Exploring the Steady Operation of a Continuous Pilot Plant for the Di‐Nitration Reaction

Continuous‐flow synthesis of the selective herbicide pendimethalin was demonstrated in both a laboratory‐scale and a pilot‐scale reactor using only concentrated nitric acid as nitrating agent. The di‐nitration reaction follows second‐order kinetics where the reaction is first order with respect to b...

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Published in:Chemical engineering & technology 2019-10, Vol.42 (10), p.2241-2251
Main Authors: Sharma, Mrityunjay, Acharya, Roopashree B., Kulkarni, Amol A.
Format: Article
Language:English
Subjects:
Chemical synthesis
Continuous flow
Continuous manufacturing
Di‐nitration
Equilibrium flow
Feature extraction
Herbicides
Laboratories
Mass transfer
Nitration
Nitric acid
Phase separation
Pilot plants
Reaction kinetics
Reactor design
Scale‐up
Steady state
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description Continuous‐flow synthesis of the selective herbicide pendimethalin was demonstrated in both a laboratory‐scale and a pilot‐scale reactor using only concentrated nitric acid as nitrating agent. The di‐nitration reaction follows second‐order kinetics where the reaction is first order with respect to both reactant and nitric acid. The pinched‐tube reactor was chosen for pilot‐scale reactor fabrication due to its excellent mixing and mass transfer characteristics compared to a straight‐tube reactor. The estimated mass transfer coefficient showed similar nature in the laboratory‐scale and the pilot‐scale pinched‐tube reactor, ensuring similar performance at the pilot scale. Di‐nitration in continuous flow, inline quenching, extraction, and phase separation are some of the salient features of the developed pilot plant. The importance of the start‐up time for achieving steady state in the flow system at the large scale is highlighted. The highly exothermic di‐nitration reaction for pendimethalin synthesis was successfully carried out in a pilot‐scale reactor. Model equations showed that a 1/4‐inch‐diameter tube as continuous reactor provides the desired output while meeting the heat transfer requirements. The time to achieve temperature steady state was the controlling factor compared to the overall time to achieve steady state.
doi_str_mv 10.1002/ceat.201900140
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subjects Chemical synthesis
Continuous flow
Continuous manufacturing
Di‐nitration
Equilibrium flow
Feature extraction
Herbicides
Laboratories
Mass transfer
Nitration
Nitric acid
Phase separation
Pilot plants
Reaction kinetics
Reactor design
Scale‐up
Steady state
title Exploring the Steady Operation of a Continuous Pilot Plant for the Di‐Nitration Reaction
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