Simulation of forward osmosis membrane process: Effect of membrane orientation and flow direction of feed and draw solutions

Simulation of forward osmosis membrane process: Effect of membrane orientation and flow direction of feed and draw solutions

Performance of forward osmosis (FO) process is significantly affected by factors such as membrane properties, concentration polarization (CP), and fouling. In this study, FO performance of a plate and frame type membrane is investigated via a numerical simulation based on mass conservation theorem....

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Veröffentlicht in:Desalination 2011-08, Vol.277 (1), p.83-91
Hauptverfasser: Jung, Da Hee, Lee, Jijung, Kim, Do Yeon, Lee, Young Geun, Park, Minkyu, Lee, Sangho, Yang, Dae Ryook, Kim, Joon Ha
Format: Artikel
Sprache:eng
Schlagworte:
Applied sciences
Computer simulation
Concentration polarization
cost effectiveness
desalination
Exact sciences and technology
Flow direction
Flux
Forward osmosis
Fouling
Mathematical models
Membrane orientation
Membranes
Orientation
Osmosis
physical properties
Plate and frame (PNF) module
Pollution
Simulation
solutes
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container_end_page 91
container_issue 1
container_start_page 83
container_title Desalination
container_volume 277
creator Jung, Da Hee
Lee, Jijung
Kim, Do Yeon
Lee, Young Geun
Park, Minkyu
Lee, Sangho
Yang, Dae Ryook
Kim, Joon Ha
description Performance of forward osmosis (FO) process is significantly affected by factors such as membrane properties, concentration polarization (CP), and fouling. In this study, FO performance of a plate and frame type membrane is investigated via a numerical simulation based on mass conservation theorem. To evaluate the FO membrane performance, permeate flux and recovery rate are simulated according to membrane orientation, flow direction of feed and draw solutions, flow rate, and solute resistivity ( K). In the case of membrane orientation, all-inside case, in which the draw solution faces the active layer, displays a relatively higher performance than all-outside and all-up cases. Notably, the membrane performance is highly affected by K indicating the extent of the internal CP. During the simulation approach, the spatial variation of the concentration profile was observed on a 2-dimensional membrane area; it was expected to cause a high diffusion load on a particular area of membrane, due to the relatively higher flux at that location. Moreover, it can result in unexpected fouling in a specific area on a membrane. Accordingly, the findings in this study suggest that the numerical simulation can be applied to optimize both physical properties and operation conditions, thereby ensuring cost-effective operation of FO processes. ► There is a considerable effect incurred by the membrane orientation. ► Spatial variation of concentration distribution and permeate flux was observed. ► Flow rate needs to be optimized for effective operation of FO processes. ► The membrane structure must be enhanced in order to attain better performance. ► The membrane properties are much more sensitive to FO membrane performance.
doi_str_mv 10.1016/j.desal.2011.04.001
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source Elsevier ScienceDirect Journals
subjects Applied sciences
Computer simulation
Concentration polarization
cost effectiveness
desalination
Exact sciences and technology
Flow direction
Flux
Forward osmosis
Fouling
Mathematical models
Membrane orientation
Membranes
Orientation
Osmosis
physical properties
Plate and frame (PNF) module
Pollution
Simulation
solutes
title Simulation of forward osmosis membrane process: Effect of membrane orientation and flow direction of feed and draw solutions
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