Energy Equipment and Systems

Energy Equipment and Systems

Thermodynamic investigation on coal fired emission free s-CO2 power cycles

Document Type : Research Paper

Authors
Meeta Sharma
Anand Pavithran
Anoop Kumar Shukla
Amity University Uttar Pradesh, Noida, India
10.22059/ees.2024.2018260.1451
Abstract
India has a large amount of coal deposits, currently account for 60% of the nation's electricity production. However, burning coal for the purpose of producing energy is not environmentally friendly practice as it releases large quantities of CO2 and greenhouse gases into the atmosphere and causing global warming issues. Emissions from power generation plants can be effectively reduced by using an oxy-fuel combustion power generation system with carbon capture and storage. This work presents an effective solution to reduce carbon emissions from coal-powered power plants. The proposed power generation system consists of a coal gasifier integrated with an oxyfuel combustion power cycle and a carbon capture and storage unit. This work discusses three different configurations of coal-based oxy-combustion power generation systems. Each proposed cycles modelled thermodynamically, and investigations were conducted using the Engineering Equation Solver (EES). The sensitivity analysis and parametric study were performed for the chosen input variables, such as cycle pressure ratio, turbine inlet temperature, coal composition, and split ratio, and observed the effect on net power and thermal efficiency. The results indicate that the coal-based oxyfuel combustion cycles possess high first-law efficiency with a 100% carbon-capturing rate. The thermal efficiency was observed 23.4% for the basic version of the oxyfuel power cycle. By incorporating a recuperator into the basic cycle, the thermal efficiency reached 39.42%. Further, the recuperator integrated cycle is again modified with stream split and double expansion, and the thermal efficiency of the power cycle reached 41.33%.
Keywords
Oxy Fuel Combustion
Coal Based Power Generation
Emission Free Power Generation
Carbon Capture and Storage
s-CO2 Power Cycle
[1] Location wise regional summary of all India installed capacity (IN MW) of power stations as on 31/12/2020" (PDF). National Power Portal, GoI. Retrieved 19 January 2021.
[2] Fletcher WD, Smith CB. Reaching net zero: What it takes to solve the global climate crisis: Elsevier; 2020.
[3] Zachary J. Options for reducing a coal-fired plant's carbon footprint, Part II. Power (New York). 2008;152(7).
[4] Rackley S. Carbon capture and storage: Butterworth-Heinemann Press; 2017.
[5] Omoregbe O, Mustapha AN, Steinberger-Wilckens R, El-Kharouf A, Onyeaka H. Carbon capture technologies for climate change mitigation: A bibliometric analysis of the scientific discourse during 1998–2018. Energy reports. 2020;6:1200-12.
[6] Suomalainen MS, Arasto A, Teir S, Siitonen S. Improving a pre-combustion CCS concept in gas turbine combined cycle for CHP production. Energy Procedia. 2013;37:2327-40.
[7] Wang J-J, Jing Y-Y, Zhang C-F, Zhao J-H. Review on multi-criteria decision analysis aid in sustainable energy decision-making. Renewable and sustainable energy reviews. 2009;13(9):2263-78.
[8] Goanta A, Bohn J-P, Blume M, Li X, Spliethoff H, editors. Numerical Characterization of a Novel Staged Combustion Concept Applied to Oxy-Fuel Carbon Capture Technology. ASME International Mechanical Engineering Congress and Exposition; 2011.
[9] Vasudevan S, Farooq S, Karimi IA, Saeys M, Quah MC, Agrawal R. Energy penalty estimates for CO2 capture: Comparison between fuel types and capture-combustion modes. Energy. 2016;103:709-14.
[10] Chen S, Zheng Y, Wu M, Hu J, Xiang W. Thermodynamic analysis of oxy-fuel combustion integrated with the sCO2 Brayton cycle for combined heat and power production. Energy Conversion and Management. 2021;232:113869.
[11] Zhang Z, Li X, Luo C, Zhang L, Xu Y, Wu Y, et al. Investigation on the thermodynamic calculation of a 35 MWth oxy-fuel combustion coal-fired boiler. International Journal of Greenhouse Gas Control. 2018;71:36-45.
[12] Scheffknecht G, Al-Makhadmeh L, Schnell U, Maier J. Oxy-fuel coal combustion—A review of the current state-of-the-art. International Journal of Greenhouse Gas Control. 2011;5:S16-S35.
[13] Wall T, Yu J, editors. Coal-fired oxyfuel technology status and progress to deployment. The Proceedings of the 35th International Technical Conference on Clean Coal & Fuel Systems, The Clearwater Clean Coal Conference June; 2009.
[14] Buhre BJ, Elliott LK, Sheng C, Gupta RP, Wall TF. Oxy-fuel combustion technology for coal-fired power generation. Progress in energy and combustion science. 2005;31(4):283-307.
[15] Skorek-Osikowska A, Bartela L, Kotowicz J, Job M. Thermodynamic and economic analysis of the different variants of a coal-fired, 460 MW power plant using oxy-combustion technology. Energy Conversion and management. 2013;76:109-20.
[16] Rogalev N, Petrenya YK, Kindra V, Rogalev A. Oxy-fuel power cycles promoting the transition to green and sustainable future in the energy sector. Sustainable Fuel Technologies Handbook: Elsevier; 2021. p. 513-39.
[17] Crespi F, Gavagnin G, Sánchez D, Martínez GS. Supercritical carbon dioxide cycles for power generation: A review. Applied energy. 2017;195:152-83.
[18] Lu X, Forrest B, Martin S, Fetvedt J, McGroddy M, Freed D, editors. Integration and optimization of coal gasification systems with a near-zero emissions supercritical carbon dioxide power cycle. Turbo Expo: Power for Land, Sea, and Air; 2016: American Society of Mechanical Engineers.
[19] Allam R, Fetvedt J, Forrest B, Freed D, editors. The oxy-fuel, supercritical CO2 Allam Cycle: New cycle developments to produce even lower-cost electricity from fossil fuels without atmospheric emissions. Turbo Expo: Power for Land, Sea, and Air; 2014: American Society of Mechanical Engineers.
[20] Shelton W, White C, Gray D, Weiland N. Performance baseline for direct-fired sCO2 cycles. National Energy Technology Laboratory (NETL), Pittsburgh, PA, Morgantown, WV …; 2016.
[21] Weiland NT, White CW. Techno-economic analysis of an integrated gasification direct-fired supercritical CO2 power cycle. Fuel. 2018;212:613-25.
[22] Zhao Y, Wang B, Chi J, Xiao Y. Parametric study of a direct-fired supercritical carbon dioxide power cycle coupled to coal gasification process. Energy conversion and management. 2018;156:733-45.
[23] Zhu Z, Chen Y, Wu J, Zheng S, Zhao W. Performance study on s-CO2 power cycle with oxygen fired fuel of s-water gasification of coal. Energy Conversion and Management. 2019;199:112058.
[24] Xu C, Xin T, Li X, Li S, Sun Y, Liu W, et al. A thermodynamic analysis of a solar hybrid coal-based direct-fired supercritical carbon dioxide power cycle. Energy conversion and management. 2019;196:77-91.
[25] Chen Z, Wang Y, Zhang X. Energy and exergy analyses of S–CO2 coal-fired power plant with reheating processes. Energy. 2020;211:118651.
[26] Zhang Y, Li H, Han W, Bai W, Yang Y, Yao M, et al. Improved design of supercritical CO2 Brayton cycle for coal-fired power plant. Energy. 2018;155:1-14.
[27] Kumar KV, Bharath M, Raghavan V, Prasad B, Chakravarthy S, Sundararajan T. Gasification of high-ash Indian coal in bubbling fluidized bed using air and steam–An experimental study. Applied Thermal Engineering. 2017;116:372-81.
[28] Jin B, Zhao H, Zheng C, Liang Z. Control optimization to achieve energy-efficient operation of the air separation unit in oxy-fuel combustion power plants. Energy. 2018;152:313-21.
[29] Thorbergsson E, Grönstedt T. A Thermodynamic Analysis of Two Competing Mid‐Sized Oxyfuel Combustion Combined Cycles. Journal of Energy. 2016; 2016(1):2438431.
[30] Zhao Y, Yu B, Wang B, Zhang S, Xiao Y. Heat integration and optimization of direct-fired supercritical CO2 power cycle coupled to coal gasification process. Applied Thermal Engineering. 2018;130:1022-32.
[31] Cormos C-C. Oxy-combustion of coal, lignite and biomass: A techno-economic analysis for a large scale Carbon Capture and Storage (CCS) project in Romania. Fuel. 2016;169:50-7.
[32] Żogała A. Equilibrium simulations of coal gasification–factors affecting syngas composition. Journal of Sustainable Mining. 2014;13(2):30-8.
[33] La Villetta M, Costa M, Massarotti N. Modelling approaches to biomass gasification: A review with emphasis on the stoichiometric method. Renewable and Sustainable Energy Reviews. 2017;74:71-88.
[34] Zainal Z, Ali R, Lean C, Seetharamu K. Prediction of performance of a downdraft gasifier using equilibrium modeling for different biomass materials. Energy conversion and management. 2001;42(12):1499-515.
[35] Sleiti AK, Al-Ammari WA. Energy and exergy analyses of novel supercritical CO2 Brayton cycles driven by direct oxy-fuel combustor. Fuel. 2021;294:120557.
[36] Luo J, Emelogu O, Morosuk T, Tsatsaronis G. Exergy-based investigation of a coal-fired allam cycle. Energy. 2021;218:119471.
[37] Scaccabarozzi R, Gatti M, Martelli E. Thermodynamic analysis and numerical optimization of the NET Power oxy-combustion cycle. Applied energy. 2016;178:505-26.
[38] Shelton WW, Ames RW, Dennis RA, White CW, Plunkett JE, Fisher JC, et al., editors. Advanced and Transformational Hydrogen Turbines for Integrated Gasification Combined Cycles. Turbo Expo: Power for Land, Sea, and Air; 2016: American Society of Mechanical Engineers.
[39] Zhu Y, Chen M, Yang Q, Alshwaikh MJ, Zhou H, Li J, et al. Life cycle water consumption for oxyfuel combustion power generation with carbon capture and storage. Journal of Cleaner Production. 2021;281:124419.
[40] Gür TM. Carbon dioxide emissions, capture, storage and utilization: Review of materials, processes and technologies. Progress in Energy and Combustion Science. 2022;89:100965.
[41] Zhang Z, Pan S-Y, Li H, Cai J, Olabi AG, Anthony EJ, et al. Recent advances in carbon dioxide utilization. Renewable and sustainable energy reviews. 2020;125:109799.
[42] Hanak DP, Powell D, Manovic V. Techno-economic analysis of oxy-combustion coal-fired power plant with cryogenic oxygen storage. Applied Energy. 2017;191:193-203.
[43] Singh D, Croiset E, Douglas PL, Douglas MA. Techno-economic study of CO2 capture from an existing coal-fired power plant: MEA scrubbing vs. O2/CO2 recycle combustion. Energy conversion and Management. 2003;44(19):3073-91.
[44] Tola V, Cau G, Ferrara F, Pettinau A. CO2 emissions reduction from coal-fired power generation: A techno-economic comparison. Journal of Energy Resources Technology. 2016;138(6):061602.
[45] Zhou C, Shah K, Moghtaderi B. Techno-economic assessment of integrated chemical looping air separation for oxy-fuel combustion: an Australian case study. Energy & Fuels. 2015;29(4):2074-88.
[46] Wei X, Manovic V, Hanak DP. Techno-economic assessment of coal-or biomass-fired oxy-combustion power plants with supercritical carbon dioxide cycle. Energy Conversion and Management. 2020;221:113143.
Energy Equipment and Systems
Volume 12, Issue 3 - Serial Number 3
Summer 2024
Pages 197-216