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Evaluation of Regional Domestic Waste Water Treatment Plant Performance in Cimahi City

*Mila Dirgawati scopus publons  -  Institut Teknologi Nasional Bandung, Indonesia
Mohamad Rangga Sururi scopus publons  -  Institut Teknologi Nasional Bandung, Indonesia
Wili Wiliana  -  Institut Teknologi Nasional Bandung, Indonesia
Nining Widiawati  -  Dinas Perumahan dan Kawasan Permukiman, Indonesia

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Abstract

Domestic wastewater treatment plant performance (WWTP) currently refers to stringent wastewater quality standards (Minister of Environment and Forestry Regulation No. 68 of 2016) considering potential environmental degradation because of pollutants in the wastewater. This study evaluated the performance of the Regional Domestic WWTP in Cimahi City. Cimahi has 10 WWTPs which were operated by an Anaerobic Baffled Reactor system. Periodic monitoring only measured the wastewater characteristics after treatment with parameters: total suspended solids (TSS), ammonia, chemical oxygen demand(COD), biological oxygen demand(BOD), and oil and grease. Therefore, wastewater characteristics were measured before and after treatment at selected WWTP during peak and non-peak hours, with TSS, ammonia, and COD. Important hydraulic factors were also measured: flow velocity at peak and non-peak hours, hydraulic detention time, and sludge height. Effluent from all WWTPs did not meet the standard. However, WWTPs with detention time >2 days produced parameter concentrations closed to the maximum value. The selected WWTP has a 5.7days detention time with removal efficiency for COD 57.52%, and TSS 42.56%, during peak period and COD 60.19% and TSS 34.84% for a non-peak period, but ammonia concentration did not decrease. Overall, WWTP has not been able to meet quality standards and the quality.

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Keywords: regional WWTP, domestic wastewater, removal efficiency, hydraulic detention time, sludge height

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  1. Aqaneghad, M., & Moussavi, G. 2016. Electrochemically enhancement of the anaerobic baffled reactor performance as an appropriate technology for treatment of municWWTP wastewater in developing countries. Sustainable Environment Research, 26(5), 203-208
  2. APHA, American Water Works Association, and Water Pollution Control Federation, 2005. Standard methods for the examination of water and wastewater, 19th ed. American Public Health Association, Washington, DC, USA
  3. BPS., Biro Pusat Statistik. 2020. Indonesia dalam Angka 2020. Badan Pusat Statistika Indonesia
  4. BPS., Biro Pusat Statistik Kota Cimahi. 2020. Kota Cimahi dalam Angka 2020. BPS Kota Cimahi
  5. Cruz, H., Luckman, P., Seviour, T., Verstraete, W., Laycock, B., & Pikaar, I. 2018. Rapid removal of ammonium from domestic wastewater using polymer hydrogels. Scientific reports, 8(1), 1-6
  6. Badan Standarisasi Nasional. 2015. SNI 8066: 2015 Tata Cara Pengukuran Debit Aliran Air Limbah dan Saluran Terbuka dengan Menggunakan Alat Ukur Arus dan Pelampung. Badan Standarisasi Nasional
  7. DLH, Dinas Lingkungan Hidup Provinsi Jawa Barat. 2020. Status Lingkungan Hidup Provinsi Jawa Barat. Bandung: Dinas Lingkungan Hidup Provinsi Jawa Barat
  8. Dirjen PLP Cipta Karya. 2012. Pedoman Pengoperasian dan Pemeliharaan Instalasi Pengolahan Air Limbah. Diseminasi Bidang Air Limbah. Kementerian Pekerjaan Umum
  9. Kemenkes., Kementerian Kesehatan. 2020. Profil Kesehatan Indonesia 2019. Kementrian Kesehatan Indonesia
  10. Friedler, E. 2004. Quality of Individual Domestic Greywater Streams and its Implication for On-Site Treatment and Reuse Possibilities. Environmental Technology, 25(9), 997-1008
  11. Gomec, C. Y. 2010. High-rate anaerobic treatment of domestic wastewater at ambient operating temperatures: A review on benefits and drawbacks. Journal of Environmental Science and Health Part A, 45(10), 1169-1184
  12. Hahn, M. J., & Figueroa, L. A. 2015. Pilot Scale Application Of Anaerobic Baffled Reactor For Biologically Enhanced Primary Treatment Of Raw MunicWWTP Wastewater. Water research, 87, 494-502
  13. Heffernan, B., Van Lier, J., & Van Der Lubbe, J. 2011. Performance Review Of Large Scale Up-Flow Anaerobic Sludge Blanket Sewage Treatment Plants. Water Science and Technology, 63(1), 100-107
  14. Jameel, A. T., Muyubi, S. A., Karim, M. I. A., & Alam, M. Z. 2011. Removal Of Oil And Grease As Emerging Pollutants Of Concern (EPC) In Wastewater Stream. IIUM Engineering Journal, 12(4)
  15. Karya, C. 2018. Detailed Engineering Planning Guidelines for Off-Site Domestic Wastewater Treatment System (Series B), B
  16. Kim, T., Gorski, C. A., & Logan, B. E. 2018. Ammonium Removal From Domestic Wastewater Using Selective Battery Electrodes. Environmental Science & Technology Letters, 5(9), 578-583
  17. Ladu, J. L. C., & Lü, X. W. 2014. Effects of Hydraulic Retention Time, Temperature, and Effluent Recycling on Efficiency of Anaerobic Filter In Treating Rural Domestic Wastewater. Water Science and Engineering, 7(2), 168-182
  18. Nadayil, J., Mohan, D., Dileep, K., Rose, M., & Parambi, R. R. P. 2015. A Study on Effect of Aeration on Domestic Wastewater. International Journal of Interdisciplinary Research and Innovations, 3(2), 10-15
  19. Roosmini, D., Notodarmojo, S., & Sururi, M. 2018. The Characteristic of Natural Organic Matter (NOM) of Water from Cikapundung River Pond. Paper presented at the IOP Conference Series: Earth and Environmental Science
  20. Reynaud, N. and Buckley, C.A. 2016. The anaerobic baffled reactor (ABR) treating communal wastewater under mesophilic conditions: a review. Water Science and Technology, 73(3), pp.463-478
  21. Sawyer, C. N., & McCarty, P. L. 1978. Chemistry for environmental engineers. New York. Mc Graw-Hill Book Company
  22. Soemirat, J. 2011. Kesehatan lingkungan. Yogyakarta, Gamapress
  23. Sumantri, A., & Cordova, M. R. 2011. Dampak limbah domestik perumahan skala kecil terhadap kualitas air ekosistem penerimanya dan dampaknya terhadap kesehatan masyarakat. Jurnal Pengelolaan Sumberdaya Alam dan Lingkungan (Journal of Natural Resources and Environmental Management), 1(2), 127-127
  24. Sururi, M. R., Ainun, S., & Abdillah, F. 2017. Wastewater Collection Performance on Communal Sanitation System in Cimahi Indonesia. Jurnal Sains & Teknologi Lingkungan, 9(1), 60-69
  25. Sururi, M. R., Notodarmojo, S., & Roosmini, D. 2019. Aquatic Organic Matter Characteristics and THMFP Occurrence in a Tropical River. International Journal, 17(62), 203-211
  26. Sururi, M. R., Notodarmojo, S., Roosmini, D., Putra, P. S., Maulana, Y. E., & Dirgawati, M. 2020). An Investigation of a Conventional Water Treatment Plant in Reducing Dissolved Organic Matter and Trihalomethane Formation Potential from a Tropical River Water Source. Journal of Engineering & Technological Sciences, 52(2)
  27. Tchobanoglous, G., & Burton, F. L. 2003. Wastewater engineering. Management, 7, 1-4
  28. Tchobanoglous, G., Burton, F. L., & Stensel, H. D. 2003. Wastewater engineering treatment and reuse. 4
  29. UN., United Nation. 2019. Total population, Both Sexes Combined (thousands). UNdata. United Nations Statistics Division
  30. Usman, M., Salama, E.-S., Arif, M., Jeon, B.-H., & Li, X. 2020. Determination of the Inhibitory Concentration Level Of Fat, Oil, And Grease (FOG) Towards Bacterial And Archaeal Communities In Anaerobic Digestion. Renewable and Sustainable Energy Reviews, 131, 110032
  31. Wang, Dong, Ji, Min, & Wang, Can. 2014. Degradation of organic pollutants and characteristics of activated sludge in an anaerobic/anoxic/oxic reactor treating chemical industrial wastewater. Brazilian Journal of Chemical Engineering, 31(3), 703-713

Last update:

  1. Performance evaluation of domestic waste water treatment system in urban Indonesia

    Mohamad Rangga Sururi, Mila Dirgawati, Wili Wiliana, Fauzi Fadlurrohman, Hardika, Nining Widiyati. Case Studies in Chemical and Environmental Engineering, 8 , 2023. doi: 10.1016/j.cscee.2023.100507

Last update: 2024-12-19 22:07:46

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