Finite Element Simulation of Thermo-Mechanical Model with Phase Change

Vasilyeva, Maria; Ammosov, Dmitry; Васильев, В. И.

doi:10.3390/computation9010005

Cited by 8 publications

(1 citation statement)

References 37 publications

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“…Various soils have similar dependence of thermal conductivity on bulk density. According to [30], it is expressed by the following equation: The common formulae for the thermal conductivity for a composite material [19,43] for wet soil with mineral and organic solid particles, liquid, and gaseous phases will take a form:…”

Section: Thermal Conductivitymentioning

confidence: 99%

On a question of non-constant thermal diffusivity of soils

Glagolev

Dyukarev

Terentieva

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

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The general heat conductivity equation includes time- and depth-dependent soil properties (soil heat capacity and thermal conductivity). The simplified form of the heat conductivity equation contains only the soil thermal diffusivity parameter. Numerical solutions of the general and simplified equations were compared to quantify the possibility of equation reduction. Two test runs for soils with different compositions were done. The thermal regime for both peat soil and dark chestnut soil does not change significantly after using a simplified heat equation according to model estimations. The maximal soil temperature discrepancy was about 0.5 °C for peat soil and 2.2-3.3 °C for dark chestnut soil, which results in 4-6% error in methane efflux estimations.

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Section: Thermal Conductivitymentioning

confidence: 99%

On a question of non-constant thermal diffusivity of soils

Glagolev

Dyukarev

Terentieva

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

View full text Add to dashboard Cite

show abstract

Modeling and analysis of ice condensation on bridge deck pavement surface based on heat transfer theory and finite element method

Chen,

Wu,

Wang

et al. 2024

Applied Thermal Engineering

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Effect of Freeze Pipe Eccentricity in Selective Artificial Ground Freezing Applications

Zueter

Madiseh

Hassani

et al. 2021

Journal of Thermal Science and Engineering Applications

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Building concentric tubes is one of biggest practical challenges in the construction of freeze-pipes of selective artificial ground freezing (S-AGF) applications for underground mines. In this study, the influence of tubes eccentricity on phase-front expansion (i.e., expansion of the frozen body) and energy consumption of S-AGF systems is analyzed. A 1+1D semi-conjugate model that solves two-phase transient energy conservation equation is derived based on the enthalpy method. The 1+1D model is firstly validated against experimental data and then verified with a fully-conjugate model from our previous work. After that, the 1+1D model is extended to a field-scale of typical underground mines to examine the effect of freeze-pipe eccentricity. The results show that concentric freeze-pipes form the desired frozen ground volume 15% faster than eccentric freeze-pipes. Also, the geometrical profile of the phase-transition-front of the frozen ground is found to be significantly influenced by the freeze-pipe eccentricity. Furthermore, in the passive zone, where S-AGF coolants are isolated from the ground to reduce energy consumption, freeze pipe eccentricity can increase the coolant heat gain by 20%. This percentage can increase up to 200 % if radiation heat transfer is minimized.

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Finite Element Simulation of Thermo-Mechanical Model with Phase Change

Cited by 8 publications

References 37 publications

On a question of non-constant thermal diffusivity of soils

On a question of non-constant thermal diffusivity of soils

Modeling and analysis of ice condensation on bridge deck pavement surface based on heat transfer theory and finite element method

Effect of Freeze Pipe Eccentricity in Selective Artificial Ground Freezing Applications

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