Effects of Convection and Fracture Boundary Conditions on Heat Transfer Shape Factor in Fractured Geothermal Reservoirs

Advection–conduction equation (ACE) used to explain the combined conduction and convection mechanisms of heat transfer thorough porous media has received considerable attention with a wide range of applications in various disciplines. The present study concentrates on developing a generalized analyt...

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Published inTransport in porous media Vol. 125; no. 2; pp. 357 - 375
Main Authors Abbasi, Mahdi, Madani, Mohammad, Keshavarz Moraveji, Mostafa, Sharifi, Mohammad
Format Journal Article
LanguageEnglish
Published Dordrecht Springer Netherlands 01.11.2018
Springer Nature B.V
Subjects
Boundary conditions
Civil Engineering
Classical and Continuum Physics
Conduction heating
Dependent variables
Dimensionless numbers
Earth and Environmental Science
Earth Sciences
Exact solutions
Finite difference method
Finite element method
Fourier series
Geotechnical Engineering & Applied Earth Sciences
Heat transfer
Hydrogeology
Hydrology/Water Resources
Industrial Chemistry/Chemical Engineering
Matrix methods
Peclet number
Porous media
Shape factor
Time dependence
Heat transfer shape factor
Peclet number
Advection–conduction equation
Analytical solution
Online AccessGet full text
ISSN0169-3913
1573-1634
DOI10.1007/s11242-018-1122-2

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Abstract Advection–conduction equation (ACE) used to explain the combined conduction and convection mechanisms of heat transfer thorough porous media has received considerable attention with a wide range of applications in various disciplines. The present study concentrates on developing a generalized analytical solution to ACE through incorporation of Fourier series and a new dependent variable for the problem of heat transfer through porous media in one-dimensional finite spatial region assuming transient boundary conditions. Then, assuming that a fracture acts as the time-dependent boundary condition, an analytical solution is obtained for a typical fractured porous medium. Based on the analytical solution, heat transfer shape factor is also obtained, on which the effects of governing parameters of matrix block such as Peclet number are investigated throughout transient and pseudo-steady-state (PSS) periods for the first time. Moreover, a correlation is generated to estimate the PSS heat transfer shape factor in terms of dimensionless time and Peclet number for constant concentration and linearly ascending temperature boundary conditions. Additionally, the numerical finite difference and finite element methods were utilized to validate the analytical solution results. The results demonstrated that the obtained generalized analytical solution can be regarded as a reliably excellent and accurate mathematical lever to describe the heat transfer phenomenon through porous media subject to determine transient boundary conditions and also to verify numerical results.
AbstractList Advection–conduction equation (ACE) used to explain the combined conduction and convection mechanisms of heat transfer thorough porous media has received considerable attention with a wide range of applications in various disciplines. The present study concentrates on developing a generalized analytical solution to ACE through incorporation of Fourier series and a new dependent variable for the problem of heat transfer through porous media in one-dimensional finite spatial region assuming transient boundary conditions. Then, assuming that a fracture acts as the time-dependent boundary condition, an analytical solution is obtained for a typical fractured porous medium. Based on the analytical solution, heat transfer shape factor is also obtained, on which the effects of governing parameters of matrix block such as Peclet number are investigated throughout transient and pseudo-steady-state (PSS) periods for the first time. Moreover, a correlation is generated to estimate the PSS heat transfer shape factor in terms of dimensionless time and Peclet number for constant concentration and linearly ascending temperature boundary conditions. Additionally, the numerical finite difference and finite element methods were utilized to validate the analytical solution results. The results demonstrated that the obtained generalized analytical solution can be regarded as a reliably excellent and accurate mathematical lever to describe the heat transfer phenomenon through porous media subject to determine transient boundary conditions and also to verify numerical results.
Author Abbasi, Mahdi
Sharifi, Mohammad
Madani, Mohammad
Keshavarz Moraveji, Mostafa
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  givenname: Mohammad
  surname: Madani
  fullname: Madani, Mohammad
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  givenname: Mostafa
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  surname: Keshavarz Moraveji
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  givenname: Mohammad
  surname: Sharifi
  fullname: Sharifi, Mohammad
  organization: Department of Petroleum Engineering, Amirkabir University of Technology (Polytechnic of Tehran)
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CitedBy_id crossref_primary_10_1016_j_gsd_2021_100691
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Copyright Springer Science & Business Media 2018
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Keywords Heat transfer shape factor
Peclet number
Advection–conduction equation
Analytical solution
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Snippet Advection–conduction equation (ACE) used to explain the combined conduction and convection mechanisms of heat transfer thorough porous media has received...
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StartPage 357
SubjectTerms Boundary conditions
Civil Engineering
Classical and Continuum Physics
Conduction heating
Dependent variables
Dimensionless numbers
Earth and Environmental Science
Earth Sciences
Exact solutions
Finite difference method
Finite element method
Fourier series
Geotechnical Engineering & Applied Earth Sciences
Heat transfer
Hydrogeology
Hydrology/Water Resources
Industrial Chemistry/Chemical Engineering
Matrix methods
Peclet number
Porous media
Shape factor
Time dependence
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Title Effects of Convection and Fracture Boundary Conditions on Heat Transfer Shape Factor in Fractured Geothermal Reservoirs
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