Electrocoagulation of simulated reactive dyebath effluent with aluminum and stainless steel electrodes

Reactive dyebath effluents are ideal candidates for electrocoagulation due to their intensive color, medium strength, recalcitrant COD and high electrolyte (NaCl) content. The present study focused on the treatability of simulated reactive dyebath effluent (COD o = 300 mg/L; color in terms of absorb...

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Bibliographic Details
Published in:Journal of hazardous materials 2009-05, Vol.164 (2), p.1586-1594
Main Authors: Arslan-Alaton, İdil, Kabdaşlı, Işık, Vardar, Burcu, Tünay, Olcay
Format: Article
Language:English
Subjects:
Aluminum
AOX abatement
Applied sciences
Chemical engineering
COD and color removal
Coloring Agents - chemistry
Current density
Electrical energy consumption
Electrocoagulation - methods
Electrocoagulation with aluminum and stainless steel electrodes
Electrodes
Electrolytes
Exact sciences and technology
Hydrogen-Ion Concentration
Pollution
Process optimization
Reactive dyebath effluent
Reactors
Stainless Steel
Water Pollutants, Chemical - chemistry
Water Purification - methods
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Summary:Reactive dyebath effluents are ideal candidates for electrocoagulation due to their intensive color, medium strength, recalcitrant COD and high electrolyte (NaCl) content. The present study focused on the treatability of simulated reactive dyebath effluent (COD o = 300 mg/L; color in terms of absorbance values A o,436 = 0.532 cm −1, A o,525 = 0.693 cm −1 and A o,620 = 0.808 cm −1) employing electrocoagulation with aluminum and stainless steel electrodes. Optimization of critical operating parameters such as initial pH (pH o 3–11), applied current density ( J c = 22–87 mA/cm 2) and electrolyte type (NaCl or Na 2SO 4) improved the overall treatment efficiencies resulting in effective decolorization (99% using stainless steel electrodes after 60 min, 95% using aluminum electrodes after 90 min electrocoagulation) and COD abatement (93% with stainless steel electrodes after 60 min, 86% with aluminum electrodes after 90 min of reaction time). Optimum electrocoagulation conditions were established as pH o 5 and J c = 22 mA/cm 2 for both electrode materials. The COD and color removal efficiencies also depended on the electrolyte type. No in situ, surplus adsorbable organically bound halogens (AOX) formation associated with the use of NaCl as the electrolyte during electrocoagulation was detected. An economical evaluation was also carried out within the frame of the study. It was demonstrated that electrocoagulation of reactive dyebath effluent with aluminum and stainless steel electrodes was a considerably less electrical energy-intensive, alternative treatment method as compared with advanced chemical oxidation techniques.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2008.09.004