Simulation and analysis of the performance of tubular enzymatic membrane reactors under different configurations, kinetics and mass transport conditions

A model was developed to simulate tubular enzymatic membrane reactors under three different configurations: dead-end, tangential flow with a porous enzymatic membrane and a non-permeable enzymatic wall. The simulations were applied to analyze the influence of reactor configuration, kinetics and mass...

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Published in:Journal of membrane science 2015-01, Vol.473, p.189-200
Main Authors: Abejón, R., Gijiu, C.L., Belleville, M.P., Paolucci-Jeanjean, D., Sanchez-Marcano, J.
Format: Article
Language:English
Subjects:
Chemical Sciences
Computer simulation
Conversion
Enzymatic membrane reactor
Membranes
Modeling
Optimization
Reaction kinetics
Reactors
Sensitivity analysis
Simulation
Transport
Walls
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cited_by cdi_FETCH-LOGICAL-c443t-9c358b644b45320bb55047c3e4555e4bd5731c762987fa63762be65be27737213
cites cdi_FETCH-LOGICAL-c443t-9c358b644b45320bb55047c3e4555e4bd5731c762987fa63762be65be27737213
container_end_page 200
container_issue
container_start_page 189
container_title Journal of membrane science
container_volume 473
creator Abejón, R.
Gijiu, C.L.
Belleville, M.P.
Paolucci-Jeanjean, D.
Sanchez-Marcano, J.
description A model was developed to simulate tubular enzymatic membrane reactors under three different configurations: dead-end, tangential flow with a porous enzymatic membrane and a non-permeable enzymatic wall. The simulations were applied to analyze the influence of reactor configuration, kinetics and mass transport conditions over the reactor performance in order to identify the main aspects to be taken into consideration for attaining optimal designs. The non-permeable enzymatic wall configuration under the evaluated conditions seems to be more valuable than the dead-end case in terms of substrate conversion and the tangential configuration looked more favorable to promote the best conversion in the permeate but not in the retentate. It was demonstrated that for a similar value, the Damköhler number can result in very dissimilar performances. The simulated results demonstrated that the most significant variable of the global performance of the enzymatic membrane reactors is the reaction kinetics: fast reactions attained very considerable conversion values under very different conditions. •A model for a membrane reactor with a tubular ceramic enzymatic membrane was developed.•Three configurations were studied: non-porous enzymatic wall, dead-end and tangential flow.•The model allowed analyzing the influence of configuration, kinetics and mass transport conditions over the reactor performance.•The most significant variable of the global performance of the enzymatic membrane reactors is the reaction kinetics.
doi_str_mv 10.1016/j.memsci.2014.09.020
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source Elsevier:Jisc Collections:Elsevier Read and Publish Agreement 2022-2024:Freedom Collection (Reading list)
subjects Chemical Sciences
Computer simulation
Conversion
Enzymatic membrane reactor
Membranes
Modeling
Optimization
Reaction kinetics
Reactors
Sensitivity analysis
Simulation
Transport
Walls
title Simulation and analysis of the performance of tubular enzymatic membrane reactors under different configurations, kinetics and mass transport conditions
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