Flow transition for natural convective heat transfer in a porous medium saturated with water near 4°C

M. R. Islam; A. Chakma; K. Nandakumar

doi:10.1002/cjce.5450680507

Flow transition for natural convective heat transfer in a porous medium saturated with water near 4°C

M. R. Islam^*, A. Chakma, K. Nandakumar

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

In this paper, the problem of buoyancy‐induced convection flow in water‐saturated porous media near 4°C is examined using a numerical model. Darcy's law is used to model flow behavior and a single equation convective heat transfer model is used for the energy equation. As the Boussinesq approximation is not valid for this case, a parabolic dependence of density on the temperature is used. Natural convection is generated and sustained by a uniform heat source. Flow behavior is governed by three natural parameters appearing in the model. They are: (i) dynamical parameter, (Formula Presented.) [[[[[k^[2] v^[2]]] (ii) geometric parameter, γ = b/a; and (iii) wall temperature, (Formula Presented.) in relation to the reference temperature at the density extremum. For certain ranges of θ_w (<0) and Gr, interesting density inversion effects are possible. Transient solutions are obtained for various aspect ratios and modified Grashof number values. For a wide range of Grashof number, steady state solutions could not be obtained. Flow mutations into periodic and chaotic solutions are investigated for a range of Grashof number (100 to 40,000) and aspect ratio values (1 to 10).

Original language	English
Pages (from-to)	777-785
Number of pages	9
Journal	Canadian Journal of Chemical Engineering
Volume	68
Issue number	5
DOIs	https://doi.org/10.1002/cjce.5450680507
State	Published - Oct 1990
Externally published	Yes

Keywords

convection
flow transition
natural convection
porous medium
water density inversion

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title = "Flow transition for natural convective heat transfer in a porous medium saturated with water near 4°C",

abstract = "In this paper, the problem of buoyancy‐induced convection flow in water‐saturated porous media near 4°C is examined using a numerical model. Darcy's law is used to model flow behavior and a single equation convective heat transfer model is used for the energy equation. As the Boussinesq approximation is not valid for this case, a parabolic dependence of density on the temperature is used. Natural convection is generated and sustained by a uniform heat source. Flow behavior is governed by three natural parameters appearing in the model. They are: (i) dynamical parameter, (Formula Presented.) [[[[[k^[2] v^[2]]] (ii) geometric parameter, γ = b/a; and (iii) wall temperature, (Formula Presented.) in relation to the reference temperature at the density extremum. For certain ranges of θw (<0) and Gr, interesting density inversion effects are possible. Transient solutions are obtained for various aspect ratios and modified Grashof number values. For a wide range of Grashof number, steady state solutions could not be obtained. Flow mutations into periodic and chaotic solutions are investigated for a range of Grashof number (100 to 40,000) and aspect ratio values (1 to 10).",

keywords = "convection, flow transition, natural convection, porous medium, water density inversion",

author = "Islam, {M. R.} and A. Chakma and K. Nandakumar",

year = "1990",

month = oct,

doi = "10.1002/cjce.5450680507",

language = "英语",

volume = "68",

pages = "777--785",

journal = "Canadian Journal of Chemical Engineering",

issn = "0008-4034",

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TY - JOUR

T1 - Flow transition for natural convective heat transfer in a porous medium saturated with water near 4°C

AU - Islam, M. R.

AU - Chakma, A.

AU - Nandakumar, K.

PY - 1990/10

Y1 - 1990/10

N2 - In this paper, the problem of buoyancy‐induced convection flow in water‐saturated porous media near 4°C is examined using a numerical model. Darcy's law is used to model flow behavior and a single equation convective heat transfer model is used for the energy equation. As the Boussinesq approximation is not valid for this case, a parabolic dependence of density on the temperature is used. Natural convection is generated and sustained by a uniform heat source. Flow behavior is governed by three natural parameters appearing in the model. They are: (i) dynamical parameter, (Formula Presented.) [[[[[k^[2] v^[2]]] (ii) geometric parameter, γ = b/a; and (iii) wall temperature, (Formula Presented.) in relation to the reference temperature at the density extremum. For certain ranges of θw (<0) and Gr, interesting density inversion effects are possible. Transient solutions are obtained for various aspect ratios and modified Grashof number values. For a wide range of Grashof number, steady state solutions could not be obtained. Flow mutations into periodic and chaotic solutions are investigated for a range of Grashof number (100 to 40,000) and aspect ratio values (1 to 10).

AB - In this paper, the problem of buoyancy‐induced convection flow in water‐saturated porous media near 4°C is examined using a numerical model. Darcy's law is used to model flow behavior and a single equation convective heat transfer model is used for the energy equation. As the Boussinesq approximation is not valid for this case, a parabolic dependence of density on the temperature is used. Natural convection is generated and sustained by a uniform heat source. Flow behavior is governed by three natural parameters appearing in the model. They are: (i) dynamical parameter, (Formula Presented.) [[[[[k^[2] v^[2]]] (ii) geometric parameter, γ = b/a; and (iii) wall temperature, (Formula Presented.) in relation to the reference temperature at the density extremum. For certain ranges of θw (<0) and Gr, interesting density inversion effects are possible. Transient solutions are obtained for various aspect ratios and modified Grashof number values. For a wide range of Grashof number, steady state solutions could not be obtained. Flow mutations into periodic and chaotic solutions are investigated for a range of Grashof number (100 to 40,000) and aspect ratio values (1 to 10).

KW - convection

KW - flow transition

KW - natural convection

KW - porous medium

KW - water density inversion

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U2 - 10.1002/cjce.5450680507

DO - 10.1002/cjce.5450680507

M3 - 文章

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SN - 0008-4034

VL - 68

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EP - 785

JO - Canadian Journal of Chemical Engineering

JF - Canadian Journal of Chemical Engineering

IS - 5

ER -

Flow transition for natural convective heat transfer in a porous medium saturated with water near 4°C

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