Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model
In this study, fouling mechanism and modelling analysis of synthetic lignocellulose biomass and agricultural palm oil effluent was studied using polyethersulfone (PES) ultrafiltration (UF) 10 kDa membrane. The impact of process variables (transmembrane pressure (TMP), pH and concentration of feed so...
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my.utm.1031552023-11-13T04:57:28Z http://eprints.utm.my/103155/ Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model Yogarathinam, Lukka Thuyavan Velswamy, Kirubakaran Gangasalam, Arthanareeswaran Ismail, Ahmad Fauzi Goh, Pei Sean Subramaniam, Mahesan Naidu Narayana, Mosangi Satya Yaacob, Nurshahnawal Abdullah, Mohd. Sohaimi TP Chemical technology In this study, fouling mechanism and modelling analysis of synthetic lignocellulose biomass and agricultural palm oil effluent was studied using polyethersulfone (PES) ultrafiltration (UF) 10 kDa membrane. The impact of process variables (transmembrane pressure (TMP), pH and concentration of feed solution) on lignocellulosic flux was analysed using pore blocking model. The feasible approaches on utilising deep learning artificial neural network (ANN) to predict smaller flux datasets are studied. Among the input variables, pH of lignin feed solution has significant control towards flux and lignin rejection coefficient for both lignin and lignocellulosic solution. Alteration in the structure of lignin at different pH conditions contributed in the improvement of lignin rejection coefficient to 0.98 at the feed pH of 9. A maximum steady state flux of 52.03 L/m2h was observed at the lower lignin concentration (0.25 g/L), TMP of 200 kPa and feed pH of 3. At high TMP and concentration, lignin rejection decreased due to enhancement of feed concentration on membrane surface. The mechanistic model exhibited that cake layer phenomena was dominant in both lignin and lignocellulosic solution. The proposed ANN model showed good correlation (R2-1.00) with experimental non-linear flux dynamic data of both lignin and synthetic lignocellulosic solution. In ANN analysis, activation function, algorithm and neuron effect have significant effect in design of accurate model for prediction of small flux datasets. Aerobically-treated palm oil mill filtration analysis also showed that cake layer phenomenon was dominant. A water recovery of 82 % was achieved even at low TMP under short durations. Elsevier Ltd 2022 Article PeerReviewed Yogarathinam, Lukka Thuyavan and Velswamy, Kirubakaran and Gangasalam, Arthanareeswaran and Ismail, Ahmad Fauzi and Goh, Pei Sean and Subramaniam, Mahesan Naidu and Narayana, Mosangi Satya and Yaacob, Nurshahnawal and Abdullah, Mohd. Sohaimi (2022) Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model. Chemosphere, 286 (NA). pp. 1-13. ISSN 0045-6535 http://dx.doi.org/10.1016/j.chemosphere.2021.131822 DOI : 10.1016/j.chemosphere.2021.131822 |
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TP Chemical technology Yogarathinam, Lukka Thuyavan Velswamy, Kirubakaran Gangasalam, Arthanareeswaran Ismail, Ahmad Fauzi Goh, Pei Sean Subramaniam, Mahesan Naidu Narayana, Mosangi Satya Yaacob, Nurshahnawal Abdullah, Mohd. Sohaimi Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
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In this study, fouling mechanism and modelling analysis of synthetic lignocellulose biomass and agricultural palm oil effluent was studied using polyethersulfone (PES) ultrafiltration (UF) 10 kDa membrane. The impact of process variables (transmembrane pressure (TMP), pH and concentration of feed solution) on lignocellulosic flux was analysed using pore blocking model. The feasible approaches on utilising deep learning artificial neural network (ANN) to predict smaller flux datasets are studied. Among the input variables, pH of lignin feed solution has significant control towards flux and lignin rejection coefficient for both lignin and lignocellulosic solution. Alteration in the structure of lignin at different pH conditions contributed in the improvement of lignin rejection coefficient to 0.98 at the feed pH of 9. A maximum steady state flux of 52.03 L/m2h was observed at the lower lignin concentration (0.25 g/L), TMP of 200 kPa and feed pH of 3. At high TMP and concentration, lignin rejection decreased due to enhancement of feed concentration on membrane surface. The mechanistic model exhibited that cake layer phenomena was dominant in both lignin and lignocellulosic solution. The proposed ANN model showed good correlation (R2-1.00) with experimental non-linear flux dynamic data of both lignin and synthetic lignocellulosic solution. In ANN analysis, activation function, algorithm and neuron effect have significant effect in design of accurate model for prediction of small flux datasets. Aerobically-treated palm oil mill filtration analysis also showed that cake layer phenomenon was dominant. A water recovery of 82 % was achieved even at low TMP under short durations. |
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Article |
| author |
Yogarathinam, Lukka Thuyavan Velswamy, Kirubakaran Gangasalam, Arthanareeswaran Ismail, Ahmad Fauzi Goh, Pei Sean Subramaniam, Mahesan Naidu Narayana, Mosangi Satya Yaacob, Nurshahnawal Abdullah, Mohd. Sohaimi |
| author_facet |
Yogarathinam, Lukka Thuyavan Velswamy, Kirubakaran Gangasalam, Arthanareeswaran Ismail, Ahmad Fauzi Goh, Pei Sean Subramaniam, Mahesan Naidu Narayana, Mosangi Satya Yaacob, Nurshahnawal Abdullah, Mohd. Sohaimi |
| author_sort |
Yogarathinam, Lukka Thuyavan |
| title |
Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
| title_short |
Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
| title_full |
Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
| title_fullStr |
Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
| title_full_unstemmed |
Parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
| title_sort |
parametric analysis of lignocellulosic ultrafiltration in lab scale cross flow module using pore blocking and artificial neural network model |
| publisher |
Elsevier Ltd |
| publishDate |
2022 |
| url |
http://eprints.utm.my/103155/ http://dx.doi.org/10.1016/j.chemosphere.2021.131822 |
| _version_ |
1783876352244449280 |
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13.214268 |