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Kinetics and heat transfer analysis of carbon catalyzed solar cracking process

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  • Ozalp, Nesrin
  • Ibrik, Karim
  • Al-Meer, Mariam

Abstract

Solar thermochemical processing offers production of many fuels and commodities via reduced emission footprint. Although solar reactor design and flow configuration play a key role in process efficiency, use of the right catalyst further enhances the overall efficiency. Solar cracking of methane provides an excellent example of the direct effect of carbon catalyst on the heat transfer which in turn affects the feedstock decomposition rate. In this paper, a compilation of our research results on the testing of carbon catalyst using thermogravimetry, and its impact on the heat transfer are summarized along with a thorough kinetics analysis of methane decomposition. It is seen that carbon seeding uniforms the reactor temperature and the volumetric heating caused by the suspended carbon particles substantially improves the reactor performance. 37 chemical gas-phase reactions and rate constants were considered to simulate the non-catalyzed methane cracking, whereas 8 chemical surface reactions and rate constants were considered for methane cracking with carbon catalyst. As for the heat transfer analysis, thermal interaction of gas-particle flow and the thermal hydraulics between gas flow and particle were studied by two way coupled Euler-Lagrange approach. Discrete ordinate model was used to solve radiative transport between reactor walls and entrained particles. The results show that when carbon loading is increased from 0.2 g/min to 0.6 g/min, the product gas temperature reduces from 1121 K to 1010 K, whereas mass fractions of methane shows 30% increase in efficiency.

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  • Ozalp, Nesrin & Ibrik, Karim & Al-Meer, Mariam, 2013. "Kinetics and heat transfer analysis of carbon catalyzed solar cracking process," Energy, Elsevier, vol. 55(C), pages 74-81.
    • Handle: RePEc:eee:energy:v:55:y:2013:i:c:p:74-81
    DOI: 10.1016/j.energy.2013.02.022
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    References listed on IDEAS

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    1. Jia, Nan & Zhang, Nan, 2011. "Multi-component optimisation for refinery hydrogen networks," Energy, Elsevier, vol. 36(8), pages 4663-4670.
    2. Neef, H.-J., 2009. "International overview of hydrogen and fuel cell research," Energy, Elsevier, vol. 34(3), pages 327-333.
    3. Johansson, Daniella & Franck, Per-Åke & Berntsson, Thore, 2012. "Hydrogen production from biomass gasification in the oil refining industry – A system analysis," Energy, Elsevier, vol. 38(1), pages 212-227.
    4. Singh, Bhawna & Strømman, Anders H. & Hertwich, Edgar G., 2012. "Scenarios for the environmental impact of fossil fuel power: Co-benefits and trade-offs of carbon capture and storage," Energy, Elsevier, vol. 45(1), pages 762-770.
    5. Keramiotis, Ch. & Vourliotakis, G. & Skevis, G. & Founti, M.A. & Esarte, C. & Sánchez, N.E. & Millera, A. & Bilbao, R. & Alzueta, M.U., 2012. "Experimental and computational study of methane mixtures pyrolysis in a flow reactor under atmospheric pressure," Energy, Elsevier, vol. 43(1), pages 103-110.
    6. Abánades, A. & Rubbia, C. & Salmieri, D., 2012. "Technological challenges for industrial development of hydrogen production based on methane cracking," Energy, Elsevier, vol. 46(1), pages 359-363.
    7. Tseng, Phillip & Lee, John & Friley, Paul, 2005. "A hydrogen economy: opportunities and challenges," Energy, Elsevier, vol. 30(14), pages 2703-2720.
    8. Dahl, Jaimee K & Buechler, Karen J & Finley, Ryan & Stanislaus, Timothy & Weimer, Alan W & Lewandowski, Allan & Bingham, Carl & Smeets, Alexander & Schneider, Adrian, 2004. "Rapid solar-thermal dissociation of natural gas in an aerosol flow reactor," Energy, Elsevier, vol. 29(5), pages 715-725.
    9. Hathaway, Brandon J. & Honda, Masanori & Kittelson, David B. & Davidson, Jane H., 2013. "Steam gasification of plant biomass using molten carbonate salts," Energy, Elsevier, vol. 49(C), pages 211-217.
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