Integration of carbon capture technologies in blast furnace based steel making: A comprehensive and systematic review
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L. Romeo | P. Lisbona | P. Kannan | V. Eveloy | M. Bailera | B. Peña | A. Raj | J. Perpiñán
[1] T. Nakagaki,et al. Limits on the integration of power to gas with blast furnace ironmaking , 2022, Journal of Cleaner Production.
[2] K. Gallucci,et al. Chemical Looping Combustion and Gasification: A Review and a Focus on European Research Projects , 2022, Industrial & Engineering Chemistry Research.
[3] Wang Hong. A techno-economic review on carbon capture, utilisation and storage systems for achieving a net-zero CO2 emissions future , 2022, Carbon Capture Science & Technology.
[4] 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.
[5] Jeong‐Hoon Kim,et al. Numerical Simulation and Optimization of 4-Component LDG Separation in the Steelmaking Industry Using Polysulfone Hollow Fiber Membranes , 2022, Membranes.
[6] Qingling Liu,et al. Techno-economic evaluation of a novel membrane-cryogenic hybrid process for carbon capture , 2022, Applied Thermal Engineering.
[7] K. Whitty. Final Report: Development of Enabling Technologies for Chemical Looping Combustion and Chemical Looping with Oxygen Uncoupling , 2021 .
[8] A. Faaij,et al. Harmonized comparison of virgin steel production using biomass with carbon capture and storage for negative emissions , 2021, International Journal of Greenhouse Gas Control.
[9] T. Nakagaki,et al. Revisiting the Rist diagram for predicting operating conditions in blast furnaces with multiple injections , 2021, Open Research Europe.
[10] L. Romeo,et al. CO2 Recycling in the Iron and Steel Industry via Power-to-Gas and Oxy-Fuel Combustion , 2021, Energies.
[11] P. Cobden,et al. A new application of the commercial high temperature water gas shift catalyst for reduction of CO2 emissions in the iron and steel industry: Lab-scale catalyst evaluation , 2021, International Journal of Hydrogen Energy.
[12] S. Yun,et al. Techno-economic assessment and comparison of absorption and membrane CO2 capture processes for iron and steel industry , 2021, Energy.
[13] A. Faaij,et al. Carbon capture and biomass in industry: A techno-economic analysis and comparison of negative emission options , 2021, Renewable and Sustainable Energy Reviews.
[14] A. Babich. Blast furnace injection for minimizing the coke rate and CO2 emissions , 2021, Ironmaking & Steelmaking.
[15] L. Petrescu,et al. Membrane technology applied to steel production: Investigation based on process modelling and environmental tools , 2021 .
[16] L. Romeo,et al. A review on CO2 mitigation in the Iron and Steel industry through Power to X processes , 2021 .
[17] S. J. Friedmann,et al. Low-carbon production of iron and steel: Technology options, economic assessment, and policy , 2021 .
[18] S. Frigo,et al. Life Cycle Assessment of Substitute Natural Gas production from biomass and electrolytic hydrogen , 2021 .
[19] Xiangping Zhang,et al. Carbon membranes for CO2 removal: Status and perspectives from materials to processes , 2020, Chemical Engineering Journal.
[20] A. Lyngfelt,et al. Commissioning, performance benchmarking, and investigation of alkali emissions in a 10 kWth solid fuel chemical looping combustion pilot , 2020, Fuel.
[21] Zhao Sun,et al. Synergistic decarbonization and desulfurization of blast furnace gas via a novel magnesium-molybdenum looping process , 2020 .
[22] Henrik Saxén,et al. A Review on Explorations of the Oxygen Blast Furnace Process , 2020, steel research international.
[23] James S. Baker,et al. Custom Formulation of Multicomponent Mixed-Matrix Membranes for Efficient Post-combustion Carbon Capture , 2020 .
[24] Chunyuan Ma,et al. Numerical Investigation on Coal Combustion in Ultralow CO2 Blast Furnace: Effect of Oxygen Temperature , 2020, Processes.
[25] J. C. Abanades,et al. Advanced Packed-Bed Ca-Cu Looping Process for the CO2 Capture From Steel Mill Off-Gases , 2020, Frontiers in Energy Research.
[26] Qun Yi,et al. Numerical study and design strategy for a low emission coke oven system using oxy-fuel combustion of coke oven gas , 2020 .
[27] Hai-bin Zuo,et al. Review of green and low-carbon ironmaking technology , 2020, Ironmaking & Steelmaking.
[28] C. Cormos,et al. Techno-Economic and Environmental Evaluations of Decarbonized Fossil-Intensive Industrial Processes by Reactive Absorption & Adsorption CO2 Capture Systems , 2020, Energies.
[29] P. Fennell,et al. Process Integration of Chemical Looping Water Splitting with a Sintering Plant for Iron Making , 2020 .
[30] G. Manzolini,et al. Techno-economic assessment of SEWGS technology when applied to integrated steel-plant for CO2 emission mitigation , 2020 .
[31] P. Roy,et al. A lithium–aluminosilicate zeolite membrane for separation of CO2 from simulated blast furnace gas , 2020, Journal of Porous Materials.
[32] Qing Lyu,et al. Energy Conservation and CO2 Abatement Potential of a Gas-injection Blast Furnace , 2020 .
[33] M. Larsson,et al. Excess heat-driven carbon capture at an integrated steel mill – Considerations for capture cost optimization , 2019 .
[34] P. Fennell,et al. Iron-based chemical-looping technology for decarbonising iron and steel production , 2019 .
[35] Anders Lyngfelt,et al. 11,000 h of chemical-looping combustion operation—Where are we and where do we want to go? , 2019, International Journal of Greenhouse Gas Control.
[36] Oishi Sanyal,et al. Carbon molecular sieve membrane preparation by economical coating and pyrolysis of porous polymer hollow fibers. , 2019, Angewandte Chemie.
[37] C. Ko,et al. FINEX® as an environmentally sustainable ironmaking process , 2019, Ironmaking & Steelmaking.
[38] E. Favvas,et al. Screening Cellulose Spinning Parameters for Fabrication of Novel Carbon Hollow Fiber Membranes for Gas Separation , 2019, Industrial & Engineering Chemistry Research.
[39] J. C. Abanades,et al. Recent progress of the Ca-Cu technology for decarbonisation of power plants and carbon intensive industries , 2019, International Journal of Greenhouse Gas Control.
[40] Luis M. Romeo,et al. Techno-economic feasibility of power to gas–oxy-fuel boiler hybrid system under uncertainty , 2019, International Journal of Hydrogen Energy.
[41] T. Nakagaki,et al. CO2 Emission Reduction and Exergy Analysis of SMART Steelmaking System Adaptive for Flexible Operating Conditions , 2019, ISIJ International.
[42] T. Ariyama,et al. Diversification of the Ironmaking Process Toward the Long-Term Global Goal for Carbon Dioxide Mitigation , 2019, Journal of Sustainable Metallurgy.
[43] F. Johnsson,et al. Integrating carbon capture into an industrial combined-heat-and-power plant: performance with hourly and seasonal load changes , 2019, International Journal of Greenhouse Gas Control.
[44] P. Aravind,et al. Design, modelling and techno-economic analysis of a solid oxide fuel cell-gas turbine system with CO2 capture fueled by gases from steel industry , 2019, Applied Thermal Engineering.
[45] D. Xiang,et al. Concept design and techno-economic performance of hydrogen and ammonia co-generation by coke-oven gas-pressure swing adsorption integrated with chemical looping hydrogen process , 2018, Applied Energy.
[46] W. Ho,et al. Recent advances in polymeric membranes for CO2 capture , 2018, Chinese Journal of Chemical Engineering.
[47] Álvaro A. Ramírez-Santos,et al. Optimization of multistage membrane gas separation processes. Example of application to CO2 capture from blast furnace gas , 2018, Journal of Membrane Science.
[48] J. C. Abanades,et al. Integration of a fluidised bed Ca–Cu chemical looping process in a steel mill , 2018, Energy.
[49] Zeyi Jiang,et al. Effects of top gas recycling on in-furnace status, productivity, and energy consumption of oxygen blast furnace , 2018, Energy.
[50] V. Manović,et al. Inherent potential of steelmaking to contribute to decarbonisation targets via industrial carbon capture and storage , 2018, Nature Communications.
[51] G. Manzolini,et al. STEPWISE Project: Sorption-Enhanced Water-Gas Shift Technology to Reduce Carbon Footprint in the Iron and Steel Industry , 2018, Johnson Matthey Technology Review.
[52] M. Larsson,et al. Evaluation of low and high level integration options for carbon capture at an integrated iron and steel mill , 2018, International Journal of Greenhouse Gas Control.
[53] T. Merkel,et al. CO2 Capture from Cement Plants and Steel Mills Using Membranes , 2018, Industrial & Engineering Chemistry Research.
[54] D. Xiang,et al. Parameter optimization and thermodynamic analysis of COG direct chemical looping hydrogen processes , 2018, Energy Conversion and Management.
[55] Robert Schlögl,et al. The Project Carbon2Chem® , 2018, Chemie Ingenieur Technik.
[56] Meihong Wang,et al. Process analysis and economic evaluation of mixed aqueous ionic liquid and monoethanolamine (MEA) solvent for CO2 capture from a coke oven plant , 2018 .
[57] Jay H. Lee,et al. Design and evaluation of CO2 capture plants for the steelmaking industry by means of amine scrubbing and membrane separation , 2018, International Journal of Greenhouse Gas Control.
[58] A. Yu,et al. Numerical Investigation of Novel Oxygen Blast Furnace Ironmaking Processes , 2018, Metallurgical and Materials Transactions B.
[59] A. Abad,et al. Chemical looping combustion of solid fuels , 2018 .
[60] Jianjun Cai,et al. Power Generation from Coke Oven Gas Using Chemical Looping Combustion: Thermodynamic Simulation , 2018 .
[61] Karl D. Amo,et al. Extended field trials of Polaris sweep modules for carbon capture , 2017 .
[62] Vitor Maggioni Gasparini,et al. Evaluation of the permeability of the dripping zone and of flooding phenomena in a blast furnace , 2017, Journal of Materials Research and Technology.
[63] T. Merkel,et al. CO2 capture from natural gas power plants using selective exhaust gas recycle membrane designs , 2017 .
[64] Xiang Zhu,et al. Assessment on the energy flow and carbon emissions of integrated steelmaking plants , 2017 .
[65] Wei Wang,et al. Medium oxygen enriched blast furnace with top gas recycling strategy , 2017 .
[66] A. Sánchez-Biezma,et al. Operating Experience in la Pereda 1.7 MWth Calcium Looping Pilot , 2017 .
[67] May-Britt Hägg,et al. Pilot Demonstration-reporting on CO2 Capture from a Cement Plant Using Hollow Fiber Process , 2017 .
[68] M. Bastos-Neto,et al. Carbon Dioxide Capture by Pressure Swing Adsorption , 2017 .
[69] Günter Scheffknecht,et al. Calcium Looping for CO2 Capture in Cement Plants – Pilot Scale Test , 2017 .
[70] Martin Helbig,et al. Long-term Carbonate Looping Testing in a 1 MWth Pilot Plant with Hard Coal and Lignite , 2017 .
[71] Xuefeng She,et al. Numerical analysis of carbon saving potential in a top gas recycling oxygen blast furnace , 2017 .
[72] Nilay Shah,et al. A techno-economic analysis and systematic review of carbon capture and storage (CCS) applied to the iron and steel, cement, oil refining and pulp and paper industries, as well as other high purity sources. , 2017 .
[73] Juan Carlos Abanades,et al. Conceptual design of a Ca–Cu chemical looping process for hydrogen production in integrated steelworks , 2017 .
[74] Li Wang,et al. A review of energy use and energy-efficient technologies for the iron and steel industry , 2017 .
[75] Shi-Shang Jang,et al. Comparison of rotating packed bed and packed bed absorber in pilot plant and model simulation for CO2 capture , 2017 .
[76] Eric Favre,et al. Utilization of blast furnace flue gas: Opportunities and challenges for polymeric membrane gas separation processes , 2017 .
[77] Z. Xue,et al. Exergy analyses of the oxygen blast furnace with top gas recycling process , 2017 .
[78] Qingbo Yu,et al. New process for hydrogen production from raw coke oven gas via sorption-enhanced steam reforming: Thermodynamic analysis , 2017 .
[79] Peng Jin,et al. The energy consumption and carbon emission of the integrated steel mill with oxygen blast furnace , 2017 .
[80] Junnian Wu,et al. Integrated assessment of exergy, energy and carbon dioxide emissions in an iron and steel industrial network , 2016 .
[81] Michitaka Sato,et al. Evolution of Blast Furnace Process toward Reductant Flexibility and Carbon Dioxide Mitigation in Steel Works , 2016 .
[82] P. K. Sen,et al. Optimization of Top Gas Recycle Blast Furnace Emissions with Implications of Downstream Energy , 2016 .
[83] Wei Zhang,et al. Unsteady Analyses of the Top Gas Recycling Oxygen Blast Furnace , 2016 .
[84] C. Téllez,et al. On the molecular mechanisms for the H2/CO2 separation performance of zeolite imidazolate framework two-layered membranes† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c6sc02411d Click here for additional data file. , 2016, Chemical science.
[85] C. Cormos. Evaluation of reactive absorption and adsorption systems for post-combustion CO2 capture applied to iron and steel industry , 2016 .
[86] V. Manović,et al. Highly efficient CO2 capture with simultaneous iron and CaO recycling for the iron and steel industry , 2016 .
[87] F. Chowdhury,et al. Sustainable Aspects of Ultimate Reduction of CO2 in the Steelmaking Process (COURSE50 Project), Part 2: CO2 Capture , 2016, Journal of Sustainable Metallurgy.
[88] Kaimin Li,et al. CO2 abatement from the iron and steel industry using a combined Ca–Fe chemical loop , 2016 .
[89] Zheng‐gen Liu,et al. Mathematical Simulation on Blast Furnace Operation of Coke Oven Gas Injection in Combination with Top Gas Recycling , 2016 .
[90] Raja Ariffin Raja Ghazilla,et al. Evaluation of criteria for CO2 capture and storage in the iron and steel industry using the 2-tuple DEMATEL technique , 2016 .
[91] Yusoff Nukman,et al. Present needs, recent progress and future trends of energy-efficient Ultra-Low Carbon Dioxide (CO2) Steelmaking (ULCOS) program , 2016 .
[92] Cheng Bao,et al. Mathematical Modeling of the Energy Consumption and Carbon Emission for the Oxygen Blast Furnace with Top Gas Recycling , 2016 .
[93] Antti Arasto,et al. Staged implementation of alternative processes in an existing integrated steel mill for improved performance and reduced CO2 emissions. Part I: technical concept analysis , 2016 .
[94] Luis M. Romeo,et al. Anthracite oxy-combustion characteristics in a 90 kWth fluidized bed reactor , 2015 .
[95] H. Saxén,et al. Operation Windows of the Oxygen Blast Furnace with Top Gas Recycling , 2015 .
[96] Michitaka Sato,et al. Predictcion of Next-Generation Ironmaking Process Based on Oxygen Blast Furnace Suitable for CO2 Mitigation and Energy Flexibility , 2015 .
[97] Raja Ariffin Raja Ghazilla,et al. A comprehensive review on energy efficient CO2 breakthrough technologies for sustainable green iron and steel manufacturing , 2015 .
[98] Matteo C. Romano,et al. CO2 capture in integrated steelworks by commercial-ready technologies and SEWGS process , 2015 .
[99] Michitaka Sato,et al. Perspective on Progressive Development of Oxygen Blast Furnace for Energy Saving , 2015 .
[100] In-Beum Lee,et al. Economic process design for separation of CO2 from the off-gas in ironmaking and steelmaking plants , 2015 .
[101] Dawid P. Hanak,et al. A review of developments in pilot-plant testing and modelling of calcium looping process for CO2 capture from power generation systems , 2015 .
[102] Rajeev Kumar Sahu,et al. Applicability of Top Gas Recycle Blast Furnace with Downstream Integration and Sequestration in an Integrated Steel Plant , 2015 .
[103] T. Nakagaki,et al. Quantitative Evaluation of CO2 Emission Reduction of Active Carbon Recycling Energy System for Ironmaking by Modeling with Aspen Plus , 2015 .
[104] A. Steinfeld,et al. Reforming of Blast Furnace Gas with Methane, Steam, and Lime for Syngas Production and CO2 Capture: A Thermodynamic Study , 2015 .
[105] Eemeli Tsupari,et al. Oxygen blast furnace with CO2 capture and storage at an integrated steel mill—Part I: Technical concept analysis , 2014 .
[106] Kunwoo Han,et al. Performance of an ammonia-based CO2 capture pilot facility in iron and steel industry , 2014 .
[107] Jochen Ströhle,et al. Carbonate looping experiments in a 1 MWth pilot plant and model validation , 2014 .
[108] Jian-xun Fu,et al. Carbon Reduction Programs and Key Technologies in global Steel Industry , 2014 .
[109] Hannu Helle,et al. OPTIMIZATION OF STEELMAKING USING FASTMET DIRECT REDUCED IRON IN THE BLAST FURNACE , 2013 .
[110] Dianne E. Wiley,et al. Comparison of CO2 capture economics for iron and steel mills , 2013 .
[111] Jae-Young Choi,et al. Selective Gas Transport Through Few-Layered Graphene and Graphene Oxide Membranes , 2013, Science.
[112] J van der Stel,et al. Top gas recycling blast furnace developments for ‘green’ and sustainable ironmaking , 2013 .
[113] A. Sánchez-Biezma,et al. Demonstration of steady state CO2 capture in a 1.7 MWth Calcium looping pilot , 2013 .
[114] Y. Mogi,et al. Psa system for the recovery of carbon dioxide from blast furnace gas in steel works the infuence of operation conditions on co2 separation , 2013 .
[115] Jochen Ströhle,et al. Continuous CO2 Capture in a 1‐MWth Carbonate Looping Pilot Plant , 2013 .
[116] Eemeli Tsupari,et al. Post-combustion capture of CO2 at an integrated steel mill – Part II: Economic feasibility , 2013 .
[117] Antti Arasto,et al. Post-combustion capture of CO2 at an integrated steel mill: Part I: Technical concept analysis , 2013 .
[118] P. Sen. Co2 Accounting and Abatement: An Approach for Iron and Steel Industry , 2013, Transactions of the Indian Institute of Metals.
[119] Y. Mogi,et al. Development of PSA system for the recovery of carbon dioxide and carbon monoxide from blast furnace gas in steel works , 2012 .
[120] Richard C. Baliban,et al. Modeling, Simulation, and Optimization of Postcombustion CO2 Capture for Variable Feed Concentration and Flow Rate. 1. Chemical Absorption and Membrane Processes , 2012 .
[121] N. Cai,et al. Effect of Sorbent Type on the Sorption Enhanced Water Gas Shift Process in a Fluidized Bed Reactor , 2012 .
[122] Yi-hua Han,et al. Reduction Behavior of Sinter Based on Top Gas Recycling-Oxygen Blast Furnace , 2012 .
[123] Xun Wang,et al. Hydrogen amplification from coke oven gas using a CO2 adsorption enhanced hydrogen amplification reactor , 2012 .
[124] Andrea Ramírez,et al. Comparative assessment of CO2 capture technologies for carbon-intensive industrial processes , 2012 .
[125] Hannu Helle,et al. Nonlinear optimization of steel production using traditional and novel blast furnace operation strategies , 2011 .
[126] Yuichi Fujioka,et al. Development of novel absorbents for CO2 capture from blast furnace gas , 2011 .
[127] Mansheng Chu,et al. Numerical Evaluation of Blast Furnace Performance under Top Gas Recycling and Lower Temperature Operation , 2010 .
[128] J. Caro,et al. Steam-stable zeolitic imidazolate framework ZIF-90 membrane with hydrogen selectivity through covalent functionalization. , 2010, Journal of the American Chemical Society.
[129] Hannu Helle,et al. Multi-objective Optimization of Ironmaking in the Blast Furnace with Top Gas Recycling , 2010 .
[130] Ming Luo,et al. Chemical looping combustion of coke oven gas by using Fe2O3/CuO with MgAl2O4 as oxygen carrier , 2010 .
[131] Hannu Helle,et al. Optimization of Top Gas Recycling Conditions under High Oxygen Enrichment in the Blast Furnace , 2010 .
[132] Chung-Sung Tan,et al. CO2 capture from hot stove gas in steel making process , 2010 .
[133] Hui Zhang,et al. Conceptual design and simulation analysis of thermal behaviors of TGR blast furnace and oxygen blast furnace , 2010 .
[134] Guangqing Zuo,et al. The Trial of the Top Gas Recycling Blast Furnace at LKAB's EBF and Scale-up , 2009 .
[135] Dianne E. Wiley,et al. Reducing the Cost of CO2 Capture from Flue Gases Using Pressure Swing Adsorption , 2008 .
[136] Finn Andrew Tobiesen,et al. Modeling of Blast Furnace CO 2 Capture Using Amine Absorbents , 2007 .
[137] May-Britt Hägg,et al. Optimization of a membrane process for CO2 capture in the steelmaking industry , 2007 .
[138] Keigo Akimoto,et al. Diffusion of energy efficient technologies and CO2 emission reductions in iron and steel sector , 2007 .
[139] H. Nogami,et al. Numerical analysis of blast furnace operations with top gas recycling , 2005 .
[140] Michitaka Sato,et al. Design of Innovative Blast Furnace for Minimizing CO2 Emission Based on Optimization of Solid Fuel Injection and Top Gas Recycling , 2004 .
[141] Hiroshi Nogami,et al. Numerical Analysis on Blast Furnace Performance under Operation with Top Gas Recycling and Carbon Composite Agglomerates Charging , 2004 .
[142] Alexander Babich,et al. Operación de hornos altos con inyecciôn de carbón pulverizado en diferentes condiciones tecnológicas , 2001 .
[143] Benny D. Freeman,et al. Basis of Permeability/Selectivity Tradeoff Relations in Polymeric Gas Separation Membranes , 1999 .
[144] Hiroshi Nogami,et al. Prediction of Blast Furnace Performance with Top Gas Recycling , 1998 .
[145] Kornelis Blok,et al. Carbon dioxide recovery from industrial processes , 1995 .
[146] S. E. Lazutkin,et al. A Flow-chart for Iron Making on the Basis of 100% Usage of Process Oxygen and Hot Reducing Gases Injection. , 1994 .
[147] Takeshi Furukawa,et al. Process Characteristics of a Commercial-scale Oxygen Blast Furnace Process with Shaft Gas Injection. , 1992 .
[148] Luis M. Romeo,et al. Integration of CO2 capture and conversion , 2020 .
[149] C. Cormos,et al. Assessing the environmental impact of an integrated steel mill with post-combustion CO2 capture and storage using the LCA methodology , 2019, Journal of Cleaner Production.
[150] G. Manzolini,et al. Life Cycle Assessment of SEWGS Technology Applied to Integrated Steel Plants , 2019, Sustainability.
[151] Eemeli Tsupari,et al. Oxygen blast furnace with CO2 capture and storage at an integrated steel mill: Part II: Economic Feasibility in Comparison with Conventional Blast Furnace Highlighting Sensitivities , 2015 .
[152] Raja Ariffin Raja Ghazilla,et al. CO2 Capture and Storage for the iron and steel manufacturing industry: Challenges and Opportunities , 2014 .
[153] Eemeli Tsupari,et al. Costs and Potential of Carbon Capture and Storage at an Integrated Steel Mill , 2013 .
[154] Shigeaki Tonomura,et al. Outline of Course 50 , 2013 .
[155] Dianne E. Wiley,et al. Assessment of Opportunities for CO2 Capture at Iron and Steel Mills: An Australian Perspective , 2011 .
[156] Li Ming-ke. Study on Industrial Test of the Oxygen Blast Furnace , 2011 .
[157] Dianne E. Wiley,et al. Comparison of MEA capture cost for low CO2 emissions sources in Australia , 2011 .
[158] J. Borlée,et al. ULCOS - Pilot testing of the Low-CO 2 Blast Furnace process at the experimental BF in Luleå , 2009 .
[159] Jae-Ou Choi,et al. CO2 Reduction by Blast Furnace Top Gas Recycling Combined with Waste Hydrocarbon Gasification , 2004 .