Analysis of conduction mode in cold energy storage using a tank filled with nanomaterial

Mashhour A. Alazwari; Ali Basem; Hussein A.Z. Al-bonsrulah; Khalid H. Almitani; Nidal H. Abu-Hamdeh; Mahmood Shaker Albdeiri; Galal A.Ahmed Alashaari

doi:10.1016/j.csite.2024.105134

Analysis of conduction mode in cold energy storage using a tank filled with nanomaterial

Mashhour A. Alazwari, Ali Basem, Hussein A.Z. Al-bonsrulah, Khalid H. Almitani, Nidal H. Abu-Hamdeh, Mahmood Shaker Albdeiri, Galal A.Ahmed Alashaari

Mathematics

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

1 Scopus citations

Abstract

The intensification of freezing rates through the incorporation of nano-sized powders and fins through a cold storage unit was examined. The Galerkin method with special meshing was utilized to solve equations, which were based on the supposition of conduction mode dominance. Additives of varying diameters (dp) and three different concentration levels (ϕ) were implemented. The findings are presented through ice front visualization, contour plots, and scalar curves. The computational code demonstrated high accuracy during the validation phase. The results reveal that as the dp increases, the solidification time initially drops by approximately 20 %, then subsequently increases by about 49.45 %. The optimal solidification time of 2951.17 s was achieved with medium-sized powders. Furthermore, an intensification in (ϕ) leads to a significant decrement in freezing time by about 41.43 %, with the most pronounced effect observed for nano-powders with dp = 40 nm.

Original language	English
Article number	105134
Journal	Case Studies in Thermal Engineering
Volume	62
DOIs	https://doi.org/10.1016/j.csite.2024.105134
State	Published - Oct 2024

Keywords

Freezing process
Galerkin method
Mesh adaption
NEPCM
Unsteady phenomena

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10.1016/j.csite.2024.105134

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@article{b584f318761e40a1a15aa7aed92a09a6,

title = "Analysis of conduction mode in cold energy storage using a tank filled with nanomaterial",

abstract = "The intensification of freezing rates through the incorporation of nano-sized powders and fins through a cold storage unit was examined. The Galerkin method with special meshing was utilized to solve equations, which were based on the supposition of conduction mode dominance. Additives of varying diameters (dp) and three different concentration levels (ϕ) were implemented. The findings are presented through ice front visualization, contour plots, and scalar curves. The computational code demonstrated high accuracy during the validation phase. The results reveal that as the dp increases, the solidification time initially drops by approximately 20 \%, then subsequently increases by about 49.45 \%. The optimal solidification time of 2951.17 s was achieved with medium-sized powders. Furthermore, an intensification in (ϕ) leads to a significant decrement in freezing time by about 41.43 \%, with the most pronounced effect observed for nano-powders with dp = 40 nm.",

keywords = "Freezing process, Galerkin method, Mesh adaption, NEPCM, Unsteady phenomena",

author = "Alazwari, \{Mashhour A.\} and Ali Basem and Al-bonsrulah, \{Hussein A.Z.\} and Almitani, \{Khalid H.\} and Abu-Hamdeh, \{Nidal H.\} and Albdeiri, \{Mahmood Shaker\} and Alashaari, \{Galal A.Ahmed\}",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors",

year = "2024",

month = oct,

doi = "10.1016/j.csite.2024.105134",

language = "English",

volume = "62",

journal = "Case Studies in Thermal Engineering",

issn = "2214-157X",

publisher = "Elsevier Ltd",

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TY - JOUR

T1 - Analysis of conduction mode in cold energy storage using a tank filled with nanomaterial

AU - Alazwari, Mashhour A.

AU - Basem, Ali

AU - Al-bonsrulah, Hussein A.Z.

AU - Almitani, Khalid H.

AU - Abu-Hamdeh, Nidal H.

AU - Albdeiri, Mahmood Shaker

AU - Alashaari, Galal A.Ahmed

PY - 2024/10

Y1 - 2024/10

N2 - The intensification of freezing rates through the incorporation of nano-sized powders and fins through a cold storage unit was examined. The Galerkin method with special meshing was utilized to solve equations, which were based on the supposition of conduction mode dominance. Additives of varying diameters (dp) and three different concentration levels (ϕ) were implemented. The findings are presented through ice front visualization, contour plots, and scalar curves. The computational code demonstrated high accuracy during the validation phase. The results reveal that as the dp increases, the solidification time initially drops by approximately 20 %, then subsequently increases by about 49.45 %. The optimal solidification time of 2951.17 s was achieved with medium-sized powders. Furthermore, an intensification in (ϕ) leads to a significant decrement in freezing time by about 41.43 %, with the most pronounced effect observed for nano-powders with dp = 40 nm.

AB - The intensification of freezing rates through the incorporation of nano-sized powders and fins through a cold storage unit was examined. The Galerkin method with special meshing was utilized to solve equations, which were based on the supposition of conduction mode dominance. Additives of varying diameters (dp) and three different concentration levels (ϕ) were implemented. The findings are presented through ice front visualization, contour plots, and scalar curves. The computational code demonstrated high accuracy during the validation phase. The results reveal that as the dp increases, the solidification time initially drops by approximately 20 %, then subsequently increases by about 49.45 %. The optimal solidification time of 2951.17 s was achieved with medium-sized powders. Furthermore, an intensification in (ϕ) leads to a significant decrement in freezing time by about 41.43 %, with the most pronounced effect observed for nano-powders with dp = 40 nm.

KW - Freezing process

KW - Galerkin method

KW - Mesh adaption

KW - NEPCM

KW - Unsteady phenomena

UR - https://www.scopus.com/pages/publications/85204737565

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DO - 10.1016/j.csite.2024.105134

M3 - Article

AN - SCOPUS:85204737565

SN - 2214-157X

VL - 62

JO - Case Studies in Thermal Engineering

JF - Case Studies in Thermal Engineering

M1 - 105134

ER -

Analysis of conduction mode in cold energy storage using a tank filled with nanomaterial

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Keywords

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