Akademik Veri Yönetim Sistemi
International Symposium on Sustainable Aquatic Research, İzmir, Türkiye, 21 - 22 Mayıs 2024, ss.72-80, (Tam Metin Bildiri)
Since leachate is a complex and highly variable wastewater, it is the most difficult to treat in
wastewater. Electrochemical processes are among the most preferred methods in leachate
treatment. The most preferred electrode materials are aluminum and iron, as they are
economical, effective and easily soluble in the electrocoagulation process. In the case of using
aluminum electrodes, it produces Al3+ and Al(OH)2+ species, which are initially converted to
Al(OH)3 and subsequently converted to Aln(OH)3n as a result of the electrolytic dissolution of
the aluminum electrode. In this study, the effects of current density, initial pH, distance between
electrodes, mixing speed and initial temperature on COD removal efficiency were investigated.
Experimental studies were used in a 20cmx8cmx10cm reactor made of plexiglass. The
electrodes are arranged in a monopolar parallel arrangement with three anodes and three
cathodes. In the COD analysis, the standard method used is the SM 5220.D Closed Reflux
Colorimetric method. In the experiments, COD removal efficiencies were determined according
to current density 15-25 mA/cm2, pH 3-9.5, temperature 20-60oC, stirring speed 100-300 rpm,
distance between electrodes 1-2 cm. In the light of the data obtained, the highest turbidity
removal efficiency was determined as 62% at current density 20 mA/cm2, pH 5, initial
temperature 20°C, distance between electrodes 1 cm, stirring speed 300 rpm. It can be said that
this is due to the tendency of aluminum to hydrolyze and adsorb colloidal structures on the
surface of the electrode. Thus, it can be said that the electrocoagulation process is a suitable
process for turbidity removal from leachate.