Microtechnology-Based Energy and Chemical Systems will most likely employ combustion for driving processes such as vapor generation and vapor barrier, endothermic chemical reactions, and (most notably) fuel reforming. Both fuel reformers and combustors will be of a miniature design relying on embedded catalysts for promoting chemical reactions at moderate temperatures (350–7501C). Many potential configurations exist depending on the application and constraints on the design. Microchannel arrays are a potential configuration; mesh and post architecture is another to achieve the desired surface area and small diffusional lengths necessary. (more…)
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Fuel cells are direct energy conversion devices that combine two reactants to produce electrical power. The reactants are typically a fuel such as hydrogen fuel cells, or methanol, and oxygen from the air. Fuel cells require an electrolyte capable of passing an ionic charge carrier across an electronic conduction barrier where the ions are driven by a concentration gradient. Fuel cells also need a catalytic-based anode and cathode for reactant preparation. For mesoscale/ microscale systems, fuel cells are best fabricated in thin film form. Depending on the desired power output of the system, the ‘‘footprint’’ may well be relatively large to supply the required power. (more…)
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Mixing is a process where two or more liquids or gas phase components are brought together and combined to form a uniform composition. Both turbulent and diffusive processes are typically employed to achieve the mixing action. As the scale of the process is reduced, diffusion becomes dominant. Microtechnology mixers are designed to bring together individual components for mixing with the smallest diffusional scales possible. (more…)
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