Computational model of a Calcium-looping fluidized bed calcination reactor with imposed concentrated solar irradiance

The Calcium-looping process is a promising option for thermochemical energy storage in concentrating solar power plants. A crucial element of this process is the solar calcination reactor, where the endothermic reaction of CaCO3 calcination occurs with formation of CaO and CO2. The solar energy that...

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Published inSolar energy Vol. 258; pp. 72 - 87
Main Authors Rodrigues, D., Alvarez Rivero, M., Pinheiro, C.I.C., Cardoso, J.P., Mendes, L.F.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.07.2023
Subjects
Calcination reactor
Calcium looping
Concentrated solar energy
Fluidized bed reactor
Indirectly irradiated system
Thermochemical energy storage
Fluidized bed reactor
Indirectly irradiated system
Concentrated solar energy
Calcium looping
Thermochemical energy storage
Calcination reactor
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Abstract The Calcium-looping process is a promising option for thermochemical energy storage in concentrating solar power plants. A crucial element of this process is the solar calcination reactor, where the endothermic reaction of CaCO3 calcination occurs with formation of CaO and CO2. The solar energy that is chemically stored in the reaction products can be retrieved by the exothermic reaction of CaO carbonation when needed. In this article, a new computational model is developed for the solar calcination reactor in this Calcium-looping process. The calcination reaction takes place in the riser of a continuous circulating fluidized bed that corresponds to an absorber tube exposed to concentrated solar radiation, which allows the reaction chamber to be indirectly heated. A core-annulus heat transfer model and a modified version of the Kunii–Levenspiel fluid dynamics model are used. In contrast to previous models found in the literature, the change in the mass flow rate of the species and in the density of the phases due to the reaction is considered. Simulation studies are performed with a fixed and imposed concentrated solar irradiance on the reactor wall, which varies in both the axial and angular directions. Wall conduction in the angular direction is also considered. The results show that nearly complete calcination can be achieved with a reactor of 4 m of height. A sensitivity analysis with respect to the model parameters and inlet conditions shows that the calcination conversion is mostly affected by the solids mass flow rate and the bed temperature at the inlet. •Solar calcination of CaCO3 is crucial in Ca-looping for thermochemical energy storage.•A model of a circulating fluidized bed reactor for solar calcination is proposed.•Simulations are performed with an imposed solar irradiance on the reactor wall.•Nearly complete calcination can be achieved with a reactor of 4 m of height.•Sensitivity analyses show large effect of inlet solids mass flow rate and temperature.
AbstractList The Calcium-looping process is a promising option for thermochemical energy storage in concentrating solar power plants. A crucial element of this process is the solar calcination reactor, where the endothermic reaction of CaCO3 calcination occurs with formation of CaO and CO2. The solar energy that is chemically stored in the reaction products can be retrieved by the exothermic reaction of CaO carbonation when needed. In this article, a new computational model is developed for the solar calcination reactor in this Calcium-looping process. The calcination reaction takes place in the riser of a continuous circulating fluidized bed that corresponds to an absorber tube exposed to concentrated solar radiation, which allows the reaction chamber to be indirectly heated. A core-annulus heat transfer model and a modified version of the Kunii–Levenspiel fluid dynamics model are used. In contrast to previous models found in the literature, the change in the mass flow rate of the species and in the density of the phases due to the reaction is considered. Simulation studies are performed with a fixed and imposed concentrated solar irradiance on the reactor wall, which varies in both the axial and angular directions. Wall conduction in the angular direction is also considered. The results show that nearly complete calcination can be achieved with a reactor of 4 m of height. A sensitivity analysis with respect to the model parameters and inlet conditions shows that the calcination conversion is mostly affected by the solids mass flow rate and the bed temperature at the inlet. •Solar calcination of CaCO3 is crucial in Ca-looping for thermochemical energy storage.•A model of a circulating fluidized bed reactor for solar calcination is proposed.•Simulations are performed with an imposed solar irradiance on the reactor wall.•Nearly complete calcination can be achieved with a reactor of 4 m of height.•Sensitivity analyses show large effect of inlet solids mass flow rate and temperature.
Author Cardoso, J.P.
Pinheiro, C.I.C.
Mendes, L.F.
Alvarez Rivero, M.
Rodrigues, D.
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Keywords Fluidized bed reactor
Indirectly irradiated system
Concentrated solar energy
Calcium looping
Thermochemical energy storage
Calcination reactor
Language English
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Snippet The Calcium-looping process is a promising option for thermochemical energy storage in concentrating solar power plants. A crucial element of this process is...
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SubjectTerms Calcination reactor
Calcium looping
Concentrated solar energy
Fluidized bed reactor
Indirectly irradiated system
Thermochemical energy storage
Title Computational model of a Calcium-looping fluidized bed calcination reactor with imposed concentrated solar irradiance
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