Kinetic determination of a highly reactive impregnated Fe2O3/Al2O3 oxygen carrier for use in gas-fueled Chemical Looping Combustion

Cabello, Arturo; Abad, Alberto; Garcı́a-Labiano, F.; Gayán, Pilar; Diego, Luis F. de; Adánez, Juan

doi:10.1016/j.cej.2014.07.083

Cited by 109 publications

(69 citation statements)

References 57 publications

(74 reference statements)

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“…However, the final oxidized mass is stabilized to about 98% after several cycles. Similar to the reduction reaction mechanism model for iron based OC proposed by Cabello et al [37], the outer layer of the reduced OC is first oxidize to Fe2O3 with forming a Fe2O3 layer, and then oxygen needs to diffuse into inner layer of OC by crossing the Fe2O3 layer. On the one hand, the investigation suggests that the oxidation process is mainly controlled by diffusional effects in the product layer [40], but on the other hand the large heat released by oxidation of metallic Fe to Fe2O3 can cause serious sinter [41] preventing diffusion of oxygen and causing a small amount of the inner OC (especially close to the interface between the active component and the Al2O3 supporter) which cannot be completely oxidized.…”

Section: Repeated Cycle Testmentioning

confidence: 98%

“…Apparently, a faster reaction rate of Fe2O3(104)/Al2O3 can be obtained. In previous investigations [37,38], the reaction for iron based OCs reduction into Fe3O4 is very quick (just consuming a few seconds at 950 °C). Despite a slightly longer reduction time required in the present work, we should recognize the fact that reaction temperature in our work is only 800 C rather than 950 °C as used in the previous studies.…”

Section: Reaction Between Ocs and Comentioning

confidence: 99%

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Study on Reaction Characteristics of Chemical-Looping Combustion between Maize Stalk and High Index Facet Iron Oxide

Lin

Wang

et al. 2016

Energies

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Section: Repeated Cycle Testmentioning

confidence: 98%

Section: Reaction Between Ocs and Comentioning

confidence: 99%

Study on Reaction Characteristics of Chemical-Looping Combustion between Maize Stalk and High Index Facet Iron Oxide

Lin

Wang

et al. 2016

Energies

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“…In the literature, both the shrinking core and diffusion model were the most frequently indicated for the description of the Fe oxide reduction reaction [14][15][16][17]24], which was the motivation of using both of these mentioned models in the natural oxygen carrier (Fe-based) kinetics calculations. In addition to these models, another model (e.g., the volumetric model) was also tested.…”

Section: Oxygen Carrier Characterizationmentioning

confidence: 99%

“…Sixty percentage of CO 2 was added to the gas mixture in the reduction reaction. The reason for using CO 2 was that carbon dioxide was an oxidation agent that helps maintain the reduction of hematite to only the magnetite phase by preventing a further reduction to wuestite or metallic Fe [24].…”

Section: Study Of the Kinetics Using A Thermogravimetric Analyzermentioning

confidence: 99%

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Studies on the redox reaction kinetics of selected, naturally occurring oxygen carrier

Ksepko

Babiński

Evdou

et al. 2015

J Therm Anal Calorim

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This paper presents the results of a chemicallooping combustion (CLC) study. The CLC technology is believed to be one of the most promising combustion technologies. The production of a concentrated CO 2 stream that is obtained after the water condensation without any loss of energy in its separation is one of the most crucial advantages of this technology. The objective of this work was to study the kinetics of both the reduction and oxidation reactions for naturally occurring oxygen carriers that show promising reactivity in CLC reactions, and might therefore be utilized as oxygen carrier materials. Kryvbas, a Fe-based ore, was selected for this analysis because it possessed sufficient concentrations of the active metal oxides (Fe oxide above 80 % and traces of Mn oxide) and a high melting temperature that was above 1500°C. Experiments were conducted under isothermal conditions within the temperature range of 750-950°C with multiple redox cycles using a thermogravimetric analyzer (TG). For the reduction and oxidation reactions, CH 4 (at different concentrations) and air were used, respectively. The sample showed promising results where a sufficient reactivity was observed with the fuel, and these results were reproducible. Both fresh material and samples that were used in multiple redox cycles were characterized by X-ray Diffraction (XRD) and Scanning Electron Microscopy combined with X-ray Microanalysis (SEM-EDS) in order to detect any structural or morphological changes as well as to determine the stability of the ore in repetitive CLC cycles. Kinetic parameters, such as the activation energy, the preexponential factor, and the reaction model, were determined for the redox reactions. Models of the redox reactions were selected by using a model fitting method. The F1 model (volumetric) was a suitable model for the modeling of the Kryvbas ore reduction reaction kinetics. The calculated E a was equal to 42.00 kJ mol -1 , while the reaction order was determined to be equal to 1.98. The best fit for the oxidation reaction was obtained for the R3 model (shrinking core model). The oxidation (regeneration) reaction activation energy was equal to 16.70 kJ mol -1 , and the reaction order was determined to be equal to approximately 0.49.

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High performance of la‐promoted Fe₂O₃/α‐Al₂O₃oxygen carrier for chemical looping combustion

Tian

Wang

et al. 2017

AIChE Journal

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Iron oxide supported oxygen carrier (OC) is regarded to a promising candidate for chemical looping combustion (CLC). However, phase separation between Fe2O3 and supports often occurs resulted from the severe sintering of supports during calcination, which leads to the sintering and breakage of Fe2O3 thus the decrease of redox reactivity. In this article, La‐promoted Fe2O3/α‐Al2O3 were used as OCs for CLC of CH4 and for the first time found that the OC with the addition of 18 wt % La exhibited outstanding reactivity and redox stability during 50 cycles of CLC of CH4. Such a superior performance originated from the formation of LaAl12O19 hexaaluminate (La‐HA) phase with not only small particle size but also excellent thermal stability at CLC conditions, which worked as a binder to prevent the phase separation thereby the sintering and breakage of active species α‐Fe2O3 were avoided during reaction. © 2017 American Institute of Chemical Engineers AIChE J, 63: 2827–2838, 2017

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Kinetic determination of a highly reactive impregnated Fe2O3/Al2O3 oxygen carrier for use in gas-fueled Chemical Looping Combustion

Cited by 109 publications

References 57 publications

Study on Reaction Characteristics of Chemical-Looping Combustion between Maize Stalk and High Index Facet Iron Oxide

Study on Reaction Characteristics of Chemical-Looping Combustion between Maize Stalk and High Index Facet Iron Oxide

Studies on the redox reaction kinetics of selected, naturally occurring oxygen carrier

High performance of la‐promoted Fe₂O₃/α‐Al₂O₃oxygen carrier for chemical looping combustion

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Kinetic determination of a highly reactive impregnated Fe2O3/Al2O3 oxygen carrier for use in gas-fueled Chemical Looping Combustion

Cited by 109 publications

References 57 publications

Study on Reaction Characteristics of Chemical-Looping Combustion between Maize Stalk and High Index Facet Iron Oxide

Study on Reaction Characteristics of Chemical-Looping Combustion between Maize Stalk and High Index Facet Iron Oxide

Studies on the redox reaction kinetics of selected, naturally occurring oxygen carrier

High performance of la‐promoted Fe2O3/α‐Al2O3oxygen carrier for chemical looping combustion

Contact Info

Product

Resources

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High performance of la‐promoted Fe₂O₃/α‐Al₂O₃oxygen carrier for chemical looping combustion