Modeling of high temperature thermal energy storage in rock beds – Experimental comparison and parametric study

•A 2D model of a 450 kWh rock bed for high temperature thermal energy storage is built.•A comparison of model results with experimental data is performed.•Smaller rock sizes and larger charging flow rates lead to higher charge efficiency.•Magnetite results in a more concentrated heat storage than Sw...

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Bibliographic Details
Published in:Applied thermal engineering 2019-12, Vol.163, p.114355, Article 114355
Main Authors: Marongiu, Fabrizio, Soprani, Stefano, Engelbrecht, Kurt
Format: Article
Language:English
Subjects:
Air flow
Alternative energy
Boundary conditions
Charge efficiency
Computer simulation
Energy storage
Flow velocity
Heat conductivity
Heat transfer
High temperature
Insulation
Parameter modification
Parametric statistics
Rock beds
Storage units
Studies
Temperature profiles
Thermal energy
Two dimensional models
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Summary:•A 2D model of a 450 kWh rock bed for high temperature thermal energy storage is built.•A comparison of model results with experimental data is performed.•Smaller rock sizes and larger charging flow rates lead to higher charge efficiency.•Magnetite results in a more concentrated heat storage than Swedish diabase.•Heat capacity of insulation layers negatively affects small-scale heat storage. The increasing penetration of renewables in energy systems requires the integration of energy storage units into electrical grids as a crucial aspect. Nevertheless, current ES technologies show, as a common issue, an excessive capital cost, which prevents them from being implemented on a large scale. The combination of high temperature thermal energy storage and bottom steam cycles has recently become an object of interest as a potential cost-effective alternative to traditional ES. In this study, a two-dimensional model of an existing high temperature thermal energy storage rock bed unit with 450 kWhth of thermal capacity is implemented. A description of the geometry, equations and boundary conditions is provided, as well as a comparison of the model results with the experimental data logged from the reference testing unit. A brief discussion about the solution method and the relative error on the final results is also presented. A study regarding the charge phase was performed, with the main focus on the modification of some parameters of interest such as rock size, air flow rate, rock type and insulation material. Results are presented in terms of two-dimensional temperature profiles, charge efficiencies and heat losses, highlighting the differences between the scenarios considered. Thermal charge efficiency was found in the range 69–96% for the considered simulations, and different improvement aspects are suggested for future studies.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2019.114355