Experimental analysis of a hybrid thermochemical cycle driven by intermediate grade heat sources for energy storage and combined cold and work productions

•Experimental Proof of Concept of a hybrid thermochemical process for cold and electricity cogeneration.•Experimental analysis of the dynamic behaviour of the prototype of hybrid thermochemical process.•Experimental sensibility study to cold source temperature.•Experimental and numerical analysis of...

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Bibliographic Details
Published in:Applied thermal engineering 2025-02, Vol.260, p.124886, Article 124886
Main Authors: Ghazale, Hasan, Pagès, Harley, Huc, Jean-Jacques, Hernandez, Emmanuel, Garcia, Roger, Neveu, Pierre, Mazet, Nathalie, Perier-Muzet, Maxime
Format: Article
Language:English
Subjects:
Applied thermodynamics
Chemical and Process Engineering
Cold and electricity congeneration
Conversion
Engineering Sciences
Heat storage
Hybrid thermochemical process
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Summary:•Experimental Proof of Concept of a hybrid thermochemical process for cold and electricity cogeneration.•Experimental analysis of the dynamic behaviour of the prototype of hybrid thermochemical process.•Experimental sensibility study to cold source temperature.•Experimental and numerical analysis of the coupling between the expander and the reactor. This paper presents an experimental study of a hybrid thermochemical cycle for the simultaneous cogeneration of cold and mechanical power, and thermal storage based on medium temperature sources. This concept is based on the integration of an expander machine on the reactive gas flow between the evaporator and the reactor to allow mechanical work production. The paper shows the proof of concept of this hybridization by continuous mechanical production and cold during the whole production phase: 68.33 kJ mechanical energy and 15.18 MJ cold, stable pressure ratio at the expander (around 1.3) and stable rotational speed (around 400 rpm). The prototype conception and design are detailed. The integration of the expander creates a pressure difference between the evaporator and the reactor (contrary to a classical thermochemical cycle), and thus an experimental sensitivity study investigating the effect of the cold production temperature at the evaporator (which defines the inlet pressure of the expander) on the mechanical production of the prototype and its dynamics is done. This allowed to analyze the strong coupling between the reactor and the expander in different operating conditions, experimentally and from a theoretical point of view. Despite the identified limitations of these two main components, it is worth mentioning that this is the first hybrid thermochemical prototype with stable output productions. The prototype works properly by providing continuous mechanical production during the whole production phase under different cold temperatures and constant electrical load, in comparison with what was found in the literature.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2024.124886