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

Ni Made Wiratini; Ngadiran Kartowasono

doi:10.14710/reaktor.16.2.65-71

DOI: https://doi.org/10.14710/reaktor.16.2.65-71

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

*Ni Made Wiratini - Universitas Pendidikan Ganesha, Indonesia

Ngadiran Kartowasono - Universitas Pendidikan Ganesha, Indonesia

Received: 13 Apr 2016; Published: 27 Jul 2016.

BibTex Citation Data :

@article{Reaktor10805,
    author = {Ni Made Wiratini and Ngadiran Kartowasono},
    title = {DAMPAK RANGKAIAN SEL ELEKTRODA AL-C  DALAM ELEKTROKIMIAUNTUK MENDEGRADASI  LIMBAH TEKSTIL},
    journal = {Reaktor},
  volume = {16},
    number = {2},
    year = {2016},
    keywords = {set of cells, electrochemical, degradation, textile waste},
    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   },
   issn = {2407-5973},   pages = {65--71}  doi = {10.14710/reaktor.16.2.65-71},
    url = {https://ejournal.undip.ac.id/index.php/reaktor/article/view/10805}
}

Citation Format:

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

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IMPACT OF CELL AL-C ELECTRODE CIRCUIT IN ELECTROCHEMISTRY FOR TEXTILES WASTE DEGARADTION

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Keywords: set of cells, electrochemical, degradation, textile waste

Funding: Universitas Pendidikan Ganesha

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Section: Research Article

Language : EN

In Volume 16 No. 2 Juni 2016

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