Energy management of photovoltaic systems using fuel cells

Renewable energy generators show an accelerated growth both production wise, as well as in research fields. Focusing only on photovoltaic panels, the generated energy has the disadvantage of being strongly oscillatory in evolution. The classical solution is to create a network between photovoltaic farms spanning on large distances, in order to share the total energy before sending it to the clients. A solution that was recently proposed is to use hydrogen in order to store the energy surplus. Fuel Cells (FCs) represent energy generators whose energy vector is usually hydrogen. These have already started the transition from the laboratory context towards commercialization. Due to their high energy density, as well as their theoretical infinite storage capacity through hydrogen, configurations based on electrolyzers and FCs are seen as high potential storage systems, both for vehicle and for stationary applications. Therefore, a study on such distributed control systems is of high importance. This paper analyzes existing solutions, with emphasis on a particular case where a supervisory system is developed and tested in a specialized simulation software.

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