A Prioritized Satellite Task Scheduling Model Based on the Fewer Observation Opportunities
The
turbulent nature of catalytic reactions has been well reported. For some
reactions, the higher the rate of turbulence, the faster the reaction process.
This paper focus on the review of various research works where turbulence
models were employed in promoting and advancing study and knowledge of
catalysis or catalytic reaction systems (such as fixed bed reactor, trickle bed
reactor, combustor, among others) or processes in the twentieth centuries. It
also draws attention to several fluid computational dynamics package employed
in the simulation and different contributions that have been made in advancing
research in the field of catalysis via turbulence modeling. The essence of
these is to enhance effective and efficient reactant access to the active sites
of the catalyst. This study, however, shows that models such as k–e and RSM
turbulence models are better suited for predicting or studying turbulence behavior
in a catalytic reaction. It was realized that apart from selecting the
turbulence model, appropriate selection of the kinetic model plays a
significant role in promoting accurate prediction when carrying out
simulations. However, this study was able to identify that only a few research
works have given attention to the right and appropriate use or selection of a
kinetic model for catalytic reaction systems.
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