Abstract
Ultrafiltration (UF) has become one of the dominant treatment processes for wastewater reclamation in China. Modeling is an effective instrument to understand and optimize UF systems. To this end, a previously developed UF model for organics removal was applied to the UF process in a typical, full-scale wastewater reclamation plant (WRP) in China. However, the sparse and incomplete field monitoring data from the studied WRP made the traditional model analysis approaches hardly work in this case. Therefore, two strategies, namely Strategy 1 and Strategy 2, were proposed, following a regional sensitivity analysis approach, for model parameter identification. Strategy 1 aimed to identify the model parameters and the missing model input, i.e. sampling times, simultaneously, while Strategy 2 tried to separate these two processes to reduce the dimension of the identification problem through an iteration procedure. With these two strategies, the model performed well in the Qinghe WRP with the absolute relative errors between the simulated and observed total organic carbon (TOC) generally below 10%. The four model parameters were all sensitive and identifiable, and even the sampling times could be roughly identified. Given the incomplete model input, these results were encouraging and added to the trustworthiness of model when it was applied to the Qinghe WRP.
Highlights
Ultrafiltration (UF) is a membrane filtration technology used for the separation of macromolecular solids from liquid
This study focuses on the UF system of the Qinghe wastewater reclamation plant (WRP), and historical monitoring data was obtained to examine the organics rejection performance of the UF system
This study aimed to examine the applicability of the previously developed UF model, which had been validated against data from the pilot-scale experiments (PSEs), to the full-scale Qinghe WRP
Summary
Ultrafiltration (UF) is a membrane filtration technology used for the separation of macromolecular solids from liquid. UF has been widely used in food, chemical and pharmaceutical industries since its development in the 1960s, and its application to water and wastewater treatment has been accelerated in the recent 30 years [1,2]. The advantages of UF technology lie in its ease of operation, high quality of permeate, and small space requirement [3]. Modeling UF process is critical to understanding, operating and optimizing UF systems, and various models have been developed to describe UF process. PLOS ONE | DOI:10.1371/journal.pone.0161300 August 16, 2016
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