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Effect of Temperature on the Compressibility Behavior of Glass Fiber-bentonite Mixture

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Publicado en:Periodica Polytechnica. Civil Engineering vol. 69, no. 3 (2025), p. 915-925
Autor principal: Batuge, Yusuf
Otros Autores: Alpaydin, Sukran Gizem, Yukselen-Aksoy, Yeliz
Publicado:
Periodica Polytechnica, Budapest University of Technology and Economics
Materias:
High temperature
Soil mechanics
Soil temperature
Swelling
Energy sources
Compressibility
Montmorillonite
Hydraulic conductivity
Laboratory experimentation
Radioactive wastes
Curing
Bentonite
Clean energy
Mixtures
Cables
Soil investigations
Piles
Energy resources
Heat resistance
Deformation
Underground cables
Room temperature
Mechanical properties
Resistance to chemicals
Deformation effects
Soil improvement
Curing (processing)
Glass fibers
Glass fibres
Montmorillonites
Temperature effects
Compression
High temperature effects
Environmental
Acceso en línea:Citation/Abstract
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Resumen:In line with the global need for energy, various renewable and clean energy sources have become increasingly popular. Heat piles, buried high-voltage cables, and high-level nuclear waste (HLW) storage areas are examples of energy structures. Since these energy structures emit high temperatures and increase the temperature of the surrounding soil, investigating and improving the thermo-hydro-mechanical behavior of soils under high temperatures has become essential. Bentonite is a clay with high montmorillonite content, which is preferred as a buffer material due to its high swelling capacity, low hydraulic conductivity and chemical resistance.In the present study, a series of laboratory experiments were conducted to investigate the volumetric deformation behavior of bentonite at 80 °C. Tests were performed on the samples kept at 80 °C to observe the effect of high temperature on the volumetric deformation of bentonite in short and long (6 months and 1 year) terms. Glass fiber (GF) was added to bentonite due to its favorable engineering properties at high temperatures. The results have shown that high temperature increased the compressibility of bentonite mixtures while decreasing swelling deformation. The compressibility of the mixtures after curing decreased. Compared to room temperature (RT), the compression strain increased by 22.8% at 80 °C. With 6-months curing at 80 °C, it further increased by up to 33.2%. However, after 1-year curing, a slight decrease of 4.9% was observed. GF significantly increased the swelling behavior of bentonite at RT. However, this effect decreased at high temperature.
ISSN:0553-6626
1587-3773
DOI:10.3311/PPci.38803
Fuente:Engineering Database