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Energy and exergy analyses of the oxidation and gasification of carbon

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  • Prins, M.J.
  • Ptasinski, K.J.

Abstract

Exergy losses in gasification and combustion of solid carbon are compared by conceptually dividing the processes into several subprocesses: instantaneous chemical reaction, heat transfer from reaction products to reactants (internal thermal energy exchange) and product mixing. Gasification is more efficient than combustion because exergy losses due to internal thermal energy exchange are reduced from 14–16 to 5–7% of expended exergy, while the chemical reactions are relatively efficient for both processes. The losses due to internal thermal energy exchange may be reduced by replacing air with oxygen, although this introduces additional process losses for separation of oxygen from air, or alternatively, preheating of air by heat exchange with product gas. For oxygen-blown gasification of fuels with high calorific value, such as solid carbon, it is advisable to moderate the temperature by introduction of steam. At optimum gasification temperatures in the ranges of 1100–1200K (for atmospheric pressure) and 1200–1300K (for 10bar pressure), up to 75% of the chemical exergy contained in solid carbon can be preserved in the chemical exergy of carbon monoxide and hydrogen.

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  • Prins, M.J. & Ptasinski, K.J., 2005. "Energy and exergy analyses of the oxidation and gasification of carbon," Energy, Elsevier, vol. 30(7), pages 982-1002.
  • Handle: RePEc:eee:energy:v:30:y:2005:i:7:p:982-1002
    DOI: 10.1016/j.energy.2004.08.010
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    1. Caton, Jerald A, 2000. "On the destruction of availability (exergy) due to combustion processes — with specific application to internal-combustion engines," Energy, Elsevier, vol. 25(11), pages 1097-1117.
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    2. Jarungthammachote, S. & Dutta, A., 2007. "Thermodynamic equilibrium model and second law analysis of a downdraft waste gasifier," Energy, Elsevier, vol. 32(9), pages 1660-1669.
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    4. Greco, Gianluca & Di Stasi, Christian & Rego, Filipe & González, Belén & Manyà, Joan J., 2020. "Effects of slow-pyrolysis conditions on the products yields and properties and on exergy efficiency: A comprehensive assessment for wheat straw," Applied Energy, Elsevier, vol. 279(C).
    5. Karamarkovic, Rade & Karamarkovic, Vladan, 2010. "Energy and exergy analysis of biomass gasification at different temperatures," Energy, Elsevier, vol. 35(2), pages 537-549.
    6. Chintala, Venkateswarlu & Subramanian, K.A., 2014. "Assessment of maximum available work of a hydrogen fueled compression ignition engine using exergy analysis," Energy, Elsevier, vol. 67(C), pages 162-175.
    7. Silva, Isabelly P. & Lima, Rafael M.A. & Silva, Gabriel F. & Ruzene, Denise S. & Silva, Daniel P., 2019. "Thermodynamic equilibrium model based on stoichiometric method for biomass gasification: A review of model modifications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 114(C), pages 1-1.
    8. Liu, Guang-jian & Li, Zheng & Wang, Ming-hua & Ni, Wei-dou, 2010. "Energy savings by co-production: A methanol/electricity case study," Applied Energy, Elsevier, vol. 87(9), pages 2854-2859, September.
    9. Pellegrini, Luiz Felipe & de Oliveira, Silvio, 2007. "Exergy analysis of sugarcane bagasse gasification," Energy, Elsevier, vol. 32(4), pages 314-327.
    10. Loha, Chanchal & Chattopadhyay, Himadri & Chatterjee, Pradip K., 2011. "Thermodynamic analysis of hydrogen rich synthetic gas generation from fluidized bed gasification of rice husk," Energy, Elsevier, vol. 36(7), pages 4063-4071.
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    14. Eftekhari, Ali Akbar & Van Der Kooi, Hedzer & Bruining, Hans, 2012. "Exergy analysis of underground coal gasification with simultaneous storage of carbon dioxide," Energy, Elsevier, vol. 45(1), pages 729-745.
    15. Zhang, Jianyun & Zhou, Zhe & Ma, Linwei & Li, Zheng & Ni, Weidou, 2013. "Efficiency of wet feed IGCC (integrated gasification combined cycle) systems with coal–water slurry preheating vaporization technology," Energy, Elsevier, vol. 51(C), pages 137-145.
    16. Toghyani, Mahboubeh & Rahimi, Amir, 2015. "Exergy analysis of an industrial unit of catalyst regeneration based on the results of modeling and simulation," Energy, Elsevier, vol. 91(C), pages 1049-1056.
    17. Tsatsaronis, George & Morosuk, Tatiana & Koch, Daniela & Sorgenfrei, Max, 2013. "Understanding the thermodynamic inefficiencies in combustion processes," Energy, Elsevier, vol. 62(C), pages 3-11.
    18. Saulov, Dmitry N. & Plumb, Ovid A. & Klimenko, A.Y., 2010. "Flame propagation in a gasification channel," Energy, Elsevier, vol. 35(3), pages 1264-1273.
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