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Dual Treatment of Milk Processing Industry Wastewater Using Electro Fenton Process Followed by Anaerobic Treatment

  • K. Thirugnanasambandham EMAIL logo und R. Ganesamoorthy
Veröffentlicht/Copyright: 24. September 2019
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International Journal of Chemical Reactor Engineering
Aus der Zeitschrift International Journal of Chemical Reactor Engineering Band 17 Heft 12

Abstract

Milk processing industry produced in large amounts wastewater with high pH, temperature and toxic matters. These effluents can exhibit serious environmental problems and public health concerns if improperly disposed. In this present study, an attempt has been made to investigate the efficiency of combined treatment for milk processing industry wastewater. Advanced oxidation process used as primary treatment where as biological process is applied as post treatment to degrade the toxic matters. Parameters affecting the combined process on the percentage removal of turbidity and chemical oxygen (COD) demand were studied in detail. Under the optimum conditions, 93 % of turbidity and 97 % of COD were removed. These results indicated that the proposed technique could be used to degrade the maximum turbidity and chemical oxygen demand from milk processing industry wastewater.

Keywords: milk wastewater; oxidation; biological process; toxic matters; turbidity removal; COD removal; optimization

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Received: 2019-04-12
Revised: 2019-06-28
Accepted: 2019-08-22
Published Online: 2019-09-24

© 2019 Walter de Gruyter GmbH, Berlin/Boston

Artikel in diesem Heft

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  2. Thermally Intensification of Steam Reforming Process by Use of Methane Tri-Reforming: A Review
  3. Articles
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  6. Chalcopyrite Leaching Kinetics in the Presence of Methanol
  7. 3D CFD Simulation of Gas Hold-up and Mass Transfer in a Modified Airlift Reactor with Net Draft Tube
  8. Catalytic Combustion of Chlorobenzene with VOx/CeO2 Catalysts: Influence of Catalyst Synthesis Method
  9. Dual Treatment of Milk Processing Industry Wastewater Using Electro Fenton Process Followed by Anaerobic Treatment
  10. A Facile Method to Synthesize Ni2P Catalysts and their Catalytic Performances in Hydrotreating Reactions
  11. Evaluation of Electrocoagulation and Activated Carbon Adsorption Techniques Used Separately or Coupled to Treat Wastewater from Industrial Dairy
  12. Theoretical Study of CO2 Absorption into Novel Reactive 1DMA2P Solvent in Split-flow Absorber-stripper Unit: Mass Transfer Performance and Kinetic Analysis
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https://doi.org/10.1515/ijcre-2019-0074
Schlagwörter für diesen Artikel
milk wastewater; oxidation; biological process; toxic matters; turbidity removal; COD removal; optimization

Artikel in diesem Heft

  1. Review
  2. Thermally Intensification of Steam Reforming Process by Use of Methane Tri-Reforming: A Review
  3. Articles
  4. Promoting Effects of Al on Ni-Based Catalyst for the Hydrodeoxygenation Performance of Ethyl Acetate
  6. Chalcopyrite Leaching Kinetics in the Presence of Methanol
  7. 3D CFD Simulation of Gas Hold-up and Mass Transfer in a Modified Airlift Reactor with Net Draft Tube
  8. Catalytic Combustion of Chlorobenzene with VOx/CeO2 Catalysts: Influence of Catalyst Synthesis Method
  9. Dual Treatment of Milk Processing Industry Wastewater Using Electro Fenton Process Followed by Anaerobic Treatment
  10. A Facile Method to Synthesize Ni2P Catalysts and their Catalytic Performances in Hydrotreating Reactions
  11. Evaluation of Electrocoagulation and Activated Carbon Adsorption Techniques Used Separately or Coupled to Treat Wastewater from Industrial Dairy
  12. Theoretical Study of CO2 Absorption into Novel Reactive 1DMA2P Solvent in Split-flow Absorber-stripper Unit: Mass Transfer Performance and Kinetic Analysis
  13. Gas-solid Flow Behaviors in a Pressurized Multi-stage Circulating Fluidized Bed with Geldart Group B Particles
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