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Environmental Earth Sciences

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01.05.2016 | Original Article

Advances in experimental investigation on hydraulic fracturing behavior of bentonite-based materials used for HLW disposal

verfasst von: Yong-Gui Chen, Ling-Yan Jia, Wei-Min Ye, Bao Chen, Yu-Jun Cui

Erschienen in: Environmental Earth Sciences | Ausgabe 9/2016

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Abstract

Bentonite-based materials (BBM) in the form of blocks or rings have been commonly proposed as buffer materials for high-level radioactive waste disposal. In a real repository, hydraulic fracturing is likely to be present when the ground water pressure exceeds to hydraulic resistance, and the existence of technological gaps increases the risk of hydraulic fracturing. Based on the previous studies of hydraulic fracturing of BBM and technological interfaces, the present work systematically analyzes the experimental achievements. Results show that the fracturing pressure of BBM and interfaces increases with hydration time, initial dry density, bentonite content and overburden pressure, while it decreases with initial water content and gap thickness. The temperature effect on hydraulic fracturing depends on the predominant cation of bentonite. For Na-bentonite, the higher temperature leads to the larger swelling pressure, and thus the stronger hydraulic resistance. Tensile failure, shear failure and synthesis failures are increasingly accepted for hydraulic fracturing mechanism. The hydraulic fracturing of highly compacted BBM is mainly controlled by tensile failure, while the initial shear failure can be found for BBM with a low enough density. Since hydraulic fracturing is expected to occur several times during the repository operation, the long-time monitoring of hydro-mechanical behavior is of vital importance until the technological gaps are completely sealed. Furthermore, the failure mechanism of hydraulic fracturing of BBM should be further researched, as well as the sealing properties of interfaces under thermo-hydro-mechanically coupled conditions are proposed to be studied thoroughly.

Vorheriger Artikel Monitoring bioconcentration of potentially toxic trace elements in soils trophic chains

Nächster Artikel Analysis and prevention of sinkhole collapses during the reconstruction and extension of Guang-Qing freeway, china

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Agus SS, Schanz T (2008) A method for predicting swelling pressure of compacted bentonites. Acta Geotech 3(2):125–127CrossRef

Ahn HS, Jo HY (2009) Influence of exchange cations on hydraulic conductivity of compacted bentonite. Appl Clay Sci 44(1–2):144–150CrossRef

Alfaro MC, Wong RCK (2001) Laboratory studies on fracturing of low-permeability soils. Can Geotech J 38(2):303–315CrossRef

Alonso EE, Romero E, Hoffmann C (2011) Hydromechanical behavior of compacted granular expansive mixtures: experimental and constitutive study. Géotechnique 61(4):329–344CrossRef

Andersen KH, Rawlings CG, Lunne TA, By TH (1994) Estimation of hydraulic fracture pressure in clay. Can Geotech J 31(6):817–828CrossRef

ANDRA (2005) Référentiel des matériaux d’un stockage de déchets à haute activité et à vie longue—Tome 4: les matériaux à base d’argilites excavées et remaniées. Rapport Andra No CRPASCM040015B

Baille W, Tripathy S, Schanz T (2010) Swelling pressures and one-dimensional compressibility behavior of bentonite at large pressures. Appl Clay Sci 48(3):324–333CrossRef

Barnichon JD, Deleruyelle F (2009) Sealing experiments at the Tournemire URL. Towards convergence of technical nuclear safety practices in Europe. EUROSAFE

Beattie TM, Williams SJ (2012) An overview of near-field evolution research in support of the UK geological disposal programme. Minera Mag 76(8):2995–3001CrossRef

Bjerrum L, Nash JKTL, Kennard RM, Gibson RE (1972) Hydraulic fracturing in field permeability testing. Géotechnique 22(2):319–332CrossRef

Blatz JA, Graham J, Chandler NA (2002) Influence of suction on the strength and stiffness of compacted sand–bentonite. Can Geotech J 39(5):1005–1015CrossRef

Bohloli B, De Pater CJ (2006) Experimental study on hydraulic fracturing of soft rocks: influence of fluid rheology and confining stress. J Pet Sci Eng 53(1):1–12CrossRef

Buzzi O, Boulon M, Deleruyelle F, Besnus F (2008) Hydromechanical behaviour of rock-bentonite interfaces under compression. Rock Mech Rock Eng 41(2):343–371CrossRef

Chandler N, Dixon D, Gray M, Hara K, Cournut A, Tillerson J (1998) The tunnel sealing experiment: an in situ demonstration of technologies for vault sealing. In: Proceedings of the 19th annual conference of the Canadian nuclear society

Chang H (2004) Hydraulic fracturing in particulate materials. Dissertation Abstracts International, America

Chapman N, Hooper A (2012) The disposal of radioactive wastes underground. Proceedings of the Geologists’ Association 123(1):46–63CrossRef

Chen YG, Ye WM, Zhang KN (2009) Strength of copolymers grouting material based on orthogonal experiment. J Cent South Univ Technol 16(1):143–148CrossRef

Chen YG, He Y, Ye WM, Lin CH, Zhang XF (2012a) Removal of chromium(III) from aqueous solutions by adsorption on bentonite from Gaomiaozi. China. Environ Earth Sci 67(5):1261–1268CrossRef

Chen YG, Zhu CM, Sun YH, Duan HY, Ye WM, Wu DB (2012b) Adsorption of La(III) onto GMZ bentonite: effect of contact time, bentonite content, pH value and ionic strength. J Radioanal Nucl Chem 292(3):1339–1347CrossRef

Chen YG, He Y, Ye WM, Sui WH, Xiao MM (2013) Effect of shaking time, ionic strength, temperature and pH value on desorption of Cr (III) adsorbed onto GMZ bentonite. Trans Nonferrous Met Soc China 23(11):3482–3489CrossRef

Chen YG, Cui YJ, Wang Q, Ye WM (2014) A preliminary study on hydraulic resistance of bentonite/host-rock seal interface. Géotechnique 64(12):997–1002CrossRef

Cho WJ, Lee JO, Chun KS (1999) The temperature effects on hydraulic conductivity of compacted bentonite. Appl Clay Sci 14(1–3):47–58CrossRef

Cho WJ, Lee JO, Kang CH (2000) Influence of temperature elevation on the sealing performance of a potential buffer material for a high-level radioactive waste repository. Ann Nucl Energy 27(14):1271–1284CrossRef

Cui YJ, Tang AM, Loiseau C, Delage P (2008) Determining the unsaturated hydraulic conductivity of a compacted sand–bentonite mixture under constant-volume and free-swell conditions. Phys Chem Earth Parts A/B/C 33:S462–S471CrossRef

Cui SL, Zhang HY, Zhang M (2012) Swelling characteristics of compacted GMZ bentonite–sand mixtures as a buffer/backfill material in China. Eng Geol 141(3):65–73CrossRef

Cui YJ, Saba S, Tang AM, Barnichon JD (2014) Investigation of the swelling behavior of compacted bentonite/sand mixture by mock-up tests. Can Geotech J 51:1399–1412CrossRef

Dixon D, Chandler N, Graham J, Gray NN (2002) Two large scale sealing tests conducted at atomic energy of Canada’s underground research laboratory: the buffer-container experiment and isothermal test. Can Geotech J 39(3):503–518CrossRef

Gens A, Guimaraes LN, Garcia-Molina A, Alonso EE (2002) Factors controlling rock-clay buffer interaction in a radioactive waste repository. Eng Geol 64(2–3):297–308CrossRef

Grindrod P, Peletier M, Takase H (1999) Mechanical interaction between swelling compacted clay and fractured rock, and the leaching of clay colloids. Eng Geol 54(1–2):159–165CrossRef

Hökmark H (2004) Hydration of the bentonite buffer in a KBS-3 repository. Appl Clay Sci 26(1):219–233CrossRef

Kenney TC, Van Veen WA, Swallow MA, Sungaila MA (1992) Hydraulic conductivity of compacted bentonite–sand mixtures. Can Geotech J 29(3):364–374CrossRef

Kobayashi A, Yamamoto K, Momoki S (2008) Characteristics of strength for hydraulic fracturing of buffer material. Soils Found 48(4):467–477CrossRef

Komine H (2004) Simplified evaluation on hydraulic conductivities of sand–bentonite mixtures backfill. Appl Clay Sci 26(1–4):13–19CrossRef

Komine H (2009) Self-sealing capability of some bentonite buffers in artificial seawater. In: Proceedings of the 17th international conference on soil mechanics and geotechnical engineering, pp 2495–2498

Komine H, Ogata N (1994) Experimental study on swelling characteristics of compacted bentonite. Can Geotech J 31(4):478–490CrossRef

Komine H, Ogata N (1999) Experimental study on swelling characteristics of sand–bentonite mixture for nuclear waste disposal. Soils Found 39(2):83–97CrossRef

Komine H, Ogata N (2003) New equations for swelling characteristics of bentonite-based buffer materials. Can Geotech J 40(2):460–475CrossRef

Lee JO, Lim JG, Kang IM, Kwon S (2012) Swelling pressures of compacted Ca-bentonite. Eng Geol 129(12):20–26CrossRef

Lloret A, Villar MV (2007) Advances on the knowledge of the thermo-hydro-mechanical behaviour of heavily compacted “FEBEX” bentonite. Phys Chem Earth Parts A/B/C 32(8–14):S701–S715CrossRef

Lo KY, Kaniare K (1990) Hydraulic fracture in earth and rock-fill dams. Can Geotech J 27(4):496–506CrossRef

Marcial D, Delage P, Cui YJ (2006) A laboratory study of the self sealing behaviour of a compacted sand–bentonite mixture. Geomech Geoeng Int J 1(1):73–85CrossRef

Martín PL, Barcala JM, Huertas F (2006) Large-scale and long-term coupled thermo-hydro-mechanic experiments with bentonite: the FEBEX mock-up test. J Iber Geol 32(2):259–282

McCombie C (2005) Geological disposal: global status and key issues. Pract Period Hazard Toxic Radioact Waste Manage 9(1):71–80CrossRef

Missana T, Alonso Ú, Turrero MJ (2003) Generation and stability of bentonite colloids at the bentonite/granite interface of a deep geological radioactive waste repository. J Contam Hydro 61(1–4):17–31CrossRef

Mori A, Tamura M (1987) Hydrofracturing pressure of cohesive soils. Soils Found Jpn Society Soil Mech Found Eng 27(1):14–22

Önal M (2007) Swelling and cation exchange capacity relationship for the samples obtained from a bentonite by acid activations and heat treatments. Appl Clay Sci 37(1–2):74–80CrossRef

Panah AK, Yanagisawa E (1989) Laboratory studies on hydraulic fracturing criteria in soil. Soils Found Jpn Society Soil Mech Found Eng 29(4):14–22

Pusch R (1992) Use of bentonite for isolation of radioactive waste products. Clay Miner 27(3):353–361CrossRef

Push R (1983) Borehole sealing for underground waste storage. J Geotech Eng 109(1):113–119CrossRef

Push R (2008) Geological storage of radioactive waste. Springer, Berlin HeidelbergCrossRef

Saba S, Barnichon JD, Cui YJ, Tang AM, Delage P (2014a) Microstructure and anisotropic swelling behavior of compacted bentonite/sand mixture. J Rock Mech Geotech Eng 6(2):126–132CrossRef

Saba S, Delage P, Lenoir N, Cui YJ, Tang AM, Barnichon JD (2014b) Further insight into the microstructure of compacted bentonite–sand mixture. Eng Geol 168(2):141–148CrossRef

Seiphoori A, Ferrari A, Laloui L (2014) Water retention behaviour and microstructural evolution of MX-80 bentonite during wetting and drying cycles. Géotechnique 64(9):721–734CrossRef

Sivapullaiah PV, Sridharan A, Stalin VK (2000) Hydraulic conductivity of bentonite–sand mixtures. Can Geotech J 37(37):406–413CrossRef

SKB (1998) Detailed programme for research and development 1999–2004. Background report to RD & D-Programme 98

SKB (2001) Programme for research, development and demonstration of methods for the management and disposal of nuclear waste. Technical report TR-01-30 to RD & D-Programme: 20–21

Soga K, Ng MYA, Gafer K (2005) Soil fractures in grouting. In: Proceedings of the 11th international conference on computer methods and advances in geomechanics, prediction, analysis and design in geomechanical applications, pp 397–406

Suzuki K, Asano H, Yahagi R, Kobayashi I, Sellin P, Svemar C, Holmqvist M (2013) Experimental investigations of piping phenomena in bentonite-based buffer materials for an HLW repository. Clay Miner 48(2):363–382CrossRef

Tang GX (1999) Suction characteristics and elastic–plastic modeling of unsaturated sand–bentonite mixture. University of Manitoba, Winnipeg

Tang AM, Munoz JJ, Cui YJ, Delage P, Li XL (2008) Experimental evaluation of the hydraulic resistance of compacted bentonite/boom clay interface. In: International conference: underground disposal unit design and emplacement processes for a deep geological repository, pp 16–18

Teachavorasinskun S, Visethrattana K (2006) Local hydraulic resistance of compacted sand–bentonite mixture. Géotechnique 56(7):511–516CrossRef

Tsang CF, Bernier F, Davies C (2005) Geohydromechanical processes in the Excavation Damaged Zone in crystalline rock, rock salt, and indurated and plastic clays—in the context of radioactive waste disposal. Int J Rock Mech Min Sci 42(1):109–125CrossRef

Tsang CF, Barnichon JD, Birkholzer J, Li XL, Liu HH, Sillen X (2012) Coupled thermo-hydro-mechanical processes in the near field of a high-level radioactive waste repository in clay formations. Int J Rock Mech Min Sci 49(1):31–44CrossRef

Tsukada Y, Kobayashi A, Kiyama S, Aoyama S (2005) Numerical analysis method for hydraulic fracturing: criterion for hydraulic fracturing in rock foundations of embankment dams. T Jpn Society of Irrig Drain Rural Eng 236:79–92

Van Geet M, Volckaert G, Roels S (2005) The use of microfocus X-ray computed tomography in characterising the hydration of a clay pellet/power mixture. Appl Clay Sci 29(2):73–87CrossRef

Villar MV, Lloret A (2004) Influence of temperature on the hydro-mechanical behavior of a compacted bentonite. Appl Clay Sci 26(1–4):337–350CrossRef

Villar MV, Lloret A (2007) Dismantling of the first section of the FEBEX in situ test: THM laboratory tests on the bentonite blocks retrieved. Phys Chem Earth Parts A/B/C 32(8–14):S716–S729CrossRef

Villar MV, Lloret A (2008) Influence of dry density and water content on the swelling of a compacted bentonite. Appl Clay Sci 39(1–2):38–49CrossRef

Villar MV, García-Siñeriz JL, Barcena I, Lloret A (2005) State of the bentonite barrier after five years operation of an in situ test simulating a high level radioactive waste repository. Eng Geol 80(3–4):175–198CrossRef

Wang Y, Dusseault MB (1991) Borehole yield and hydraulic fracture initiation in poorly consolidated rock strata—part I. Impermeable media. Int J Rock Mech Min Sci Geomech Abstr 28(4):235–246CrossRef

Wang JJ, Zhu JG, Chiu CF, Zhang H (2007a) Experimental study on fracture toughness and tensile strength of a clay. Eng Geol 94(1–2):65–75CrossRef

Wang JJ, Zhu JG, Mroueh H, Chiu CF (2007b) Hydraulic fracturing of rock-fill dam. Int J Multiphy 1(2):199–219CrossRef

Wang Q, Tang AM, Cui YJ, Delage P, Gatmiri B (2012) Experimental study on the swelling behavior of bentonite/claystone mixture. Eng Geol 124(1):59–66CrossRef

Wang Q, Cui YJ, Tang AM, Barnichon JD, Saba S, Ye WM (2013a) Hydraulic conductivity and microstructure changes of compacted bentonite/sand mixture during hydration. Eng Geol 164(4):67–76CrossRef

Wang Q, Tang AM, Cui YJ, Delage P, Barnichon JD, Ye WM (2013b) The effects of technological voids on the hydro-mechanical behavior of compacted bentonite–sand mixture. Soils Found 53(2):232–245CrossRef

Wang Q, Tang AM, Cui YJ, Barnichon JD, Ye WM (2013c) A comparative study on the hydro-mechanical behavior of compacted bentonite/sand plug based on laboratory and field infiltration tests. Eng Geol 162(14):79–87CrossRef

Wen ZJ, Jintoku T (2005) Preliminary study on static mechanical property of GMZ Na-bentonite. World Nucl Geosci 22(4):211–214 (in Chinese)

Westsik JH Jr, Hodges FN, Kuhn WL, Myers TR (1983) Water migration through compacted bentonite backfills for containment of high-level nuclear waste. Nucl Chem Waste Manage 4(4):291–299CrossRef

Wu DB, Zhu CM, Chen YG, Zhu BH, Yang YH, Wang QG, Ye WM (2012) Preparation, characterization and adsorptive study of rare earth ions using magnetic GMZ bentonite. Appl Clay Sci 62–63:87–93CrossRef

Xia HW, Moore ID (2006) Estimation of maximum mud pressure in purely cohesive material during directional drilling. Geomech Geoeng 1(1):3–11CrossRef

Yanagisawa E, Panah AK (1994) Two dimensional study of hydraulic fracturing criteria in cohesive soils. Soils Found 34(1):1–9CrossRef

Ye WM, Schaze S, Qian LX, Wang J, Arifin Y (2007) Characteristics of swelling pressure of densely compacted gaomiaozi bentonite GMZ01. Chin J Rock Mech Eng 26(S2):3861–3865 (in Chinese)

Ye WM, Cui YJ, Qian LX, Chen B (2009) An experimental study of the water transfer through confined compacted GMZ bentonite. Eng Geol 108(3):169–176CrossRef

Ye WM, Chen YG, Chen B, Wang Q, Wang J (2010) Advances on the knowledge of the buffer/backfill properties of heavily-compacted GMZ bentonite. Eng Geol 116(1–2):12–20CrossRef

Ye WM, Wan M, Chen B, Chen YG, Cui YJ, Wang J (2012a) Temperature effects on the unsaturated permeability of the densely compacted GMZ01 bentonite under confined conditions. Eng Geol 126(4):107

Ye WM, Zhang YW, Chen B, Zheng ZJ, Chen YG, Cui YJ (2012b) Investigation on compression behaviour of highly compacted GMZ01 bentonite with suction and temperature control. Nucl Eng Des 252:11–18CrossRef

Ye WM, Wan M, Chen B, Chen YG, Cui YJ, Wang J (2013) Temperature effects on the swelling pressure and saturated hydraulic conductivity of the compacted GMZ01 bentonite. Environ Earth Sci 68(1):281–288CrossRef

Zhang KN, Chen YG, Deng FY, Tian QY (2004) Retention of clay-solidified grouting curtain to Cd²⁺, Pb²⁺, Hg²⁺ in landfill of municipal solid waste. J Cent South Univ Technol 11(4):419–422CrossRef

Zhang M, Zhang HY, Zhou L, Wang BM, Wang SJ (2014) Hydro-mechanical analysis of GMZ bentonite–sand mixtures in the water infiltration process as the buffer/backfill mixture in an engineered nuclear barrier. Appl Clay Sci 97–98:115–124CrossRef

Zhu BH, Wu DB, Yang YH, Chen YG, Li WJ, Guo JF, Wang QG (2012) Selective removal of La(III) ions using super-paramagnetic nanosorbent coated by saponified sec-octylphenoxy acetic acid. J Chem Eng Data 57(2):553–560CrossRef

Titel: Advances in experimental investigation on hydraulic fracturing behavior of bentonite-based materials used for HLW disposal
verfasst von: Yong-Gui Chen
Ling-Yan Jia
Wei-Min Ye
Bao Chen
Yu-Jun Cui
Publikationsdatum: 01.05.2016
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 9/2016
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-016-5644-z

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