Co-firing of coal and biomass in oxy-fuel fluidized bed for CO2 capture: A review of recent advances

doi:10.1016/j.cjche.2019.07.013

摘要/Abstract

摘要： The co-firing of coal and biomass in oxy-fuel fluidized beds is one of the most promising technologies for capturing CO₂. This technology has attracted wide attention from academia and industry in recent years as a negative emission method to capture CO₂ produced by carbon contained in biomass. In the past decades, many studies have been carried out regarding experiments and numerical simulations under oxy-fuel combustion conditions. This paper firstly briefly discusses the techno-economic viability of the biomass and coal co-firing with oxycombustion and then presents a review of recent advancements involving experimental research and computational fluid dynamics (CFD) simulations in this field. Experimental studies on mechanism research, such as thermogravimetric analysis and tube furnace experiments, and fluidized bed experiments based on oxy-fuel fluidized beds with different sizes as well as the main findings, are summarized as a part of this review. It has been recognized that CFD is a useful approach for understanding the behaviors of the co-firing of coal and biomass in oxyfuel fluidized beds. We summarize a recent survey of published CFD research on oxy-fuel fluidized bed combustion, which categorized into Eulerian and Lagrangian methods. Finally, we discuss the challenges and interests for future research.

关键词: Oxy-fuel combustion, Co-firing of coal and biomass, Oxy-fuel fluidized bed, CFD simulation

Abstract: The co-firing of coal and biomass in oxy-fuel fluidized beds is one of the most promising technologies for capturing CO₂. This technology has attracted wide attention from academia and industry in recent years as a negative emission method to capture CO₂ produced by carbon contained in biomass. In the past decades, many studies have been carried out regarding experiments and numerical simulations under oxy-fuel combustion conditions. This paper firstly briefly discusses the techno-economic viability of the biomass and coal co-firing with oxycombustion and then presents a review of recent advancements involving experimental research and computational fluid dynamics (CFD) simulations in this field. Experimental studies on mechanism research, such as thermogravimetric analysis and tube furnace experiments, and fluidized bed experiments based on oxy-fuel fluidized beds with different sizes as well as the main findings, are summarized as a part of this review. It has been recognized that CFD is a useful approach for understanding the behaviors of the co-firing of coal and biomass in oxyfuel fluidized beds. We summarize a recent survey of published CFD research on oxy-fuel fluidized bed combustion, which categorized into Eulerian and Lagrangian methods. Finally, we discuss the challenges and interests for future research.

Key words: Oxy-fuel combustion, Co-firing of coal and biomass, Oxy-fuel fluidized bed, CFD simulation

Qinwen Liu, Yan Shi, Wenqi Zhong, Aibing Yu. Co-firing of coal and biomass in oxy-fuel fluidized bed for CO₂ capture: A review of recent advances[J]. 中国化学工程学报, 2019, 27(10): 2261-2272.

Qinwen Liu, Yan Shi, Wenqi Zhong, Aibing Yu. Co-firing of coal and biomass in oxy-fuel fluidized bed for CO₂ capture: A review of recent advances[J]. Chinese Journal of Chemical Engineering, 2019, 27(10): 2261-2272.

参考文献

[1] E.S. Rubin, H. Mantripragada, A. Marks, et al., The outlook for improved carbon capture technology, Prog. Energy Combust. Sci. 38(5) (2012) 630-671.
[2] C. Zheng, Y. Zhao, X. Guo, Research and development of oxy-fuel combustion in China, Proceedings of the CSEE 34(23) (2014) 3856-3864.
[3] T. Wall, R. Stanger, S. Santos, Demonstrations of coal-fired oxy-fuel technology for carbon capture and storage and issues with commercial deployment, International journal of greenhouse gas control 5(1) (2011) 5-15.
[4] G. Scheffknecht, L. Al-Makhadmeh, U. Schnell, et al., Oxy-fuel coal combustion-a review of the current state-of-the-art, International Journal of Greenhouse Gas Control 5(1) (2011) 16-35.
[5] Y. Zhuang, J.H. Pavlish, Fate of hazardous air pollutants in oxygen-fired coal combustion with different flue gas recycling, Environmental science & technology 46(8) (2012) 4657-4665.
[6] T.F. Wall, Combustion processes for carbon capture, Proc. Combust. Inst. 31(1) (2007) 31-47.
[7] B. Leckner, A. Gómez-Barea, Oxy-fuel combustion in circulating fluidized bed boilers, Appl. Energy 125(15) (2014) 308-318.
[8] R.I. Singh, R. Kumar, Current status and experimental investigation of oxy-fired fluidized bed, Renew. Sust. Energ. Rev. 61(2016) 398-420.
[9] Q. Yi, Y.J. Zhao, Y. Huang, et al., Life cycle energy-economic-CO₂, emissions evaluation of biomass/coal, with and without CO₂, capture and storage, in a pulverized fuel combustion power plant in the United Kingdom, Appl. Energy 225(2018) 258-272.
[10] Q. Liu, W. Zhong, X. Liu, et al., CO₂ enrichment characteristics of coal/biomass fluidized oxy-fuel combustion, CIESC Journal 69(12) (2018) 5199-5208.
[11] T. Wall, Y. Liu, S. Bhattacharya, A Scoping Study on Oxy-CFB Technology as an Alternative Carbon Capture Option for Australian Black and Brown Coals, Monash University, ANLEC R&D, 2012.
[12] T. Lockwood, Techno-economic analysis of PC versus CFB combustion technology, IEA Clean Coal Centre, Report CCC/226, London, UK, 2013.
[13] L. Jia, Y. Tan, D. McCalden, et al., Commissioning of a 0.8 MWth CFBC for oxy-fuel combustion, International Journal of Greenhouse Gas Control 7(2012) 240-243.
[14] Y. Tan, L. Jia, Y. Wu, et al., Experiences and results on a 0.8 MWth oxy-fuel operation pilot-scale circulating fluidized bed, Appl. Energy 92(2012) 343-347.
[15] Y. Tan, L. Jia, Y. Wu, Some combustion characteristics of biomass and coal cofiring under oxy-fuel conditions in a pilot-scale circulating fluidized combustor, Energy Fuel 27(11) (2013) 7000-7007.
[16] M. Lupion, I. Alvarez, P. Otero, et al., 30 MWth CIUDEN oxy-cfb boiler-first experiences, Energy Procedia 37(2013) 6179-6188.
[17] H. Haykiri-Acma, S. Yaman, S. Kucukbayrak, Co-combustion of low rank coal/waste biomass blends using dry air or oxygen, Appl. Therm. Eng. 50(1) (2013) 251-259.
[18] E. Shou, Study on Oxy-Fuel Combustion Characteristics of Biomass and Coal Blending in Circulating Fluidized Bed, Institute of Engineering Thermophysics, Chinese Academic of Sciences, 2014.
[19] G. Pu, H. Zan, J. Du, et al., Study on NO emission in the oxy-fuel combustion of cofiring coal and biomass in a bubbling fluidized bed combustor, BioResources 12(1) (2017) 1890-1902.
[20] J. Wang, X. Zhao, Demonstration of key technologies for clean and efficient utilization of low-rank coal, Bull. Chin. Acad. Sci. 27(3) (2012) 382-388.
[21] Y. Guo, Y. Zhang, F. Cheng, Industrial development and prospect about comprehensive utilization of coal gangue, CIESC Journal 65(7) (2014) 2443-2453.
[22] J. Marion, N. Nsakala, Mcwhinnie R, Greenhouse gas emissions control by oxygen firing in circulating fluidized bed boilers, Office of Scientific & Technical Information Technical Reports, 2003.
[23] T. Czakiert, Z. Bis, W. Muskala, et al., Fuel conversion from oxy-fuel combustion in a circulating fluidized bed, Fuel Process. Technol. 87(6) (2006) 531-538.
[24] L.M. Romeo, L.I. Díez, I. Guedea, et al., Design and operation assessment of an oxyfuel fluidized bed combustor, Exp. Thermal Fluid Sci. 35(3) (2011) 477-484.
[25] J. Krzywański, T. Czakiert, W. Muskała, et al., Modelling of CO₂, CO, SO₂, O₂ and NO_x emissions from the oxy-fuel combustion in a circulating fluidized bed, Fuel Process. Technol. 92(3) (2011) 590-596.
[26] H. Li, C. Wang, C. Zhu, et al., Influence of oxy-fuel atmosphere on melting behavior and microscopic physicochemical properties of Zhundong coal ash, CIESC Journal 69(06) (2018) 2632-2638.
[27] E.J. Anthony, H. Hack, Oxy-fired fluidized bed combustion:Technology, prospects and new developments, Fluidized Bed Technologies for Near-Zero Emission Combustion and Gasification (2013) 867-894.
[28] F. Normann, H. Thunman, F. Johnsson, Process analysis of an oxygen lean oxy-fuel power plant with co-production of synthesis gas, Energy Convers. Manag. 50(2) (2009) 279-286.
[29] M.M. Hasan, Biomass Based Oxyfuel Combustion in CHP Power Plant with Opportunity of Oxygen Storage System for Carbon Capture and Storage, 2012.
[30] Z. Zhou, Z. You, Z. Wang, et al., Process design and optimization of state of the art carbon capture technologies, Environ. Prog. Sustain. Energy 33(3) (2014) 993-999.
[31] S. Fogarasi, C.C. Cormos, Assessment of coal and sawdust co-firing power generation under oxy-combustion conditions with carbon capture and storage, J. Clean. Prod. 142(2017) 3527-3535.
[32] B. Morrison, J.S. Golden, Life cycle assessment of co-firing coal and wood pellets in the southeastern United States, J. Clean. Prod. 150(2017) 188-196.
[33] N.Y. Nsakala, G.N. Liljedahl, D.G. Turek, Commercialization development of oxygen fired CFB for greenhouse gas control, Petroleum 28(8) (2007) 1679-1688.
[34] B. Leckner, A. Gómez-Barea, Oxy-fuel combustion in circulating fluidized bed boilers, Appl. Energy 125(2014) 308-318.
[35] Y. Shi, W.Q. Zhong, Y.J. Shao, et al., Energy efficiency analysis of pressurized oxycoal combustion system utilizing circulating fluidized bed, Appl. Therm. Eng. 150(2019) 1104-1115.
[36] L. Chen, S.Z. Yong, A.F. Ghoniem, Oxy-fuel combustion of pulverized coal:Characterization, fundamentals, stabilization and CFD modeling, Prog. Energy Combust. Sci. 38(2) (2012) 156-214.
[37] J. Zuwała, J. Lasek, 6-co-Combustion of Low-Rank Coals with Biomass, Low-Rank Coals for Power Generation, Fuel and Chemical Production, 2017125-158.
[38] T.Y. Mun, T.Z. Tumsa, U. Lee, et al., Performance evaluation of co-firing various kinds of biomass with low rank coals in a 500 MWe coal-fired power plant, Energy 115(2016) 954-962.
[39] K. Ericsson, Co-firing-a strategy for bioenergy in Poland? Energy 32(10) (2007) 1838-1847.
[40] C.C. Cormos, Oxy-combustion of coal, lignite and biomass:A techno-economic analysis for a large scale Carbon Capture and Storage (CCS) project in Romania, Fuel 169(2016) 50-57.
[41] L. Pang, Y.J. Shao, W.Q. Zhong, et al., Experimental investigation on the coal combustion in a pressurized fluidized bed, Energy 165(2018) 1119-1128.
[42] S. Tokarski, K. Głód, J. Lasek, et al., Evaluation of models for estimation of heating values of solid fuels and their test in full-scale combustion chambers. Part II:Analysis of co-firing combustion chambers, Rynek Energii 105(2) (2013) 65-68.
[43] J. Zuwała, Influence of biomass co-firing on the operational parameters of utility plants, Energetyka 2(2010) 1-7.
[44] E. Karampinis, P. Grammelis, M. Agraniotis, et al., Co-Firing of Biomass with Coal in Thermal Power Plants:Technology Schemes, Impacts, and Future Perspectives//Advances in Bioenergy:The Sustainability Challenge, John Wiley & Sons, Ltd, 2015.
[45] G.M. Dias, N.W. Ayer, K. Kariyapperuma, et al., Life cycle assessment of thermal energy production from short-rotation willow biomass in southern Ontario, Canada, Appl. Energy 204(2017) 343-352.
[46] G.A. Tsalidis, Y. Joshi, G. Korevaar, et al., Life cycle assessment of direct co-firing of torrefied and/or pelletised woody biomass with coal in the Netherlands, J. Clean. Prod. 81(2014) 168-177.
[47] I. Andric, N. Jamali-Zghal, M. Santarelli, et al., Environmental performance assessment of retrofitting existing coal fired power plants to co-firing with biomass:Carbon footprint and emergy approach, J. Clean. Prod. 103(2015) 13-27.
[48] I.M.N. Mohd, H. Hashim, N.H. Razak, Spatial optimisation of oil palm biomass cofiring for emissions reduction in coal-fired power plant, J. Clean. Prod. 172(2018) 3428-3447.
[49] E. Beagle, E. Belmont, Comparative life cycle assessment of biomass utilization for electricity generation in the European Union and the United States, Energy Policy 128(2019) 267-275.
[50] E. Agbor, A.O. Oyedun, X. Zhang, et al., Integrated techno-economic and environmental assessments of sixty scenarios for co-firing biomass with coal and natural gas, Appl. Energy 169(2016) 433-449.
[51] H. Haykiri-Acma, A.Z. Turan, S. Yaman, et al., Controlling the excess heat from oxycombustion of coal by blending with biomass, Fuel Process. Technol. 91(11) (2010) 1569-1575.
[52] N.S. Yuzbasi, N. Selçuk, Air and oxy-fuel combustion characteristics of biomass/lignite blends in TGA-FTIR, Fuel Process. Technol. 92(5) (2011) 1101-1108.
[53] H. Namkung, Y.J. Lee, J.H. Park, et al., Blending effect of sewage sludge and woody biomass into coal on combustion and ash agglomeration behavior, Fuel 225(2018) 266-276.
[54] C.R. Yörük, T. Meriste, S. Sener, et al., Thermogravimetric analysis and process simulation of oxy-fuel combustion of blended fuels including oil shale, semicoke, and biomass, Int. J. Energy Res. 42(6) (2018) 2213-2224.
[55] L. Fryda, C. Sobrino, M. Cieplik, et al., Study on ash deposition under oxyfuel combustion of coal/biomass blends, Fuel 89(8) (2010) 1889-1902.
[56] T.S. Farrow, C. Sun, C.E. Snape, Impact of biomass char on coal char burn-out under air and oxy-fuel conditions, Fuel 114(2013) 128-134.
[57] J. Xie, S. Cheng, H. Zhang, et al., Experimental study on NO emission characteristic:Co-firing of biomass and coal in O₂/CO₂ atmosphere, Thermal Power Generation 41(08) (2012) 32-36.
[58] J. Xie, S. Cheng, H. Zhang, et al., Experimental study on SO₂ emission characteristics of coal blending with biomass in O₂/CO₂ atmosphere, Boiler Technology 43(5) (2012) 74-78.
[59] A. Więckol-Ryk, A. Smoliński, Co-firing coal and biomass blends and their influence on the post-combustion CO₂ capture installation.E3S Web of Conferences, EDP Sciences 19(2017), 01008.
[60] K. Zhao, A.D. Jensen, P. Glarborg, NO formation during oxy-fuel combustion of coal and biomass chars, Energy Fuel 28(7) (2014) 4684-4693.
[61] B. Arias, C. Pevida, F. Rubiera, et al., Effect of biomass blending on coal ignition and burnout during oxy-fuel combustion, Fuel 87(12) (2008) 2753-2759.
[62] J. Riaza, L. Álvarez, M.V. Gil, et al., Effect of oxy-fuel combustion with steam addition on coal ignition and burnout in an entrained flow reactor, Energy 36(8) (2011) 5314-5319.
[63] M.V. Gil, J. Riaza, L. Álvarez, et al., Oxy-fuel combustion kinetics and morphology of coal chars obtained in N₂ and CO₂ atmospheres in an entrained flow reactor, Appl. Energy 91(1) (2012) 67-74.
[64] J. Riaza, M.V. Gil, L. Álvarez, et al., Oxy-fuel combustion of coal and biomass blends, Energy 41(1) (2012) 429-435.
[65] F. Sher, M.A. Pans, C. Sun, et al., Oxy-fuel combustion study of biomass fuels in a 20 kWth fluidized bed combustor, Fuel 215(2018) 778-786.
[66] M. Varol, R. Symonds, E.J. Anthony, et al., Emissions from co-firing lignite and biomass in an oxy-fired CFBC, Fuel Process. Technol. 173(2018) 126-133.
[67] J.H. Sung, S.K. Back, B.M. Jeong, et al., Oxy-fuel co-combustion of sewage sludge and wood pellets with flue gas recirculation in a circulating fluidized bed, Fuel Process. Technol. 172(2018) 79-85.
[68] X. Wang, Q.Q. Ren, W. Li, et al., Nitrogenous gas emissions from coal/biomass cocombustion under a high oxygen concentration in a circulating fluidized bed, Energy Fuel 31(3) (2017) 3234-3242.
[69] X.T. Zhang, S.Y. Li, W. Li, Study on NO and N₂O emission characteristics during cocombustion of biomass and coal in oxy-fuel CFB combustor, Renewable Energy Resources 35(2) (2017) 159-165.
[70] R. Kumar, R.I. Singh, An investigation in 20 kWth oxygen-enriched bubbling fluidized bed combustor using coal and biomass, Fuel Process. Technol. 148(2016) 256-268.
[71] U. Kayahan, S. Özdoğan, Oxygen enriched combustion and co-combustion of lignites and biomass in a 30 kWth circulating fluidized bed, Energy 116(2016) 317-328.
[72] C. Lupiáñez, M.C. Mayoral, L.I. Díez, et al., The role of limestone during fluidized bed oxy-combustion of coal and biomass, Appl. Energy 184(2016) 670-680.
[73] C. Lupiáñez, M.C. Mayoral, I. Guedea, et al., Effect of co-firing on emissions and deposition during fluidized bed oxy-combustion, Fuel 184(2016) 261-268.
[74] C. Lupiáñez, M.C. Mayoral, L.I. Díez, et al., On the oxy-combustion of lignite and corn Stover in a lab-scale fluidized bed reactor, Biomass Bioenergy 96(2017) 152-161.
[75] L. Duan, Y. Duan, C. Zhao, et al., NO emission during co-firing coal and biomass in an oxy-fuel circulating fluidized bed combustor, Fuel 150(2015) 8-13.
[76] M. Lupion, B. Navarrete, P. Otero, et al., Experimental programme in CIUDEN's CO₂ capture technology development plant for power generation, Chem. Eng. Res. Des. 89(9) (2011) 1494-1500.
[77] M. Lupion, R. Diego, L. Loubeau, et al., CIUDEN CCS project:Status of the CO₂ capture technology development plant in power generation, Energy Procedia 4(2011) 5639-5646.
[78] X. Wang, Experimental Study on Combustion Characteristics and Nitrogen Transformation of Coal/Biomass Circulating Fluidized Bed Oxy-Fuel Combustion, Institute of Engineering Thermophysics, Chinese Academic of Sciences, 2017.
[79] X. Yang, A. Chen, J. Xie, et al., Emissions of NO and N₂O in a Decoupled Circulating Fluidized Bed Combustor during Coal and Biomass Co-Firing, Proceedings of international symposium on ecotopia science 2007.
[80] N. Jurado, N.J. Simms, E.J. Anthony, et al., Effect of co-firing coal and biomass blends on the gaseous environments and ash deposition during pilot-scale oxycombustion trials, Fuel 197(2017) 145-158.
[81] W. Ma, H. Zhou, J. Zhang, et al., Behavior of slagging deposits during coal and biomass co-combustion in a 300 kW down-fired furnace, Energy Fuel 32(4) (2018) 4399-4409.
[82] Y. Qi, S. Ji, M. Wang, et al., Experimental study of the high-temperature slagging characteristics of coal ash-biomass ash blends under different atmospheres, J. Energy Inst. 92(6) (2019) 1914-1925.
[83] W. Zhong, A. Yu, G. Zhou, et al., CFD simulation of dense particulate reaction system:Approaches, recent advances and applications, Chem. Eng. Sci. 140(2016) 16-43.
[84] W. Zhou, C. Zhao, L. Duan, et al., CFD modeling of oxy-coal combustion in circulating fluidized bed, International Journal of Greenhouse Gas Control 5(6) (2011) 1489-1497.
[85] W. Zhou, C. Zhao, L. Duan, et al., A simulation study of coal combustion under O₂/CO₂ and O₂/RFG atmospheres in circulating fluidized bed, Chem. Eng. J. 223(2013) 816-823.
[86] L. Yu, Experimental & Numerical Simulation Study on Combustion Performance of Circulating Fluidized Bed Boiler in Oxygen-Rich Environment, North China Electric Power University, 2014.
[87] Y. Wu, D. Liu, L. Duan, et al., Three-dimensional CFD simulation of oxy-fuel combustion in a circulating fluidized bed with warm flue gas recycle, Fuel 216(2018) 596-611.
[88] L.M. Amoo, Computational fluid dynamics simulation of Lafia-Obi bituminous coal in a fluidized-bed chamber for air-and oxy-fuel combustion technologies, Fuel 140(2015) 178-191.
[89] L. Ren, Numerical Simulation of Fluidized Bed Experimental Setup under Oxyenriched Atmosphere, Harbin Institute of Technology 2013.
[90] H. Zhou, Model Simulate of the NO_x in the Oxy-Fuel CFB Combustion, North China Electric Power University, 2009.
[91] C. Wang, H. Zhou, Experimental study and simulation of NO_x formation by oxygenenriched combustion in a mini-CFB, Journal of Chinese Society of Power Engineering 30(6) (2010) 420-424.
[92] Z. Luo, Y. Mao, X. Wu, et al., Test study on and analysis of burning behavior for coal under atmophere of O₂/CO₂, Thermal Power Generation 8(12) (2004) 1657-1671.
[93] Y. Mao, M. Fang, Z. Luo, et al., Experimental study on coal combustion in a circulating fluidized bed test-facility under oxygen-enriched atmosphere, J. Combustion Sci. Technol. 2(2005) 188-191.
[94] Y. Mao, Theoretical and Experimental Study on Oxygen-Enriched Combustion Technology in Circulating Fluidized Bed, Zhejiang University, 2003.
[95] J. Krzywanski, T. Czakiert, W. Muskala, et al., Modeling of solid fuels combustion in oxygen-enriched atmosphere in circulating fluidized bed boiler:Part 1. The mathematical model of fuel combustion in oxygen-enriched CFB environment, Fuel Process. Technol. 91(3) (2010) 290-295.
[96] J. Krzywanski, T. Czakiert, W. Muskala, et al., Modeling of solid fuels combustion in oxygen-enriched atmosphere in circulating fluidized bed boiler:Part 2. Numerical simulations of heat transfer and gaseous pollutant emissions associated with coal combustion in O₂/CO₂ and O₂/N₂ atmospheres enriched with oxygen under circulating fluidized bed conditions, Fuel Process. Technol. 91(2011) 364-368.
[97] Fong Bo, Study on Numerical Simulation of Coal and Biomass Co-Firing in Bubbling Fluidized Bed under O₂/CO₂ Atmospheres, Southeast University, 2013.
[98] W.P. Adamczyk, P. Kozołub, G. Węcel, et al., Modeling oxy-fuel combustion in a 3D circulating fluidized bed using the hybrid Euler-Lagrange approach, Appl. Therm. Eng. 71(1) (2014) 266-275.
[99] W.P. Adamczyk, P. Kozołub, A. Klimanek, et al., Numerical simulations of the industrial circulating fluidized bed boiler under air-and oxy-fuel combustion, Appl. Therm. Eng. 87(2015) 127-136.
[100] M. Upadhyay, H.C. Park, J.G. Hwang, et al., Computational particle-fluid dynamics simulation of gas-solid flow in a circulating fluidized bed with air or O₂/CO₂ as fluidizing gas, Powder Technol. 318(2017) 350-362.
[101] S. Black, J. Szuhánszki, A. Pranzitelli, et al., Effects of firing coal and biomass under oxy-fuel conditions in a power plant boiler using CFD modelling, Fuel 113(2013) 780-786.
[102] L. Álvarez, C. Yin, J. Riaza, et al., Oxy-coal combustion in an entrained flow reactor:Application of specific char and volatile combustion and radiation models for oxyfiring conditions, Energy 62(2013) 255-268.
[103] L. Álvarez, C. Yin, J. Riaza, et al., Biomass co-firing under oxy-fuel conditions:a computational fluid dynamics modelling study and experimental validation, Fuel Process. Technol. 120(2014) 22-33.
[104] A.A. Bhuiyan, J. Naser, Computational modelling of co-firing of biomass with coal under oxy-fuel condition in a small scale furnace, Fuel 143(2015) 455-466.
[105] A.A. Bhuiyan, J. Naser, CFD modelling of co-firing biomass with coal under oxy-fuel combustion in a large scale power plant, Fuel 159(2015) 150-168.
[106] C. Yin, J. Yan, Oxy-fuel combustion of pulverized fuels:Combustion fundamentals and modeling, Appl. Energy 162(2016) 742-762.

Co-firing of coal and biomass in oxy-fuel fluidized bed for CO₂ capture: A review of recent advances

Co-firing of coal and biomass in oxy-fuel fluidized bed for CO₂ capture: A review of recent advances

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 7

编辑推荐

Metrics

本文评价

[1]	Xun Tao, Fan Zhou, Xinlei Yu, Songling Guo, Yunfei Gao, Lu Ding, Guangsuo Yu, Zhenghua Dai, Fuchen Wang. Effect of carbon dioxide on oxy-fuel combustion of hydrogen sulfide: An experimental and kinetic modeling[J]. 中国化学工程学报, 2023, 59(7): 105-117.
[2]	Qian Cheng, Dunyu Liu, Jun Chen, Jing Jin, Wei Li, Shuaishuai Yu. Gas-phase oxidation of NO at high pressure relevant to sour gas compression purification process for oxy-fuel combustion flue gas[J]. 中国化学工程学报, 2019, 27(4): 884-895.
[3]	Khalid El Sheikh, Mohammad Jakir Hossain Khan, Mahar Diana Hamid, Siddhartha Shrestha, Brahim Si Ali, G.A. Ryabov, Lya A. Dolgushin, Mohd Azlan Hussain, Tatiana V. Bukharkina, Elena A. Gorelova. Advances in reduction of NO_x and N₂O1 emission formation in an oxyfired fluidized bed boiler[J]. Chinese Journal of Chemical Engineering, 2019, 27(2): 426-443.
[4]	Jiyizhe Zhang, Yundong Wang, Geoffrey W. Stevens, Weiyang Fei. A state-of-the-art review on single drop study in liquid-liquid extraction: Experiments and simulations[J]. 中国化学工程学报, 2019, 27(12): 2857-2875.
[5]	Xinyu Yu, Tianwen Chen, Qi Zhang, Tiefeng Wang. CFD simulations of quenching process for partial oxidation of methane: Comparison of jet-in-cross-flow and impinging flow configurations[J]. Chinese Journal of Chemical Engineering, 2018, 26(5): 903-913.
[6]	Lei Huang, Lin Qi, Hongna Wang, Jinli Zhang, Xiaoqiang Jia. Optimal design of heat exchanger header for coal gasification in supercritical water through CFD simulations[J]. , 2017, 25(8): 1101-1108.
[7]	Yufeng Ma, Lijun Ji, Jiexu Zhang, Kui Chen, BinWu, YanyangWu, Jiawen Zhu. CFD gas-liquid simulation of oriented valve tray[J]. Chinese Journal of Chemical Engineering, 2015, 23(10): 1603-1609.