Numerical modeling for thermal behavior of nanomaterial laminar flow and convective heat transfer in appearance of magnetic field

Wenhao Cao; Sami H. Altoum; Hakeem A. Othman; Alia M. Alzubaidi; Abed Saif Alghawli

doi:10.1016/j.csite.2023.102727

Numerical modeling for thermal behavior of nanomaterial laminar flow and convective heat transfer in appearance of magnetic field

Wenhao Cao
, Sami H. Altoum
, Hakeem A. Othman
, Alia M. Alzubaidi
, Abed Saif Alghawli

Computer Sciences

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

10 Scopus citations

Abstract

The new computational approach has been incorporated for modeling the nanofluid flow through a cavity involving a wavy inner wall which experiences uniform flux. The fluid was created by loading alumina powders with various shapes within the water. The stream function formulation was applied after employing Darcy law and final equations have been generated. The container is under the impact of Lorentz force in addition to buoyancy forces. With loading additives, Nu enhances about 17.07% and 41.57% depending on the amount of Ha. The greater value of Ha makes the effect of adding nanoparticles become more sensible. With increasing the value of shape factor, Nu increases about 11.76%. As Ha grows, the rate of cooling decreases about 41.31%. With augment of Ra, Nu enhances about 50.41% in absence of Ha.

Original language	English
Article number	102727
Journal	Case Studies in Thermal Engineering
Volume	42
DOIs	https://doi.org/10.1016/j.csite.2023.102727
State	Published - Feb 2023

Keywords

Free convection
Nanomaterial
Numerical modeling
Porous Darcy law
Stream function

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10.1016/j.csite.2023.102727

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@article{2789301a77744c05801ddf77af7e8d94,

title = "Numerical modeling for thermal behavior of nanomaterial laminar flow and convective heat transfer in appearance of magnetic field",

abstract = "The new computational approach has been incorporated for modeling the nanofluid flow through a cavity involving a wavy inner wall which experiences uniform flux. The fluid was created by loading alumina powders with various shapes within the water. The stream function formulation was applied after employing Darcy law and final equations have been generated. The container is under the impact of Lorentz force in addition to buoyancy forces. With loading additives, Nu enhances about 17.07\% and 41.57\% depending on the amount of Ha. The greater value of Ha makes the effect of adding nanoparticles become more sensible. With increasing the value of shape factor, Nu increases about 11.76\%. As Ha grows, the rate of cooling decreases about 41.31\%. With augment of Ra, Nu enhances about 50.41\% in absence of Ha.",

keywords = "Free convection, Nanomaterial, Numerical modeling, Porous Darcy law, Stream function",

author = "Wenhao Cao and Altoum, \{Sami H.\} and Othman, \{Hakeem A.\} and Alzubaidi, \{Alia M.\} and Alghawli, \{Abed Saif\}",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors.",

year = "2023",

month = feb,

doi = "10.1016/j.csite.2023.102727",

language = "English",

volume = "42",

journal = "Case Studies in Thermal Engineering",

issn = "2214-157X",

publisher = "Elsevier Ltd",

}

TY - JOUR

T1 - Numerical modeling for thermal behavior of nanomaterial laminar flow and convective heat transfer in appearance of magnetic field

AU - Cao, Wenhao

AU - Altoum, Sami H.

AU - Othman, Hakeem A.

AU - Alzubaidi, Alia M.

AU - Alghawli, Abed Saif

PY - 2023/2

Y1 - 2023/2

N2 - The new computational approach has been incorporated for modeling the nanofluid flow through a cavity involving a wavy inner wall which experiences uniform flux. The fluid was created by loading alumina powders with various shapes within the water. The stream function formulation was applied after employing Darcy law and final equations have been generated. The container is under the impact of Lorentz force in addition to buoyancy forces. With loading additives, Nu enhances about 17.07% and 41.57% depending on the amount of Ha. The greater value of Ha makes the effect of adding nanoparticles become more sensible. With increasing the value of shape factor, Nu increases about 11.76%. As Ha grows, the rate of cooling decreases about 41.31%. With augment of Ra, Nu enhances about 50.41% in absence of Ha.

AB - The new computational approach has been incorporated for modeling the nanofluid flow through a cavity involving a wavy inner wall which experiences uniform flux. The fluid was created by loading alumina powders with various shapes within the water. The stream function formulation was applied after employing Darcy law and final equations have been generated. The container is under the impact of Lorentz force in addition to buoyancy forces. With loading additives, Nu enhances about 17.07% and 41.57% depending on the amount of Ha. The greater value of Ha makes the effect of adding nanoparticles become more sensible. With increasing the value of shape factor, Nu increases about 11.76%. As Ha grows, the rate of cooling decreases about 41.31%. With augment of Ra, Nu enhances about 50.41% in absence of Ha.

KW - Free convection

KW - Nanomaterial

KW - Numerical modeling

KW - Porous Darcy law

KW - Stream function

UR - https://www.scopus.com/pages/publications/85147095764

U2 - 10.1016/j.csite.2023.102727

DO - 10.1016/j.csite.2023.102727

M3 - Article

AN - SCOPUS:85147095764

SN - 2214-157X

VL - 42

JO - Case Studies in Thermal Engineering

JF - Case Studies in Thermal Engineering

M1 - 102727

ER -

Numerical modeling for thermal behavior of nanomaterial laminar flow and convective heat transfer in appearance of magnetic field

Abstract

Keywords

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