Review of pressurized chemical looping processes for power generation and chemical production with integrated CO2 capture

Osman, Mogahid; Khan, Mohammed N.; Zaabout, Abdelghafour; Cloete, Schalk; Amini, Shahriar

doi:10.1016/j.fuproc.2020.106684

Cited by 62 publications

(25 citation statements)

References 155 publications

(256 reference statements)

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“…If we want to couple a CLC combustor with a gas turbine, we have to take into consideration that for the aims of the GTCLC_NEG process the kinetic triplets need to be derived at high pressure (with Pressurized TGA tests, see table 2). Pressurized Chemical Looping is well described in the recent review [54], many works presented in table 2 are taken from it. Table 2 reports only reduction tests performed at high pressure, while CSIC and TU Eindhoven and also CanmetEnergy have realized also oxidation tests in pressurized conditions [55,56].…”

Section: Detailed Kinetic Models Of Iron Reductionmentioning

confidence: 99%

Integration of Multiphase CFD Models With Detailed Kinetics to Understand the Behavior of Oxygen Carriers Under Pressurized Conditions

Pietro¹,

Bartocci²,

Abad³

et al. 2022

Preprint

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Section: Detailed Kinetic Models Of Iron Reductionmentioning

confidence: 99%

Integration of Multiphase CFD Models With Detailed Kinetics to Understand the Behavior of Oxygen Carriers Under Pressurized Conditions

Pietro¹,

Bartocci²,

Abad³

et al. 2022

Preprint

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“…3d and e. Amini et al [80] have recently reviewed the effect of pressure in chemical looping system, concluding that high pressure is beneficial for the reaction kinetics and hydrogen production process. More review and discussion on the effect of reactor system configuration are addressed in Sect.…”

Section: Product Selectivity: Stoichiometry Thermodynamics and Kineticsmentioning

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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“…24,25 Although the CFB configuration has been demonstrated at the lab 26−28 and pilot 29−38 scales for several chemical looping processes, pressurizing this configuration (Figure 2a) could be difficult for this application considering that each reactor needs to be pressurized individually with the need for precise control of the circulation of the oxygen carriers to fulfill the heat and mass balances of the process; only a few studies are reported on pressurized chemical looping using the interconnected fluidized bed configuration. 39 The challenges magnify in threesteps processes such as CLPOX-H 2 , which would require three interconnected reactors with an oxygen carrier circulating between them. As a consequence, the studies on pressurized chemical looping operations are still very limited.…”

Section: Introductionmentioning

confidence: 99%

“…To maximize the economic and environmental benefits of CLPOX (or CLPOX-H 2 ), a pressurized operation is required to improve the overall process efficiency and simplify its integration with downstream GTL processes. Chemical looping-based processes have been investigated at larger scales using interconnected circulating fluidized beds (CFB). , Although the CFB configuration has been demonstrated at the lab − and pilot − scales for several chemical looping processes, pressurizing this configuration (Figure a) could be difficult for this application considering that each reactor needs to be pressurized individually with the need for precise control of the circulation of the oxygen carriers to fulfill the heat and mass balances of the process; only a few studies are reported on pressurized chemical looping using the interconnected fluidized bed configuration . The challenges magnify in three-steps processes such as CLPOX-H 2 , which would require three interconnected reactors with an oxygen carrier circulating between them.…”

Section: Introductionmentioning

confidence: 99%

Combined Syngas and Hydrogen Production using Gas Switching Technology

Ugwu

Zaabout

Donat

et al. 2021

Ind. Eng. Chem. Res.

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This paper focuses on the experimental demonstration of a three-stage GST (gas switching technology) process (fuel, steam/CO 2 , and air stages) for syngas production from methane in the fuel stage and H 2 /CO production in the steam/CO 2 stage using a lanthanum-based oxygen carrier (La 0.85 Sr 0.15 Fe 0.95 Al 0.05 O 3 ). Experiments were performed at temperatures between 750–950 °C and pressures up to 5 bar. The results show that the oxygen carrier exhibits high selectivity to oxidizing methane to syngas at the fuel stage with improved process performance with increasing temperature although carbon deposition could not be avoided. Co-feeding CO 2 with CH 4 at the fuel stage reduced carbon deposition significantly, thus reducing the syngas H 2 /CO molar ratio from 3.75 to 1 (at CO 2 /CH 4 ratio of 1 at 950 °C and 1 bar). The reduced carbon deposition has maximized the purity of the H 2 produced in the consecutive steam stage thus increasing the process attractiveness for the combined production of syngas and pure hydrogen. Interestingly, the cofeeding of CO 2 with CH 4 at the fuel stage showed a stable syngas production over 12 hours continuously and maintained the H 2 /CO ratio at almost unity, suggesting that the oxygen carrier was exposed to simultaneous partial oxidation of CH 4 with the lattice oxygen which was restored instantly by the incoming CO 2 . Furthermore, the addition of steam to the fuel stage could tune up the H 2 /CO ratio beyond 3 without carbon deposition at H 2 O/CH 4 ratio of 1 at 950 °C and 1 bar; making the syngas from gas switching partial oxidation suitable for different downstream processes, for example, gas-to-liquid processes. The process was also demonstrated at higher pressures with over 70% fuel conversion achieved at 5 bar and 950 °C.

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Review of pressurized chemical looping processes for power generation and chemical production with integrated CO2 capture

Cited by 62 publications

References 155 publications

Integration of Multiphase CFD Models With Detailed Kinetics to Understand the Behavior of Oxygen Carriers Under Pressurized Conditions

Integration of Multiphase CFD Models With Detailed Kinetics to Understand the Behavior of Oxygen Carriers Under Pressurized Conditions

Chemical looping reforming: process fundamentals and oxygen carriers

Combined Syngas and Hydrogen Production using Gas Switching Technology

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