Development of a new design for cold energy storage using finned porous containers filled with nanomaterials

Mashhour A. Alazwari; Ali Basem; Hussein A.Z. AL-bonsrulah; Nidal H. Abu-Hamdeh; Awatif M.A. Elsiddieg; Abdulmalik A. Aljinaidi

doi:10.1016/j.rineng.2025.105829

Development of a new design for cold energy storage using finned porous containers filled with nanomaterials

Mashhour A. Alazwari, Ali Basem, Hussein A.Z. AL-bonsrulah, Nidal H. Abu-Hamdeh, Awatif M.A. Elsiddieg, Abdulmalik A. Aljinaidi

Mathematics

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

Abstract

This study numerically investigates the freezing behavior in a finned container filled with water enhanced by hybrid nanoparticles to boost thermal conductivity. A novel combination of reduced porosity, hybrid nanofluids, and radiation modeling is applied to accelerate solidification. The equations are solved implementing an implicit scheme with adaptive meshing for improved accuracy. Results show that reducing porosity enhances the solid fraction and shortens freezing time by 80.6 %. The addition of hybrid nanoparticles leads to a 6.6 % reduction, while radiation further decreases solidification time by 14.23 %. These findings demonstrate the synergistic potential of combining thermal enhancement techniques for efficient cold energy storage.

Original language	English
Article number	105829
Journal	Results in Engineering
Volume	27
DOIs	https://doi.org/10.1016/j.rineng.2025.105829
State	Published - Sep 2025

Keywords

Cold storage
Metal foam
Nanoparticles
Solidification
Unsteady simulation

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10.1016/j.rineng.2025.105829

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title = "Development of a new design for cold energy storage using finned porous containers filled with nanomaterials",

abstract = "This study numerically investigates the freezing behavior in a finned container filled with water enhanced by hybrid nanoparticles to boost thermal conductivity. A novel combination of reduced porosity, hybrid nanofluids, and radiation modeling is applied to accelerate solidification. The equations are solved implementing an implicit scheme with adaptive meshing for improved accuracy. Results show that reducing porosity enhances the solid fraction and shortens freezing time by 80.6 \%. The addition of hybrid nanoparticles leads to a 6.6 \% reduction, while radiation further decreases solidification time by 14.23 \%. These findings demonstrate the synergistic potential of combining thermal enhancement techniques for efficient cold energy storage.",

keywords = "Cold storage, Metal foam, Nanoparticles, Solidification, Unsteady simulation",

author = "Alazwari, \{Mashhour A.\} and Ali Basem and AL-bonsrulah, \{Hussein A.Z.\} and Abu-Hamdeh, \{Nidal H.\} and Elsiddieg, \{Awatif M.A.\} and Aljinaidi, \{Abdulmalik A.\}",

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year = "2025",

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doi = "10.1016/j.rineng.2025.105829",

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AU - Alazwari, Mashhour A.

AU - Basem, Ali

AU - AL-bonsrulah, Hussein A.Z.

AU - Abu-Hamdeh, Nidal H.

AU - Elsiddieg, Awatif M.A.

AU - Aljinaidi, Abdulmalik A.

PY - 2025/9

Y1 - 2025/9

N2 - This study numerically investigates the freezing behavior in a finned container filled with water enhanced by hybrid nanoparticles to boost thermal conductivity. A novel combination of reduced porosity, hybrid nanofluids, and radiation modeling is applied to accelerate solidification. The equations are solved implementing an implicit scheme with adaptive meshing for improved accuracy. Results show that reducing porosity enhances the solid fraction and shortens freezing time by 80.6 %. The addition of hybrid nanoparticles leads to a 6.6 % reduction, while radiation further decreases solidification time by 14.23 %. These findings demonstrate the synergistic potential of combining thermal enhancement techniques for efficient cold energy storage.

AB - This study numerically investigates the freezing behavior in a finned container filled with water enhanced by hybrid nanoparticles to boost thermal conductivity. A novel combination of reduced porosity, hybrid nanofluids, and radiation modeling is applied to accelerate solidification. The equations are solved implementing an implicit scheme with adaptive meshing for improved accuracy. Results show that reducing porosity enhances the solid fraction and shortens freezing time by 80.6 %. The addition of hybrid nanoparticles leads to a 6.6 % reduction, while radiation further decreases solidification time by 14.23 %. These findings demonstrate the synergistic potential of combining thermal enhancement techniques for efficient cold energy storage.

KW - Cold storage

KW - Metal foam

KW - Nanoparticles

KW - Solidification

KW - Unsteady simulation

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VL - 27

JO - Results in Engineering

JF - Results in Engineering

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Development of a new design for cold energy storage using finned porous containers filled with nanomaterials

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Keywords

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