Efisiensi Penurunan Kadar Logam Cu pada Limbah Cair Industri Elektroplating dengan Proses Elektrokoagulasi
Abstract
Liquid waste in the electroplating industry contains heavy metals such as nickel, copper and zinc. If the waste is discharged directly to the environment without any prior treatment it will cause damage to humans and the environment. One method that can be used to treat this wastewater is electrocoagulation. Where electrocoagulation is an electrolysis process that requires electric power, electrical conductors and electrodes. The purpose of this research is to determine the efficiency of reducing the concentration of Cu in the variation voltage and stirring speed on the electrocoagulation processes. First and second order reaction rate constant have been evaluated. Eighty mL of electroplating waste is added to reactor, stirred using magnetic stirer in the variation of voltage (12,14,16 V) and in the variation speed (200, 300, 400) rpm. Every 40 minutes samples were analyzed using AAS. Electrocoagulation processes were stopped in 160 minutes. The results showed the highest efficiency in the variation of voltage and string speed are 95.92% and 96.81 % in that order. First order reaction rate constant in the variation stirring speed and voltage are 0,0163 s-1 and 1,8937 s-1 respectively. On the other hand second order reaction rate constant in the variation stirring speed and voltage are 0,0269 s-1 dan 3,9322 s-1 respectively.
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Adhoum N, Monser L, Bellakhal N, Belgaied JE. Treatment of electroplating wastewater containing cu2+, zn 2+ and cr(vi) by electrocoagulation. Journal of Hazardous Materials 2004; 112 (3): 207–213.
Hernaningsih T. Tinjauan teknologi pengolahan air limbah industri dengan reviews of electrocoagulation process on waste water treatment. Jurnal Teknologi Lingkungan 2016; 9 (1): 31–46.
Kobya M, Demirbas E, Oncel MS, Yildrim Y, Sik E, Goren AY, dan Akyol A. Modelling and optimization of arsenite removal from groundwater using al ball anodes by electrocoagulation process. Juornal of Selcuk University Natural and Applied Sciences Online 2014: 803-811. ISSN 2147-3781.
Mazumder D, Ghosh D, Bandyopadhyay P. Treatment of electroplating wastewater by adsorption technique. International Journal of Civil and Environmental Engineering 2011; 3 (2): 101–110.
Pamungkas AS, Prasetyo H, Mulyaningsih N. Pengaruh variasi temperatur elektroplating terhadap ketebalan lapisan nikel baja st37 grafik hubungan temperatur dan tebal nikel. Jurnal Mer-c 2018; 1(2): 3–5.
Retno S. Kajian proses elektrokagulasi untuk pengolahan air limbah. Sekolah Teknik Lingkungan dalam Seminar Nasional IV. Yogyakarta. 2008. ISSN 1978-0176.
Sutomo S, Rahmat. Pengaruh arus dan waktu pada pelapisan nikel dengan elektroplating untuk bentuk plat. Rotasi 2010; 6 (2): 11–20.
Xia L, Hu YX, Zhang BH. Kinetics and equilibrium adsorption of copper(ii) and nickel(ii) ions from aqueous solution using sawdust xanthate modified with ethanediamine. Transactions of Nonferrous Metals Society of China (English Edition) 2014; 24 (3): 868–875.
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