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Abstract
Laboratory swelling deformation tests were carried out on compacted GMZ bentonite and bentonite-sand mixtures with 30% and 50 % sand contents at 20, 40, 60, 80 and 90 °C with infiltration of distilled water. Influence of temperature, initial dry density, and quartz sand content on the swelling deformation characteristic of compacted bentonite specimens was analyzed. Results indicate that the swelling deformation process is accelerated, and the maximum swelling strain increases with the increase in temperature, while the maximum swelling strain tends to be stable with increasing temperature. In the meantime, the temperature effects depend on both of the sand content and the initial dry density of the specimens, the increases of the maximum swelling strain induced by increasing temperature, are enlarged by increasing sand content or initial dry density. Adding of quartz sand to bentonite not only influences the integrality of bentonite specimen, but also increase the microfissuring in area on quartz sand, which are advantageous to the heat transfer, leading to the increase of swelling deformation capacity of the specimen. The increased dry density relatively increases the bentonite content, so the swelling property is enhanced. However, no change on mineral composition of bentonite was observed when temperature was changed from 20 to 90 °C.
Keywords
GMZ bentonite
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swelling strain
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temperature
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initial dry density
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sand content
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Su-li Cui, Yan-feng Du, Xue-pan Wang, Sen Huang, Wan-li Xie.
Influence of temperature on swelling deformation characteristic of compacted GMZ bentonite-sand mixtures.
Journal of Central South University, 2018, 25(11): 2819-2830 DOI:10.1007/s11771-018-3955-9
| [1] |
RadhakrishnaH S, ChanH T, CrawfordA M, LauK C. Thermal and physical properties of candidate buffer-backfill materials for a nuclear fuel waste disposal vault [J]. Canadian Geotechnical Journal, 1989, 26: 629-639
|
| [2] |
ChapmanN, HooperA. The disposal of radioactive wastes underground [J]. Proceedings of the Geologists’ Association, 2012, 123(1): 46-63
|
| [3] |
VillarMV. Investigation of the behaviour of bentonite by means of suction controlled oedometer tests [J]. Engineering Geology, 19996773
|
| [4] |
YeW M, ChenY G, ChenB, WangQ, WangJ. Advances on the knowledge of the buffer/backfill properties of heavily-compacted GMZ bentonite [J]. Engineering Geology, 2010, 116(1): 12-20
|
| [5] |
KaufholdS, BailleW, SchanzT, DohrmannR. About differences of swelling pressure-dry density relations of compacted bentonites [J]. Applied Clay Science, 2015, 107: 52-61
|
| [6] |
CuiS L, ZhangH Y, ZhangM. Swelling characteristics of compacted GMZ bentonite–sand mixtures as a buffer/backfill material in China [J]. Engineering Geology, 2012, 141–142: 65-73
|
| [7] |
YeW M, ZhuC M, ChenY G, ChenB, CuiY J, WangJ. Influence of salt solutions on the swelling behaviour of the compacted GMZ01 bentonite [J]. Environmental Earth Sciences, 2015, 74: 793-802
|
| [8] |
YeW M, WanM, ChenB, ChenY G, CuiY J, WangJ. Temperature effects on the swelling pressure and saturated hydraulic conductivity of the compacted GMZ01 bentonite [J]. Environmental Earth Sciences, 2013, 68: 281-288
|
| [9] |
YeW, WanM, ChenB, ChenYG, CuiYJ, WangJ. Effect of temperature on soil-water characteristics and hysteresis of compacted Gaomiaozi bentonite [J]. Journal of Central South University, 2009, 16(5): 821-826
|
| [10] |
RamakrishnaB, AhsanR. Effect of temperature on swelling pressure and compressibility characteristics of soil [J]. Applied Clay Science, 2017, 136: 1-7
|
| [11] |
VillarM V, Gomez-EspinaR, LloretA. Experimental investigation into temperature effect on hydro-mechanical behaviours of bentonite [J]. Journal Rock Mechanics and Geotechnical Engineering, 2010, 2(1): 71-78
|
| [12] |
ChoW J, LeeJO, KangC H. Influence of temperature elevation on the sealing performance of a potential buffer material for a high-level radioactive waste repository [J]. Annals of Nuclear Energy, 2000, 27: 1271-1284
|
| [13] |
RomeroE, GensA, LloretA. Suction effects on a compacted clay under non-isothermal conditions [J]. Géotechnique, 2003, 53(1): 65-81
|
| [14] |
RomeroE, VillarM V, LloretA. Thermo-hydromechanical behaviour of two heavily overconsolidated clays [J]. Engineering Geology, 2005, 81: 255-268
|
| [15] |
LloretA, RomeroE, VillarM VFEBEX II project final report on thermo-hydro-mechanical laboratory tests [R], 2004, Madrid, Publicación Técnica ENRESA 10/04
|
| [16] |
TangA M, CuiY J, BarnelN. Thermo-mechanical behaviour of a compacted swelling clay [J]. Géotechnique, 2008, 58(1): 45-54
|
| [17] |
CuiY J, TangA M, QianL X, YeW M, ChenB. Thermal-mechanical behaviour of compacted GMZ bentonite [J]. Soils and Foundations, 2011, 51(6): 1065-1074
|
| [18] |
PuschRThe permeability of highly compacted bentonite [R], 1980
|
| [19] |
PuschR, KarnlandO, HokmarkHGMM a general microstructural model for qualitative and quantitative studies of smectite clays [R], 1990, Stockholm, SKB
|
| [20] |
VillarM V, LloretA. Influence of temperature on the hydro-mechanical behaviour of a compacted bentonite [J]. Applied Clay Science, 2004, 26: 337-350
|
| [21] |
BagR, RabbaniA. Effect of temperature on swelling pressure and compressibility characteristics of soil [J]. Applied Clay Science, 2017, 136: 1-7
|
| [22] |
TripathyS, BagR, ThomasH R. Enhanced isothermal effect on swelling pressure of compacted MX80 bentonite [J]. Engineering Geology, 2015, 6: 537-539
|
| [23] |
ChenB, QianLX, YeW, CuiY, WangJ. Soil-water characteristic curves of Gaomiaozi bentonite [J]. Chinese Journal of Rock Mechanics and Engineering, 2006, 25(4): 788-793
|
| [24] |
LuiY, XuG, LiuSStudy on the basic property of Gaomiaozi bentonite, Inner Mongolia [M], 2001, Beijing, China Nuclear Industry Audio & Visual Publishing House
|
| [25] |
ChenY G, YeW M, YangX M, DengF Y, HeY. Effect of contact time, pH, and ionic strength on Cd (II) adsorption from aqueous solution onto bentonite from Gaomiaozi, China [J]. Environmental Earth Sciences, 2011, 64(2): 329-336
|
| [26] |
YeW M, CuiY J, QianL X, ChenB. An experimental study of the water transfer through confined compacted GMZ bentonite [J]. Engineering Geology, 2009, 108(34): 169-176
|
| [27] |
CuiS, SiD. Experimental research of swelling behaviors with initial water content and matric suction of bentonite–sand mixtures [J]. Geosystem Engineering, 2014, 17(6): 317-324
|
| [28] |
ZhangH, CuiS, ZhangM, JiaL. Swelling behaviors of GMZ bentonite-sand mixtures inundated in NaCl-Na2SO4 solution [J]. Nuclear Engineering and Design, 2012, 242: 115-123
|
| [29] |
YeW M, ZhangY W, CehnY G, ChenB, CuiY J. Experimental investigation on the thermal volumetric behaviour of highly compacted GMZ01 Bent [J]. Applied Clay Science, 2013, 83–84: 210-216
|
| [30] |
YeW M, ZhangY W, ChenB, ChenY G, CuiY J. Investigation on compressibility of highly compacted GMZ01 bentonite with suction and temperature control [J]. Nuclear Engineering and Design, 2012, 252: 11-18
|
| [31] |
YeW M, ZhengZ J, ChenB, ChenY G, CuiY J, WangJ. Effects of pH and temperature on the swelling pressure and hydraulic conductivity of compacted GMZ01 bentonite [J]. Applied Clay Sciences, 2014, 101: 192-198
|
| [32] |
YeW M, HeY, ChenY G, ChenB, CuiY J. Thermochemical effects on the smectite alteration of GMZ bentonite for deep geological repository [J]. Environmental Earth Sciences, 2016, 75(10): 1-11
|
| [33] |
QiuM, YangG, ShenQ, YangX, WangG, LinYu. Dynamic behavior of new cutting subgrade structure of expensive soil under train loads coupling with service environment [J]. Journal of Central South University, 2017, 24(4): 875-890
|
| [34] |
PastinaB, HelläPExpected evolution of a spent nuclear fuel repository at Olkiluoto [R], 2006, Olkiluoto, Finland, Posiva Oy
|
| [35] |
HökmarkH, FälthBThermal dimensioning of the deep repository [R], 2003, Svensk, Kärnbränslehantering AB
|
| [36] |
WashburnE W. Note on a method of determining the distribution of pore sizes in a porous material [J]. Proceedings of the National Academy of Sciences of the United States of America, 1921, 7(4): 115-116
|
| [37] |
SridharanA, GurtugY. Swelling behaviour of compacted fine-grained soils [J]. Engineering Geology, 2004, 72(1): 9-18
|
| [38] |
RaoS M, ThyagarajT, ThomasH R. Swelling of compacted clay under osmotic gradients [J]. Geotechnique, 2006, 56(10): 707-713
|
| [39] |
ShackelfordC, DanielD. Diffusion in saturated soils, Part I [J]. Geotechnical Engineering, 1991, 117: 467-484
|
| [40] |
ShearM K, CooperA M, KlermanG L, BuschF N, ShapiroT. A psychodynamic model of panic disorder [J]. American Journal of Psychiatry, 1993, 150: 859-866
|
| [41] |
XieM, WangW Q, JongeK. Numerical modelling of swelling pressure in unsaturated expansive elasto-plastic porous media [J]. Transport in Porous Media, 2007, 66: 311-339
|
| [42] |
XuL, YeW M, ChenB, ChenY G, CuiY J. Experimental investigations on thermo-hydro-mechanical properties of compacted GMZ01 bentonite-sand mixture using as buffer materials [J]. Engineering Geology, 2016, 213(1): 46-54
|
| [43] |
InoueA. Formation of clay minerals in hydrothermal environments [J]. Origin and Mineralogy of Clays, 1995268329
|
| [44] |
YeW M, HeY, ChenY G, ChenB, CuiY J. Thermochemical effects on the smectite alteration of GMZ bentonite for deep geological repository [J]. Environmental Earth Sciences, 2016, 75(10): 1-11
|
