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Chemical looping reforming and gasification

January 06, 2023

Chemical looping reforming (CLR) and gasification (CLG) are the operations that involve the use of gaseous carbonaceous feedstock and solid carbonaceous feedstock, respectively, in their conversion to syngas in the chemical looping scheme.[1] The typical gaseous carbonaceous feedstocks used are natural gas and reducing tail gas, while the typical solid carbonaceous feedstocks used are coal and biomass. The feedstocks are partially oxidized to generate syngas using metal oxide oxygen carriers as the oxidant. The reduced metal oxide is then oxidized in the regeneration step using air. The syngas is an important intermediate for generation of such diverse products as electricity, chemicals, hydrogen, and liquid fuels.

The motivation for developing the CLR and CLG processes lies in their advantages of being able to avoid the use of pure oxygen in the reaction, thereby circumventing the energy intensive air separation requirement in the conventional reforming and gasification processes. The energy conversion efficiency of the processes can, thus, be significantly increased. Steam and carbon dioxide can also be used as the oxidants. As the metal oxide also serves as the heat transfer medium in the chemical looping process, the exergy efficiency of the reforming and gasification processes like that for the combustion process is also higher as compared to the conventional processes.[1][2]

Description

The CLR and CLG processes use solid metal oxides as the oxygen carrier instead of pure oxygen as the oxidant. In one reactor, termed the reducer or fuel reactor, the carbonaceous feedstock is partially oxidized to syngas, while the metal oxide is reduced to a lower oxidation state as given by:

CHaOb + 1-b/δ MeOx → CO + a/2 H2 + 1-b/δ MeOx-δ

where Me is a metal. It is noted that the reaction in the reducer of the CLR and CLG processes differs from that in the chemical looping combustion (CLC) process in that, the feedstock in CLC process is fully oxidized to CO2 and H2O. In another reactor, termed the oxidizer, combustor or air reactor (when air is used as the regeneration agent), the reduced metal oxide from the reducer is re-oxidized by air or steam as given by:

2δ MeOx-δ + O2 (air) → 2δ MeOx + (O2 depleted air)
1δ MeOx-δ + H2O → 1δ MeOx + H2

The solid metal oxide oxygen carrier is then circulated between these two reactors. That is the reducer and the oxidizer/combustor are connected in a solids circulatory loop, while the gaseous reactants and products from each of the two reactors are isolated by the gas seals between the reactors. This streamlining configuration of the chemical looping system possesses a process intensification property with a smaller process footprint as compared to that for the traditional systems.

Oxygen carriers

 
Fig 1. Modified Ellingham diagram:(a) to determine metal oxide performance in chemical looping processes; (b) with sections indicated for chemical looping applications.[3][4]

The Ellingham diagram that provides the Gibbs free energy formation of a variety of metal oxides is widely used in metallurgical processing for determining the relative reduction-oxidation potentials of metal oxides at different temperatures.[5] It depicts the thermodynamic property of a variety of metal oxides to be used as potential oxygen carrier materials. It can be modified to provide the Gibbs free energy changes for metals and metal oxides under various oxidation states so that it can be directly used for the selection of metal oxide oxygen carrier materials based on their oxidation capabilities for specific chemical looping applications.[1][3][4] The modified Ellingham diagram is given in Fig 1a. As shown in Fig 1b, the diagram can be divided into four different sections based on the following four key reactions:

Reaction line 1: 2CO + O2 → 2CO2
Reaction line 2: 2H2 + O2 → 2H2O
Reaction line 3: 2C + O2 → 2CO
Reaction line 4: 2CH4 + O2 → 2CO + 4H2

The sections identified in Fig 1b provide the information on metal oxide materials that can be selected as potential oxygen carriers for desired chemical looping applications. Specifically, highly oxidative metal oxides, such as NiO, CoO, CuO, Fe2O3 and Fe3O4 belong to the combustion section (Section A) and they all lie above the reaction lines 1 and 2. These metal oxides have a high oxidizing tendency and can be used as oxygen carriers for the chemical looping combustion, gasification or partial oxidation processes. The metal oxides in Section E, the small section between the reaction lines 1 and 2, can be used for CLR and CLG, although a significant amount of H2O may present in the syngas product. The section for syngas production lies between reaction lines 2 and 3 (Section B). Metal oxides lying in this region, such as CeO2, have moderate oxidation tendencies and are suitable for CLR and CLG but not for the complete oxidation reactions. Metal oxides below reaction line 3 (Sections C and D) are not thermodynamically favored for oxidizing the fuels to syngas. Thus, they cannot be used as oxygen carriers and are generally considered to be inert. These materials include Cr2O3 and SiO2. They can, however, be used as support materials along with active oxygen carrier materials. In addition to the relative redox potentials of metal oxide materials illustrated in Fig 1b, the development of desired oxygen carriers for chemical looping applications requires to consider such properties as oxygen carrying capacity, redox reactivity, reaction kinetics, recyclability, attrition resistance, heat carrying capacity, melting point, and production cost.[1][6][7][8][9][10][11][12][13][14]

Process configurations

The CLR and CLG processes can be configured based on the types of carbonaceous feedstocks given and desired products to be produced. Among a broad range of products, the CLG process can produce electricity through chemical looping IGCC. The syngas produced from the CLR and the CLG can be used to synthesize a variety of chemicals, liquid fuels and hydrogen. Given below are some specific examples of the CLR and CLG processes.

Steam methane reforming with chemical looping combustion (CLC-SMR)

 
Fig 2. CLC-SMR system for H2 production: (a) SMR reactor inside the reducer (fuel reactor) (b) SMR reactor inside the combustor (air reactor)[15][16]

Hydrogen and syngas are currently produced largely by steam methane reforming (SMR). The main reaction in SMR is:

CH4 + H2O → CO + 3H2

Steam can be further used to convert CO to H2 via the water-gas shift reaction (WGS):

H2O + CO → CO2 + H2

The SMR reaction is endothermic, which requires heat input. The state-of-art SMR system places the tubular catalytic reactors in a furnace, in which fuel gas is burned to provide the required heat.

In the SMR with chemical looping combustion (CLC-SMR) concepts shown in Fig 2,[15][16] the syngas production is carried out by the SMR in a tubular catalytic reactor while the chemical looping combustion system is used to provide the heat for the catalytic reaction. Depending on which chemical looping reactor is used to provide the SMR reaction heat, two CLC-SMR schemes can be configured. In Scheme 1 (Fig 2a), the reaction heat is provided by the reducer (fuel reactor). In Scheme 2 (Fig 2b), the reaction heat is provided by the combustor (air reactor). In either scheme, the combustion of metal oxide by air in the chemical looping system provides the heat source that sustains the endothermic SMR reactions. In the chemical looping system, natural gas and the recycled off-gas from the pressure swing adsorption (PSA) of the SMR process system are used as the feedstock for the CLC fuel reactor operation with CO2 and the steam as the reaction products. The CLC-SMR concepts have mainly been studied from the perspective of the process simulation. It is seen that both schemes do not engage directly the chemical looping system as a means for syngas production.

Chemical looping reforming (CLR)

 
Fig 3. CLR using a circulating fluidized bed configuration[17]
 
Fig 4. CLR system with a moving bed reducer[18]

Chemical looping systems can directly be engaged as an effective means for syngas production. Compared to the conventional partial oxidation (POX) or autothermal reforming (ATR) processes, the key advantage of the chemical looping reforming (CLR) process is the elimination of the air separation unit (ASU) for oxygen production. The gaseous fuel, typically natural gas, is fed to the fuel reactor, in which a solid metal oxide oxygen carrier partially oxidizes the fuel to generate syngas:

CH4 + 1δ MeOx → CO + 2H2 + 1δ MeOx-δ

Steam can be added to the reaction in order to increase the generation of H2, via the water-gas shift reaction (WGS) and/or steam methane reforming.

The CLR process can produce a syngas with a H2:CO molar ratio of 2:1 or higher, which is suitable for Fischer–Tropsch synthesis, methanol synthesis, or hydrogen production. The reduced oxygen carrier from the reducer is oxidized by air in the combustor:

2δ MeOx-δ + O2 (air) → 2δ MeOx

The overall reaction in the CLR system is a combination of the partial oxidation reaction of the fuel and the WGS reaction:

CH4 + 1-a/2 O2 + a H2O → CO + (2+a) H2

It is noted that the actual reaction products for such reactions as those given above can vary depending on the actual operating conditions. For example, the CLR reactions can also produce CO2 when highly oxidative oxygen carriers such as NiO and Fe2O3 are used. The carbon deposition occurs particularly when the oxygen carrier is highly reduced. Reduced oxygen carrier species, such as Ni and Fe, catalyze the hydrocarbon pyrolysis reactions.

Fig 3 shows a CLR system that has been studied experimentally by Vienna University of Technology. The system consists of a fluidized bed reducer and a fluidized bed combustor, connected by loop seals and cyclones.[17] Commonly used oxygen carriers are based on NiO or Fe2O3. The NiO-based oxygen carriers exhibit excellent reactivity, as shown by the high conversion of natural gas. The Fe2O3-based oxygen carriers have a lower material cost while their reactivity is lower than that of the NiO-based ones. Operating variables such as temperature, pressure, type of metal oxide, and molar ratio of metal oxide to gaseous fuel will influence the fuel conversion and product compositions. However, with the effects of the back mixing and distributed residence time for the metal oxide particles in the fluidized bed, the oxidation state of the metal oxide particles in the fluidized bed varies that prevents a high purity of the syngas to be produced from the reactor.

The moving bed reactor that does not have the effects of back mixing of the metal oxide particles is another gas-solid contact configuration for CLR/CLG operation.[18] This reactor system developed by Ohio State University is characterized by a co-current gas-solid moving bed reducer as given in Fig 4. The moving bed reducer can maintain the uniform oxidation state of the exit metal oxide particles from the reactor. thereby synchronizing the process operation to achieve the thermodynamic equilibrium conditions.[18][19] The CLR moving bed process applied to the methane to syngas (MTS) reactions has the flexibility of co-feeding CO2 as a feedstock with such gaseous fuels as natural gas, shale gas, and reducing tail gases, yielding a CO2 negative process system.[20][21][22][23][24] The CLR-MTS system can yield a higher energy efficiency and cost benefits over the conventional syngas technologies. In a benchmark study for production of 50,000 barrels per day of liquid fuels using the natural gas as the feedstock, the CLR - MTS system for syngas production can reduce the natural gas usage by 20% over the conventional systems involving the Fischer–Tropsch technology.[20]

Chemical looping gasification (CLG)

Chemical looping gasification (CLG) differs from the CLR in that it uses solid fuels such as coal and biomass instead of gaseous fuels as feedstocks. The operating principles for the CLG is similar to CLR. For solid feedstocks, devolatilization and pyrolysis of the solid fuel occur when the solid fuels are introduced into the reducer and mixed with the oxygen carrier particles. With the fluidized bed reducer, the released volatiles, including light organic compounds and tars, may channel through the reducer and exit with the syngas. The light organic compounds may reduce the purity of the syngas, while the tars may accumulate in downstream pipelines and instruments. For example, the carbon efficiency using the coal CLG fluidized bed reducer may vary from 55% to 81%,[25] whereas the carbon efficiency using the coal moving bed reducer can reach 85% to 98%.[26] The syngas derived from the biomass CLG fluidized bed reducer may consist of up to 15% methane, while the syngas derived from the biomass CLG moving bed reducer can reach a methane concentration of less than 5%.[27] In general, increasing the temperature of the CLG system can promote volatile and char conversion. This may also promote the full oxidation side reaction resulting in an increased CO2 concentration in the syngas. Additional equipment for gas cleanup including scrubber, catalytic steam reformer and/or tar reformer may be necessary downstream of the CLG system in order to remove or convert the unwanted byproducts in the syngas stream. Char, the remaining solid from the devolatilization and reactions, requires additional time for conversion. For a fluidized bed reducer with particle back mixing, unconverted char may leave the reducer with the reduced metal oxide particles. A carbon stripper may be needed at the solid outlet of the fluidized bed reducer to allow the unconverted char to be separated from the oxygen carriers.[28][29] The char can be recycled back to the reducer for further conversion.

 
Fig 5. Chemical looping three-reactor system for hydrogen production[1]

In a similar operating scheme to the CLR - MTS system given in Fig 4, chemical looping gasification (CLG) of solid fuels carried out in a co-current moving bed reducer to partially oxidize solid fuels into syngas can reach an appropriate H2/CO ratio for downstream processing.[26][27] Coal ash is removed through in-situ gas-solid separation operation. The moving bed prevents the channeling or bypassing of the volatiles and chars, thereby maximizing the conversion of the solid fuel. The full oxidation side reactions can be impeded through the control of the oxidation state formed for the oxygen carriers in the moving bed reactor. The CLR moving bed process applied to the coal to syngas (CTS) reactions also has the flexibility of co-feeding CO2 as a feedstock with coal yielding a CO2 negative process system with a high purity of syngas production.[30] In a benchmark study for production of 10,000 ton/day of methanol from coal, the upstream gasification capital cost can be reduced by 50% when the chemical looping moving bed gasification system is used.[31]

Broader context

In a general sense, the CLR and CLG processes for syngas production are part of the chemical looping partial oxidation or selective oxidation reaction schemes. The syngas production can lead to the hydrogen production from the downstream water-gas shift reaction. The CLG process can also be applied to electricity generation, resembling the IGCC based on the syngas generated from the chemical looping processes. The chemical looping three-reactor (including reducer, oxidizer and combustor) system using a moving bed reducer for metal oxide reduction by fuel followed by a moving bed oxidizer for the water splitting to produce hydrogen is given in Fig 5.[1] For coal-based feedstock applications, this system is estimated to reduce the cost for electricity generation by 5-15% as compared to conventional systems.[1]

The selective oxidation based chemical looping processes can be used to produce directly in one step value-added products beyond syngas. These chemical looping processes require the use of designed metal oxide oxygen carrier that has a high product selectivity and a high feedstock conversion. An example is the chemical looping selective oxidation process developed by DuPont for producing maleic anhydride from butane. The oxygen carrier used in this process is vanadium phosphorus oxide (VPO) based material. This chemical looping process was advanced to the commercial level. Its commercial operation, however, was hampered in part by the inadequacies in the chemical and mechanical viability of the oxygen carrier VPO and its associated effects on the reaction kinetics of the particles.[1][32]

Chemical looping selective oxidation was also applied to the production of olefins from methane. In chemical looping oxidative coupling of methane (OCM), the oxygen carrier selectively converts methane into ethylene.[1][33][34]

References

  1. ^ a b c d e f g h i Fan, Liang-Shih (2017). Chemical Looping Partial Oxidation: Gasification, Reforming and Chemical Syntheses. Cambridge University Press. doi:10.1017/9781108157841. ISBN 9781108157841.
  2. ^ Mukherjee, Sanjay; Kumar, Prashant; Yang, Aidong; Fennell, Paul (2015). "Energy and exergy analysis of chemical looping combustion technology and comparison with pre-combustion and oxy-fuel combustion technologies for CO 2 capture". Journal of Environmental Chemical Engineering. 3 (3): 2104–2114. doi:10.1016/j.jece.2015.07.018. ISSN 2213-3437.
  3. ^ a b Luo, Siwei; Zeng, Liang; Fan, Liang-Shih (2015). "Chemical Looping Technology: Oxygen Carrier Characteristics". Annual Review of Chemical and Biomolecular Engineering. 6 (1): 53–75. doi:10.1146/annurev-chembioeng-060713-040334. ISSN 1947-5438. PMID 25898071.
  4. ^ a b Zeng, Liang; Kathe, Mandar V; Chung, Elena Y; Fan, Liang-Shih (2012). "Some remarks on direct solid fuel combustion using chemical looping processes". Current Opinion in Chemical Engineering. 1 (3): 290–295. doi:10.1016/j.coche.2012.05.001. ISSN 2211-3398.
  5. ^ Ellingham, H.J.T. (1944). "Reducibility of Oxides and Sulfides in Metallurgical Processes". Journal of the Society of Chemical Industry. 63: 125–133.
  6. ^ Adánez, J.; de Diego, L. F.; García-Labiano, F.; Gayán, P.; Abad, A.; Palacios, J. M. (2004). "Selection of Oxygen Carriers for Chemical-Looping Combustion". Energy & Fuels. 18 (2): 371–377. doi:10.1021/ef0301452. ISSN 0887-0624.
  7. ^ Galinsky, Nathan L.; Huang, Yan; Shafiefarhood, Arya; Li, Fanxing (2013). "Iron Oxide with Facilitated O2– Transport for Facile Fuel Oxidation and CO2 Capture in a Chemical Looping Scheme". ACS Sustainable Chemistry & Engineering. 1 (3): 364–373. doi:10.1021/sc300177j. ISSN 2168-0485.
  8. ^ Imtiaz, Qasim; Hosseini, Davood; Müller, Christoph Rüdiger (2013). "Review of Oxygen Carriers for Chemical Looping with Oxygen Uncoupling (CLOU): Thermodynamics, Material Development, and Synthesis". Energy Technology. 1 (11): 633–647. doi:10.1002/ente.201300099. ISSN 2194-4288.
  9. ^ Jacobs, Marijke; van der Kolk, Tjalling; Albertsen, Knuth; Mattisson, Tobias; Lyngfelt, Anders; Snijkers, Frans (2018). "Synthesis and upscaling of perovskite Mn-based oxygen carrier by industrial spray drying route". International Journal of Greenhouse Gas Control. 70: 68–75. doi:10.1016/j.ijggc.2018.01.006. ISSN 1750-5836.
  10. ^ Chan, Martin S.C.; Liu, Wen; Ismail, Mohammad; Yang, Yanhui; Scott, Stuart A.; Dennis, John S. (2016). "Improving hydrogen yields, and hydrogen:steam ratio in the chemical looping production of hydrogen using Ca 2 Fe 2 O 5". Chemical Engineering Journal. 296: 406–411. doi:10.1016/j.cej.2016.03.132. ISSN 1385-8947.
  11. ^ Siriwardane, Ranjani; Riley, Jarrett; Bayham, Samuel; Straub, Douglas; Tian, Hanjing; Weber, Justin; Richards, George (2018). "50-kWth methane/air chemical looping combustion tests with commercially prepared CuO-Fe 2 O 3 -alumina oxygen carrier with two different techniques". Applied Energy. 213: 92–99. doi:10.1016/j.apenergy.2018.01.016. ISSN 0306-2619. OSTI 1461079.
  12. ^ Larring, Yngve; Pishahang, Mehdi; Sunding, Martin F.; Tsakalakis, Konstantinos (2015). "Fe–Mn based minerals with remarkable redox characteristics for chemical looping combustion". Fuel. 159: 169–178. doi:10.1016/j.fuel.2015.06.083. ISSN 0016-2361.
  13. ^ Shen, Laihong; Wu, Jiahua; Gao, Zhengping; Xiao, Jun (2009). "Reactivity deterioration of NiO/Al2O3 oxygen carrier for chemical looping combustion of coal in a 10kWth reactor". Combustion and Flame. 156 (7): 1377–1385. doi:10.1016/j.combustflame.2009.02.005. ISSN 0010-2180.
  14. ^ Kim, Jun Young; Ellis, Naoko; Lim, C.Jim; Grace, John R. (2020). "Effect of calcination/carbonation and oxidation/reduction on attrition of binary solid species in sorption-enhanced chemical looping reforming". Fuel. 271: 117665. doi:10.1016/j.fuel.2020.117665. ISSN 0016-2361.
  15. ^ a b Rydén, Magnus; Lyngfelt, Anders (2006). "Using steam reforming to produce hydrogen with carbon dioxide capture by chemical-looping combustion". International Journal of Hydrogen Energy. 31 (10): 1271–1283. doi:10.1016/j.ijhydene.2005.12.003. ISSN 0360-3199.
  16. ^ a b Adanez, Juan; Abad, Alberto; Garcia-Labiano, Francisco; Gayan, Pilar; de Diego, Luis F. (2012). "Progress in Chemical-Looping Combustion and Reforming technologies" (PDF). Progress in Energy and Combustion Science. 38 (2): 215–282. doi:10.1016/j.pecs.2011.09.001. hdl:10261/78793. ISSN 0360-1285.
  17. ^ a b Pröll, Tobias; Kolbitsch, Philipp; Bolhàr-Nordenkampf, Johannes; Hofbauer, Hermann (2009-08-13). "A novel dual circulating fluidized bed system for chemical looping processes". AIChE Journal. 55 (12): 3255–3266. doi:10.1002/aic.11934. ISSN 0001-1541.
  18. ^ a b c Luo, Siwei; Zeng, Liang; Xu, Dikai; Kathe, Mandar; Chung, Elena; Deshpande, Niranjani; Qin, Lang; Majumder, Ankita; Hsieh, Tien-Lin; Tong, Andrew; Sun, Zhenchao; Fan, Liang-Shih (2014-10-07). "Shale gas-to-syngas chemical looping process for stable shale gas conversion to high purity syngas with a H2 : CO ratio of 2 : 1". Energy Environ. Sci. 7 (12): 4104–4117. doi:10.1039/c4ee02892a. ISSN 1754-5692.
  19. ^ Fan, Liang-Shih; Zeng, Liang; Luo, Siwei (2014-12-04). "Chemical-looping technology platform". AIChE Journal. 61 (1): 2–22. doi:10.1002/aic.14695. ISSN 0001-1541.
  20. ^ a b Kathe, Mandar; Fryer, Charles; Sandvik, Peter; Kong, Fanhe; Zhang, Yitao; Empfield, Abbey; Fan, Liang-Shih (2017-03-18). "Modularization strategy for syngas generation in chemical looping methane reforming systems with CO2 as feedstock". AIChE Journal. 63 (8): 3343–3360. doi:10.1002/aic.15692. ISSN 0001-1541.
  21. ^ Pang, Yean Ling; Lim, Steven; Ong, Hwai Chyuan; Chong, Wen Tong (2016). "Research progress on iron oxide-based magnetic materials: Synthesis techniques and photocatalytic applications". Ceramics International. 42 (1): 9–34. doi:10.1016/j.ceramint.2015.08.144. ISSN 0272-8842.
  22. ^ Qin, Lang; Cheng, Zhuo; Fan, Jonathan A.; Kopechek, David; Xu, Dikai; Deshpande, Niranjani; Fan, Liang-Shih (2015). "Nanostructure formation mechanism and ion diffusion in iron–titanium composite materials with chemical looping redox reactions". Journal of Materials Chemistry A. 3 (21): 11302–11312. doi:10.1039/c5ta01853f. ISSN 2050-7488.
  23. ^ Qin, Lang; Majumder, Ankita; Fan, Jonathan A.; Kopechek, David; Fan, Liang-Shih (2014). "Evolution of nanoscale morphology in single and binary metal oxide microparticles during reduction and oxidation processes". J. Mater. Chem. A. 2 (41): 17511–17520. doi:10.1039/c4ta04338c. ISSN 2050-7488.
  24. ^ Chung, Cheng; Qin, Lang; Shah, Vedant; Fan, Liang-Shih (2017). "Chemically and physically robust, commercially-viable iron-based composite oxygen carriers sustainable over 3000 redox cycles at high temperatures for chemical looping applications". Energy & Environmental Science. 10 (11): 2318–2323. doi:10.1039/c7ee02657a. ISSN 1754-5692.
  25. ^ Guo, Qingjie; Cheng, Yu; Liu, Yongzhuo; Jia, Weihua; Ryu, Ho-Jung (2013-12-10). "Coal Chemical Looping Gasification for Syngas Generation Using an Iron-Based Oxygen Carrier". Industrial & Engineering Chemistry Research. 53 (1): 78–86. doi:10.1021/ie401568x. ISSN 0888-5885.
  26. ^ a b Hsieh, Tien-Lin; Zhang, Yitao; Xu, Dikai; Wang, Chenghao; Pickarts, Marshall; Chung, Cheng; Fan, Liang-Shih; Tong, Andrew (2018-02-09). "Chemical Looping Gasification for Producing High Purity, H2-Rich Syngas in a Cocurrent Moving Bed Reducer with Coal and Methane Cofeeds". Industrial & Engineering Chemistry Research. 57 (7): 2461–2475. doi:10.1021/acs.iecr.7b04204. ISSN 0888-5885.
  27. ^ a b Xu, Dikai; Zhang, Yitao; Hsieh, Tien-Lin; Guo, Mengqing; Qin, Lang; Chung, Cheng; Fan, Liang-Shih; Tong, Andrew (2018). "A novel chemical looping partial oxidation process for thermochemical conversion of biomass to syngas". Applied Energy. 222: 119–131. doi:10.1016/j.apenergy.2018.03.130. ISSN 0306-2619.
  28. ^ Ströhle, Jochen; Orth, Matthias; Epple, Bernd (2014). "Design and operation of a 1MWth chemical looping plant". Applied Energy. 113: 1490–1495. doi:10.1016/j.apenergy.2013.09.008. ISSN 0306-2619.
  29. ^ Kramp, M.; Thon, A.; Hartge, E.-U.; Heinrich, S.; Werther, J. (2012-01-30). "Carbon Stripping - A Critical Process Step in Chemical Looping Combustion of Solid Fuels". Chemical Engineering & Technology. 35 (3): 497–507. doi:10.1002/ceat.201100438. ISSN 0930-7516.
  30. ^ Kathe, Mandar; Sandvik, Peter; Fryer, Charles; Kong, Fanhe; Zhang, Yitao; Grigonis, Gabrielle; Fan, Liang-Shih (2018-01-12). "Coal Refining Chemical Looping Systems with CO2 as a Co-Feedstock for Chemical Syntheses". Energy & Fuels. 32 (2): 1139–1154. doi:10.1021/acs.energyfuels.7b02742. ISSN 0887-0624.
  31. ^ Kathe, Mandar; Xu, Dikai; Hsieh, Tien-Lin; Simpson, James; Statnick, Robert; Tong, Andrew; Fan, Liang-Shih (2015). Chemical Looping Gasification for Hydrogen Enhanced Syngas Production with In-Situ CO2 Capture (Technical report). The Ohio State University.
  32. ^ Contractor, R.M.; Garnett, D.I.; Horowitz, H.S.; Bergna, H.E.; Patience, G.S.; Schwartz, J.T.; Sisler, G.M. (1994), "A New Commercial Scale Process for n-Butane Oxidation to Maleic Anhydride Using a Circulating Fluidized Bed Reactor", in V. Cortés Corberán; S. Vic Bellón (eds.), New Developments in Selective Oxidation II, Proceedings of the Second World Congress and Fourth European Workshop Meeting, Elsevier, pp. 233–242, doi:10.1016/s0167-2991(08)63415-1, ISBN 9780444815521
  33. ^ Chung, Elena Y.; Wang, William K.; Nadgouda, Sourabh G.; Baser, Deven S.; Sofranko, John A.; Fan, Liang-Shih (2016-12-06). "Catalytic Oxygen Carriers and Process Systems for Oxidative Coupling of Methane Using the Chemical Looping Technology". Industrial & Engineering Chemistry Research. 55 (50): 12750–12764. doi:10.1021/acs.iecr.6b03304. ISSN 0888-5885.
  34. ^ Fleischer, Vinzenz; Littlewood, Patrick; Parishan, Samira; Schomäcker, Reinhard (2016). "Chemical looping as reactor concept for the oxidative coupling of methane over a Na 2 WO 4 /Mn/SiO 2 catalyst". Chemical Engineering Journal. 306: 646–654. doi:10.1016/j.cej.2016.07.094. ISSN 1385-8947.

January 06, 2023
chemical, looping, reforming, gasification, chemical, looping, reforming, gasification, operations, that, involve, gaseous, carbonaceous, feedstock, solid, carbonaceous, feedstock, respectively, their, conversion, syngas, chemical, looping, scheme, typical, ga. Chemical looping reforming CLR and gasification CLG are the operations that involve the use of gaseous carbonaceous feedstock and solid carbonaceous feedstock respectively in their conversion to syngas in the chemical looping scheme 1 The typical gaseous carbonaceous feedstocks used are natural gas and reducing tail gas while the typical solid carbonaceous feedstocks used are coal and biomass The feedstocks are partially oxidized to generate syngas using metal oxide oxygen carriers as the oxidant The reduced metal oxide is then oxidized in the regeneration step using air The syngas is an important intermediate for generation of such diverse products as electricity chemicals hydrogen and liquid fuels The motivation for developing the CLR and CLG processes lies in their advantages of being able to avoid the use of pure oxygen in the reaction thereby circumventing the energy intensive air separation requirement in the conventional reforming and gasification processes The energy conversion efficiency of the processes can thus be significantly increased Steam and carbon dioxide can also be used as the oxidants As the metal oxide also serves as the heat transfer medium in the chemical looping process the exergy efficiency of the reforming and gasification processes like that for the combustion process is also higher as compared to the conventional processes 1 2 Contents 1 Description 2 Oxygen carriers 3 Process configurations 3 1 Steam methane reforming with chemical looping combustion CLC SMR 3 2 Chemical looping reforming CLR 3 3 Chemical looping gasification CLG 4 Broader context 5 ReferencesDescription EditThe CLR and CLG processes use solid metal oxides as the oxygen carrier instead of pure oxygen as the oxidant In one reactor termed the reducer or fuel reactor the carbonaceous feedstock is partially oxidized to syngas while the metal oxide is reduced to a lower oxidation state as given by CHaOb 1 b d MeOx CO a 2 H2 1 b d MeOx dwhere Me is a metal It is noted that the reaction in the reducer of the CLR and CLG processes differs from that in the chemical looping combustion CLC process in that the feedstock in CLC process is fully oxidized to CO2 and H2O In another reactor termed the oxidizer combustor or air reactor when air is used as the regeneration agent the reduced metal oxide from the reducer is re oxidized by air or steam as given by 2 d MeOx d O2 air 2 d MeOx O2 depleted air 1 d MeOx d H2O 1 d MeOx H2The solid metal oxide oxygen carrier is then circulated between these two reactors That is the reducer and the oxidizer combustor are connected in a solids circulatory loop while the gaseous reactants and products from each of the two reactors are isolated by the gas seals between the reactors This streamlining configuration of the chemical looping system possesses a process intensification property with a smaller process footprint as compared to that for the traditional systems Oxygen carriers Edit Fig 1 Modified Ellingham diagram a to determine metal oxide performance in chemical looping processes b with sections indicated for chemical looping applications 3 4 The Ellingham diagram that provides the Gibbs free energy formation of a variety of metal oxides is widely used in metallurgical processing for determining the relative reduction oxidation potentials of metal oxides at different temperatures 5 It depicts the thermodynamic property of a variety of metal oxides to be used as potential oxygen carrier materials It can be modified to provide the Gibbs free energy changes for metals and metal oxides under various oxidation states so that it can be directly used for the selection of metal oxide oxygen carrier materials based on their oxidation capabilities for specific chemical looping applications 1 3 4 The modified Ellingham diagram is given in Fig 1a As shown in Fig 1b the diagram can be divided into four different sections based on the following four key reactions Reaction line 1 2CO O2 2CO2 Reaction line 2 2H2 O2 2H2O Reaction line 3 2C O2 2CO Reaction line 4 2CH4 O2 2CO 4H2The sections identified in Fig 1b provide the information on metal oxide materials that can be selected as potential oxygen carriers for desired chemical looping applications Specifically highly oxidative metal oxides such as NiO CoO CuO Fe2O3 and Fe3O4 belong to the combustion section Section A and they all lie above the reaction lines 1 and 2 These metal oxides have a high oxidizing tendency and can be used as oxygen carriers for the chemical looping combustion gasification or partial oxidation processes The metal oxides in Section E the small section between the reaction lines 1 and 2 can be used for CLR and CLG although a significant amount of H2O may present in the syngas product The section for syngas production lies between reaction lines 2 and 3 Section B Metal oxides lying in this region such as CeO2 have moderate oxidation tendencies and are suitable for CLR and CLG but not for the complete oxidation reactions Metal oxides below reaction line 3 Sections C and D are not thermodynamically favored for oxidizing the fuels to syngas Thus they cannot be used as oxygen carriers and are generally considered to be inert These materials include Cr2O3 and SiO2 They can however be used as support materials along with active oxygen carrier materials In addition to the relative redox potentials of metal oxide materials illustrated in Fig 1b the development of desired oxygen carriers for chemical looping applications requires to consider such properties as oxygen carrying capacity redox reactivity reaction kinetics recyclability attrition resistance heat carrying capacity melting point and production cost 1 6 7 8 9 10 11 12 13 14 Process configurations EditThe CLR and CLG processes can be configured based on the types of carbonaceous feedstocks given and desired products to be produced Among a broad range of products the CLG process can produce electricity through chemical looping IGCC The syngas produced from the CLR and the CLG can be used to synthesize a variety of chemicals liquid fuels and hydrogen Given below are some specific examples of the CLR and CLG processes Steam methane reforming with chemical looping combustion CLC SMR Edit Fig 2 CLC SMR system for H2 production a SMR reactor inside the reducer fuel reactor b SMR reactor inside the combustor air reactor 15 16 Hydrogen and syngas are currently produced largely by steam methane reforming SMR The main reaction in SMR is CH4 H2O CO 3H2Steam can be further used to convert CO to H2 via the water gas shift reaction WGS H2O CO CO2 H2The SMR reaction is endothermic which requires heat input The state of art SMR system places the tubular catalytic reactors in a furnace in which fuel gas is burned to provide the required heat In the SMR with chemical looping combustion CLC SMR concepts shown in Fig 2 15 16 the syngas production is carried out by the SMR in a tubular catalytic reactor while the chemical looping combustion system is used to provide the heat for the catalytic reaction Depending on which chemical looping reactor is used to provide the SMR reaction heat two CLC SMR schemes can be configured In Scheme 1 Fig 2a the reaction heat is provided by the reducer fuel reactor In Scheme 2 Fig 2b the reaction heat is provided by the combustor air reactor In either scheme the combustion of metal oxide by air in the chemical looping system provides the heat source that sustains the endothermic SMR reactions In the chemical looping system natural gas and the recycled off gas from the pressure swing adsorption PSA of the SMR process system are used as the feedstock for the CLC fuel reactor operation with CO2 and the steam as the reaction products The CLC SMR concepts have mainly been studied from the perspective of the process simulation It is seen that both schemes do not engage directly the chemical looping system as a means for syngas production Chemical looping reforming CLR Edit Fig 3 CLR using a circulating fluidized bed configuration 17 Fig 4 CLR system with a moving bed reducer 18 Chemical looping systems can directly be engaged as an effective means for syngas production Compared to the conventional partial oxidation POX or autothermal reforming ATR processes the key advantage of the chemical looping reforming CLR process is the elimination of the air separation unit ASU for oxygen production The gaseous fuel typically natural gas is fed to the fuel reactor in which a solid metal oxide oxygen carrier partially oxidizes the fuel to generate syngas CH4 1 d MeOx CO 2H2 1 d MeOx dSteam can be added to the reaction in order to increase the generation of H2 via the water gas shift reaction WGS and or steam methane reforming The CLR process can produce a syngas with a H2 CO molar ratio of 2 1 or higher which is suitable for Fischer Tropsch synthesis methanol synthesis or hydrogen production The reduced oxygen carrier from the reducer is oxidized by air in the combustor 2 d MeOx d O2 air 2 d MeOxThe overall reaction in the CLR system is a combination of the partial oxidation reaction of the fuel and the WGS reaction CH4 1 a 2 O2 a H2O CO 2 a H2It is noted that the actual reaction products for such reactions as those given above can vary depending on the actual operating conditions For example the CLR reactions can also produce CO2 when highly oxidative oxygen carriers such as NiO and Fe2O3 are used The carbon deposition occurs particularly when the oxygen carrier is highly reduced Reduced oxygen carrier species such as Ni and Fe catalyze the hydrocarbon pyrolysis reactions Fig 3 shows a CLR system that has been studied experimentally by Vienna University of Technology The system consists of a fluidized bed reducer and a fluidized bed combustor connected by loop seals and cyclones 17 Commonly used oxygen carriers are based on NiO or Fe2O3 The NiO based oxygen carriers exhibit excellent reactivity as shown by the high conversion of natural gas The Fe2O3 based oxygen carriers have a lower material cost while their reactivity is lower than that of the NiO based ones Operating variables such as temperature pressure type of metal oxide and molar ratio of metal oxide to gaseous fuel will influence the fuel conversion and product compositions However with the effects of the back mixing and distributed residence time for the metal oxide particles in the fluidized bed the oxidation state of the metal oxide particles in the fluidized bed varies that prevents a high purity of the syngas to be produced from the reactor The moving bed reactor that does not have the effects of back mixing of the metal oxide particles is another gas solid contact configuration for CLR CLG operation 18 This reactor system developed by Ohio State University is characterized by a co current gas solid moving bed reducer as given in Fig 4 The moving bed reducer can maintain the uniform oxidation state of the exit metal oxide particles from the reactor thereby synchronizing the process operation to achieve the thermodynamic equilibrium conditions 18 19 The CLR moving bed process applied to the methane to syngas MTS reactions has the flexibility of co feeding CO2 as a feedstock with such gaseous fuels as natural gas shale gas and reducing tail gases yielding a CO2 negative process system 20 21 22 23 24 The CLR MTS system can yield a higher energy efficiency and cost benefits over the conventional syngas technologies In a benchmark study for production of 50 000 barrels per day of liquid fuels using the natural gas as the feedstock the CLR MTS system for syngas production can reduce the natural gas usage by 20 over the conventional systems involving the Fischer Tropsch technology 20 Chemical looping gasification CLG Edit Chemical looping gasification CLG differs from the CLR in that it uses solid fuels such as coal and biomass instead of gaseous fuels as feedstocks The operating principles for the CLG is similar to CLR For solid feedstocks devolatilization and pyrolysis of the solid fuel occur when the solid fuels are introduced into the reducer and mixed with the oxygen carrier particles With the fluidized bed reducer the released volatiles including light organic compounds and tars may channel through the reducer and exit with the syngas The light organic compounds may reduce the purity of the syngas while the tars may accumulate in downstream pipelines and instruments For example the carbon efficiency using the coal CLG fluidized bed reducer may vary from 55 to 81 25 whereas the carbon efficiency using the coal moving bed reducer can reach 85 to 98 26 The syngas derived from the biomass CLG fluidized bed reducer may consist of up to 15 methane while the syngas derived from the biomass CLG moving bed reducer can reach a methane concentration of less than 5 27 In general increasing the temperature of the CLG system can promote volatile and char conversion This may also promote the full oxidation side reaction resulting in an increased CO2 concentration in the syngas Additional equipment for gas cleanup including scrubber catalytic steam reformer and or tar reformer may be necessary downstream of the CLG system in order to remove or convert the unwanted byproducts in the syngas stream Char the remaining solid from the devolatilization and reactions requires additional time for conversion For a fluidized bed reducer with particle back mixing unconverted char may leave the reducer with the reduced metal oxide particles A carbon stripper may be needed at the solid outlet of the fluidized bed reducer to allow the unconverted char to be separated from the oxygen carriers 28 29 The char can be recycled back to the reducer for further conversion Fig 5 Chemical looping three reactor system for hydrogen production 1 In a similar operating scheme to the CLR MTS system given in Fig 4 chemical looping gasification CLG of solid fuels carried out in a co current moving bed reducer to partially oxidize solid fuels into syngas can reach an appropriate H2 CO ratio for downstream processing 26 27 Coal ash is removed through in situ gas solid separation operation The moving bed prevents the channeling or bypassing of the volatiles and chars thereby maximizing the conversion of the solid fuel The full oxidation side reactions can be impeded through the control of the oxidation state formed for the oxygen carriers in the moving bed reactor The CLR moving bed process applied to the coal to syngas CTS reactions also has the flexibility of co feeding CO2 as a feedstock with coal yielding a CO2 negative process system with a high purity of syngas production 30 In a benchmark study for production of 10 000 ton day of methanol from coal the upstream gasification capital cost can be reduced by 50 when the chemical looping moving bed gasification system is used 31 Broader context EditIn a general sense the CLR and CLG processes for syngas production are part of the chemical looping partial oxidation or selective oxidation reaction schemes The syngas production can lead to the hydrogen production from the downstream water gas shift reaction The CLG process can also be applied to electricity generation resembling the IGCC based on the syngas generated from the chemical looping processes The chemical looping three reactor including reducer oxidizer and combustor system using a moving bed reducer for metal oxide reduction by fuel followed by a moving bed oxidizer for the water splitting to produce hydrogen is given in Fig 5 1 For coal based feedstock applications this system is estimated to reduce the cost for electricity generation by 5 15 as compared to conventional systems 1 The selective oxidation based chemical looping processes can be used to produce directly in one step value added products beyond syngas These chemical looping processes require the use of designed metal oxide oxygen carrier that has a high product selectivity and a high feedstock conversion An example is the chemical looping selective oxidation process developed by DuPont for producing maleic anhydride from butane The oxygen carrier used in this process is vanadium phosphorus oxide VPO based material This chemical looping process was advanced to the commercial level Its commercial operation however was hampered in part by the inadequacies in the chemical and mechanical viability of the oxygen carrier VPO and its associated effects on the reaction kinetics of the particles 1 32 Chemical looping selective oxidation was also applied to the production of olefins from methane In chemical looping oxidative coupling of methane OCM the oxygen carrier selectively converts methane into ethylene 1 33 34 References Edit a b c d e f g h i Fan Liang Shih 2017 Chemical Looping Partial Oxidation Gasification Reforming and Chemical Syntheses Cambridge University Press doi 10 1017 9781108157841 ISBN 9781108157841 Mukherjee Sanjay Kumar Prashant Yang Aidong Fennell Paul 2015 Energy and exergy analysis of chemical looping combustion technology and comparison with pre combustion and oxy fuel combustion technologies for CO 2 capture Journal of Environmental Chemical Engineering 3 3 2104 2114 doi 10 1016 j jece 2015 07 018 ISSN 2213 3437 a b Luo Siwei Zeng Liang Fan Liang Shih 2015 Chemical Looping Technology Oxygen Carrier Characteristics Annual Review of Chemical and Biomolecular Engineering 6 1 53 75 doi 10 1146 annurev chembioeng 060713 040334 ISSN 1947 5438 PMID 25898071 a b Zeng Liang Kathe Mandar V Chung Elena Y Fan Liang Shih 2012 Some remarks on direct solid fuel combustion using chemical looping processes Current Opinion in Chemical Engineering 1 3 290 295 doi 10 1016 j coche 2012 05 001 ISSN 2211 3398 Ellingham H J T 1944 Reducibility of Oxides and Sulfides in Metallurgical Processes Journal of the Society of Chemical Industry 63 125 133 Adanez J de Diego L F Garcia Labiano F Gayan P Abad A Palacios J M 2004 Selection of Oxygen Carriers for Chemical Looping Combustion Energy amp Fuels 18 2 371 377 doi 10 1021 ef0301452 ISSN 0887 0624 Galinsky Nathan L Huang Yan Shafiefarhood Arya Li Fanxing 2013 Iron Oxide with Facilitated O2 Transport for Facile Fuel Oxidation and CO2 Capture in a Chemical Looping Scheme ACS Sustainable Chemistry amp Engineering 1 3 364 373 doi 10 1021 sc300177j ISSN 2168 0485 Imtiaz Qasim Hosseini Davood Muller Christoph Rudiger 2013 Review of Oxygen Carriers for Chemical Looping with Oxygen Uncoupling CLOU Thermodynamics Material Development and Synthesis Energy Technology 1 11 633 647 doi 10 1002 ente 201300099 ISSN 2194 4288 Jacobs Marijke van der Kolk Tjalling Albertsen Knuth Mattisson Tobias Lyngfelt Anders Snijkers Frans 2018 Synthesis and upscaling of perovskite Mn based oxygen carrier by industrial spray drying route International Journal of Greenhouse Gas Control 70 68 75 doi 10 1016 j ijggc 2018 01 006 ISSN 1750 5836 Chan Martin S C Liu Wen Ismail Mohammad Yang Yanhui Scott Stuart A Dennis John S 2016 Improving hydrogen yields and hydrogen steam ratio in the chemical looping production of hydrogen using Ca 2 Fe 2 O 5 Chemical Engineering Journal 296 406 411 doi 10 1016 j cej 2016 03 132 ISSN 1385 8947 Siriwardane Ranjani Riley Jarrett Bayham Samuel Straub Douglas Tian Hanjing Weber Justin Richards George 2018 50 kWth methane air chemical looping combustion tests with commercially prepared CuO Fe 2 O 3 alumina oxygen carrier with two different techniques Applied Energy 213 92 99 doi 10 1016 j apenergy 2018 01 016 ISSN 0306 2619 OSTI 1461079 Larring Yngve Pishahang Mehdi Sunding Martin F Tsakalakis Konstantinos 2015 Fe Mn based minerals with remarkable redox characteristics for chemical looping combustion Fuel 159 169 178 doi 10 1016 j fuel 2015 06 083 ISSN 0016 2361 Shen Laihong Wu Jiahua Gao Zhengping Xiao Jun 2009 Reactivity deterioration of NiO Al2O3 oxygen carrier for chemical looping combustion of coal in a 10kWth reactor Combustion and Flame 156 7 1377 1385 doi 10 1016 j combustflame 2009 02 005 ISSN 0010 2180 Kim Jun Young Ellis Naoko Lim C Jim Grace John R 2020 Effect of calcination carbonation and oxidation reduction on attrition of binary solid species in sorption enhanced chemical looping reforming Fuel 271 117665 doi 10 1016 j fuel 2020 117665 ISSN 0016 2361 a b Ryden Magnus Lyngfelt Anders 2006 Using steam reforming to produce hydrogen with carbon dioxide capture by chemical looping combustion International Journal of Hydrogen Energy 31 10 1271 1283 doi 10 1016 j ijhydene 2005 12 003 ISSN 0360 3199 a b Adanez Juan Abad Alberto Garcia Labiano Francisco Gayan Pilar de Diego Luis F 2012 Progress in Chemical Looping Combustion and Reforming technologies PDF Progress in Energy and Combustion Science 38 2 215 282 doi 10 1016 j pecs 2011 09 001 hdl 10261 78793 ISSN 0360 1285 a b Proll Tobias Kolbitsch Philipp Bolhar Nordenkampf Johannes Hofbauer Hermann 2009 08 13 A novel dual circulating fluidized bed system for chemical looping processes AIChE Journal 55 12 3255 3266 doi 10 1002 aic 11934 ISSN 0001 1541 a b c Luo Siwei Zeng Liang Xu Dikai Kathe Mandar Chung Elena Deshpande Niranjani Qin Lang Majumder Ankita Hsieh Tien Lin Tong Andrew Sun Zhenchao Fan Liang Shih 2014 10 07 Shale gas to syngas chemical looping process for stable shale gas conversion to high purity syngas with a H2 CO ratio of 2 1 Energy Environ Sci 7 12 4104 4117 doi 10 1039 c4ee02892a ISSN 1754 5692 Fan Liang Shih Zeng Liang Luo Siwei 2014 12 04 Chemical looping technology platform AIChE Journal 61 1 2 22 doi 10 1002 aic 14695 ISSN 0001 1541 a b Kathe Mandar Fryer Charles Sandvik Peter Kong Fanhe Zhang Yitao Empfield Abbey Fan Liang Shih 2017 03 18 Modularization strategy for syngas generation in chemical looping methane reforming systems with CO2 as feedstock AIChE Journal 63 8 3343 3360 doi 10 1002 aic 15692 ISSN 0001 1541 Pang Yean Ling Lim Steven Ong Hwai Chyuan Chong Wen Tong 2016 Research progress on iron oxide based magnetic materials Synthesis techniques and photocatalytic applications Ceramics International 42 1 9 34 doi 10 1016 j ceramint 2015 08 144 ISSN 0272 8842 Qin Lang Cheng Zhuo Fan Jonathan A Kopechek David Xu Dikai Deshpande Niranjani Fan Liang Shih 2015 Nanostructure formation mechanism and ion diffusion in iron titanium composite materials with chemical looping redox reactions Journal of Materials Chemistry A 3 21 11302 11312 doi 10 1039 c5ta01853f ISSN 2050 7488 Qin Lang Majumder Ankita Fan Jonathan A Kopechek David Fan Liang Shih 2014 Evolution of nanoscale morphology in single and binary metal oxide microparticles during reduction and oxidation processes J Mater Chem A 2 41 17511 17520 doi 10 1039 c4ta04338c ISSN 2050 7488 Chung Cheng Qin Lang Shah Vedant Fan Liang Shih 2017 Chemically and physically robust commercially viable iron based composite oxygen carriers sustainable over 3000 redox cycles at high temperatures for chemical looping applications Energy amp Environmental Science 10 11 2318 2323 doi 10 1039 c7ee02657a ISSN 1754 5692 Guo Qingjie Cheng Yu Liu Yongzhuo Jia Weihua Ryu Ho Jung 2013 12 10 Coal Chemical Looping Gasification for Syngas Generation Using an Iron Based Oxygen Carrier Industrial amp Engineering Chemistry Research 53 1 78 86 doi 10 1021 ie401568x ISSN 0888 5885 a b Hsieh Tien Lin Zhang Yitao Xu Dikai Wang Chenghao Pickarts Marshall Chung Cheng Fan Liang Shih Tong Andrew 2018 02 09 Chemical Looping Gasification for Producing High Purity H2 Rich Syngas in a Cocurrent Moving Bed Reducer with Coal and Methane Cofeeds Industrial amp Engineering Chemistry Research 57 7 2461 2475 doi 10 1021 acs iecr 7b04204 ISSN 0888 5885 a b Xu Dikai Zhang Yitao Hsieh Tien Lin Guo Mengqing Qin Lang Chung Cheng Fan Liang Shih Tong Andrew 2018 A novel chemical looping partial oxidation process for thermochemical conversion of biomass to syngas Applied Energy 222 119 131 doi 10 1016 j apenergy 2018 03 130 ISSN 0306 2619 Strohle Jochen Orth Matthias Epple Bernd 2014 Design and operation of a 1MWth chemical looping plant Applied Energy 113 1490 1495 doi 10 1016 j apenergy 2013 09 008 ISSN 0306 2619 Kramp M Thon A Hartge E U Heinrich S Werther J 2012 01 30 Carbon Stripping A Critical Process Step in Chemical Looping Combustion of Solid Fuels Chemical Engineering amp Technology 35 3 497 507 doi 10 1002 ceat 201100438 ISSN 0930 7516 Kathe Mandar Sandvik Peter Fryer Charles Kong Fanhe Zhang Yitao Grigonis Gabrielle Fan Liang Shih 2018 01 12 Coal Refining Chemical Looping Systems with CO2 as a Co Feedstock for Chemical Syntheses Energy amp Fuels 32 2 1139 1154 doi 10 1021 acs energyfuels 7b02742 ISSN 0887 0624 Kathe Mandar Xu Dikai Hsieh Tien Lin Simpson James Statnick Robert Tong Andrew Fan Liang Shih 2015 Chemical Looping Gasification for Hydrogen Enhanced Syngas Production with In Situ CO2 Capture Technical report The Ohio State University Contractor R M Garnett D I Horowitz H S Bergna H E Patience G S Schwartz J T Sisler G M 1994 A New Commercial Scale Process for n Butane Oxidation to Maleic Anhydride Using a Circulating Fluidized Bed Reactor in V Cortes Corberan S Vic Bellon eds New Developments in Selective Oxidation II Proceedings of the Second World Congress and Fourth European Workshop Meeting Elsevier pp 233 242 doi 10 1016 s0167 2991 08 63415 1 ISBN 9780444815521 Chung Elena Y Wang William K Nadgouda Sourabh G Baser Deven S Sofranko John A Fan Liang Shih 2016 12 06 Catalytic Oxygen Carriers and Process Systems for Oxidative Coupling of Methane Using the Chemical Looping Technology Industrial amp Engineering Chemistry Research 55 50 12750 12764 doi 10 1021 acs iecr 6b03304 ISSN 0888 5885 Fleischer Vinzenz Littlewood Patrick Parishan Samira Schomacker Reinhard 2016 Chemical looping as reactor concept for the oxidative coupling of methane over a Na 2 WO 4 Mn SiO 2 catalyst Chemical Engineering Journal 306 646 654 doi 10 1016 j cej 2016 07 094 ISSN 1385 8947 Retrieved from https en wikipedia org w index php title Chemical looping reforming and gasification amp oldid 1028597120, wikipedia, wiki, book, books, library,

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