4.7 Article

hr Electro-oxidation of wastewater from a beauty salon: The influence of electrolyte type in the removal of organic load and energy consumption

Journal

PROCESS SAFETY AND ENVIRONMENTAL PROTECTION
Volume 177, Issue -, Pages 1260-1271

Publisher

ELSEVIER
DOI: 10.1016/j.psep.2023.07.078

Keywords

Beauty salon effluent; Electro-oxidation; Precipitates analysis; High-turbidity wastewater; Silicates; diamond electrode

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The aim of ensuring water quality and wastewater treatment is emphasized in the sixth sustainable development goal (SDG6) set by the United Nations. Beauty salons (BS), as widely available services, generate effluents with potentially hazardous chemicals that require treatment before being discharged into the sewage system. This study presents a comprehensive characterization of a BS effluent and investigates its electrochemical treatment using boron-doped diamond (BDD) as the anode, stainless steel as the cathode, and NaCl and Na2SO4 as additional supporting electrolytes. The analysis of chemical oxygen demand (COD) removal and energy consumption shows that NaCl is more efficient than Na2SO4 in treating the BS effluent, exhibiting higher COD removal (70% compared to 64% at a current density of 10 mA cm-2), lower turbidity and color in the effluent, and a pH closer to neutral without the need for further correction before discharge. The study also identifies Si-based oxides as the cause of high turbidity in the raw effluent, which can be effectively treated using NaCl as the electrolyte. The proposed treatment method aligns with SDG6 and can serve as an alternative for decision-makers and governments in implementing better water sanitation policies.
The aim to ensure water quality and wastewater treatment is sought by the United Nations and expressly proposed in the sixth sustainable development goal (SDG6). As universally available services, beauty salons (BS) are places that deal with potentially hazardous chemicals, and their effluent should be treated before goes to the sewage system. This work presents a wide characterization of a BS effluent and its respective electrochemical treatment by using boron-doped diamond (BDD) as the anode, stainless steel as the cathode, as well as NaCl and Na2SO4 as additional supporting electrolytes. The effectiveness of the processes and the comparative study of the performance of the electrolytes were mainly performed by the analysis of chemical oxygen demand (COD) removal and energy consumption. However, other parameters were taken into consideration, such as color, conductivity/salinity, pH, and more extensive analysis regarding the cause of turbidity and the appearance of a precipitate before and during the electrolysis. NaCl proved to be more efficient than Na2SO4 to treat this BS effluent; it was not only because achieves a better COD removal (70% against 64%, with a current density of 10 mA cm � 2), but also because it promoted an effluent with less turbidity and color, besides a pH closer to neutral, with no need to further correction before discharge. Regarding the electrolyte concentration, the excess of salt proved to be necessary to promote a higher removal rate in COD values with less charge and energy consumption. Thus, the concentration of 0.16 M of NaCl associated with a current density of 10 mA cm-2 was chosen as the best condition for treating this effluent. In addition, Si-based oxides were detected in the raw effluent and these were pointed out as responsible for its high turbidity. Proper discharge of it into the sewage system is reached with NaCl as the electrolyte. The treatment proposed in this work deals with SDG6 and can be used as an alternative to decision-makers and governments to help in the implementation of better politics of water sanitation.

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