Research Article
BibTex RIS Cite
Year 2021, Volume: 9 Issue: 2, 122 - 128, 06.12.2021
https://doi.org/10.51354/mjen.928670

Abstract

References

  • Iskander S.Md., Zhao R., Pathak A., Gupta A., Pruden A., Novak J.T., He Z., “A review of landfill leachate induced ultraviolet quenching substances: Sources, characteristics, and treatment”, Water Research, 145 (2018) 297-311.
  • Renou S., Givaudan J., Poulain S., Dirassouyan F., Moulin P., “Landfill leachate treatment: review and opportunity”, J. Hazard. Mater. 150 (2008) 468–493.
  • Kurniawan T. A., Waihung Lo., Chana G., Mika E. T. Sillanpaa., “Biological processes for treatment of landfill leachate”, Journal of Environmental Monitoring, 2010, 12, 2032–2047.
  • Foo K.Y., Hameed B.H., “An overview of landfill leachate treatment via activated carbon adsorption process”, Journal of Hazardous Materials 171 (2009) 54–60.
  • Gao J., Oloibiri V., Chys M., Audenaert W., Decostere B., He Y., Langenhove H.V., Demeestere K., Hulle S.W.H.V., “The present status of landfill leachate treatment and its development trend from a technological point of view”, Rev Environ Sci Biotechnology, 14 (2015) 93–122.
  • Ahmed F.N., Lan C.Q., “Treatment of landfill leachate using membrane bioreactors: A review”, Desalination, 287, (2012), 41-54.
  • Zhang Q.Q., Tian B.H., Zhang X., Ghulam A., Fang C.R., He R., “Investigation on characteristics of leachate and concentrated leachate in three landfill leachate treatment plants”, Waste Management, 33 (2013) 2277–2286.
  • Gautam P., Kumar S., Lokhandwala S., “Advanced oxidation processes for treatment of leachate fromhazardous waste landfill: A critical review”, Journal of Cleaner Production, 237 (2019) 117639.
  • Mandal P., Dubey B.K., Gupta A.K., “Review on landfill leachate treatment by electrochemical oxidation: Drawbacks, challenges and future scope”, Waste Management, 69 (2017) 250-273.
  • APHA (2005) Standard Methods for the Examination of Water and Wastewater. 21st Edition, American Public Health Association/American Water Works Association/Water Environment Federation, Washington DC.
  • Fleck E., Gewehr A.G., Cybis L.F.A., Gehling G.R., Juliano V.B., “Evaluation of the treatability of municipal waste landfill leachate in a SBR and by coagulation-flocculation on a bench scale”, Brazilian Journal of Chemical Engineering, 33 (2016) 851-861.
  • Long Y., Xu J., Shen D., Du Y., Feng H., “Effective removal of contaminants in landfill leachate membrane concentrates by coagulation”, Chemosphere, 167 (2017) 512-519.
  • Orescanin V., Ruk D., Kollar R., Mikelic I.L.,Nad K., Mikulic N., “A combined treatment of landfill leachate using calciumoxide, ferric chloride and clinoptilolite”, J. Environ. Sci. Health A, 46 (2011) 323-328.
  • Maranon E., CastrillonL., Fernandez-Nava Y., Fernandez-Mendez A., Fernandez-Sanchez, A., “Coagulation–flocculation as a pretreatment process ata landfill leachate nitrification–denitrification plant”, J. Hazard. Mater., 156 (2008) 538-544.
  • Garcia-Segura S., Ocon J.D., Chong M.N., “Electrochemical oxidation remediation of realwastewater effluents-A review”, Process Safety and Environmental Protection, 113 (2018) 48-67.
  • Anglada A., Urtiaga A., Ortiz I., Mantzavinos D., Diamadopoulos E., “Boron-doped diamond anodic treatment of landfill leachate:Evaluation of operating variables and formation of oxidationby-products”, Water Research, 45 (2011) 828-838.
  • FernandesA., PachecoM.J., CiríacoL., LopesA., “Review on the electrochemical processes for the treatment of sanitarylandfill leachates: Present and future”, Applied Catalysis B, 176 (2015) 183-200.

Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater

Year 2021, Volume: 9 Issue: 2, 122 - 128, 06.12.2021
https://doi.org/10.51354/mjen.928670

Abstract

 The disposal of municipal solid wastes (MSW) is one of the important issues today. The MSW is generally disposed of in a landfill. The disintegration of wastes in landfill generates the wastewater known as leachate and it became one of the budding environmental impacts. The landfill leachate seeps into natural ponds next to the Bishkek (Kyrgyzstan) landfill. The MSWs are dumped with an irregular landfill in Bishkek, and it has been observed that this situation creates many environmental pollution problems (air pollution due to the combustion of wastes and generated biogas, due to leakage of leachate from the landfill) around the landfill. The leachate in the ponds is not treated and leaks into the environment. In this study, the potential of the coagulation-flocculation(CF) and electrooxidation (EO) processes was investigated for the treatment of leachate from the sanitary landfill located in Bishkek-Kyrgyzstan. The initial COD (1400 ± 50 mg/L), TOC (540 ± 15 mg/L), and ammonia nitrogen (315 ± 10 mg/L) from landfill leachate were treated by the CF process as 33, 23, and 14% at pH 6.5 with alum dosage of 5 g/L, and 40, 29 and 10.1% at pH 8.5 with ferric chloride dosage of 5 g/L, respectively.
Removal efficiencies at applied currents of 1.0, 3.0, and 5.0 A with an EO reactor using boron-doped diamond (BDD) plate anode and stainless steel (SS) plate cathode were 67.20, 88.30, and 97.90% for COD, 60.10, 85.38, and 95.53% for TOC, and 48.9, 94.6 and 99.8% for ammonia nitrogen, respectively. As a result, it was seen that Bishkek’s irregular solid waste landfilling leachate, which causes environmental pollution, was effectively treated with the EO process. By establishing a regular landfill, Bishkek municipal solid wastes must be disposed of in the landfill and treated of the leachate.

References

  • Iskander S.Md., Zhao R., Pathak A., Gupta A., Pruden A., Novak J.T., He Z., “A review of landfill leachate induced ultraviolet quenching substances: Sources, characteristics, and treatment”, Water Research, 145 (2018) 297-311.
  • Renou S., Givaudan J., Poulain S., Dirassouyan F., Moulin P., “Landfill leachate treatment: review and opportunity”, J. Hazard. Mater. 150 (2008) 468–493.
  • Kurniawan T. A., Waihung Lo., Chana G., Mika E. T. Sillanpaa., “Biological processes for treatment of landfill leachate”, Journal of Environmental Monitoring, 2010, 12, 2032–2047.
  • Foo K.Y., Hameed B.H., “An overview of landfill leachate treatment via activated carbon adsorption process”, Journal of Hazardous Materials 171 (2009) 54–60.
  • Gao J., Oloibiri V., Chys M., Audenaert W., Decostere B., He Y., Langenhove H.V., Demeestere K., Hulle S.W.H.V., “The present status of landfill leachate treatment and its development trend from a technological point of view”, Rev Environ Sci Biotechnology, 14 (2015) 93–122.
  • Ahmed F.N., Lan C.Q., “Treatment of landfill leachate using membrane bioreactors: A review”, Desalination, 287, (2012), 41-54.
  • Zhang Q.Q., Tian B.H., Zhang X., Ghulam A., Fang C.R., He R., “Investigation on characteristics of leachate and concentrated leachate in three landfill leachate treatment plants”, Waste Management, 33 (2013) 2277–2286.
  • Gautam P., Kumar S., Lokhandwala S., “Advanced oxidation processes for treatment of leachate fromhazardous waste landfill: A critical review”, Journal of Cleaner Production, 237 (2019) 117639.
  • Mandal P., Dubey B.K., Gupta A.K., “Review on landfill leachate treatment by electrochemical oxidation: Drawbacks, challenges and future scope”, Waste Management, 69 (2017) 250-273.
  • APHA (2005) Standard Methods for the Examination of Water and Wastewater. 21st Edition, American Public Health Association/American Water Works Association/Water Environment Federation, Washington DC.
  • Fleck E., Gewehr A.G., Cybis L.F.A., Gehling G.R., Juliano V.B., “Evaluation of the treatability of municipal waste landfill leachate in a SBR and by coagulation-flocculation on a bench scale”, Brazilian Journal of Chemical Engineering, 33 (2016) 851-861.
  • Long Y., Xu J., Shen D., Du Y., Feng H., “Effective removal of contaminants in landfill leachate membrane concentrates by coagulation”, Chemosphere, 167 (2017) 512-519.
  • Orescanin V., Ruk D., Kollar R., Mikelic I.L.,Nad K., Mikulic N., “A combined treatment of landfill leachate using calciumoxide, ferric chloride and clinoptilolite”, J. Environ. Sci. Health A, 46 (2011) 323-328.
  • Maranon E., CastrillonL., Fernandez-Nava Y., Fernandez-Mendez A., Fernandez-Sanchez, A., “Coagulation–flocculation as a pretreatment process ata landfill leachate nitrification–denitrification plant”, J. Hazard. Mater., 156 (2008) 538-544.
  • Garcia-Segura S., Ocon J.D., Chong M.N., “Electrochemical oxidation remediation of realwastewater effluents-A review”, Process Safety and Environmental Protection, 113 (2018) 48-67.
  • Anglada A., Urtiaga A., Ortiz I., Mantzavinos D., Diamadopoulos E., “Boron-doped diamond anodic treatment of landfill leachate:Evaluation of operating variables and formation of oxidationby-products”, Water Research, 45 (2011) 828-838.
  • FernandesA., PachecoM.J., CiríacoL., LopesA., “Review on the electrochemical processes for the treatment of sanitarylandfill leachates: Present and future”, Applied Catalysis B, 176 (2015) 183-200.
There are 17 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Article
Authors

Venera Edilbek Kyzy This is me 0000-0002-9345-3660

Nurzat Shaykieva

Kubat Kemelov 0000-0001-7375-6325

Mustafa Dolaz This is me 0000-0002-9684-5555

Mehmet Kobya 0000-0001-5052-7220

Publication Date December 6, 2021
Published in Issue Year 2021 Volume: 9 Issue: 2

Cite

APA Edilbek Kyzy, V., Shaykieva, N., Kemelov, K., Dolaz, M., et al. (2021). Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater. MANAS Journal of Engineering, 9(2), 122-128. https://doi.org/10.51354/mjen.928670
AMA Edilbek Kyzy V, Shaykieva N, Kemelov K, Dolaz M, Kobya M. Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater. MJEN. December 2021;9(2):122-128. doi:10.51354/mjen.928670
Chicago Edilbek Kyzy, Venera, Nurzat Shaykieva, Kubat Kemelov, Mustafa Dolaz, and Mehmet Kobya. “Environmental Pollution Size of the Bishkek Solid Waste Landfill and Treatment of Generated Leachate Wastewater”. MANAS Journal of Engineering 9, no. 2 (December 2021): 122-28. https://doi.org/10.51354/mjen.928670.
EndNote Edilbek Kyzy V, Shaykieva N, Kemelov K, Dolaz M, Kobya M (December 1, 2021) Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater. MANAS Journal of Engineering 9 2 122–128.
IEEE V. Edilbek Kyzy, N. Shaykieva, K. Kemelov, M. Dolaz, and M. Kobya, “Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater”, MJEN, vol. 9, no. 2, pp. 122–128, 2021, doi: 10.51354/mjen.928670.
ISNAD Edilbek Kyzy, Venera et al. “Environmental Pollution Size of the Bishkek Solid Waste Landfill and Treatment of Generated Leachate Wastewater”. MANAS Journal of Engineering 9/2 (December 2021), 122-128. https://doi.org/10.51354/mjen.928670.
JAMA Edilbek Kyzy V, Shaykieva N, Kemelov K, Dolaz M, Kobya M. Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater. MJEN. 2021;9:122–128.
MLA Edilbek Kyzy, Venera et al. “Environmental Pollution Size of the Bishkek Solid Waste Landfill and Treatment of Generated Leachate Wastewater”. MANAS Journal of Engineering, vol. 9, no. 2, 2021, pp. 122-8, doi:10.51354/mjen.928670.
Vancouver Edilbek Kyzy V, Shaykieva N, Kemelov K, Dolaz M, Kobya M. Environmental pollution size of the Bishkek Solid Waste Landfill and treatment of generated leachate wastewater. MJEN. 2021;9(2):122-8.

Manas Journal of Engineering 

16155