Effect of Compaction Pressure and Water Content on the Thermal Conductivity of Some Natural Clays

Alain Beziat; Michel Dardaine; Victor Gabis

doi:10.1346/CCMN.1988.0360512

Abstract

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This paper presents thermal conductivity data for highly compacted Ca-smectite, Na-smectite, illite, and palygorskite as a function of density (i.e., compaction pressure), water content, and temperature. All the clays behaved similarly: thermal conductivity increased directly with density and water content. Specifically, the thermal conductivity increased from 0.63 to 1.32 W/m·K as the dry density increased from 1.2 to 1.8 g/cm3 (for a water content of 17%). An increase of water content from 6 to 17% resulted in an increase in thermal conductivity from 0.63 to 1.22 W/m·K (for a dry density of 1.6 g/cm3). Differences from one clay to the other were less important. The thermal conductivity (in W/m·K) for constant conditions of 12% of water and a dry density of 1.6 g/cm3 were: Ca-smectite 0.80, Na-smectite 0.74, palygorskite 0.71, and illite 0.69. Heating to 188°C produced only a 10% increase in the thermal conductivity.

Résumé

Cet article présente des mesures de conductivité thermique effectuées sur des argiles hautement compactées—smectite-Ca, smectite-Na, illite, palygorskite—en fonction de la densité (c'est à dire de la pression de compaction), de la teneur en eau et de la température. Toutes les argiles étudiées ont le même comportement: la conductivité thermique augmente avec la densité et la teneur en eau. La conductivité thermique croit de 0,63 à 1,32 W/m·K quand la densité augmente de 1,2 à 1,8 g/cm3 (pour une teneur en eau de 17%). Une variation de teneur en eau de 6 à 17% produit une augmentation de conductivité de 0,6 à 1,22 W/m·K (pour une densité sèche de 1,6 g/cm3).

Les différences d'une argile à l'autre sont moins importantes: la conductivité en W/m·K pour une teneur en eau de 12% et une densité sèche de 1,6 g/cm3 sont: 0,80 pour la smectite Ca, 0,74 pour la smectite Na, 0,71 pour la palygorskite et 0,69 pour l'illite. La température, jusqu’à 188°C, n'a qu'une faible influence sur la conductivité thermique (elle ne provoque qu'une augmentation de l'ordre de 10%).

References

Carslaw, H. S. and Jaeger, J. C., 1959 Conduction of Heat in Solids Oxford Clarendon Press.Google Scholar

Coulon, H., Lajudie, A., Debrabant, P., Atabek, R., Jorda, M. and Andre-Jehan, R., 1987 Choice of French clays as engineered barrier components for waste disposal Mat. Res. Soc. Symp. 84 813 – 823.CrossRef Google Scholar

Kahr, G. and Muller-Vonmoos, M. (1982) Warmeleitfahigkeit von Bentonit MX80 und von Montigel nach der Heizdrahtmethod: Nat. Genos. Lagerung Radioak. Abf., Baden, Switzerland, Tech. Bericht 82–06, 19 pp.Google Scholar

Lappin, A. R. and Olsson, W. A., 1979 Material properties of Eleana argillite Proc. Nuclear Energy Agency Workshop on the Use of Argillaceous Materials for the Isolation of Radioactive Waste, Paris, 1979 Paris Nuclear Energy Agency 75 – 93.Google Scholar

Parrot, J. E. and Stuckes, A. D., 1975 Thermal Conductivity of Solids London Pion Limited 12 – 22.Google Scholar

Pusch, R., 1983 Use of clays as buffers in radioactive repositories Svensk Karnbransleforsorjning Abdelning KBS, Stockholm Report 83–46 20 – 52.Google Scholar

Radhakrishna, J. S., 1984 Thermal properties of clay based buffer material for a nuclear fuel waste disposal vault Manitoba Whiteshell Nuclear Research Est., Pinawa 6 – 8.Google Scholar

Tassoni, E., 1980 Comportamento termico dei materiali argillosi Italy European Nuclear Energy Agency, Comitato Nationale per la Ricerca e per lo Sviluppo dell’Energia Nucleare e delle Energie Alternative 17 – 36.Google Scholar

Touloukian, Y. S., 1981 Physical Properties of Rocks and Minerals New York McGraw-Hill 414 – 416.Google Scholar

Crossref Citations

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Geneste, Ph. Raynal, M. Atabek, R. Dardaine, M. and Oliver, J. 1990. Characterization of a french clay barrier and outline of the experimental programme. Engineering Geology, Vol. 28, Issue. 3-4, p. 443.

Beziat, A. Dardaine, M. and Mouche, E. 1992. Measurements of the thermal conductivity of clay-sand and clay-graphite mixtures used as engineered barriers for high-level radioactive waste disposal. Applied Clay Science, Vol. 6, Issue. 4, p. 245.

Ledru, Patrick and Guillou Frottier, Laurent 2010. Geothermal Energy Systems. p. 1.

Jorand, Rachel Fehr, Annick Koch, Andreas and Clauser, Christoph 2011. Study of the variation of thermal conductivity with water saturation using nuclear magnetic resonance. Journal of Geophysical Research, Vol. 116, Issue. B8,

Caridad, Victoria Ortiz de Zárate, José M. Khayet, Mohamed and Legido, José L. 2014. Thermal conductivity and density of clay pastes at various water contents for pelotherapy use. Applied Clay Science, Vol. 93-94, Issue. , p. 23.

Jorand, Rachel Clauser, Christoph Marquart, Gabriele and Pechnig, Renate 2015. Statistically reliable petrophysical properties of potential reservoir rocks for geothermal energy use and their relation to lithostratigraphy and rock composition: The NE Rhenish Massif and the Lower Rhine Embayment (Germany). Geothermics, Vol. 53, Issue. , p. 413.

Ballarini, E. Graupner, B. and Bauer, S. 2017. Thermal–hydraulic–mechanical behavior of bentonite and sand-bentonite materials as seal for a nuclear waste repository: Numerical simulation of column experiments. Applied Clay Science, Vol. 135, Issue. , p. 289.

Abootalebi, Pedram and Siemens, Greg 2018. Thermal properties of engineered barriers for a Canadian deep geological repository. Canadian Geotechnical Journal, Vol. 55, Issue. 6, p. 759.

Siddiqua, Sumi Tabiatnejad, Bardia and Siemens, Greg 2018. Impact of pore fluid chemistry on the thermal conductivity of bentonite–sand mixture. Environmental Earth Sciences, Vol. 77, Issue. 1,

Zhang, Hairong Zhang, Liquan Li, Qinglin Huang, Chao Guo, Haijun Xiong, Lian and Chen, Xinde 2019. Preparation and characterization of methyl palmitate/palygorskite composite phase change material for thermal energy storage in buildings. Construction and Building Materials, Vol. 226, Issue. , p. 212.

Lee, Jae Owan Choi, Heui-Joo Kim, Geon Young and Cho, Dong-Keun 2019. Numerical analysis of the effect of gap-filling options on the maximum peak temperature of a buffer in an HLW repository. Progress in Nuclear Energy, Vol. 111, Issue. , p. 138.

Xu, Yunshan Sun, De'an Zeng, Zhaotian and Lv, Haibo 2019. Temperature dependence of apparent thermal conductivity of compacted bentonites as buffer material for high-level radioactive waste repository. Applied Clay Science, Vol. 174, Issue. , p. 10.

Nocko, Leticia M. Botelho, Keaton Morris, Jeremy W. F. Gupta, Ranjiv and McCartney, John S. 2020. Thermal Conductivity of Municipal Solid Waste from In Situ Heat Extraction Tests. Journal of Geotechnical and Geoenvironmental Engineering, Vol. 146, Issue. 9,

Yoon, Seok Park, Seunghun Kim, Min-Seop Kim, Geon-Young and Lee, Seung-Rae 2020. Thermal Conductivity Evaluation of Compacted Bentonite Buffers Considering Temperature Variations. Journal of Nuclear Fuel Cycle and Waste Technology(JNFCWT), Vol. 18, Issue. 1, p. 43.

Bhatt, Bhaskar Kalel, Navnath Abdel-Latif, May and Bijwe, Jayashree 2020. Influence of Increasing Amount of Attapulgite on the Performance Properties of Cu-Free Brake-Pads. Vol. 1, Issue. ,

Dalla Santa, Giorgia Galgaro, Antonio Sassi, Raffaele Cultrera, Matteo Scotton, Paolo Mueller, Johannes Bertermann, David Mendrinos, Dimitrios Pasquali, Riccardo Perego, Rodolfo Pera, Sebastian Di Sipio, Eloisa Cassiani, Giorgio De Carli, Michele and Bernardi, Adriana 2020. An updated ground thermal properties database for GSHP applications. Geothermics, Vol. 85, Issue. , p. 101758.

Roshankhah, Shahrzad Garcia, Adrian V. and Carlos Santamarina, J. 2021. Thermal Conductivity of Sand–Silt Mixtures. Journal of Geotechnical and Geoenvironmental Engineering, Vol. 147, Issue. 2,

Liu, Lanmin He, Hailong Dyck, Miles and Lv, Jialong 2021. Modeling thermal conductivity of clays: A review and evaluation of 28 predictive models. Engineering Geology, Vol. 288, Issue. , p. 106107.

Damasceno, Flávio A. Taraba, Joseph L. Day, George B. Black, Randi A. Bewley, Jeffrey M. Fernandes, Tales J. Oliveira, Carlos E. A. Andrade, Rafaella R. Barbari, Matteo Ferraz, Patrícia F. P. and Leso, Lorenzo 2021. Development of Predictive Equations for Thermal Conductivity of Compost Bedding. Applied Sciences, Vol. 11, Issue. 18, p. 8503.

Lee, Eun Young Tejada, Maria Luisa G. Song, Insun Chun, Seung Soo Gier, Susanne Riquier, Laurent White, Lloyd T. Schnetger, Bernhard Brumsack, Hans‐Jürgen Jones, Matthew M. and Martinez, Mathieu 2021. Petrophysical Property Modifications by Alteration in a Volcanic Sequence at IODP Site U1513, Naturaliste Plateau. Journal of Geophysical Research: Solid Earth, Vol. 126, Issue. 10,

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Article contents

Effect of Compaction Pressure and Water Content on the Thermal Conductivity of Some Natural Clays

Abstract

Résumé

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References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Effect of Compaction Pressure and Water Content on the Thermal Conductivity of Some Natural Clays

Abstract

Résumé

Keywords

References

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