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Intelligent optimization for modelling superhydrophobic ceramic membrane oil flux and oil-water separation efficiency: Evidence from wastewater treatment and experimental laboratory

Usman, Jamilu and A. Salami, Babatunde and Gbadamosi, Afeez and Adamu, Haruna and Usman, A. G. and Mohammed Benaafi, Mohammed Benaafi and Abba, S. I. and Othman, Mohd. Hafiz Dzarfan and Aljundi, Isam H. (2023) Intelligent optimization for modelling superhydrophobic ceramic membrane oil flux and oil-water separation efficiency: Evidence from wastewater treatment and experimental laboratory. Chemosphere, 331 (NA). NA-NA. ISSN 0045-6535

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Official URL: http://dx.doi.org/10.1016/j.chemosphere.2023.13872...

Abstract

Due to the significant energy and economic losses brought on by the global oil spill, there has been an increased interest in oil-water separation. This study presents strong non-linear machine learning models (support vector regression (SVR) and Gaussian process regression (GPR)) with the Response surface method (RSM) to predict the oil flux and oil-water separation efficiency of wastewater using ceramic membrane technology. For the model development and prediction of oil flux (OF) and oil-water separation efficiency (OSE), oil concentration (mg/L), feed flow rate (mL/min), and pH were considered as input variables. The input variables are combined in three combinations to study the most contributing input features to the models’ performance. Mean square error (MSE) and Nash-Sutcliffe coefficient efficiency (NSE) were used to assess the prediction performances of the developed models with the different number of input combinations considered in the study. For the two target variables (OF and OSE), GPR and SVR models were used to separately predict them. For OF, the SVR-2 [Combo-2] model (MSE = 0.9255 and NSE = 2.7976) performed better with higher prediction accuracy compared to GPR-2 [Combo-2] model (MSE = 0.763 and NSE = 6.437). In addition, for OSE, the GPR-3 [Combo-3] model (MSE = 0.995 and NSE = 0.5544) performed slightly better than SVR-3 [Combo-3] model (MSE = 0.992 and NSE = 0.8066). The results showed that the SVR model with the combo-2 and GPR-3 models for OF and OSE variables are the proposed models with the best performance and accuracy. This machine learning study will aid in better evaluating the function of materials such as ceramic in membrane performance features such as oil flux and rejection prediction, separation efficiency, water recovery, membrane fouling, and so on. As for academics and manufacturers, this machine learning (ML) strategy will boost performance and allow a better understanding of system governance.

Item Type:Article
Uncontrolled Keywords:Ceramic membrane, Machine learning, Oil flux, Oil-water separation, Oily wastewater
Subjects:T Technology > TP Chemical technology
Divisions:Chemical and Energy Engineering
ID Code:106089
Deposited By: Widya Wahid
Deposited On:06 Jun 2024 08:22
Last Modified:06 Jun 2024 08:22

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