Schemes for solving filtration problem of a heat-conducting two-phase liquid in a porous medium Текст научной статьи по специальности «Физика»

References

1. Ivanov M.I., Kremer I.A., Laevsky Yu.M. A computational model of fluid filtration in fractured porous media //

Siberian J. Num. Math. 2021. V. 24, N. 2. P. 145-166.

2. Ivanov, M.I., Kremer, I.A., Urev, M.V. Solving the Pure Neumann Problem by a Finite Element Method // Numer.

Analys. Appl. 2019. V. 12, N. 4. P. 359�371. https://doi.org/10.1134/S1995423919040049.

Schemes for solving filtration problem of a heat-conducting two-phase liquid in a porous medium

M. I. Ivanov1, I. A. Kremer1,2, Yu. M. Laevsky1,2

1Institute of Computational Mathematics and Mathematical Geophysics SB RAS

2Novosibirsk State University

Email:ivanov@sscc.ru, kremer@sscc.ru, laev@labchem.sscc.ru

DOI 10.24412/cl-35065-2021-1-00-22

This work is a continuation of the study of the problem of the motion of a two-phase liquid in a porous

medium [1]. In addition, the dependence of the oil viscosity on the temperature is determined, and the energy

equation is included in the system of equations. In the framework of the single-temperature model, the energy

equation is reduced to the heat equation, which describes the conductive mechanism of heat propagation in a

in a porous structure and in a heat-conducting liquid, as well as the convective heat transfer by the filtration

flow. The heat equation is written in a mixed generalized formulation. By analogy with the IMPES scheme, the

convective term is considered on the explicit time layer, and the integration of the conductive term is carried

out using the implicit scheme. This approach to the numerical solution of the heat equation allows to save the

value of the integration step and reuse previously developed codes for filtration problems. The representation

of phase velocities in the form of components co-directed with the total flow, and oppositely directed compo-

nents [2] provides a strict balance of heat in the grid elements. The properties of the proposed algorithm are

discussed on the examples of numerical solutions of model problems.

This work was supported by the RSF (grant 19-11-00048).

References

1. Ivanov M. I., Kremer I. A., Laevsky Yu. M. On the streamline upwind scheme of solution to the filtration problem //

Siberian Electronic Mathematical Reports. 2019. V. 16. P. 757-776. DOI:10.33048/semi.2019.16.051.

2. Ivanov M.I., Kremer I.A., Laevsky Yu. M. Numerical model of gravity segregation of two-phase fluid in porous

media based on hybrid upwinding // Russian J. of Numerical Analysis and Mathematical Modelling. 2021. V. 36, N 1.

P. 17-32. DOI: https://doi.org/10.1515/rnam-2021-0002.

Simulation of heat transfer with considering permafrost thawing in 3D media

D. A. Karavaev

Institute of Computational Mathematics and Mathematical Geophysics SB RAS

Email: kda@opg.sscc.ru

DOI 10.24412/cl-35065-2021-1-00-23

An approach to mathematical modeling of heat transfer with permafrost algorithm [1, 2] in 3D based on

the idea of localizing the phase transition area is considered. The paper presents a problem statement for a

non-stationary heat transfer and a description of a numerical method based on a predictor-corrector scheme.

For a better understanding of the proposed splitting method the approximation accuracy was studied taking

into account inhomogeneous right-hand side. The phase changes in the numerical implementation of perma-

frost thawing is considered in the temperature range and requires recalculation of coefficients values of heat