Achieving Adequate Circulation in Chemical Looping Combustion─Design Proposal for a 200 MW<sub>th</sub> Chemical Looping Combustion Circulating Fluidized Bed Boiler

Lyngfelt, Anders; Pallarès, David; Linderholm, Carl Johan; Lind, Fredrik; Thunman, Henrik; Leckner, Bo G

doi:10.1021/acs.energyfuels.1c03615

Cited by 36 publications

(25 citation statements)

References 111 publications

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“…Thus, the effect of the temperature, circulation, and fuel flow could not be assessed. (2) This also means that, in contrast to LD slag, there was no oxidation to NO for the cases when CO was zero.…”

Section: Discussionmentioning

confidence: 99%

Fate of NO and Ammonia in Chemical Looping Combustion─Investigation in a 300 W Chemical Looping Combustion Reactor System

2022

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Chemical looping combustion (CLC) is a novel combustion concept that transfers oxygen from air to fuel using an oxygen carrier that circulates between an air reactor and a fuel reactor. Thus, the combustion products, H 2 O and CO 2 , are obtained in a separate flow, and ideally, a pure CO 2 gas stream is obtained after condensation of H 2 O. Consequently, CLC has a unique potential for avoiding the high costs and energy penalties of CO 2 capture. Further, NO emissions can potentially be avoided. CLC is flameless, and the temperature is too low for the formation of thermal NO x . Moreover, fuel NO x and prompt NO x do not form in the air reactor in the absence of fuel. In the fuel reactor, the absence of oxygen prevents normal NO x formation. However, when using fuels containing nitrogen, NO may form in the fuel reactor because the oxygen carrier can oxidize fuel nitrogen compounds. To achieve a CO 2 stream suited for storage, NO must be removed. Dependent upon how NO is removed, the process could be free from any NO emissions. NO formation and NO reduction were investigated in a 300 W CLC reactor by adding either NH 3 or NO. The work involved two different oxygen carriers, Linz−Donawitz (LD) slag and ilmenite, two temperatures, 850 and 900°C, two circulation rates, and different flows of syngas fuel. Further, operation without fuel with a fully and partially oxidized oxygen carrier was studied. For LD slag, lower fuel flow promoted the formation of NO and decreased the reduction of NO. Likewise, higher temperatures raised NO formation and lowered NO reduction. Ilmenite, however, was by far more superior with respect to NO. Thus, NO formation only occurred in the absence of fuel and with a fully oxidized oxygen carrier. Likewise, NO was fully reduced to N 2 for all conditions, except in the absence of fuel and with fully oxidized ilmenite.

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Section: Discussionmentioning

confidence: 99%

Fate of NO and Ammonia in Chemical Looping Combustion─Investigation in a 300 W Chemical Looping Combustion Reactor System

2022

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“… 7 , 12 , 13 These investigations have shown that CLC provides an efficient and cost-effective method for the combustion of gaseous fuels with inherent capture of CO 2 . 14 …”

Section: Introductionmentioning

confidence: 99%

“…The CLC process implicitly reduces the energy penalties of separating CO 2 and other products associated with a traditional air-based combustion. This technology for the combustion of gaseous fuels, particularly natural gas, has been an active research area for the last two decades. ,, These investigations have shown that CLC provides an efficient and cost-effective method for the combustion of gaseous fuels with inherent capture of CO 2 …”

Section: Introductionmentioning

confidence: 99%

“…7,12,13 These investigations have shown that CLC provides an efficient and cost-effective method for the combustion of gaseous fuels with inherent capture of CO 2 . 14 Given the vast abundance of solid fuels (coal, petroleum coke, biomass, etc.) and their importance in the generation of electrical power, it is highly attractive to apply CLC to the combustion of solid fuels for CO 2 capture.…”

Section: Introductionmentioning

confidence: 99%

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Hydrotalcite-Derived Copper-Based Oxygen Carrier Materials for Efficient Chemical-Looping Combustion of Solid Fuels with CO₂ Capture

et al. 2022

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Chemical-looping combustion (CLC) is a promising technology that utilizes metal oxides as oxygen carriers for the combustion of fossil fuels to CO 2 and H 2 O, with CO 2 readily sequestrated after the condensation of steam. Thermally stable and reactive metal oxides are desirable as oxygen carrier materials for the CLC processes. Here, we report the performance of Cu-based mixed oxides derived from hydrotalcite (also known as layered double hydroxides) precursors as oxygen carriers for the combustion of solid fuels. Two types of CLC processes were demonstrated, including chemical looping oxygen uncoupling (CLOU) and in situ gasification (iG-CLC) in the presence of steam. The Cu-based oxygen carriers showed high performance for the combustion of two solid fuels (a lignite and a bituminous coal), maintaining high thermal stability, fast reaction kinetics, and reversible oxygen release and storage over multiple redox cycles. Slight deactivation and sintering of the oxygen carrier occurred after redox cycles at an very high operation temperature of 985 °C. We expect that our material design strategy will inspire the development of better oxygen carrier materials for a variety of chemical looping processes for the clean conversion of fossil fuels with efficient CO 2 capture.

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“…This technology uses gasphase O 2 , generated by metal oxides such as those of copper, to react with the solid fuel directly, through comparatively fast solid-gas reactions. In the past two decades, pilot megawatt-scale CLC reactors have been developed [22][23][24][25] , showing great promise for industrial scale decarbonization.…”

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confidence: 99%

Precursor engineering of hydrotalcite-derived redox sorbents for reversible and stable thermochemical oxygen storage

et al. 2022

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Chemical looping processes based on multiple-step reduction and oxidation of metal oxides hold great promise for a variety of energy applications, such as CO2 capture and conversion, gas separation, energy storage, and redox catalytic processes. Copper-based mixed oxides are one of the most promising candidate materials with a high oxygen storage capacity. However, the structural deterioration and sintering at high temperatures is one key scientific challenge. Herein, we report a precursor engineering approach to prepare durable copper-based redox sorbents for use in thermochemical looping processes for combustion and gas purification. Calcination of the CuMgAl hydrotalcite precursors formed mixed metal oxides consisting of CuO nanoparticles dispersed in the Mg-Al oxide support which inhibited the formation of copper aluminates during redox cycling. The copper-based redox sorbents demonstrated enhanced reaction rates, stable O2 storage capacity over 500 redox cycles at 900 °C, and efficient gas purification over a broad temperature range. We expect that our materials design strategy has broad implications on synthesis and engineering of mixed metal oxides for a range of thermochemical processes and redox catalytic applications.

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Achieving Adequate Circulation in Chemical Looping Combustion─Design Proposal for a 200 MW_th Chemical Looping Combustion Circulating Fluidized Bed Boiler

Cited by 36 publications

References 111 publications

Fate of NO and Ammonia in Chemical Looping Combustion─Investigation in a 300 W Chemical Looping Combustion Reactor System

Fate of NO and Ammonia in Chemical Looping Combustion─Investigation in a 300 W Chemical Looping Combustion Reactor System

Hydrotalcite-Derived Copper-Based Oxygen Carrier Materials for Efficient Chemical-Looping Combustion of Solid Fuels with CO₂ Capture

Precursor engineering of hydrotalcite-derived redox sorbents for reversible and stable thermochemical oxygen storage

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Achieving Adequate Circulation in Chemical Looping Combustion─Design Proposal for a 200 MWth Chemical Looping Combustion Circulating Fluidized Bed Boiler

Cited by 36 publications

References 111 publications

Fate of NO and Ammonia in Chemical Looping Combustion─Investigation in a 300 W Chemical Looping Combustion Reactor System

Fate of NO and Ammonia in Chemical Looping Combustion─Investigation in a 300 W Chemical Looping Combustion Reactor System

Hydrotalcite-Derived Copper-Based Oxygen Carrier Materials for Efficient Chemical-Looping Combustion of Solid Fuels with CO2 Capture

Precursor engineering of hydrotalcite-derived redox sorbents for reversible and stable thermochemical oxygen storage

Contact Info

Product

Resources

About

Achieving Adequate Circulation in Chemical Looping Combustion─Design Proposal for a 200 MW_th Chemical Looping Combustion Circulating Fluidized Bed Boiler

Hydrotalcite-Derived Copper-Based Oxygen Carrier Materials for Efficient Chemical-Looping Combustion of Solid Fuels with CO₂ Capture