Abstract
High-throughput experimentation for catalysis testing has become an established practice in catalytic research, yet obtaining accurate and relevant results is still considered an art. Here, the engineering concepts of the Flowrence parallel smallscale reactor systems are discussed. The influence of catalyst particle size, flow patterns, pressure drop and temperature profiles on the quality of catalytic results is exemplified by several case studies on Fischer-Tropsch, Oxidative Coupling of Methane and Hydrotreating to obtain Ultra Low Sulfur Diesel.
Keywords: Flowrence, parallel small-scale reactor, catalyst particle size, catalyst bed dilution, hydrodynamics, flow patterns, trickle flow, mass transfer phenomena, heat transfer, isothermal, kinetic measurements, Fischer-Tropsch, Oxidative Coupling of Methane (OCM), Hydrotreating to Ultra Low Sulfur Diesel.
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