Triggering Xylitol crystallization in a 42 kWhth shell and tubes latent heat thermal energy storage system

•Xylitol is a promising phase change material but presents a persistent supercooling.•An innovative 42 kWh latent heat storage prototype using Xylitol is studied.•The coupling between seeding and bubbling gives promising results.•An optimized seeding step improves the storage outlet temperature.•A t...

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Bibliographic Details
Published in:Applied thermal engineering 2023-02, Vol.221, p.119802, Article 119802
Main Authors: Piquard, Louis, Gagnière, Emilie, Largiller, Grégory, Mangin, Denis, Bentivoglio, Fabrice
Format: Article
Language:English
Subjects:
Bubbling
Chemical and Process Engineering
Crystallization
Engineering Sciences
Heat Storage
Phase change materials
Seeding
Sugar alcohols
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Summary:•Xylitol is a promising phase change material but presents a persistent supercooling.•An innovative 42 kWh latent heat storage prototype using Xylitol is studied.•The coupling between seeding and bubbling gives promising results.•An optimized seeding step improves the storage outlet temperature.•A thermal homogenisation of liquid Xylitol due to bubbling is bring to light. Xylitol is a very promising Phase Change Material for district heating networks decentralized Latent Heat Thermal Energy Storages. However, it presents a high and persistent supercooling that requires the implementation of specific ways to trigger its crystallization. In previous works, the coupling of bubbling and seeding has been successfully tested as an efficient way to trigger Xylitol crystallization in small-scale crystallizers. The present work first studies the feasibility of using Xylitol as PCM in a 42 kWhth shell and tubes Latent Heat Thermal Energy Storage prototype integrating a bubbling and seeding system. Then, the benefits of optimizing the seeding step is discussed. Indeed, if the coupling between bubbling and seeding results in a fast and reproducible PCM crystallization, optimizing the seeding step allows to completely remove the effects of Xylitol supercooling on the restituted temperature levels. Another effect of bubbling in a Latent Heat Thermal Energy Storage is also brought to light: during the beginning of the discharge, a vertical temperature homogenization is observed in the liquid PCM. The consequences of this vertical temperature homogenization on the heat transfers and the performances of the storage are discussed.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2022.119802