Oxyfuel Combustion Makes Carbon Capture More Efficient

Fossil energy carriers cannot be totally replaced, especially if nuclear power stations are stopped and renewable energy is not available. To fulfill emission regulations, however, points such as emission sources should be addressed. Besides desulfurization, carbon capture and utilization have become increasingly important engineering activities. Oxyfuel technologies offer new options to reduce greenhouse gas emissions; however, the use of clean oxygen instead of air can be dangerous in the case of certain existing technologies. To replace the inert effect of nitrogen, carbon dioxide is mixed with oxygen gas in the case of such air combustion processes. In this work, the features of carbon capture in five different flue gases of air combustion and such oxyfuel combustion where additional carbon dioxide is mixed with clean oxygen are studied and compared. The five different flue gases originate from the gas-fired power plant, coal-fired power plant, coal-fired combined heat and power plant, the aluminum production industry, and the cement manufacturing industry. Monoethanolamine, which is an industrially preferred solvent for carbon dioxide capture from gas streams at low pressures, is selected as an absorbent, and the same amount of carbon dioxide is captured; that is, always that amount of carbon dioxide is captured, which is the result of the fossil combustion process. ASPEN Plus is used for mathematical modeling. The results show that the oxyfuel combustion cases need significantly less energy, especially at high carbon dioxide removal rates, e.g., higher than 90%, than that of the air combustion cases. The savings can even be as high as 84%. Moreover, 100% carbon capture was also be completed. This finding can be due to the fact that in the oxyfuel combustion cases, the carbon dioxide concentration is much higher than that of the air combustion cases because of the inert carbon dioxide and that higher carbon dioxide concentration results in a higher driving force for the mass transfer. The oxyfuel combustion processes also show another advantage over the air combustion processes since no nitrogen oxides are produced in the combustion process.

[1]  Xiongwen Zhao,et al.  Risk-assessment of carbon-dioxide recycling in a gas-fired power plant using CVaR-based convex optimization , 2023, Journal of Cleaner Production.

[2]  Shiliang Yang,et al.  Investigation of the oxy-fuel combustion process in the full-loop circulating fluidized bed , 2023, Energy.

[3]  Wenqi Zhong,et al.  Particle-Scale Investigation of Oxy-Fuel Combustion in a Pressurized Fluidized Bed , 2023, SSRN Electronic Journal.

[4]  R. Chacartegui,et al.  Large-scale oxygen-enriched air (OEA) production from polymeric membranes for partial oxycombustion processes , 2023, Energy.

[5]  S. McCoy,et al.  Cost and Life Cycle Emissions of Ethanol Produced with an Oxyfuel Boiler and Carbon Capture and Storage , 2023, Environmental science & technology.

[6]  Sofía T. Blanco,et al.  Effect of the impurities O2 or NO present in non-purified flue gas from oxy-fuel combustion processes for carbon capture and storage technology. , 2023, Process Safety and Environmental Protection.

[7]  Yangyang Guo,et al.  A review of low-carbon technologies and projects for the global cement industry. , 2023, Journal of environmental sciences.

[8]  D. Selvakumar,et al.  Activated carbon from biomass: Preparation, factors improving basicity and surface properties for enhanced CO2 capture capacity – A review , 2023, Journal of CO2 Utilization.

[9]  N. Rogalev,et al.  Review of Closed SCO2 and Semi-Closed Oxy–Fuel Combustion Power Cycles for Multi-Scale Power Generation in Terms of Energy, Ecology and Economic Efficiency , 2022, Energies.

[10]  Jae Won Lee,et al.  Sustainable Energy Harvesting from Post-Combustion Co2 Capture Using Amine-Functionalized Solvents , 2022, SSRN Electronic Journal.

[11]  Mostafa Safdari Shadloo,et al.  Review on CO2 capture by blended amine solutions , 2022, International Journal of Greenhouse Gas Control.

[12]  Alireza Aslani,et al.  Comparison of amine adsorbents and strong hydroxides soluble for direct air CO2 capture by life cycle assessment method , 2022, Environmental Technology & Innovation.

[13]  X. Wen,et al.  Contributions of climate, elevated atmospheric CO2 concentration and land surface changes to variation in water use efficiency in Northwest China , 2022, CATENA.

[14]  Xia Xu,et al.  Development of green solvents for efficient post-combustion CO2 capture with good regeneration performance , 2022, Journal of CO2 Utilization.

[15]  J. Ren,et al.  Simulation of CO2 Capture Process in Flue Gas from Oxy-Fuel Combustion Plant and Effects of Properties of Absorbent , 2022, Separations.

[16]  J. Palomar,et al.  Aspen Plus supported design of pre-combustion CO2 capture processes based on ionic liquids , 2022, Separation and Purification Technology.

[17]  D. Che,et al.  Experimental evaluation on NO formation and burnout characteristics of oxy-fuel Co-combustion of ultra-low volatile carbon-based solid fuels and bituminous coal , 2022, Energy.

[18]  E. Vakkilainen,et al.  Integrating oxy-fuel combustion and power-to-gas in the cement industry: A process modeling and simulation study , 2022, International Journal of Greenhouse Gas Control.

[19]  W. Cai,et al.  Increased ENSO sea surface temperature variability under four IPCC emission scenarios , 2022, Nature Climate Change.

[20]  Sujeet Yadav,et al.  A review on the progress and prospects of oxy-fuel carbon capture and sequestration (CCS) technology , 2022, Fuel.

[21]  N. Matin,et al.  Life cycle assessment of amine-based versus ammonia-based post combustion CO2 capture in coal-fired power plants , 2022, International Journal of Greenhouse Gas Control.

[22]  J. Morud,et al.  Energy assessments of onboard CO2 capture from ship engines by MEA-based post combustion capture system with flue gas heat integration , 2022, International Journal of Greenhouse Gas Control.

[23]  Dunxi Yu,et al.  A Comprehensive Review of Ash Issues in Oxyfuel Combustion of Coal and Biomass: Mineral Matter Transformation, Ash Formation, and Deposition , 2021, Energy & Fuels.

[24]  L. Shao,et al.  Carbon dioxide absorption with aqueous amine solutions promoted by piperazine and 1-methylpiperazine in a rotating zigzag bed , 2021 .

[25]  Zhien Zhang,et al.  Life cycle assessment of combustion-based electricity generation technologies integrated with carbon capture and storage: A review. , 2021, Environmental research.

[26]  Saeed Talei,et al.  Comparative Analysis of Three Different Negative Emission Technologies, BECCS, Absorption and Adsorption of Atmospheric CO2 , 2021, Civil and Environmental Engineering Reports.

[27]  F. Raganati,et al.  Adsorption of Carbon Dioxide for Post-combustion Capture: A Review , 2021, Energy & Fuels.

[28]  Y. Pei,et al.  Oxy‐fuel combustion for carbon capture and storage in internal combustion engines – A review , 2021, International Journal of Energy Research.

[29]  Ismael Díaz,et al.  Green solvent screening using modeling and simulation , 2021 .

[30]  J. Park,et al.  A performance comparison study of five single and sixteen blended amine absorbents for CO2 capture using ceramic hollow fiber membrane contactors , 2021 .

[31]  Sujeet Yadav,et al.  Numerical investigation of 660 MW pulverized coal-fired supercritical power plant retrofitted to oxy-coal combustion , 2021 .

[32]  Shanshan Liu,et al.  CO2 capture performance and mechanism of blended amine solvents regulated by N-methylcyclohexyamine , 2021 .

[33]  Usman Ali,et al.  Process analysis of improved process modifications for ammonia-based post-combustion CO2 capture , 2020 .

[34]  J. Baeyens,et al.  Post-combustion carbon capture , 2020, Renewable and Sustainable Energy Reviews.

[35]  Edemar Morsch Filho,et al.  Experimental investigation of the thermal behavior for oxy-fired and air-fired high temperature furnaces for the vitreous ceramic industry , 2020, Thermal Science and Engineering Progress.

[36]  U. Kayahan,et al.  A comparative study on the air, the oxygen-enriched air and the oxy-fuel combustion of lignites in CFB , 2020 .

[37]  Y. Lim,et al.  Techno-economic analysis of ultra-supercritical power plants using air- and oxy-combustion circulating fluidized bed with and without CO2 capture , 2020 .

[38]  Saleem H. Ali,et al.  Transparency on greenhouse gas emissions from mining to enable climate change mitigation , 2020 .

[39]  P. Luis,et al.  Advanced Amino Acid-Based Technologies for CO2 Capture: A Review , 2019, Industrial & Engineering Chemistry Research.

[40]  Ahmad Baroutaji,et al.  Outlook of carbon capture technology and challenges. , 2019, The Science of the total environment.

[41]  J. Brennecke,et al.  Recyclability of Encapsulated Ionic Liquids for Post-Combustion CO2 Capture , 2019, Industrial & Engineering Chemistry Research.

[42]  T. V. Bukharkina,et al.  Advances in reduction of NO and N2O1 emission formation in an oxy-fired fluidized bed boiler , 2019, Chinese Journal of Chemical Engineering.

[43]  Meihong Wang,et al.  Thermodynamic performance evaluation of supercritical CO2 closed Brayton cycles for coal-fired power generation with solvent-based CO2 capture , 2019, Energy.

[44]  R. Yu,et al.  Thermodynamic Analysis and Optimization of an Oxyfuel Fluidized Bed Combustion Power Plant for CO2 Capture , 2018, Industrial & Engineering Chemistry Research.

[45]  Z. Abubakar,et al.  Numerical Study of the Combustion Characteristics of Propane–Oxyfuel Flames with CO2 Dilution , 2018 .

[46]  G. Cau,et al.  CO2-free coal-fired power generation by partial oxy-fuel and post-combustion CO2 capture: Techno-economic analysis , 2018 .

[47]  R. Ben‐Mansour,et al.  Oxy‐fuel combustion technology: current status, applications, and trends , 2017 .

[48]  S. Gu,et al.  ASPEN PLUS simulation model for CO2 removal with MEA: Validation of desorption model with experimental data , 2017 .

[49]  Calin-Cristian Cormos,et al.  Oxy-combustion of coal, lignite and biomass: A techno-economic analysis for a large scale Carbon Capture and Storage (CCS) project in Romania , 2016 .

[50]  Debangsu Bhattacharyya,et al.  Development of Model and Model-Predictive Control of an MEA-Based Postcombustion CO2 Capture Process , 2016 .

[51]  Thomas Hills,et al.  Carbon Capture in the Cement Industry: Technologies, Progress, and Retrofitting. , 2016, Environmental science & technology.

[52]  Günter Scheffknecht,et al.  Oxyfuel combustion for CO2 capture in power plants , 2015 .

[53]  Tibor Nagy,et al.  Model verification and analysis of the CO2-MEA absorber–desorber system , 2015 .

[54]  A. Chaffee,et al.  Improvements in the Pre-Combustion Carbon Dioxide Sorption Capacity of a Magnesium Oxide–Cesium Carbonate Sorbent , 2014 .

[55]  Chonghun Han,et al.  Design and Analysis of a Combined Rankine Cycle for Waste Heat Recovery of a Coal Power Plant Using LNG Cryogenic Exergy , 2014 .

[56]  Hans Hasse,et al.  Modeling and simulation of reactive absorption of CO2 with MEA: Results for four different packings on two different scales , 2014 .

[57]  Mai Bui,et al.  Dynamic modelling and optimisation of flexible operation in post-combustion CO2 capture plants - A review , 2014, Comput. Chem. Eng..

[58]  C. Ramshaw,et al.  Process analysis of intensified absorber for post-combustion CO2 capture through modelling and simulation , 2014 .

[59]  Eric Croiset,et al.  Dynamic modelling and control of MEA absorption processes for CO2 capture from power plants , 2014 .

[60]  Peter Mizsey,et al.  Effect of fossil fuels on the parameters of CO2 capture. , 2013, Environmental science & technology.

[61]  Masoud Mofarahi,et al.  Comparison of rate-based and equilibrium-stage models of a packed column for post-combustion CO2 capture using 2-amino-2-methyl-1-propanol (AMP) solution , 2013 .

[62]  Thijs J. H. Vlugt,et al.  State-of-the-Art of CO2 Capture with Ionic Liquids , 2012 .

[63]  Ping Li,et al.  Onsite CO2 Capture from Flue Gas by an Adsorption Process in a Coal-Fired Power Plant , 2012 .

[64]  Ying Zhang,et al.  Thermodynamic modeling for CO2 absorption in aqueous MEA solution with electrolyte NRTL model , 2011 .

[65]  Ryo Yoshiie,et al.  Gas-Phase Reaction of NOX Formation in Oxyfuel Coal Combustion at Low Temperature , 2011 .

[66]  P. López-Mahía,et al.  As, Hg, and Se flue gas sampling in a coal-fired power plant and their fate during coal combustion. , 2003, Environmental science & technology.

[67]  G. Soave Equilibrium constants from a modified Redlich-Kwong equation of state , 1972 .

[68]  J. Abildskov,et al.  Mobile pilot plant for CO2 capture in biogas upgrading using 30 wt% MEA , 2023, Fuel.

[69]  G. Saevarsdottir,et al.  Direct and Indirect CO2 Equivalent Emissions from Primary Aluminium Production , 2022, Light Metals 2022.

[70]  Shuiqing Li,et al.  Measurements and modelling of oxy-fuel coal combustion , 2019, Proceedings of the Combustion Institute.

[71]  T. Nagy Comprehensive study of carbon dioxide capture from industrial gases with monoethanolamine-water mixture , 2016 .

[72]  M. Melaaen,et al.  Simulation of Carbon Dioxide Capture for Aluminium Production Process , 2014 .

[73]  Chonghun Han,et al.  Modeling and Simulation of CO2 Capture Process for Coal- based Power Plant Using Amine Solvent in South Korea , 2013 .

[74]  Ying Zhang,et al.  Modeling CO2 Absorption and Desorption by Aqueous Monoethanolamine Solution with Aspen Rate-based Model☆ , 2013 .

[75]  Arto Hotta,et al.  30 MWth CIUDEN Oxy-cfb Boiler - First Experiences☆ , 2013 .