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Tracking of the melting front in tube-in-tube latent thermal energy storage heat exchangers
In this study, the shrinking solid regime is investigated in a high aspect ratio tube-in-tube latent thermal energy storage (LTES) heat exchanger by tracking the phase change front evolution. In the setup, water flows through the inner tube as heat transfer fluid (HTF) and the shell contains a paraf...
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| Published in: | Journal of physics. Conference series 2024-05, Vol.2766 (1), p.12053 |
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| container_issue | 1 |
| container_start_page | 12053 |
| container_title | Journal of physics. Conference series |
| container_volume | 2766 |
| creator | Van Zele, J Goderis, M Couvreur, K Beyne, W De Paepe, M |
| description | In this study, the shrinking solid regime is investigated in a high aspect ratio tube-in-tube latent thermal energy storage (LTES) heat exchanger by tracking the phase change front evolution. In the setup, water flows through the inner tube as heat transfer fluid (HTF) and the shell contains a paraffin RT35HC as phase change material (PCM). A series of melting experiments have been performed in which the HTF mass flow rate, HTF inlet temperature and initial PCM temperature were varied. During each experiment, the movement of the phase change front was tracked using a camera placed next to the PCM tube. The front position as a function of time follows an S-shape curve. The effect of the operating conditions on the evolution of the phase change front is analysed. It is found that the temperature difference between the HTF and PCM exerts a more pronounced influence on the front position compared to the HTF Reynolds number. Finally, a correlation was developed to determine the temporal evolution of the front position. This research contributes to a deeper understanding of phase change phenomena in LTES systems and the found correlation can be a valuable tool for predicting and optimizing the performance of tube-in-tube LTES heat exchangers. |
| doi_str_mv | 10.1088/1742-6596/2766/1/012053 |
| format | article |
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In the setup, water flows through the inner tube as heat transfer fluid (HTF) and the shell contains a paraffin RT35HC as phase change material (PCM). A series of melting experiments have been performed in which the HTF mass flow rate, HTF inlet temperature and initial PCM temperature were varied. During each experiment, the movement of the phase change front was tracked using a camera placed next to the PCM tube. The front position as a function of time follows an S-shape curve. The effect of the operating conditions on the evolution of the phase change front is analysed. It is found that the temperature difference between the HTF and PCM exerts a more pronounced influence on the front position compared to the HTF Reynolds number. Finally, a correlation was developed to determine the temporal evolution of the front position. 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| subjects | Energy storage Evolution Fluid flow Heat exchangers High aspect ratio Inlet temperature Mass flow rate Performance prediction Phase change materials Reynolds number Shape effects Temperature gradients Thermal energy Tracking |
| title | Tracking of the melting front in tube-in-tube latent thermal energy storage heat exchangers |
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