This study focuses on thermochemical cavity-type reactor, with a reactive material directly irradiated by concentrated solar energy. General tendencies of reactor performance are analyzed as a function of the reactor geometry. The objective is to define a simplified model that can be adapted easily to different reactor designs or different operating conditions. For this reason, the chemical reaction is not precisely fixed but rather characterized by a reaction temperature and a useful power consumed by the endothermic reaction, inside the reactive material. In order to increase the efficiency, two new reactor designs are proposed. These designs allow obtaining a nonuniform distribution of the useful power consumed by the reaction with the depth in a circular cylindrical cavity (z-axis). This is done in two ways: by varying the reactive material thickness along the axis or by varying its density at a constant thickness. The results show that these reactor concepts lead to a more uniform temperature distribution along the z-axis and a diminution of the heat losses. Thus, the reactor efficiency can increase significantly. The results of the simplified model can be used as a system predesign. A more accurate CFD model could be used afterward to refine the optimal shape.

Issue Section:
Research Papers
Keywords:
chemical energy conversion, chemical reactions, chemical reactors, computational fluid dynamics, heat sinks, optimisation, power consumption, solar energy concentrators, solar power, temperature distribution, solar thermochemical reactor, concentrated solar energy, cavity reactor, geometrical optimization, new reactor design
Topics:
Cavities, Heat sinks, Optimization, Shapes, Solar energy, Temperature, Chemical reactions, Temperature distribution, Geometry, Design

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