No fins attached? Numerical analysis of internal–external fins coupled PCM melting for solar applications

Barthwal, Mohit; Rakshit, Dibakar

doi:10.1016/j.applthermaleng.2022.118911

Cited by 19 publications

(2 citation statements)

References 32 publications

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“…However, their low thermal conductivity can significantly slow thermal energy's charging and discharging cycle [2]. To enhance the performance of the phase change materials, various methods have been proposed, including adding high-conductivity additives or using finned tubes [2,[5][6][7][8]. Another approach is to fill phase change materials into a porous, highly conductive structure to improve their melting performance.…”

Section: Introductionmentioning

confidence: 99%

A Computational Study of Particle Mass Transport during Melting of NePCM in a Square Cavity with a Single Adiabatic Side

Hasadi¹

2023

Coatings

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Nanostructured phase change materials (NePCM) are phase change materials that contain different types and sizes of colloidal I removed the word sizes particles. Many investigations in the literature assess those type of phase change materials to investigate their thermal performance. However, there is a discrepancy between the experimental observations and numerical results of the melting process of the NePCM because most numerical models do not count for the mass transfer of the particles. In the current work, we will investigate the melting process of NePCM that consists of copper nanoparticles suspended in water for the geometry of a square cavity, heated from the two sides, cooled from one side, and the remaining side is thermally insulated. Our numerical model will account for the mass transfer of the particles using a one-fluid mixture and the enthalpy porosity model for accounting for the phase change process. We found that adding the particles will lead to the deceleration of the melting process, as described by the experiments, because of the reduction of the convection intensity. We found that for NePCM suspension containing 10% of nanoparticles by mass, the deceleration of melting will be about 2.2% compared to pure water. Most of the particles are convected away by the flow cells toward the bottom side of the cavity, especially near the isolated right side of the cavity. Our findings indicate that incorporating mass transport of particles leads to a significantly improved prediction of the melting behavior of the NePCM.

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Section: Introductionmentioning

confidence: 99%

A Computational Study of Particle Mass Transport during Melting of NePCM in a Square Cavity with a Single Adiabatic Side

Hasadi¹

2023

Coatings

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“…More recent works on this matter are related to the phase change phenomenon under different container configurations. In [39], a numerical analysis of PCM melting with internal/external fins serves to study the effect of varying fin designs on the phase change behavior. Similar work is presented in [40], where differently shaped containers are considered in the melting process of different PCMs.…”

Section: Introductionmentioning

confidence: 99%

Experimentally Based Testing of the Enthalpy-Porosity Method for the Numerical Simulation of Phase Change of Paraffin-Type Pcms

Martínez¹,

Carmona

Cortés

et al. 2022

SSRN Journal

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Numerical Analysis on Charging Performance of the Macro-Encapsulating Combined Sensible-Latent Heat Storage System with Structural Parameters

Wang,

Pan,

Wang

et al. 2024

J. Therm. Sci.

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No fins attached? Numerical analysis of internal–external fins coupled PCM melting for solar applications

Cited by 19 publications

References 32 publications

A Computational Study of Particle Mass Transport during Melting of NePCM in a Square Cavity with a Single Adiabatic Side

A Computational Study of Particle Mass Transport during Melting of NePCM in a Square Cavity with a Single Adiabatic Side

Experimentally Based Testing of the Enthalpy-Porosity Method for the Numerical Simulation of Phase Change of Paraffin-Type Pcms

Numerical Analysis on Charging Performance of the Macro-Encapsulating Combined Sensible-Latent Heat Storage System with Structural Parameters

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