skip to main content

DAMPAK RANGKAIAN SEL ELEKTRODA AL-C DALAM ELEKTROKIMIAUNTUK MENDEGRADASI LIMBAH TEKSTIL

*Ni Made Wiratini  -  Universitas Pendidikan Ganesha, Indonesia
Ngadiran Kartowasono  -  Universitas Pendidikan Ganesha, Indonesia
Open Access Copyright (c) 2016 REAKTOR

Citation Format:
Abstract

Abstract

IMPACT OF AL-C ELECTRODE CELL CIRCUIT IN ELECTROCHEMISTRY
FOR TEXTILES WASTE DEGRADATION
. The purpose of this study was to determine the impact circuit of Al-C electrode cell in electrochemical to degrade textile waste. To achieve these goals, 1) cells that were developed using 3 electrode by varying the electrochemical cell circuit  such as: cell circuit 1(anode: Al-C series, cathode C), cell circuit 2 ( anode: Al-C parallel, cathode C), cell circuit 3(anode: Al-C series, cathode: Al), and cell circuit 4 ( anode: Al-C parallel, cathode: Al); 2) varying the electrode spacing, ie: 3, 6, 9 and 12 cm; and 3) varying the voltage, which is 3, 6, 9, and 13, 5 V. BOD, DO, COD, pH, and absorbance were  measured before and after degradation in every varying cell circuit, electrode spacing, and voltage.  The results showed: black textile waste, odor, COD 2540 mg / L, DO 0 mg / L, BOD 0 mg / L, pH 11, and the absorbance was 0.92. While  best cells circuit is cell circuit 2 (anode: Al-C parallel and c in cathodes), best electrode spacing for processing textile waste is 3 cm, and the best voltage to degrade textile waste is 13.5 V.

Key words: degradation, electrochemical, set of cells, textile waste

Abstrak

Tujuan penelitian ini adalah mengetahui dampak rangkaian sel elektroda Al-C dalam elektrokimia untuk mendegradasi limbah tekstil. Untuk mencapai tujuan tersebut, 1) sel yang dikembangkan menggunakan 3 elektroda dengan memvariasikan rangkaian sel elektrokimia  yaitu: rangkaian 1 (anoda: Al-C seri, katoda C), rangkaian 2(anoda: Al-C paralel, katoda C), rangkaian 3( anoda: Al-C seri, katoda: Al), dan rangkaian 4( anoda: Al-C paralel, katoda: Al); 2) memvariasikan jarak elektroda, yaitu: 3,6, 9, dan 12 cm; dan 3) memvariasikan voltase, yaitu 3, 6, 9, dan 13, 5 V. BOD, DO, COD, pH dan absorbansi diukur sebelum dan sesudah degradasi pada setiap variasi rangkaian sel, jarak, dan voltase. Hasil penelitian menunjukkan: limbah tekstil berwarna hitam, berbau, COD 2540 mg/L, DO 0 mg/L, BOD 0 mg/L, pH 11, dan absorbansi 0,92. Sedangkan rangkaian sel yang paling baik adalah rangkaian sell 2 (anoda: Al-C parallel dan katoda: C), jarak elektroda terbaik untuk pengolahan limbah tekstil adalah 3 cm, dan voltase yang terbaik untuk mendegradasi limbah tekstil 13,5 V.

Kata-kata kunci: degradasi, elektrokimia, limbah tekstil,  rangkaian sel


Note: This article has supplementary file(s).

Fulltext View|Download |  Data Set
IMPACT OF CELL AL-C ELECTRODE CIRCUIT IN ELECTROCHEMISTRY FOR TEXTILES WASTE DEGARADTION
Subject set of cells, electrochemical, degradation, textile waste
Type Data Set
  Download (340KB)    Indexing metadata
Keywords: set of cells, electrochemical, degradation, textile waste
Funding: Universitas Pendidikan Ganesha

Article Metrics:

  1. A. Cerqueira, C. Russo, M.R.C. Marques, (2009), Electroflocculation for Textile Wastewater Treatment, Brazilian Jornal of Chemical Engineering, 26(04), pp. 659-668
  2. Anchalee Sringrangsan, Maneerat Ongwandee, Orathai Chavalparit, (2009), Treatment of Biodiesel by Electrocoagulation Process, Environment Asia Journal 2, pp. 15-19
  3. Caria Regina Costa, Francisco Montilla, Emillia Morallon, Paulo Olivi, (2010), Electrochemical Oxidation of Synthetic Tannery Wastewater in Chloride Free Aqueous Media, Journal of Hazardous Materials, 180, (1-3), pp. 429-435
  4. Chiang. L.C., Chang. J.E., Wen. T.C., (1995), Indirect Oxidation Effect in Electrochemical Oxidation Treatment of Landfill Leachate, Water Research, 29(2), pp. 671-678
  5. Copa. W.M., Meidl. J.A., (1986), Powdered carbon Effectively Treats Toxic Leachate, Pollution Engineering, 18 (7), pp. 32-34
  6. Daneshvar, N., Khataee, A. R., Ghadim, A. R. A., Rasoulifard, M. H. (2007), Decolorization of c.i. Acid Yellow 23 Solution by Electrocoagulation Process: Investigation of Operational Parameters and Evaluation of Specific Electrical Energy Consumption (SEEC), Journal of Hazardous Materials, 148(3), pp.566
  7. Daniel Ogwoka Siringi, Patrick Home, Joseph S. C., Enno K., (2012), Is Electrocoagulation (EC) A Solution to the Treatmeant of Wastwater and Providing clean Water for Daily Use, ARPN Jounal of Engineering and Applied Science, 7(2), pp. 197-204
  8. Keputusan Menteri Negara Lingkungan Hidup No. Kep-15/MENLH/10/1995 Tentang Baku Mutu Limbah Cair bagi Kegiatan Industri
  9. Li. X.M.. Wang. M.. Jiao. Z.K.. Chen. Z.Y., (2001), Study of Electrolytic Oxidation for Landfill Leachate Treatment, China Water & Wastewater, 17(8). pp. 14-17
  10. Mathur N., (2005), Assessing Mutagenicity of Textile Dyes from Pali (Rajasthan) Using Ames Bioassy, Applied Ecology and Environmental Research, 4(1), pp .111-118
  11. Mehmet Kobya∗, Orhan Taner Can, Mahmut Bayramoglu, (2003), Treatment of Textile Wastewaters by Electrocoagulation Using iron and Aluminum Electrodes, Journal of Hazardous Materials B100, pp. 163–178
  12. Mikko Vapsalainen, (2012), Electrocoagulation in the Treatment of Industrial Water and Wastewater, Desertation. Jukaisija, Utgivare, http://www.vtt.fi/publication/, diakses 12 April 2014
  13. M.N. Sprykina, (2012), A New Design of the Electrocoagulation Apparatus for Removal of Micromycetes from Water, Journal of Water Chemistry and Technology, 34(5), pp 240-245
  14. Pandey, A., Singh,P.& Lyengar, L., (2007), Bacterial Decolorization and Degradation of Azo Dyes, International Biodeteoration and Biodegradation, 59, pp. 73-84
  15. Satish I Chaturvedi, (2013), Electrocoagulation: A Novel Waste Water treatment Method, International Journal of modern Engineering Research, 3(I), pp. 93-100
  16. Shofian M., (2005), Kesan Perencat terhadap Keberkesanan Reagen Fenton dalam Mengolah Pewarna Industri tekstil, Akademi Tentera, UT Malaysia
  17. Tatsi A.A., Zouboulis A.I., Matis K.A., Samaras P.,(2003), Coagulation–Flocculation Pretreatment of Sanitary Landfill leachates, Chemosphere 53 (2003), pp.737–744
  18. Wei Li, Qitiang Zhou, Tao Hua, (2010), Removal of Organic Matter from Landfill Leachate by Advanced Oxidation Processes: A review, International Journal Of Chemical Engineering, 2010, pp. 1-10
  19. Wiratini Ni Made, Suja I Wayan, Lasia I Ketut , (2011), Perombakan Zat Warna Tekstil Diazo Remazol Black 5 dengan Teknik Elektrooksidasi Menggunakan Larutan NaCl, Proseding Seminar Nasional Pengembangan Pendidikan Karakter Menuju Bangsa yang Mandiri Melalui Penelitian dan Pendidikan MIPA, hal. 136-139 Singaraja: FMIPA Universitas Pendidikan Ganesha
  20. Wiratini Ni Made, Yuninggrat Ni Wayan, Gunamantha I Made, (2012), Degradasi Pencemar Organik dalam Lindi dengan Proses Oksidasi Lanjut, Jurnal Sains dan Teknologi, 1 (2), pp. 73-84
  21. Wiratini Ni Made, Gunamantha I Made, (2013), Desain Reaktor Elektrooksidasi Berbasis Potensi Lingkungan untuk Mendegradasi Limbah Organik Lindi di Tempat Pembuangan Sampah, Laporan Penelitian HB I. Undiksha: Singaraja
  22. Wiszniowski. J., Robert. D., Surmacz Gorska. J., (2006), Landfill Leachate Treatment Methods: A Review, Environmental Chemical, 4, pp. 51-61
  23. Yang Deng, J.D.Englehardt, (2007), Electrochemical oxidation fo landfill leachate treatment, Waste Management. 27(3), pp. 380-389
  24. Zazo. J.A., Casas. J.A., Mohendano. A.F., Gilarranz. Rodriguez. J.J., (2005), Chemical Path Way and Kinetics ff Phenol Oxidation by Fenton’s Reagent, Environmental Sciences Technologies, 39, pp. 9295-9305

Last update:

  1. The effect of direct current sources for electrolysis of laundry liquid waste surfactants using PbO2/Pb electrodes with parallel circuit

    Irmanto, Wisnu Permadi, Suyata, Santi Nur Handayani. VIII INTERNATIONAL ANNUAL CONFERENCE “INDUSTRIAL TECHNOLOGIES AND ENGINEERING” (ICITE 2021), 2650 , 2022. doi: 10.1063/5.0103716
  2. Analysis of Bubbles Size Produced in Electroflotation Using Graphite and Stainless Steel Electrode With DinoCapture 2.0

    Rudy Syah Putra, Muhammad Sarkawi, Farokhatul Faikha, Ludfi Fitmoko. 2021 IEEE International Conference on Health, Instrumentation & Measurement, and Natural Sciences (InHeNce), 2021. doi: 10.1109/InHeNce52833.2021.9537230

Last update: 2024-03-19 12:02:04

No citation recorded.