings of the 2nd international conference on advances in soft soil engineering and technology, pp 589–600
Rashid ASA (2011) Behaviour of weak soils reinforced with soil columns formed by the deep mixing method. PhD thesis, The University of Sheffield
Rashid ASA, Noor NM (2012) Estimation of interface resistance between testing chamber and soil model using shear box test. Eur J Sci Res 80(4):472–478
Rashid ASA, Black JA, Mohammad H, Noor NM (2015a) Behavior of weak soils reinforced with end-bearing soil–cement columns formed by the deep mixing method. Mar Georesour Geotechnol 33(6):473–486CrossRef
Rashid ASA, Black JA, Kueh ABH, Noor NM (2015b) Behaviour of weak soils reinforced with soil cement columns formed by the deep mixing method: rigid and flexible footings. Meas J Int Meas Confed 68:262–279CrossRef
Sandros C, Holm G (1996) Deep stabilisation with the wet cement mixing method. In: Proceedings of 12th Nordic geotechnical conference, pp 129–134
Shen S, Han J, Du Y (2008) Deep mixing induced property changes in surrounding sensitive marine clays. J Geotech Geoenvironmental Eng 134:145–154CrossRef
Smith C, Gilbert M (2007) Application of discontinuity layout optimisation to plane plasticity problems. Proc R Soc A 463:2461–2484CrossRef
Tatsuoka F, Kobayashi A (1983) Triaxial strength characteristic of cement treated soft clay. In: Proceedings of the 8th European conference on soil mechanics and foundation engineering, vol 1, pp 421–426
Terashi M (2003) The state of practice in deep mixing methods. In: Proceedings of the 3rd international conference on grouting and ground treatment, ASCE geotechnical special publication no. 120, pp 25–49
Terashi M (1997) Theme lecture: deep mixing—brief state of the art. In: Proceeding of the 14th international conference on soil mechanics and foundation engineering, vol 4, pp 2475–2478
Terashi M (2005) Keynote lecture: design of deep mixing in infrastructure applications. In: Proceedings of international conference on deep mixing—best practice and recent advance, pp K25–K45
Terashi M, Juran I (2000) Ground improvement—state of the art. In: GEOENG 2000, Melbourne
Terashi M, Miki H (1999) Importance of prediction in ground improvement, Prediction and performance of ground improvement, Practitioners series no. 11. Japanese Geotechnical Society, pp 1–10
Terashi M, Tanaka H (1981) Ground improved by deep mixing method. In: Proceedings of the 10th ICSMFE, vol 3, pp 777–780
Topolnicki M (2004) In situ soil mixing. Ground improvement. Spon Press, New York, pp 331–428
Uddin K, Balasubramaniam AS, Bergado DT (1997) Engineering behaviour of cement-treated Bangkok Soft Clay. Geotech Eng 28(1):89–119
White DJ (2002) An investigation into the behaviour of pressed-in piles. PhD dissertation, University of Cambridge
White DJ, Take WA (2002) GeoPIV: Particle Image Velocimetry (PIV) software for use in geotechnical testing. Technical report CUED/D-SOILS/TR322, Cambridge University, Engineering Department
Yin JH, Fang Z (2006) Physical modelling of consolidation behaviour of a composite foundation consisting of a cement-mixed soil column and untreated soft marine clay. Geotechnique 56(1):63–68CrossRef
Yoshizawa H, Okumura R, Hosoya Y, Sumi M, Yamada T (1997) JGS TC report: factors affecting the quality of treated soil during execution of DMM. In: Proceedings, ISTokyo ‘96/2nd international conference on ground improvement geosystems, vol 2, Tokyo, pp 931–937
Metadaten
Titel
The Deep Mixing Method: Bearing Capacity Studies
verfasst von
Ahmad Safuan A Rashid
Aliff Ridzuan Bunawan
Khairun Nissa Mat Said
Publikationsdatum
10.03.2017
Verlag
Springer International Publishing
Erschienen in
Geotechnical and Geological Engineering / Ausgabe 4/2017
Print ISSN: 0960-3182
Elektronische ISSN: 1573-1529
DOI
https://doi.org/10.1007/s10706-017-0196-x

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