Potentialities of a dense skin hollow fiber membrane contactor for biogas purification by pressurized water absorption

Potentialities of a dense skin hollow fiber membrane contactor for biogas purification by pressurized water absorption

Gas purification technologies are a key step in the technological chain using energy sources such as natural gas, coal gas or biogas, and represent a significant part of production costs. Numerous separation technologies exist to achieve required purity specifications depending on the particular app...

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Bibliographic Details
Published in:Journal of membrane science Vol. 513; pp. 236 - 249
Main Authors: Belaissaoui, Bouchra, Claveria-Baro, Joan, Lorenzo-Hernando, Ana, Albarracin Zaidiza, David, Chabanon, Elodie, Castel, Christophe, Rode, Sabine, Roizard, Denis, Favre, Eric
Format: Journal Article
Language:English
Published: Elsevier B.V 01-09-2016
Elsevier
Subjects:
Absorption
Biogas
Biogas purification
Chemical and Process Engineering
Chemical engineering
Chemical Sciences
Contactors
Dense skin membrane
Engineering Sciences
Intensification
Liquids
Mass transfer
Mathematical models
Membrane contactor
Membranes
Purification
Dense skin membrane
Intensification
Membrane contactor
Absorption
Biogas purification
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Summary:Gas purification technologies are a key step in the technological chain using energy sources such as natural gas, coal gas or biogas, and represent a significant part of production costs. Numerous separation technologies exist to achieve required purity specifications depending on the particular application (absorption, adsorption, cryogenic, membranes). The objective of this work is to present an evaluation of the potentialities of using a membrane contactor based on a dense skin Poly (Phenylene Oxide) (PPO) hollow fiber module for CO2 absorption from biogas by pressurized water through simulations and experiments. In this system, the liquid flowing on the shell-side is in direct contact with the dense skin, thus enabling pressurization and avoiding membrane wetting in order to maintain stable absorption performances. The overall mass transfer coefficient Kov, CO2 removal efficiency, and CH4 loss are evaluated for a range of liquid and gas flow rates. A one-dimensional (1D) model based on resistance in series provides very good predictions of the experimental results when the Graetz approach is used for shell-side mass transfer calculations. Membrane mass transfer resistance is shown to be negligible compared to the liquid resistance. Consequently, the overall mass transfer performances of the dense skin contactor are close to typical values of packed columns (10−5–10−4m/s). Thanks to the increased gas-liquid interfacial area offered by the membrane contactor, a significant volume reduction of the absorption unit (up to 15 process intensification factor) is potentially achievable. Moreover, a selective dense skin could minimize methane losses. •Similar mass transfer performances between dense skin and microporous.•Intensification factor up to 15 compared to packed columns.•Dense skin selectivity help to reduce methane losses.•Very good 1D model predictions.•Shell side mass transfer correlation is very important.
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ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2016.04.037