- Title
- Mixing and segregation of binary oxygen carrier mixtures in a cold flow model of a chemical looping combustor
- Creator
- Alghamdi, Yusif A.; Moghtaderi, Behdad; Doroodchi, Elham
- Relation
- ARC.LP100200872
- Relation
- Chemical Engineering Journal Vol. 223, p. 772-784
- Publisher Link
- http://dx.doi.org/10.1016/j.cej.2013.03.037
- Publisher
- Elsevier
- Resource Type
- journal article
- Date
- 2013
- Description
- In a typical chemical looping combustion process, the oxygen for fuel combustion is supplied by circulating metal based oxygen carriers between two interconnected fluidised bed reactors. The redox characteristics of oxygen carriers and hence the overall performance of the process can be significantly improved by utilising binary mixtures of oxygen carrier particles. The full potential of such multi-species particle systems however can be only realised when particles segregation is minimised. This study is concerned with gaining an understanding of the mixing and segregation behaviour of binary mixtures of oxygen carrier particles with different sizes and densities in a cold flow model representing a 10. kWth chemical looping combustor. The hydrodynamics of such systems were investigated and compared with a typical chemical looping combustion process where single species are used. This was followed by investigating the solids mixing and segregation behaviour in terms of segregation intensity and species weight percentage at each reactor as a function of operating parameters. It was shown that increasing the total solid inventory, particle terminal velocity ratio, composition, and air reactor superficial velocity increases the riser pressure, solid circulation rates, and riser solid holdup. Mixing and segregation regimes of the fuel reactor and the component segregation between the two reactors were also mapped. The results showed that, for mixtures of species with low terminal velocity to high terminal velocity ratios of greater than 0.7, a good mixing in the fuel reactor can be achieved by maintaining the superficial gas velocity to the mixture minimum fluidisation velocity ratio above 5. For the tested conditions, the component segregation between the two reactors was avoided by maintaining the ratio of the riser superficial velocity to the terminal velocity of the species with a high terminal velocity between 1.25 and 2.
- Subject
- chemical looping combustor; mixing and segregation; binary mixtures
- Identifier
- http://hdl.handle.net/1959.13/1300413
- Identifier
- uon:20069
- Identifier
- ISSN:1385-8947
- Language
- eng
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