Use of CuO/MgAl2O4 and La0.8Sr0.2FeO3/γ‐Al2O3 in chemical looping reforming system for tar removal from gasification gas

Keller, Martin; Leion, Henrik; Mattisson, Tobias

doi:10.1002/aic.15034

Cited by 24 publications

(6 citation statements)

References 23 publications

(31 reference statements)

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“…Also, the mechanical strength and antisintering of the oxygen carrier need to be concerned . Up to now, metallic oxides including Cu, Fe, Co, Ni, and Mn − as well as nonmetallic oxides such as CaSO 4 , have been widely studied as oxygen and heat carriers in chemical looping combustion (CLC) or CLG process. Among them, Ni-based oxygen carriers have attracted much attention due to their higher redox activity and catalytic effect to decompose tar.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of Fe–Ni–Al Oxygen Carrier Derived from Hydrotalcite-like Precursors for the Chemical Looping Gasification of Biomass Char

Wei

Zhao

et al. 2017

Energy Fuels

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Chemical looping gasification (CLG) of biomass uses the lattice oxygen of oxygen carriers to convert biomass into syngas with a low tar content, high heating value, and low price. It is of key importance to exploit well-dispersed and thermally stable oxygen carriers for the CLG process. In the current work, a series of oxygen carriers with varied Fe and Ni molar ratios were synthesized from hydrotalcite compound precursors (HTlcs), which made the metallic elements mix at the molecular level. Consequently, highly dispersed complex metal oxygen carriers can be achieved after precursor calcinations. CLG of biomass char was carried out in TGA and a fixed bed reactor accompanied by various physical and chemical analyses for the fresh and used oxygen carriers. The result manifested the HTlcs crystalline form, which was formed in the precursors and produced the Fe0.99Ni0.6Al1.1O4 compound after calcination, suggesting that a high degree dispersion of the multimetal oxygen carrier was synthesized. The main H2 uptake and CLG reactivity of the oxygen carriers were related to its higher metal dispersion and synergistic effect between Fe and Ni. Accordingly, there was an optimum Fe/Ni ratio of 4:1 in oxygen carriers at which the oxygen carrier can achieve better CLG reactivity. Also, the oxygen carrier to biomass char mass ratio of 7:3 provided a maximum weight loss of 35.59% and a largest mass loss rate of 2.46 wt %/min, suggesting higher lattice oxygen releasing efficiency. CO exhibited a higher generating rate in the CLG reactions owing to its higher reaction activation energy with lattice oxygen [O], while H2 was more prone to being consumed. The morphological analysis of fresh and regenerated samples exhibited that the oxygen carrier was reduced to the Fe3Ni2 alloy phase after the CLG process, and the lattice oxygen can be fully recovered in an air atmosphere. Although the BET surface displayed a decreased trend in the regenerated oxygen carriers, serious sintering was not observed in the samples, and the main metallic crystallized phases were still maintained.

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Section: Introductionmentioning

confidence: 99%

Experimental Investigation of Fe–Ni–Al Oxygen Carrier Derived from Hydrotalcite-like Precursors for the Chemical Looping Gasification of Biomass Char

Wei

Zhao

et al. 2017

Energy Fuels

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“…It is known that B-site dopant will have a higher impact than the A-site dopant on vacancy creation, which is related to the oxygen release ability of the compound . However, the effect of MgO addition to the B site was tested for a CLOU application. , A study revealed that MgO-doped CaMnO 3 showed good stability in a 50-cycle test and a small increase in reactivity was also observed . Both in thermal analysis and fluidized bed experiments (Figures and for CMM1 and CMM2, respectively), the reduction peak temperature was observed around 975–985 °C for both MgO-doped CaMnO 3 .…”

Section: Resultsmentioning

confidence: 99%

Utilization of Promising Calcium Manganite Oxygen Carriers for Potential Thermochemical Energy Storage Application

Darwish

Leion

2021

Ind. Eng. Chem. Res.

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In this study, oxygen release/consumption behavior of calcium manganese-based oxides (CaMn1–x B x O3, where B: Cu, Fe, Mg and x = 0.1 or 0.2) used in a chemical looping oxygen uncoupling (CLOU) application was investigated. The effect of B-site dopants such as Fe, Mg, and Cu on the oxygen release behavior was also investigated with the aim to use these materials in thermal energy storage (TES). Previous literature studies about CLOU performance of doped calcium manganites were taken into consideration for dopants selection. Calcium manganite-based oxides have been used in chemical looping oxygen uncoupling (CLOU) applications owing to their oxygen release behavior to the gas phase. Studies have revealed that calcium manganite-based oxides show a promising nonstoichiometry over a range of temperatures and oxygen partial pressures, which makes them useful for thermochemical energy storage applications. However, the related literature studies have been mainly focused on their nonstoichiometric characteristics related to temperature and oxygen partial pressure and thermodynamic properties. In this work, thermal analysis and fluidized bed tests were carried out as complementary techniques. CaMn0.8Cu0.2O3 showed the highest oxygen release performance in fluidized bed tests, while CaMn0.9Mg0.1O3 had the best cyclic stability overall among the samples used in the study.

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“…Both supports and promoters have been tested to alleviate the sintering problem. The addition of inert supports such as Al 2 O 3 [133,[296][297][298], TiO 2 [133,297,299], and MgAl 2 O 4 [300] can slow down the sintering problem of copper oxide, but the addition of Al 2 O 3 , an acidic support, leads to the aggravation of carbon deposition [301]. As a result, Alirezaei et al [193] incorporated ZrO 2 into Al 2 O 3 , which promoted the dispersion of copper oxide and adjusted the mechanical properties of oxygen carriers.…”

Section: Copper Based Oxygen Carriermentioning

confidence: 99%

Chemical looping reforming: process fundamentals and oxygen carriers

et al. 2022

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Chemical looping reforming (CLR) provides a viable process intensification approach for clean and efficient syngas production from carbonaceous fuel with inherent gas–gas separation. The rational design of metal oxide-based oxygen carriers and the scale-up of associated CLR reactor systems play important roles in CLR process development. This review first introduces the concept and advantages of CLR as well as its historical development. The process fundamentals, including basic schemes, reaction stoichiometry, thermodynamics, kinetics and reactor system design, are reviewed. The integral approach for CLR process development is illustrated, showing that the design and compatibility of oxygen carriers and reactor systems are critical for CLR performance. The reaction principle during the reduction of oxygen carriers is discussed, followed by strategies for improving the redox reactivity and stability. We further review and discuss the latest exciting advances on this subject with the purpose of illustrating factors that govern fundamental mechanisms in the redox reaction chemistry of oxygen carriers and their design principles for sustained chemical looping reactor applications. It is expected that these new advances will inspire more effective oxygen carriers and efficient reactor systems for the development and deployment of various CLR processes.

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Use of CuO/MgAl₂O₄ and La_0.8Sr_0.2FeO₃/γ‐Al₂O₃ in chemical looping reforming system for tar removal from gasification gas

Cited by 24 publications

References 23 publications

Experimental Investigation of Fe–Ni–Al Oxygen Carrier Derived from Hydrotalcite-like Precursors for the Chemical Looping Gasification of Biomass Char

Experimental Investigation of Fe–Ni–Al Oxygen Carrier Derived from Hydrotalcite-like Precursors for the Chemical Looping Gasification of Biomass Char

Utilization of Promising Calcium Manganite Oxygen Carriers for Potential Thermochemical Energy Storage Application

Chemical looping reforming: process fundamentals and oxygen carriers

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