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Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation

Airgap membrane distillation (AGMD) is an efficient configuration employed widely for the solar membrane distillation desalination process. In the present work, 1-D Knudsen and molecular transport (KMT) model has been developed to investigate the performance of the flat sheet PVDF membrane. A new so...

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Main Authors: Gopi, G., Vasanthkumar, M., Arthanareeswaran, G., Ismail, A. F., Thuyavan, Y. Lukka, Goh, P. S., Matsuura, T.
Format: Article
Published: Elsevier B.V. 2023
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TP Chemical technology
Online Access:http://eprints.utm.my/106557/
http://dx.doi.org/10.1016/j.desal.2023.116400
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spelling my.utm.1065572024-07-09T06:55:30Z http://eprints.utm.my/106557/ Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation Gopi, G. Vasanthkumar, M. Arthanareeswaran, G. Ismail, A. F. Thuyavan, Y. Lukka Goh, P. S. Matsuura, T. TP Chemical technology Airgap membrane distillation (AGMD) is an efficient configuration employed widely for the solar membrane distillation desalination process. In the present work, 1-D Knudsen and molecular transport (KMT) model has been developed to investigate the performance of the flat sheet PVDF membrane. A new solution algorithm for the co-current and counter-current flow regime has been designed to solve the heat and mass transfer equations iteratively for a single-stage AGMD module. The feed temperature, feed flow rate, airgap size, salinity, membrane porosity and module length were varied and compared with experimental results. The increase in feed temperature from 40 °C to 80 °C resulted in 10.38 times increase in flux for co-current flow and 11.05 times for counter-current flow. The maximum permeate flux at 80 °C was 8.668 kg/m2h and 8.871 kg/m2h for the co-current and counter-current processes, respectively. Optimizing the feed temperature, flow rate, and membrane length using RSM suggests 80 °C, 1.528 LPM and 10 m as the optimum operating condition. An AGMD module of size 0.8 m width and 10 m length under the optimum operating condition exhibited a freshwater yield of 8.73 kg/h by consuming 24.98 kWh/m3 of specific energy, and the water production cost would be around $2.25/m3. Elsevier B.V. 2023 Article PeerReviewed Gopi, G. and Vasanthkumar, M. and Arthanareeswaran, G. and Ismail, A. F. and Thuyavan, Y. Lukka and Goh, P. S. and Matsuura, T. (2023) Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation. Desalination, 551 (NA). NA-NA. ISSN 0011-9164 http://dx.doi.org/10.1016/j.desal.2023.116400 DOI : 10.1016/j.desal.2023.116400
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic TP Chemical technology
spellingShingle TP Chemical technology
Gopi, G.
Vasanthkumar, M.
Arthanareeswaran, G.
Ismail, A. F.
Thuyavan, Y. Lukka
Goh, P. S.
Matsuura, T.
Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation
description Airgap membrane distillation (AGMD) is an efficient configuration employed widely for the solar membrane distillation desalination process. In the present work, 1-D Knudsen and molecular transport (KMT) model has been developed to investigate the performance of the flat sheet PVDF membrane. A new solution algorithm for the co-current and counter-current flow regime has been designed to solve the heat and mass transfer equations iteratively for a single-stage AGMD module. The feed temperature, feed flow rate, airgap size, salinity, membrane porosity and module length were varied and compared with experimental results. The increase in feed temperature from 40 °C to 80 °C resulted in 10.38 times increase in flux for co-current flow and 11.05 times for counter-current flow. The maximum permeate flux at 80 °C was 8.668 kg/m2h and 8.871 kg/m2h for the co-current and counter-current processes, respectively. Optimizing the feed temperature, flow rate, and membrane length using RSM suggests 80 °C, 1.528 LPM and 10 m as the optimum operating condition. An AGMD module of size 0.8 m width and 10 m length under the optimum operating condition exhibited a freshwater yield of 8.73 kg/h by consuming 24.98 kWh/m3 of specific energy, and the water production cost would be around $2.25/m3.
format Article
author Gopi, G.
Vasanthkumar, M.
Arthanareeswaran, G.
Ismail, A. F.
Thuyavan, Y. Lukka
Goh, P. S.
Matsuura, T.
author_facet Gopi, G.
Vasanthkumar, M.
Arthanareeswaran, G.
Ismail, A. F.
Thuyavan, Y. Lukka
Goh, P. S.
Matsuura, T.
author_sort Gopi, G.
title Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation
title_short Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation
title_full Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation
title_fullStr Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation
title_full_unstemmed Performance, energy and economic investigation of airgap membrane distillation system: An experimental and numerical investigation
title_sort performance, energy and economic investigation of airgap membrane distillation system: an experimental and numerical investigation
publisher Elsevier B.V.
publishDate 2023
url http://eprints.utm.my/106557/
http://dx.doi.org/10.1016/j.desal.2023.116400
_version_ 1805880830761893888
score 13.2014675

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