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Compaction and swelling characteristics of sand-bentonite and pumice-bentonite mixtures

Published online by Cambridge University Press:  09 July 2018

Z. Gökalp*
Affiliation:
Agricultural Structures and Irrigation Department, Erciyes University Agricultural Faculty, 38039, Kayseri, Turkey
M. Başaran
Affiliation:
Soil Science Department, Erciyes University Agricultural Faculty, 38039, Kayseri, Turkey
O. Uzun
Affiliation:
Soil Science Department, Erciyes University Agricultural Faculty, 38039, Kayseri, Turkey

Abstract

Bentonite mixed with varying quantities of sand is currently of widespread interest as engineering liners for water containment and waste disposal. However, the alternative use of pumice, widespread in many volcanic regions, has been less studied and requires further characterization of geotechnical properties and performance prior to its extensive use. The objective of this study was to determine and compare the compaction and swelling characteristics of sandbentonite and pumice-bentonite mixtures using available geo-materials from Turkey. Standard Proctor compaction tests and constant volume swell tests were carried out using mixtures with four different bentonite contents (15, 20, 25, 30%) and three different sand and pumice grain size ranges (2.00–1.00; 1.00–0.50; 0.50–0.25 mm). The results indicate that pumice-bentonite mixtures have lower maximum dry unit weights, higher optimum moisture contents and greater swelling potentials than equivalent sand-bentonite mixtures. Important differences occur in the swelling potentials of the sand and pumice mixtures with respect to grain size whereby sand-bentonite mixtures show increased swelling with coarsening grain size, in contrast to the pumice–bentonite mixtures which showed a decrease. These differences are attributed to the amount of grain-size-dependent connected pore space that can be filled during bentonite expansion and the presence of dissolvable salts in the pumice. It is concluded that locally available pumice material could be used to replace sand in engineering bentonite seals, despite some differences in their geotechnical properties.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2011

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References

Agus, S.S. & Schanz, T. (2005) Effects of shrinking and swelling on micro structures and fabric of compacted bentonite-sand mixture. Pp. 543550 in: Proceedings of International Conference on Problematic Soils, Cyprus, 2.Google Scholar
Akgün, H. (2010) Geotechnical characterization and performance assessment of bentonite/sand mixtures for underground waste repository sealing. Applied Clay Science, 49, 394399.CrossRefGoogle Scholar
Akgün, H., Koçkar, M.K. & Aktürk, Ö. (2006) Evaluation of compacted bentonite/sand seal for underground waste repository isolation. Environmental Geology, 50,331-337.Google Scholar
Alawaji, HA. (1999) Swell and compressibility characteristics of sand-bentonite mixtures inundated with liquids. Applied Clay Science, 15, 411430.Google Scholar
Alonso, E.E., Romero, E., Hofmann, E. & Garcia- Escudero, E. (2005) Expansive bentonite-sand mixtures in cyclic controlled-suction drying and wetting. Engineering Geology, 81, 213226.CrossRefGoogle Scholar
Al-Rawas, A.A., Mohamedzein, Y.E., Al-Shabibi, A.S. & Al-Katheiri, S. (2006) Sand-attapulgite clay mixtures as a landfill liner. Geotechnical and Geological Engineering, 24, 13651383.Google Scholar
Anonymous (2000a) Annual Book of ASTM Standards. D 698 Standard Test Method for Laboratory Compaction Characteristics of Soil Using Standard Effort. American Society for Testing and Materials, Section 4, 04.08(1), 78-85.Google Scholar
Anonymous (2000b) Annual Book of ASTM Standards. D 4546 Standard Test Methods for One-Dimensional Swell of Settlement Potential of Cohesive Soils. American Society for Testing and Materials, Section 4, 04.08(1); 693-699.Google Scholar
Anonymous (2010) Characteristics of Lipari Pumice, http://www.italpomice.it/characte.htm Google Scholar
Çanbensan (2010) Properties of Çanbensan Bentonite, Çanbensan Export Co., Ankara, Turkey, http://www.canbensan.com Google Scholar
Chapius, R.P. (1990) Sand-bentonite liners: Predicting permeability from laboratuary tests. Canadian Geotechnical Journal, 27, 4757.Google Scholar
Chapius, R.P., Marcotte, D. & Aubertin, M. (2006) Discussion of ‘Network model for hyraulic conductivity of sand-bentonite mixtures'. Canadian Geotechnical Journal, 43, 110114.CrossRefGoogle Scholar
Dadey, K.A. & Klaus, A. (1992) Physical properties of volcaniclastic sediments in the Izu-Bonin area. Pp. 543550 in: Proceedings of the Ocean Drilling Program, Scientific Result. (B. Taylor & K. Fujioka, editors).Google Scholar
Dixon, D.A., Gray, M.N. & Thomas, A.W. (1985) A study of the compaction properties of potential clay-sand buffer mixtures for use in nuclear fuel waste disposal. Engineering Geology, 21, 247255.Google Scholar
Esposito, L. & Guadagno, F.M. (1998) Some special geotechnical properties of pumice deposits. Bulletin of Engineering Geology and the Environment, 57, 4150.Google Scholar
Garden Pomza (2010) Properties of Pumice. Garden Pomza Manufacture and Trade Co., Develi, Kayseri, Turkey, http://www.gardenpomza.com Google Scholar
Gökalp, Z. (2009) Engineering characteristics of sandclay mixtures used for clay cores of earth-fill dams. Clay Minerals, 44, 319326.Google Scholar
Hyde, C. (1998) Pond Building: A Guide to Planning, Constructing and Maintaining Recreational Ponds. Alabama Cooperative Extension System, ANR1114, Alabama A&M and Auburn Universities, USA.Google Scholar
Jan, Y.L., Tsai, S.C., Cheng, H.P. & Hsu, C.N. (2007) Associating characterization of bentonite-based buffer/ backfill materials by distributing ratio (Rj) and plastic index (PI). Journal of Marine Science and Technology, 15, 1723.Google Scholar
Kadlec, H.R. & Knight, R.L. (1996) Treatment Wetlands. Lewis Publishers, Florida, USA.Google Scholar
Kadlec, R.H., Knight, R. L. Vymazal L, Brix, H., Cooper, P. & Haberl, R. (2000) Constructed Wetlands for Pollution Control; Processes, Performances, Design and Operation. Scientific and Technical Report No. 8, IWA Publishing, London.Google Scholar
Kayabali, K. (1997) Engineering aspects of a novel landfill liner material: bentonite-amended natural zeolite. Engineering Geology, 46, 105114.Google Scholar
Keskin, S.N., Cimen, O. Goksan, T.S., Uzundurukan, S. & Karpuzcu, M. (2009) Effect of geotextiles on the compaction properties of soils. Second International Conference on New Developments in Soil Mechanics and Geotechnical Engineering, 28—30 May, Near East University, Nicosia, Northern Cyprus.Google Scholar
Komine, H. (2004) Simplified evaluation of hydraulic conductivities of sand-bentonite mixture backfill. Applied Clay Science, 26, 1319.CrossRefGoogle Scholar
Komine, H. (2010) Predicting hydraulic conductivity of sand-bentonite mixture backfill before and after swelling deformation for underground disposal of radioactive wastes. Engineering Geology, 114, 123134.Google Scholar
Komine, H. & Ogata, N. (1999) Experimental study on swelling characteristics of sand-bentonite mixture for nuclear waste disposal. Soils and Foundations, 39, 8397.Google Scholar
Lura, P., Bentz, D.P., Lange, D.A., Kovler, K. & Bentur, A. (2004) Pumice aggregates for internal water curing. Pp. 137151 in: Proceedings of the International Symposium on Concrete Science and Engineering, Google Scholar
PRO 36, RILEM Publications, S.A.R.L. Madsen, F.T. & Mueller-Vonmoos, M. (1989) The swelling behaviour of clays. Applied Clay Science, 4, 143156.Google Scholar
Mishra, A.K., Dhawan, S. & Rao, S.M. (2008) Analysis of swelling and shrinkage behavior of compacted clays. Geotechnical and Geological Engineering, 26, 289298.Google Scholar
Mollamahmutoglu, M. & Yilmaz, Y. (2001) Potential use of fly ash and bentonite mixtures as liner or cover at waste disposal areas. Environmental Geology, 40, 13161324.Google Scholar
Muntohar, A.S. (2003) Swelling and compressibility characteristics of soil-bentonite mixtures. Dimensi Teknik Sipil, 5, no. 2, September 2003, 93-98.Google Scholar
Ozkan, S.G. & Twicer, G. (2001) Pomza Madendligine Genel Bir Bakis. 4. Endustriel Hammaddeler Sempozyumu, 1819 Ekim, Izmir, Turkiye.Google Scholar
Pusch, R. (1994) Waste Disposal in Rock. Developments in Geotechnical Engineering, 76. Elsevier Publishing. Co.Google Scholar
Pusch, R. (2001) The Buffer and Backfill Handbook, Part 2: Materials and Techniques. Geodevelopment AB, Technical Report TR-02-12.Google Scholar
Sällfors, G. & Öberg-Högsta, A.L. (2002) Determination of hydraulic conductivity of sand-bentonite mixtures for engineering purposes. Geotechnical and Geological Engineering, 20, 6580.CrossRefGoogle Scholar
Sivapullaiah, P.V., Sridharan, A. & Stalin, V.K. (1996) Swelling behaviour of soil—bentonite mixtures. Canadian Geotechnical Journal, 33, 808814.Google Scholar
Sohling, U., Ruf, F., Schurz, K., Emmerich, K., Steudel, A., Schuhmann, R., Weidler, P., Ralla, K., Riechers, D., Kasper, C. & Scheper, T. (2009) Natural mixture of silica and smectite as a new clayey material for industrial applications. Clay Minerals, 44, 525537.Google Scholar
Sridharan, A. & Gurtug, Y. (2004) Swelling behaviour of compacted fine-grained soil. Engineering Geology, 72, 918.Google Scholar
Studds, P.G., Stewart, D.I. & Cousens, T.W. (1998) The effects of salt solutions on the properties of bentonitesand mixtures. Clay Minerals, 33, 651660.CrossRefGoogle Scholar
Sun, D.A., Cui, H. & Sun, W. (2009) Swelling of compacted sand-bentonite mixtures. Applied Clay Science, 43, 485492.Google Scholar
Tien, Y.M., Wu, P.L., Chuang, W.S. & Wu, L.H. (2004) Micromechanical model for compaction characteristics of bentonite-sand mixtures. Applied Clay Science, 26, 489498.Google Scholar
Villar, M.V. (2006) Infiltration tests on a granite/ bentonite mixture: Influence of water salinity. Applied Clay Science, 31, 96109.Google Scholar