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A solar chemical reactor for co-production of zinc and synthesis gas

Author

Listed:
  • Steinfeld, A.
  • Brack, M.
  • Meier, A.
  • Weidenkaff, A.
  • Wuillemin, D.

Abstract

A novel solar chemical reactor has been designed to perform the combined ZnO-reduction and CH4-reforming processes. It consists of a gas-particle vortex flow confined to a solar cavity-receiver that is exposed to concentrated solar irradiation. A 5-kW reactor was fabricated and tested in a high-flux solar furnace. The design methodology and experimental program are described. Tests were conducted from 1000 to 1600K and yielded up to 90% chemical conversion of zinc in a single pass.

Suggested Citation

  • Steinfeld, A. & Brack, M. & Meier, A. & Weidenkaff, A. & Wuillemin, D., 1998. "A solar chemical reactor for co-production of zinc and synthesis gas," Energy, Elsevier, vol. 23(10), pages 803-814.
  • Handle: RePEc:eee:energy:v:23:y:1998:i:10:p:803-814
    DOI: 10.1016/S0360-5442(98)00026-7
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    Citations

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    Cited by:

    1. Kräupl, Stefan & Wieckert, Christian, 2007. "Economic evaluation of the solar carbothermic reduction of ZnO by using a single sensitivity analysis and a Monte-Carlo risk analysis," Energy, Elsevier, vol. 32(7), pages 1134-1147.
    2. Alvarez Rivero, M. & Rodrigues, D. & Pinheiro, C.I.C. & Cardoso, J.P. & Mendes, L.F., 2022. "Solid–gas reactors driven by concentrated solar energy with potential application to calcium looping: A comparative review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 158(C).
    3. Cabeza, Luisa F. & Solé, Aran & Fontanet, Xavier & Barreneche, Camila & Jové, Aleix & Gallas, Manuel & Prieto, Cristina & Fernández, A. Inés, 2017. "Thermochemical energy storage by consecutive reactions for higher efficient concentrated solar power plants (CSP): Proof of concept," Applied Energy, Elsevier, vol. 185(P1), pages 836-845.
    4. Epstein, Michael & Ehrensberger, Koebi & Yogev, Amnon, 2004. "Ferro-reduction of ZnO using concentrated solar energy," Energy, Elsevier, vol. 29(5), pages 745-756.
    5. Kodama, T & Ohtake, H & Matsumoto, S & Aoki, A & Shimizu, T & Kitayama, Y, 2000. "Thermochemical methane reforming using a reactive WO3/W redox system," Energy, Elsevier, vol. 25(5), pages 411-425.
    6. Halmann, M. & Frei, A. & Steinfeld, A., 2002. "Thermo-neutral production of metals and hydrogen or methanol by the combined reduction of the oxides of zinc or iron with partial oxidation of hydrocarbons," Energy, Elsevier, vol. 27(12), pages 1069-1084.
    7. Palumbo, R. & Keunecke, M. & Möller, S. & Steinfeld, A., 2004. "Reflections on the design of solar thermal chemical reactors: thoughts in transformation," Energy, Elsevier, vol. 29(5), pages 727-744.
    8. Cesare Caputo & Ondřej Mašek, 2021. "SPEAR (Solar Pyrolysis Energy Access Reactor): Theoretical Design and Evaluation of a Small-Scale Low-Cost Pyrolysis Unit for Implementation in Rural Communities," Energies, MDPI, vol. 14(8), pages 1-27, April.
    9. Sarker, M.R.I. & Mandal, Soumya & Tuly, Sumaiya Sadika, 2018. "Numerical study on the influence of vortex flow and recirculating flow into a solid particle solar receiver," Renewable Energy, Elsevier, vol. 129(PA), pages 409-418.
    10. Gabriel Zsembinszki & Aran Solé & Camila Barreneche & Cristina Prieto & A. Inés Fernández & Luisa F. Cabeza, 2018. "Review of Reactors with Potential Use in Thermochemical Energy Storage in Concentrated Solar Power Plants," Energies, MDPI, vol. 11(9), pages 1-23, September.
    11. Sarker, M.R.I. & Saha, Manabendra & Rahman, Md Sazan & Beg, R.A., 2016. "Recirculating metallic particles for the efficiency enhancement of concentrated solar receivers," Renewable Energy, Elsevier, vol. 96(PA), pages 850-862.
    12. Halmann, M. & Frei, A. & Steinfeld, A., 2007. "Carbothermal reduction of alumina: Thermochemical equilibrium calculations and experimental investigation," Energy, Elsevier, vol. 32(12), pages 2420-2427.
    13. Nikulshina, V. & Hirsch, D. & Mazzotti, M. & Steinfeld, A., 2006. "CO2 capture from air and co-production of H2 via the Ca(OH)2–CaCO3 cycle using concentrated solar power–Thermodynamic analysis," Energy, Elsevier, vol. 31(12), pages 1715-1725.
    14. Adrián García & Rut Sanchis & Francisco J. Llopis & Isabel Vázquez & María Pilar Pico & María Luisa López & Inmaculada Álvarez-Serrano & Benjamín Solsona, 2020. "Ni Supported on Natural Clays as a Catalyst for the Transformation of Levulinic Acid into γ-Valerolactone without the Addition of Molecular Hydrogen," Energies, MDPI, vol. 13(13), pages 1-19, July.
    15. Kodama, T. & Shimizu, T. & Satoh, T. & Shimizu, K.-I., 2003. "Stepwise production of CO-rich syngas and hydrogen via methane reforming by a WO3-redox catalyst," Energy, Elsevier, vol. 28(11), pages 1055-1068.
    16. Wieckert, Christian & Palumbo, Robert & Frommherz, Ulrich, 2004. "A two-cavity reactor for solar chemical processes: heat transfer model and application to carbothermic reduction of ZnO," Energy, Elsevier, vol. 29(5), pages 771-787.

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