Mathematical simulation and optimization of methanol dehydration and cyclohexane dehydrogenation in a thermally coupled dual-membrane reactor

Thermally coupling of endothermic and exothermic reactions in a membrane reactor improves thermal efficiency and production rate in the processes, reduces the size of reactors and decreases purification cost. This paper focuses on modeling and optimization of a thermally coupled dual-membrane reacto...

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Published in:International journal of hydrogen energy 2011-11, Vol.36 (22), p.14416-14427
Main Authors: Farsi, M., Jahanmiri, A.
Format: Article
Language:English
Subjects:
Alternative fuels. Production and utilization
Applied sciences
Benzene
Dehydration
Differential evolution
DME
Dual-membrane reactor
Energy
Exact sciences and technology
Fuels
Hydrogen
Hydrogen storage
Mathematical models
Membranes
Methyl alcohol
Optimization
Reactors
Thermally coupled reactor
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cited_by cdi_FETCH-LOGICAL-c374t-861619cba6c01ded2cd76d44ca0b518ef9da27b26f645b09755b6bf28da0d973
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container_end_page 14427
container_issue 22
container_start_page 14416
container_title International journal of hydrogen energy
container_volume 36
creator Farsi, M.
Jahanmiri, A.
description Thermally coupling of endothermic and exothermic reactions in a membrane reactor improves thermal efficiency and production rate in the processes, reduces the size of reactors and decreases purification cost. This paper focuses on modeling and optimization of a thermally coupled dual-membrane reactor for simultaneous production of hydrogen, dimethyl ether (DME) and benzene. A steady state heterogeneous mathematical model is developed to predict the performance of this novel configuration. The catalytic methanol dehydration reaction takes place in the exothermic side that supplies the necessary heat for the catalytic dehydrogenation of cyclohexane to benzene in the endothermic side. Selective permeation of hydrogen and water vapor through the Pd/Ag and composite membranes are achieved by co-current flow of sweep gas through the membrane wall. The differential evolution method is applied to optimize the thermally coupled dual-membrane reactor considering the summation of DME and benzene mole fractions from reaction sides and hydrogen mole fraction in the permeation side as the main objectives. The optimization results are compared with corresponding predictions for an industrial methanol dehydration adiabatic reactor operated at the same feed conditions. Methanol conversion enhances about 5.5% in the optimized thermally coupled dual-membrane reactor relative to the conventional DME reactor. The results suggest that coupling of these reactions in the proposed configuration could be feasible and beneficial. ► A thermally coupled dual-membrane reactor is modeled for production of hydrogen, DME and benzene. ► The model of methanol dehydration side is validated against conventional DME reactor. ► The operating conditions of the proposed reactor is optimized with DE algorithm.
doi_str_mv 10.1016/j.ijhydene.2011.08.019
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1879-3487
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source Elsevier:Jisc Collections:Elsevier Read and Publish Agreement 2022-2024:Freedom Collection (Reading list)
subjects Alternative fuels. Production and utilization
Applied sciences
Benzene
Dehydration
Differential evolution
DME
Dual-membrane reactor
Energy
Exact sciences and technology
Fuels
Hydrogen
Hydrogen storage
Mathematical models
Membranes
Methyl alcohol
Optimization
Reactors
Thermally coupled reactor
title Mathematical simulation and optimization of methanol dehydration and cyclohexane dehydrogenation in a thermally coupled dual-membrane reactor
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