 Proof of concept for unsteady dynamic model of sorption thermal battery with H2O/LiBr and universal methodology to optimize energy storage densityHyung Won Choi, Jinhee Jeong, Ja Ryong Koo, Young Kim and Yong Tae Kang Energy, 2025, vol. 328, issue C Abstract: This study presents an unsteady dynamic model developed specifically to address limitations in conventional modeling of sorption thermal battery. The model introduces the concept of effective specific heat capacity to represent sensible and latent heat transfer under a single framework, and explicitly considers the transient evolution of vapor mass, pressure, and energy by treating the vapor domain as thermodynamically active unlike conventional quasi-steady models, which assume instantaneous vapor-liquid equilibrium and negligible vapor dynamics. Sorption thermal battery poses unique modeling challenges due to sharp transitions between subcooled and saturated solution regions. The presented model establishes a vapor-liquid equilibrium time scale as a function of chamber volume and hot water velocity, providing a boundary for the applicability of quasi-steady models. Experimental validation using a 1 kW prototype shows strong agreement with simulation results, achieving an energy storage density of 188 kWh/m3. This work not only resolves critical gaps in transient modeling but also proposes a universal methodology for optimizing energy storage density based on dimensionless time constants and vapor-liquid equilibrium dynamics. This provides a foundation for the accurate design and control of sorption thermal battery. Keywords: Energy storage density; Optimal operating time; Proof of concept prototype; Sorption thermal battery; Unsteady dynamic model (search for similar items in EconPapers) Downloads: (external link) Related works: Export reference: BibTeX RIS (EndNote, ProCite, RefMan) HTML/Text Persistent link: https://EconPapers.repec.org/RePEc:eee:energy:v:328:y:2025:i:c:s0360544225022546 DOI: 10.1016/j.energy.2025.136612 Access Statistics for this article Energy is currently edited by Henrik Lund and Mark J. Kaiser More articles in Energy from Elsevier |
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