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Counting bubbles : precision process control of gas-liquid reactions in flow with an optical inline sensor
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Cherkasov, Nikolay, Exposito, Antonio, Bai, Yang and Rebrov, Evgeny V. (2019) Counting bubbles : precision process control of gas-liquid reactions in flow with an optical inline sensor. Reaction Chemistry & Engineering, 4 (1). pp. 112-121. doi:10.1039/C8RE00186C ISSN 2058-9883.
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WRAP-counting-bubbles-prcision-gas-liquid-flow-Cherkasov-2018.pdf - Accepted Version - Requires a PDF viewer. Download (1321Kb) | Preview |
Official URL: http://dx.doi.org/10.1039/C8RE00186C
Abstract
Quality by Design encouraged by the US Food and Drug Administration (FDA) in the continuous flow synthesis requires tight monitoring of all the reaction input and output parameters to improve reproducibility and eliminate the process rejects. The reaction monitoring, however, relies on costly (above 10,000$) process analytical technology (PAT) – one of the factors that prevents a wider utilisation of continuous processes. In the work, we show that gas-liquid reactions can be monitored using low-cost (10$) hardware – optical liquid inline sensors – that allows instantaneous analysis of gas fraction in the moving stream. We discuss the application of the sensor for various gas-liquid reactions. The gas-consuming reactions such as hydrogenation are the easiest to implement because the sensor without calibration provides accurate readings close to complete consumption of the gas. The gas-evolving reactions can be monitored but require sensor calibration to determine the gas fraction accurately. Operation of the sensor was demonstrated for various hydrogenation reactions self-optimised using a proportional-integral (PID) algorithm which adjusted the substrate concentration to provide high (but not full) pre-defined hydrogen consumption. The optimised hydrogen consumption agreed with the product analysis for a range of the substrates hydrogenated under various pressures and with different selectivities. The optical sensor was also proven to be an efficient tool in adapting the reaction condition to the catalyst deactivation in the reaction of 2-methyl-3-butyn-2-ol semi-hydrogenation – the autonomous reactor allowed reaching a turn-over number (TON) of 2.7·106 with the value of 1.5·107 expected till a twofold decrease in the catalyst activity. The TON values demonstrated are significantly higher than those observed in batch reactors (~103) even in case of catalyst re-use (105) demonstrating a substantial improvement of process sustainability operating with the process control.
Item Type: | Journal Article | ||||||||
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Subjects: | Q Science > QC Physics Q Science > QD Chemistry |
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Divisions: | Faculty of Science, Engineering and Medicine > Engineering > Engineering | ||||||||
Library of Congress Subject Headings (LCSH): | Hydrogenation, Hydrogenolysis, Liquids -- Optical properties | ||||||||
Journal or Publication Title: | Reaction Chemistry & Engineering | ||||||||
Publisher: | Royal Society of Chemistry | ||||||||
ISSN: | 2058-9883 | ||||||||
Official Date: | 1 January 2019 | ||||||||
Dates: |
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Volume: | 4 | ||||||||
Number: | 1 | ||||||||
Page Range: | pp. 112-121 | ||||||||
DOI: | 10.1039/C8RE00186C | ||||||||
Status: | Peer Reviewed | ||||||||
Publication Status: | Published | ||||||||
Access rights to Published version: | Restricted or Subscription Access | ||||||||
Date of first compliant deposit: | 29 October 2018 | ||||||||
Date of first compliant Open Access: | 23 October 2019 | ||||||||
RIOXX Funder/Project Grant: |
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