Predicting the concentration of hazardous phenolic compounds in refinery wastewater-a multivariate data analysis approach

abstract

The present study focused on the methodology for identification of the wastewater stream that presents the highest phenolic impact at a large oil refinery. As a case-study, the oil refinery, Petrogal S.A., in Sines, Portugal, was selected. Firstly, stripped sour water from the cracking complex was identified as the most relevant wastewater stream concerning phenolic emission. Secondly, multivariate data analysis was used, through projection to latent structures (PLS) regression, to find existing correlations between process parameters and phenols content in stripped sour water. The models developed allowed the prediction of phenols concentration with predictive errors down to 20.16 mg/L (corresponding to 8.2% average error), depending on the complexity of the correlation used, and R-2 values as high as 0.85. Models were based in input parameters related to fluid catalytic crackers (FCC) feedstock quality, crudemix and steam injected in the catalyst stripper. The studied data analysis approach showed to be useful as a tool to predict the phenolic content in stripped sour water. Such prediction would help improve the wastewater management system, especially the units responsible for phenol degradation. The methodology shown in this work can be used in other refineries containing catalytic cracking complexes, providing a tool which allows the online prediction of phenols in stripped sour water and the identification of the most relevant process parameters. An optimised system at any refinery leads to an improvement in the wastewater quality and costs associated with pollutant discharge; thus, the development of monitoring online tools, as proposed in this work, is essential.

keywords

ATMOSPHERIC RESIDUE; PLS; IDENTIFICATION

subject category

Environmental Sciences & Ecology

authors

Bastos, PDA; Galinha, CF; Santos, MA; Carvalho, PJ; Crespo, JG

our authors

acknowledgements

This work was supported by the Associated Laboratory for Sustainable Chemistry-Clean Processes and Technologies-LAQV and by CICECO-Aveiro Institute of Materials, which are financed by Portuguese national funds from Fundacao para a Ciencia e Tecnologia (Portugal) (UIDB/50006/2020 and UIDP/50011/2020) and co-financed by the ERDF under the PT2020 Partnership Agreement (POCI-01-0145-FEDER-007265). Galp and Fundacao para a Ciencia e Tecnologia (Portugal) funded the PhD grant PD/BDE/128604/2017 (P. D. A. Bastos) under a PhD project within an industrial environment and Doctoral Program in Refining, Petrochemical and Chemical Engineering (EngIQ). Fundacao para a Ciencia e Tecnologia (Portugal) funded the contract Investigador FCT 2015, contract number IF/00758/2015 (P. J. Carvalho).

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