Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid

Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid

Technological advancements in thermal systems demand an innovative heat dissipation technology. Magnetorheological (MR) fluid has a huge potential to solve the problem. However, characterising thermal conductivity of the materials in magnetic fields required tailored instruments. This paper presents...

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Main Authors: Rahim M.S.A., Ismail I., Wahid S.A., Aid S., Aqida S.N.
Format: Article
Language:English
Published: EDP Sciences 2017-01-01
Series:MATEC Web of Conferences
Online Access:http://dx.doi.org/10.1051/matecconf/20179001061
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spelling doaj-fcb5a54c85c94d3395d80d7b53e1ede32021-02-02T03:06:12ZengEDP SciencesMATEC Web of Conferences2261-236X2017-01-01900106110.1051/matecconf/20179001061matecconf_aigev2017_01061Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluidRahim M.S.A.0Ismail I.Wahid S.A.1Aid S.2Aqida S.N.Faculty of Manufacturing Engineering, Universiti Malaysia PahangFaculty of Manufacturing Engineering, Universiti Malaysia PahangFaculty of Manufacturing Engineering, Universiti Malaysia PahangTechnological advancements in thermal systems demand an innovative heat dissipation technology. Magnetorheological (MR) fluid has a huge potential to solve the problem. However, characterising thermal conductivity of the materials in magnetic fields required tailored instruments. This paper presents a concept design of the MR fluids thermal conductivity measurement instrument. The developed instrument was designed to be able to measure thermal conductivity in both parallel and perpendicular orientations with magnetic field. Magnetic fields distribution of the proposed concept design was analysed using finite element method for magnetics. Design modification then conducted to improve the magnetic fields strength. Findings of this study showed that gap thickness played a significant factor in determining the optimal design. Simulated magnetic fields strength at both parallel and perpendicular orientations were found identical, yet varied in distributions.http://dx.doi.org/10.1051/matecconf/20179001061
collection DOAJ
language English
format Article
sources DOAJ
author Rahim M.S.A.
Ismail I.
Wahid S.A.
Aid S.
Aqida S.N.
spellingShingle Rahim M.S.A.
Ismail I.
Wahid S.A.
Aid S.
Aqida S.N.
Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
MATEC Web of Conferences
author_facet Rahim M.S.A.
Ismail I.
Wahid S.A.
Aid S.
Aqida S.N.
author_sort Rahim M.S.A.
title Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
title_short Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
title_full Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
title_fullStr Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
title_full_unstemmed Magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
title_sort magnetic field simulation of a thermal conductivity measurement instrument for magnetorheological fluid
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2017-01-01
description Technological advancements in thermal systems demand an innovative heat dissipation technology. Magnetorheological (MR) fluid has a huge potential to solve the problem. However, characterising thermal conductivity of the materials in magnetic fields required tailored instruments. This paper presents a concept design of the MR fluids thermal conductivity measurement instrument. The developed instrument was designed to be able to measure thermal conductivity in both parallel and perpendicular orientations with magnetic field. Magnetic fields distribution of the proposed concept design was analysed using finite element method for magnetics. Design modification then conducted to improve the magnetic fields strength. Findings of this study showed that gap thickness played a significant factor in determining the optimal design. Simulated magnetic fields strength at both parallel and perpendicular orientations were found identical, yet varied in distributions.
url http://dx.doi.org/10.1051/matecconf/20179001061
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AT ismaili magneticfieldsimulationofathermalconductivitymeasurementinstrumentformagnetorheologicalfluid
AT wahidsa magneticfieldsimulationofathermalconductivitymeasurementinstrumentformagnetorheologicalfluid
AT aids magneticfieldsimulationofathermalconductivitymeasurementinstrumentformagnetorheologicalfluid
AT aqidasn magneticfieldsimulationofathermalconductivitymeasurementinstrumentformagnetorheologicalfluid
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