Simulation of unsteady process of converting liquid to solid phase inside a solar storage system utilizing nanoparticles

Mohammed N. Ajour; Nidal H. Abu-Hamdeh; Osama K. Nusier; Hussein A.Z. AL-bonsrulah; Abd Elmotaleb A.M.A. Elamin

doi:10.1016/j.est.2023.108841

Simulation of unsteady process of converting liquid to solid phase inside a solar storage system utilizing nanoparticles

Mohammed N. Ajour
, Nidal H. Abu-Hamdeh
, Osama K. Nusier
, Hussein A.Z. AL-bonsrulah
, Abd Elmotaleb A.M.A. Elamin

Mathematics

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

3 Scopus citations

Abstract

The completion time of discharging has been reduced in current study with installing fins and dispersing additives. The tank has an insulated sinusoidal bottom wall and is filled with water. The conduction mode of water has been improved with dispersing nanoparticles. To calculate the conductivity, the fraction and configurations of powders were considered as variables. The equations for modeling were simplified by considering the assumption of neglecting convection mode. Galerkin modeling incorporating implicit methods has been selected to achieve the modeling. With increasing ϕ form 0.02 to twice amount, the time of freezing declines around 16.9 %. If the tank is filled with water, it takes 300.06 s to reach full solidification. The rate of process enhances about 32.61 % with loading nanoparticles with blade shape of blade.

Original language	English
Article number	108841
Journal	Journal of Energy Storage
Volume	73
DOIs	https://doi.org/10.1016/j.est.2023.108841
State	Published - 1 Dec 2023

Keywords

Conduction equation
Discharging process
Nanomaterial
Thermal storage unit
Unsteady simulation

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10.1016/j.est.2023.108841

Cite this

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title = "Simulation of unsteady process of converting liquid to solid phase inside a solar storage system utilizing nanoparticles",

abstract = "The completion time of discharging has been reduced in current study with installing fins and dispersing additives. The tank has an insulated sinusoidal bottom wall and is filled with water. The conduction mode of water has been improved with dispersing nanoparticles. To calculate the conductivity, the fraction and configurations of powders were considered as variables. The equations for modeling were simplified by considering the assumption of neglecting convection mode. Galerkin modeling incorporating implicit methods has been selected to achieve the modeling. With increasing ϕ form 0.02 to twice amount, the time of freezing declines around 16.9 \%. If the tank is filled with water, it takes 300.06 s to reach full solidification. The rate of process enhances about 32.61 \% with loading nanoparticles with blade shape of blade.",

keywords = "Conduction equation, Discharging process, Nanomaterial, Thermal storage unit, Unsteady simulation",

author = "Ajour, \{Mohammed N.\} and Abu-Hamdeh, \{Nidal H.\} and Nusier, \{Osama K.\} and AL-bonsrulah, \{Hussein A.Z.\} and Elamin, \{Abd Elmotaleb A.M.A.\}",

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doi = "10.1016/j.est.2023.108841",

language = "English",

volume = "73",

journal = "Journal of Energy Storage",

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T1 - Simulation of unsteady process of converting liquid to solid phase inside a solar storage system utilizing nanoparticles

AU - Ajour, Mohammed N.

AU - Abu-Hamdeh, Nidal H.

AU - Nusier, Osama K.

AU - AL-bonsrulah, Hussein A.Z.

AU - Elamin, Abd Elmotaleb A.M.A.

PY - 2023/12/1

Y1 - 2023/12/1

N2 - The completion time of discharging has been reduced in current study with installing fins and dispersing additives. The tank has an insulated sinusoidal bottom wall and is filled with water. The conduction mode of water has been improved with dispersing nanoparticles. To calculate the conductivity, the fraction and configurations of powders were considered as variables. The equations for modeling were simplified by considering the assumption of neglecting convection mode. Galerkin modeling incorporating implicit methods has been selected to achieve the modeling. With increasing ϕ form 0.02 to twice amount, the time of freezing declines around 16.9 %. If the tank is filled with water, it takes 300.06 s to reach full solidification. The rate of process enhances about 32.61 % with loading nanoparticles with blade shape of blade.

AB - The completion time of discharging has been reduced in current study with installing fins and dispersing additives. The tank has an insulated sinusoidal bottom wall and is filled with water. The conduction mode of water has been improved with dispersing nanoparticles. To calculate the conductivity, the fraction and configurations of powders were considered as variables. The equations for modeling were simplified by considering the assumption of neglecting convection mode. Galerkin modeling incorporating implicit methods has been selected to achieve the modeling. With increasing ϕ form 0.02 to twice amount, the time of freezing declines around 16.9 %. If the tank is filled with water, it takes 300.06 s to reach full solidification. The rate of process enhances about 32.61 % with loading nanoparticles with blade shape of blade.

KW - Conduction equation

KW - Discharging process

KW - Nanomaterial

KW - Thermal storage unit

KW - Unsteady simulation

UR - https://www.scopus.com/pages/publications/85169551584

U2 - 10.1016/j.est.2023.108841

DO - 10.1016/j.est.2023.108841

M3 - Article

AN - SCOPUS:85169551584

SN - 2352-152X

VL - 73

JO - Journal of Energy Storage

JF - Journal of Energy Storage

M1 - 108841

ER -

Simulation of unsteady process of converting liquid to solid phase inside a solar storage system utilizing nanoparticles

Abstract

Keywords

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