Solidification of water in a thermal storage unit equipped with nanoparticle

Hasanen M. Hussen; Wissam H. Alawee; Hayder A. Dhahad; Narjes Turki Khalifa; Saad Althobaiti; Amira M. Hussin

doi:10.1016/j.est.2022.105339

Solidification of water in a thermal storage unit equipped with nanoparticle

Hasanen M. Hussen, Wissam H. Alawee, Hayder A. Dhahad, Narjes Turki Khalifa, Saad Althobaiti, Amira M. Hussin

Mathematics

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

4 Scopus citations

Abstract

As a viable approach for accelerating the freezing process, inclined fins were attached to cold surfaces in this study. The enclosure has two adiabatic surface and two cold ones. The domain was filled with liquid water and due to cold surfaces; it starts to change to solid. In such situation where conduction plays the key role, convection is of secondary importance and can be ignored in mathematical model. With this proposition, two equations remain including unsteady terms and finite element method was applied to attain the solution with involvement of adaptive mesh. Moreover, validation respected to earlier numerical work indicated the reasonable accommodation. By altering the shape parameter to greater value the period of freezing declines around 5.4 %. Also, adding greater volume of platelet nanoparticles makes time to decrease a bit higher than 11 %.

Original language	English
Article number	105339
Journal	Journal of Energy Storage
Volume	55
DOIs	https://doi.org/10.1016/j.est.2022.105339
State	Published - 1 Nov 2022

Keywords

Conduction
Freezing
Latent heat
Nano-powders
Shape parameter

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10.1016/j.est.2022.105339

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title = "Solidification of water in a thermal storage unit equipped with nanoparticle",

abstract = "As a viable approach for accelerating the freezing process, inclined fins were attached to cold surfaces in this study. The enclosure has two adiabatic surface and two cold ones. The domain was filled with liquid water and due to cold surfaces; it starts to change to solid. In such situation where conduction plays the key role, convection is of secondary importance and can be ignored in mathematical model. With this proposition, two equations remain including unsteady terms and finite element method was applied to attain the solution with involvement of adaptive mesh. Moreover, validation respected to earlier numerical work indicated the reasonable accommodation. By altering the shape parameter to greater value the period of freezing declines around 5.4 \%. Also, adding greater volume of platelet nanoparticles makes time to decrease a bit higher than 11 \%.",

keywords = "Conduction, Freezing, Latent heat, Nano-powders, Shape parameter",

author = "Hussen, \{Hasanen M.\} and Alawee, \{Wissam H.\} and Dhahad, \{Hayder A.\} and Khalifa, \{Narjes Turki\} and Saad Althobaiti and Hussin, \{Amira M.\}",

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doi = "10.1016/j.est.2022.105339",

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TY - JOUR

T1 - Solidification of water in a thermal storage unit equipped with nanoparticle

AU - Hussen, Hasanen M.

AU - Alawee, Wissam H.

AU - Dhahad, Hayder A.

AU - Khalifa, Narjes Turki

AU - Althobaiti, Saad

AU - Hussin, Amira M.

PY - 2022/11/1

Y1 - 2022/11/1

N2 - As a viable approach for accelerating the freezing process, inclined fins were attached to cold surfaces in this study. The enclosure has two adiabatic surface and two cold ones. The domain was filled with liquid water and due to cold surfaces; it starts to change to solid. In such situation where conduction plays the key role, convection is of secondary importance and can be ignored in mathematical model. With this proposition, two equations remain including unsteady terms and finite element method was applied to attain the solution with involvement of adaptive mesh. Moreover, validation respected to earlier numerical work indicated the reasonable accommodation. By altering the shape parameter to greater value the period of freezing declines around 5.4 %. Also, adding greater volume of platelet nanoparticles makes time to decrease a bit higher than 11 %.

AB - As a viable approach for accelerating the freezing process, inclined fins were attached to cold surfaces in this study. The enclosure has two adiabatic surface and two cold ones. The domain was filled with liquid water and due to cold surfaces; it starts to change to solid. In such situation where conduction plays the key role, convection is of secondary importance and can be ignored in mathematical model. With this proposition, two equations remain including unsteady terms and finite element method was applied to attain the solution with involvement of adaptive mesh. Moreover, validation respected to earlier numerical work indicated the reasonable accommodation. By altering the shape parameter to greater value the period of freezing declines around 5.4 %. Also, adding greater volume of platelet nanoparticles makes time to decrease a bit higher than 11 %.

KW - Conduction

KW - Freezing

KW - Latent heat

KW - Nano-powders

KW - Shape parameter

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DO - 10.1016/j.est.2022.105339

M3 - Article

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SN - 2352-152X

VL - 55

JO - Journal of Energy Storage

JF - Journal of Energy Storage

M1 - 105339

ER -

Solidification of water in a thermal storage unit equipped with nanoparticle

Abstract

Keywords

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