Deep learning with data preprocessing methods for water quality prediction in ultrafiltration

Ultrafiltration (UF) has been widely used to remove colloidal substances and suspended solids in feed water. However, UF membrane breakage can lead to downstream impurities flow, hindering subsequent filtration such as reverse osmosis. Preliminary detection for abnormal water quality after UF is vit...

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Bibliographic Details
Published inJournal of cleaner production Vol. 428; p. 139217
Main Authors Shim, Jaegyu, Hong, Seokmin, Lee, Jiye, Lee, Seungyong, Kim, Young Mo, Chon, Kangmin, Park, Sanghun, Cho, Kyung Hwa
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 20.11.2023
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Summary:Ultrafiltration (UF) has been widely used to remove colloidal substances and suspended solids in feed water. However, UF membrane breakage can lead to downstream impurities flow, hindering subsequent filtration such as reverse osmosis. Preliminary detection for abnormal water quality after UF is vital for cost-efficient operations, but current predictive models lack accuracy. This study investigated the predictive models using deep learning algorithms, specifically convolutional neural network (CNN) and long short-term memory (LSTM) structures. One month of data was provided from a UF system in a real seawater desalination plant. Unfortunately, conventional CNN and LSTM models struggled to predict sudden turbidity spikes caused by UF membrane damage (R2 < 0.2351). To address this challenge, we proposed a novel approach coupling wavelet signals and raw data. This technique enriched turbidity data with abundant waveform signals, resulting in a significant improvement in predictive accuracy (R2 < 0.9203). Shapley additive explanation demonstrated that the wavelet signals emphasized turbidity spikes, helping models in recognizing the extent of changes. This outcome of this study is the development of highly accurate predictive models for outflow turbidity after UF. These models will enhance the safety and efficiency of UF and subsequent filtration systems, improving their overall performance. •Four deep learning based models were proposed to predict turbidity after damaged UF.•Predicting drastic fluctuations in turbidity after UF was challenged with high error.•Coupling deep learning and wavelet transform helped improving predictive performance.•Sensitivity analysis proved the advantage of wavelet signals for precise prediction.
ISSN:0959-6526
1879-1786
DOI:10.1016/j.jclepro.2023.139217