Modeling and optimizing the performance of PVC/PVB ultrafiltration membranes using supervised learning approaches
Modeling and optimizing the performance of PVC/PVB ultrafiltration membranes using supervised learning approaches
Mathematical models play an important role in performance prediction and optimization of ultrafiltration (UF) membranes fabricated via dry/wet phase inversion in an efficient and economical manner. In this study, a systematic approach, namely, a supervised, learning-based experimental data analytics framework, is developed to model and optimize the flux and rejection rate of poly(vinyl chloride) (PVC) and polyvinyl butyral (PVB) blend UF membranes. Four supervised learning (SL) approaches, namely, the multiple additive regression tree (MART), the neural network (NN), linear regression (LR), and the support vector machine (SVM), are employed in a rigorous fashion. The dependent variables representing membrane performance response with regard to independent variables representing fabrication conditions are systematically analyzed. By comparing the predicting indicators of the four SL methods, the NN model is found to be superior to the other SL models with training and testing R-squared values as high as 0.8897 and 0.6344, respectively, for the rejection rate, and 0.9175 and 0.8093, respectively, for the flux. The optimal combination of processing parameters and the most favorable flux and rejection rate for PVC/PVB ultrafiltration membranes are further predicted by the NN model and verified by experiments. We hope the approach is able to shed light on how to systematically analyze multi-objective optimization issues for fabrication conditions to obtain the desired ultrafiltration membrane performance based on complex experimental data characteristics.
28038-28046
Chi, Lina
ae1400a8-9860-4851-94d6-6981267c5afd
Wang, Jie
6554e5ad-1ddd-485d-b954-89fee4685557
Chu, Tianshu
cda457ed-07b7-43be-abea-3ec8563069dc
Qian, Yingjia
52fab006-a18a-4c1c-9732-2e1c4d975336
Yu, Zhenjiang
f40d74d5-0f4a-4a6c-96b3-725355bc302e
Wu, Deyi
ff31fe43-6ba5-4a89-a659-3df67399635d
Zhang, Zhenjia
27f28f9a-1f64-431d-937e-0691c46a0afb
Jiang, Zheng
bcf19e78-f5c3-48e6-802b-fe77bd12deab
Leckie, James O.
e14a6eab-5c06-47fc-96d0-05e8aa41fc0d
11 March 2016
Chi, Lina
ae1400a8-9860-4851-94d6-6981267c5afd
Wang, Jie
6554e5ad-1ddd-485d-b954-89fee4685557
Chu, Tianshu
cda457ed-07b7-43be-abea-3ec8563069dc
Qian, Yingjia
52fab006-a18a-4c1c-9732-2e1c4d975336
Yu, Zhenjiang
f40d74d5-0f4a-4a6c-96b3-725355bc302e
Wu, Deyi
ff31fe43-6ba5-4a89-a659-3df67399635d
Zhang, Zhenjia
27f28f9a-1f64-431d-937e-0691c46a0afb
Jiang, Zheng
bcf19e78-f5c3-48e6-802b-fe77bd12deab
Leckie, James O.
e14a6eab-5c06-47fc-96d0-05e8aa41fc0d
Chi, Lina, Wang, Jie, Chu, Tianshu, Qian, Yingjia, Yu, Zhenjiang, Wu, Deyi, Zhang, Zhenjia, Jiang, Zheng and Leckie, James O.
(2016)
Modeling and optimizing the performance of PVC/PVB ultrafiltration membranes using supervised learning approaches.
RSC Advances, 6 (33), .
(doi:10.1039/C5RA24654G).
Abstract
Mathematical models play an important role in performance prediction and optimization of ultrafiltration (UF) membranes fabricated via dry/wet phase inversion in an efficient and economical manner. In this study, a systematic approach, namely, a supervised, learning-based experimental data analytics framework, is developed to model and optimize the flux and rejection rate of poly(vinyl chloride) (PVC) and polyvinyl butyral (PVB) blend UF membranes. Four supervised learning (SL) approaches, namely, the multiple additive regression tree (MART), the neural network (NN), linear regression (LR), and the support vector machine (SVM), are employed in a rigorous fashion. The dependent variables representing membrane performance response with regard to independent variables representing fabrication conditions are systematically analyzed. By comparing the predicting indicators of the four SL methods, the NN model is found to be superior to the other SL models with training and testing R-squared values as high as 0.8897 and 0.6344, respectively, for the rejection rate, and 0.9175 and 0.8093, respectively, for the flux. The optimal combination of processing parameters and the most favorable flux and rejection rate for PVC/PVB ultrafiltration membranes are further predicted by the NN model and verified by experiments. We hope the approach is able to shed light on how to systematically analyze multi-objective optimization issues for fabrication conditions to obtain the desired ultrafiltration membrane performance based on complex experimental data characteristics.
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Accepted/In Press date: 9 March 2016
Published date: 11 March 2016
Organisations:
Energy Technology Group
Identifiers
Local EPrints ID: 390009
URI: http://eprints.soton.ac.uk/id/eprint/390009
ISSN: 2046-2069
PURE UUID: 8e9432cb-9cc8-447d-856d-0407402759d8
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Date deposited: 17 Mar 2016 10:40
Last modified: 15 Mar 2024 05:26
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Contributors
Author:
Lina Chi
Author:
Jie Wang
Author:
Tianshu Chu
Author:
Yingjia Qian
Author:
Zhenjiang Yu
Author:
Deyi Wu
Author:
Zhenjia Zhang
Author:
James O. Leckie
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