Thermal synthesis of a thermochemical heat storage with heat exchanger optimization
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In: Applied Thermal Engineering, Vol. 101, 25.05.2016, p. 669-677.
Research output: Journal contributions › Journal articles › Research › peer-review
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TY - JOUR
T1 - Thermal synthesis of a thermochemical heat storage with heat exchanger optimization
AU - Fopah Lele, Armand
AU - Kuznik, Frédéric
AU - Osterland, Thomas
AU - Ruck, Wolfgang
PY - 2016/5/25
Y1 - 2016/5/25
N2 - Thermochemical materials, particularly salt hydrates, have a significant potential for use in thermal energy storage systems. When a salt hydrate is heated to a critical temperature, a chemical reaction is initiated to dissociate it into its anhydrous form and water vapour. The anhydrous salt stores the sensible energy that was supplied for dehydration, which can be later extracted by allowing cooler water or water vapour to flow through the salt, transforming the stored energy into higher sensible heat. This work presents a thermal synthesis modelling of a thermochemical heat storage based on the reactive porous bed of MgCl 22H 2O in a closed system. An analytical sharp front model is also developed to determine the required hydration time and the optimal bed size for such a system at prototype level. A sensitivity analysis helps to identify the optimal parameters that significantly affect the performance of the heat release process. Numerical heat and mass transfer through principal system components is studied using Comsol Multiphysics Software. Numerical results show good concordance with the experiment and reveal that to achieve quasi-complete hydration of the bed, mass flow rate should not be higher than 0.001 kġh -1 for a bed thickness between 4 and 5 cm, considering the present system configuration. In this closed system, inlet vapour pressure into the bed has no influence on the conversion process. Optimal porosity of around 0.76 is found based on the heat and mass transfer dilemma analysis. Optimal heat exchanger design is performed for mass transfer enhancement in the reactive bed.
AB - Thermochemical materials, particularly salt hydrates, have a significant potential for use in thermal energy storage systems. When a salt hydrate is heated to a critical temperature, a chemical reaction is initiated to dissociate it into its anhydrous form and water vapour. The anhydrous salt stores the sensible energy that was supplied for dehydration, which can be later extracted by allowing cooler water or water vapour to flow through the salt, transforming the stored energy into higher sensible heat. This work presents a thermal synthesis modelling of a thermochemical heat storage based on the reactive porous bed of MgCl 22H 2O in a closed system. An analytical sharp front model is also developed to determine the required hydration time and the optimal bed size for such a system at prototype level. A sensitivity analysis helps to identify the optimal parameters that significantly affect the performance of the heat release process. Numerical heat and mass transfer through principal system components is studied using Comsol Multiphysics Software. Numerical results show good concordance with the experiment and reveal that to achieve quasi-complete hydration of the bed, mass flow rate should not be higher than 0.001 kġh -1 for a bed thickness between 4 and 5 cm, considering the present system configuration. In this closed system, inlet vapour pressure into the bed has no influence on the conversion process. Optimal porosity of around 0.76 is found based on the heat and mass transfer dilemma analysis. Optimal heat exchanger design is performed for mass transfer enhancement in the reactive bed.
KW - Chemistry
KW - Thermal synthesis
KW - Thermochemical storage
KW - Sharp front model
KW - MgCl2⋅2H2O
KW - Heat exchanger
KW - Modelling
KW - Sustainability Science
KW - Energy research
UR - http://www.scopus.com/inward/record.url?scp=84969941503&partnerID=8YFLogxK
U2 - 10.1016/j.applthermaleng.2015.12.103
DO - 10.1016/j.applthermaleng.2015.12.103
M3 - Journal articles
VL - 101
SP - 669
EP - 677
JO - Applied Thermal Engineering
JF - Applied Thermal Engineering
SN - 1359-4311
ER -