Biomass production by micro-algae is by a factor of 10 more efficient than by plants, by which an economic process of solar energy harvesting can be established. Owing to the very low dry mass content of algal suspensions, the most promising way of their conversion to a high exoergic and transportable form of energy is the anaerobic production of biogas. On account of this, we are developing such processes including a micro-algal reactor, methods for micro-algal cell separation and biomass treatment, and a subsequent two-stage anaerobic fermentation process. First results from parts of this development work are shown. The continuous feeding of the anaerobic process over several weeks using micro-algal biomass is discussed in more details. The biogas is composed of methane, higher hydrocarbons, carbon dioxide, and hydrogen sulphide. Using steam reforming, it can be converted to a mixture of carbon dioxide and hydrogen. These gases can be separated using membrane technology. It is possible to form a closed carbon cycle by recycling the carbon dioxide to the micro-algal process. The transportable and storable hydrogen product is a valuable energy source and can be converted to electrical energy and heat using fuel cells. The simulation of such a process will be explicated.
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August 2008
This article was originally published in
Journal of Fuel Cell Science and Technology
Research Papers
Combination of Biological Processes and Fuel Cells to Harvest Solar Energy
Dieter F. Ihrig,
Dieter F. Ihrig
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany
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H. Michael Heise,
H. Michael Heise
Institute for Analytical Sciences (ISAS) at Dortmund University of Technology
, 44139 Dortmund, Germany
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Ulrich Brunert,
Ulrich Brunert
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany; Institute for Analytical Sciences (ISAS) at Dortmund University of Technology
, 44139 Dortmund, Germany
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Martin Poschmann,
Martin Poschmann
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany
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Ruediger Kuckuk,
Ruediger Kuckuk
Institute for Analytical Sciences (ISAS) at Dortmund University of Technology
, 44139 Dortmund, Germany
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Klaus Stadtlander
Klaus Stadtlander
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany
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Dieter F. Ihrig
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany
H. Michael Heise
Institute for Analytical Sciences (ISAS) at Dortmund University of Technology
, 44139 Dortmund, Germany
Ulrich Brunert
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany; Institute for Analytical Sciences (ISAS) at Dortmund University of Technology
, 44139 Dortmund, Germany
Martin Poschmann
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, Germany
Ruediger Kuckuk
Institute for Analytical Sciences (ISAS) at Dortmund University of Technology
, 44139 Dortmund, Germany
Klaus Stadtlander
University of Applied Sciences Suedwestfalen
, 58644 Iserlohn, GermanyJ. Fuel Cell Sci. Technol. Aug 2008, 5(3): 031001 (5 pages)
Published Online: May 9, 2008
Article history
Received:
November 30, 2005
Revised:
February 20, 2007
Published:
May 9, 2008
Citation
Ihrig, D. F., Heise, H. M., Brunert, U., Poschmann, M., Kuckuk, R., and Stadtlander, K. (May 9, 2008). "Combination of Biological Processes and Fuel Cells to Harvest Solar Energy." ASME. J. Fuel Cell Sci. Technol. August 2008; 5(3): 031001. https://doi.org/10.1115/1.2889031
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