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Heat transfer enhancement in shell and tube Latent Heat Thermal Energy Storage units for waste heat recovery applications: A 3D numerical study on melting–solidification kinetics

Soumaya Sokakini, J.V. Simo Tala, Lionel Nadau, Adrian Ilinca, Daniel Bougeard

2025Applied Thermal Engineering26 citationsDOIOpen Access PDF

Abstract

This study presents a novel three-dimensional (3D) numerical investigation of a finned diamond-shaped multi-tube latent heat thermal energy storage (LHTES) unit for low-temperature industrial waste heat recovery applications. Unlike existing studies that rely on simplified two-dimensional (2D) simulations and square shaped tubes geometry, this work introduces an innovative diamond-shaped tube configuration with longitudinal fins, enhancing both melting and solidification dynamics. The proposed heat storage unit is compared at iso-volume of PCM to a finless multi-tube unit, considered a reference case. Using erythritol as phase change material (PCM) and Hytherm 600 as heat transfer fluid (HTF), the study demonstrates that the proposed design achieves reductions of 24.5 % and 45.5 % in the melting and solidification times, respectively, compared to a finless reference case. Additionally, the influence of axial temperature gradients and Reynolds number variations on phase change dynamics is thoroughly examined, revealing non-negligible three-dimensional effects and significant improvements in heat transfer performance. The axial temperature gradient in the tubes and the tridimensionality effect involved influence phase change dynamics with a difference exceeding 17 % and 16.36 % in melting and solidification, respectively. Moreover, the Reynolds number effect is more significant during the melting process and for the enhanced configuration. Up to 14 % and 8 % reductions in melting and solidification times is achieved for the improved configuration, compared with 12.1 % and only 3 % for the reference case when the Reynolds number was increased from 1000 to 2000.

Topics & Concepts

Materials scienceThermal energy storageHeat transferLatent heatTube (container)ThermodynamicsKineticsWaste heatWaste heat recovery unitThermalNuclear engineeringShell and tube heat exchangerWaste managementComposite materialHeat exchangerEngineeringPhysicsQuantum mechanicsPhase Change Materials ResearchAdsorption and Cooling Systems
Heat transfer enhancement in shell and tube Latent Heat Thermal Energy Storage units for waste heat recovery applications: A 3D numerical study on melting–solidification kinetics | Litcius