Catalyst-trap microreactor for hydrogenation of a pharmaceutical intermediate

S. McGovern, H. Gadre, R. S. Besser, C. S. Pai, W. Mansfield, S. Pau

Research output: Chapter in Book/Report/Conference proceedingConference contribution

1 Scopus citations

Abstract

A silicon microreactor has been developed to investigate gas-liquid-solid catalytic reactions. The reactor employs a three-channel "catalyst-trap" design, whereby solid catalyst is suspended in the liquid channel by an arrangement of posts. Such a device has advantages in that commercial catalysts are supported, and that pressure drop across the bed can be reduced by engineering the packing density. A model incorporating the transport and kinetic effects is developed to design the reactor. The reaction chosen is one in a family of reactions relevant to the pharmaceutical industry, the liquid-phase hydrogenation of o-nitroanisole to o-anisidine. The reaction is carried out across a range of gas and liquid flow rates that encompasses three distinct flow regimes, termed gas-dominated, liquid-dominated, and transitional. Experiments seek to assign a reaction conversion and selectivity to each point in this two-phase "flow map", then reconcile differences in performance with the characteristics of the respective flow regime. We observe the highest reaction conversion in the transitional flow regime, where competition between the two phases results in the generation of a large amount of gas-liquid interfacial area. The experimental conversion is greater than that predicted by the model, an effect attributable to the mass transfer enhancement induced by transitional flow. Reaction time within the microchannel is sufficiently small so that selectivity towards production of o-anisidine is nearly 100% across all flow regimes. In this work we relate our map of conversion to the flow behavior and reactor geometry, and we discuss steps for further exploring the mass transfer characteristics of the transitional flow regime. This reactor architecture may be useful for catalyst evaluation through rapid screening, or in large numbers as an alternative to macro-scale production reactors.

Original languageEnglish (US)
Title of host publicationTopical Conference on Applications of Micro-Reactor Engineering 2006, Held at the 2006 AIChE Spring National Meeting
PublisherAIChE
Pages295-303
Number of pages9
ISBN (Electronic)9781604235258
StatePublished - 2006
Externally publishedYes
EventTopical Conference on Applications of Micro-Reactor Engineering 2006, Held at the 2006 AIChE Spring National Meeting - Orlando, United States
Duration: Apr 23 2006Apr 27 2006

Publication series

NameTopical Conference on Applications of Micro-Reactor Engineering 2006, Held at the 2006 AIChE Spring National Meeting

Other

OtherTopical Conference on Applications of Micro-Reactor Engineering 2006, Held at the 2006 AIChE Spring National Meeting
Country/TerritoryUnited States
CityOrlando
Period4/23/064/27/06

ASJC Scopus subject areas

  • Process Chemistry and Technology
  • Industrial and Manufacturing Engineering

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