Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam

Thermal energy storage units conventionally have the drawback of slow charging response. Thus, heat transfer enhancement techniques are required to reduce charging time. Using nanoadditives is a promising approach to enhance the heat transfer and energy storage response time of materials that store...

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Main Authors: Mohammad Ghalambaz, Seyed Abdollah Mansouri Mehryan, Kasra Ayoubi Ayoubloo, Ahmad Hajjar, Mohamad El Kadri, Obai Younis, Mohsen Saffari Pour, Christopher Hulme-Smith
Format: Article
Language:English
Published: MDPI AG 2021-03-01
Series:Molecules
Subjects:
Online Access:https://www.mdpi.com/1420-3049/26/5/1491
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author Mohammad Ghalambaz
Seyed Abdollah Mansouri Mehryan
Kasra Ayoubi Ayoubloo
Ahmad Hajjar
Mohamad El Kadri
Obai Younis
Mohsen Saffari Pour
Christopher Hulme-Smith
author_facet Mohammad Ghalambaz
Seyed Abdollah Mansouri Mehryan
Kasra Ayoubi Ayoubloo
Ahmad Hajjar
Mohamad El Kadri
Obai Younis
Mohsen Saffari Pour
Christopher Hulme-Smith
author_sort Mohammad Ghalambaz
collection DOAJ
description Thermal energy storage units conventionally have the drawback of slow charging response. Thus, heat transfer enhancement techniques are required to reduce charging time. Using nanoadditives is a promising approach to enhance the heat transfer and energy storage response time of materials that store heat by undergoing a reversible phase change, so-called phase change materials. In the present study, a combination of such materials enhanced with the addition of nanometer-scale graphene oxide particles (called nano-enhanced phase change materials) and a layer of a copper foam is proposed to improve the thermal performance of a shell-and-tube latent heat thermal energy storage (LHTES) unit filled with capric acid. Both graphene oxide and copper nanoparticles were tested as the nanometer-scale additives. A geometrically nonuniform layer of copper foam was placed over the hot tube inside the unit. The metal foam layer can improve heat transfer with an increase of the composite thermal conductivity. However, it suppressed the natural convection flows and could reduce heat transfer in the molten regions. Thus, a metal foam layer with a nonuniform shape can maximize thermal conductivity in conduction-dominant regions and minimize its adverse impacts on natural convection flows. The heat transfer was modeled using partial differential equations for conservations of momentum and heat. The finite element method was used to solve the partial differential equations. A backward differential formula was used to control the accuracy and convergence of the solution automatically. Mesh adaptation was applied to increase the mesh resolution at the interface between phases and improve the quality and stability of the solution. The impact of the eccentricity and porosity of the metal foam layer and the volume fraction of nanoparticles on the energy storage and the thermal performance of the LHTES unit was addressed. The layer of the metal foam notably improves the response time of the LHTES unit, and a 10% eccentricity of the porous layer toward the bottom improved the response time of the LHTES unit by 50%. The presence of nanoadditives could reduce the response time (melting time) of the LHTES unit by 12%, and copper nanoparticles were slightly better than graphene oxide particles in terms of heat transfer enhancement. The design parameters of the eccentricity, porosity, and volume fraction of nanoparticles had minimal impact on the thermal energy storage capacity of the LHTES unit, while their impact on the melting time (response time) was significant. Thus, a combination of the enhancement method could practically reduce the thermal charging time of an LHTES unit without a significant increase in its size.
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spelling doaj.art-b907a187634a46d9841fe8d4f6b14a2a2023-11-21T09:46:45ZengMDPI AGMolecules1420-30492021-03-01265149110.3390/molecules26051491Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper FoamMohammad Ghalambaz0Seyed Abdollah Mansouri Mehryan1Kasra Ayoubi Ayoubloo2Ahmad Hajjar3Mohamad El Kadri4Obai Younis5Mohsen Saffari Pour6Christopher Hulme-Smith7Metamaterials for Mechanical, Biomechanical and Multiphysical Applications Research Group, Ton Duc Thang University, Ho Chi Minh City 758307, VietnamYoung Researchers and Elite Club, Yasooj Branch, Islamic Azad University, Yasooj 7591493686, IranDepartment of Mechanical Engineering, Shahid Chamran University of Ahvaz, Ahvaz 61355, IranECAM Lyon, LabECAM, Université de Lyon, 69005 Lyon, FranceCentre Scientifique et Technique du Bâtiment, 44323 Nantes, FranceDepartment of Mechanical Engineering, College of Engineering at Wadi Addwaser, Prince Sattam Bin Abdulaziz University, Wadi Addwaser 11991, Saudi ArabiaDepartment of Mechanical Engineering, Faculty of Engineering, Shahid Bahonar University of Kerman, Kerman 7616913439, IranDepartment of Materials Science and Engineering, KTH Royal Institute of Technology, SE-100 44 Stockholm, SwedenThermal energy storage units conventionally have the drawback of slow charging response. Thus, heat transfer enhancement techniques are required to reduce charging time. Using nanoadditives is a promising approach to enhance the heat transfer and energy storage response time of materials that store heat by undergoing a reversible phase change, so-called phase change materials. In the present study, a combination of such materials enhanced with the addition of nanometer-scale graphene oxide particles (called nano-enhanced phase change materials) and a layer of a copper foam is proposed to improve the thermal performance of a shell-and-tube latent heat thermal energy storage (LHTES) unit filled with capric acid. Both graphene oxide and copper nanoparticles were tested as the nanometer-scale additives. A geometrically nonuniform layer of copper foam was placed over the hot tube inside the unit. The metal foam layer can improve heat transfer with an increase of the composite thermal conductivity. However, it suppressed the natural convection flows and could reduce heat transfer in the molten regions. Thus, a metal foam layer with a nonuniform shape can maximize thermal conductivity in conduction-dominant regions and minimize its adverse impacts on natural convection flows. The heat transfer was modeled using partial differential equations for conservations of momentum and heat. The finite element method was used to solve the partial differential equations. A backward differential formula was used to control the accuracy and convergence of the solution automatically. Mesh adaptation was applied to increase the mesh resolution at the interface between phases and improve the quality and stability of the solution. The impact of the eccentricity and porosity of the metal foam layer and the volume fraction of nanoparticles on the energy storage and the thermal performance of the LHTES unit was addressed. The layer of the metal foam notably improves the response time of the LHTES unit, and a 10% eccentricity of the porous layer toward the bottom improved the response time of the LHTES unit by 50%. The presence of nanoadditives could reduce the response time (melting time) of the LHTES unit by 12%, and copper nanoparticles were slightly better than graphene oxide particles in terms of heat transfer enhancement. The design parameters of the eccentricity, porosity, and volume fraction of nanoparticles had minimal impact on the thermal energy storage capacity of the LHTES unit, while their impact on the melting time (response time) was significant. Thus, a combination of the enhancement method could practically reduce the thermal charging time of an LHTES unit without a significant increase in its size.https://www.mdpi.com/1420-3049/26/5/1491latent heat thermal energy storageannuli enclosuregraphene oxide nanoparticlescopper metal foamthermal enhancement
spellingShingle Mohammad Ghalambaz
Seyed Abdollah Mansouri Mehryan
Kasra Ayoubi Ayoubloo
Ahmad Hajjar
Mohamad El Kadri
Obai Younis
Mohsen Saffari Pour
Christopher Hulme-Smith
Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam
Molecules
latent heat thermal energy storage
annuli enclosure
graphene oxide nanoparticles
copper metal foam
thermal enhancement
title Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam
title_full Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam
title_fullStr Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam
title_full_unstemmed Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam
title_short Thermal Energy Storage and Heat Transfer of Nano-Enhanced Phase Change Material (NePCM) in a Shell and Tube Thermal Energy Storage (TES) Unit with a Partial Layer of Eccentric Copper Foam
title_sort thermal energy storage and heat transfer of nano enhanced phase change material nepcm in a shell and tube thermal energy storage tes unit with a partial layer of eccentric copper foam
topic latent heat thermal energy storage
annuli enclosure
graphene oxide nanoparticles
copper metal foam
thermal enhancement
url https://www.mdpi.com/1420-3049/26/5/1491
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