Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys

Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys

Evaluation of thermal conductivity of composite materials is extremely important to control material performance and stability in thermal applications as well as to study transport phenomena. In this paper, numerical simulation of effective thermal conductivity of Al-Sn miscibility gap alloys is val...

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Main Authors: Ziwei Li, Chiara Confalonieri, Elisabetta Gariboldi
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Metals
Subjects:
thermal conductivity
composite materials
Lattice Monte-Carlo
laser flash analysis
Al-Sn
Online Access:https://www.mdpi.com/2075-4701/11/4/650
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spelling doaj-271240df160a43f4b26dc828cf2cd2de2021-04-16T23:01:21ZengMDPI AGMetals2075-47012021-04-011165065010.3390/met11040650Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn AlloysZiwei Li0Chiara Confalonieri1Elisabetta Gariboldi2Department of Mechanical Engineering, Politecnico di Milano, Via La Masa 1, 20156 Milan, ItalyDepartment of Mechanical Engineering, Politecnico di Milano, Via La Masa 1, 20156 Milan, ItalyDepartment of Mechanical Engineering, Politecnico di Milano, Via La Masa 1, 20156 Milan, ItalyEvaluation of thermal conductivity of composite materials is extremely important to control material performance and stability in thermal applications as well as to study transport phenomena. In this paper, numerical simulation of effective thermal conductivity of Al-Sn miscibility gap alloys is validated with experimental results. Lattice Monte-Carlo (LMC) method is applied to two-phase and three-phase materials, allowing to estimate effective thermal conductivity from micrographs and individual phase properties. Numerical results are compared with literature data for cast Al-Sn alloys for the two-phase model and with a specifically produced powder metallurgy Al-10vol%Sn, tested using laser flash analysis, for a three-phase simulation. A good agreement between numerical and experimental data was observed. Moreover, LMC simulations confirmed the effect of phase morphology as well as actual phase composition on thermal conductivity of composite materials.https://www.mdpi.com/2075-4701/11/4/650thermal conductivitycomposite materialsLattice Monte-Carlolaser flash analysisAl-Sn
collection DOAJ
language English
format Article
sources DOAJ
author Ziwei Li
Chiara Confalonieri
Elisabetta Gariboldi
spellingShingle Ziwei Li
Chiara Confalonieri
Elisabetta Gariboldi
Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys
Metals
thermal conductivity
composite materials
Lattice Monte-Carlo
laser flash analysis
Al-Sn
author_facet Ziwei Li
Chiara Confalonieri
Elisabetta Gariboldi
author_sort Ziwei Li
title Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys
title_short Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys
title_full Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys
title_fullStr Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys
title_full_unstemmed Numerical and Experimental Evaluation of Thermal Conductivity: An Application to Al-Sn Alloys
title_sort numerical and experimental evaluation of thermal conductivity: an application to al-sn alloys
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2021-04-01
description Evaluation of thermal conductivity of composite materials is extremely important to control material performance and stability in thermal applications as well as to study transport phenomena. In this paper, numerical simulation of effective thermal conductivity of Al-Sn miscibility gap alloys is validated with experimental results. Lattice Monte-Carlo (LMC) method is applied to two-phase and three-phase materials, allowing to estimate effective thermal conductivity from micrographs and individual phase properties. Numerical results are compared with literature data for cast Al-Sn alloys for the two-phase model and with a specifically produced powder metallurgy Al-10vol%Sn, tested using laser flash analysis, for a three-phase simulation. A good agreement between numerical and experimental data was observed. Moreover, LMC simulations confirmed the effect of phase morphology as well as actual phase composition on thermal conductivity of composite materials.
topic thermal conductivity
composite materials
Lattice Monte-Carlo
laser flash analysis
Al-Sn
url https://www.mdpi.com/2075-4701/11/4/650
work_keys_str_mv AT ziweili numericalandexperimentalevaluationofthermalconductivityanapplicationtoalsnalloys
AT chiaraconfalonieri numericalandexperimentalevaluationofthermalconductivityanapplicationtoalsnalloys
AT elisabettagariboldi numericalandexperimentalevaluationofthermalconductivityanapplicationtoalsnalloys
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