Removal Efficiency of Nitrite and Sulfide Pollutants by Electrochemical Process by Using Ti/RuIrO 2  Anode

Aris Mukimin; Agus Purwanto

doi:10.22146/ijc.26609

Removal Efficiency of Nitrite and Sulfide Pollutants by Electrochemical Process by Using Ti/RuIrO₂ Anode

https://doi.org/10.22146/ijc.26609

Aris Mukimin^(1*), Agus Purwanto⁽²⁾

(1) Center of Industrial Pollution Prevention Technology, Jl. Ki Mangunsarkoro No. 6 PO Box 829, Semarang 50136, Indonesia
(2) Center of Industrial Pollution Prevention Technology, Jl. Ki Mangunsarkoro No. 6 PO Box 829, Semarang 50136, Indonesia
(*) Corresponding Author

Abstract

In general, wastewater treatment by physical, chemical and biological methods are only focused on TSS, BOD and COD removals that the effluent still contains anion pollutant as NO₂^- and S^2-. Electrochemical technology is a proper method for those pollutants treatment due to its fast process, easy operation and minimum amount of sludge. Electrocatalytic reactor with 8 L capacity using Ti/RuIrO₂ cylinder as anode and Fe plate as cathode was arranged and applied to treat anion pollutants. Hydraulic retention time (30, 60, 90 and 120 min), salt concentration (250, 500 and 750 mg/L) and voltage (4, 5, and 6 V) were chosen as operation variables and NO₂^- and S^2- concentrations as parameter indicators. Nitrite removal efficiency reached 75 and 99.7% after 60 and 120 min of electrolysis, respectively, while sulfide could obtain higher efficiency, i.e., 97 and 99.9% after 60 and 90 min, respectively, at operation variables of potential of 5 V and salt of 500 mg/L. Removal process is dominated by indirect oxidation mechanism by HClO/ClO^- oxidators generated at anode surface as intermediate products. The lifespan of electrode and electric consumption are two main factors of operation cost. Electric consumed was 0.452 kWh per 1 g nitrite removed.

Keywords

sulfide; nitrite; electrochemical; Ti/RuIrO2 anode; Fe cathode

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References

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DOI: https://doi.org/10.22146/ijc.26609

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