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Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi

Yıl 2020, Cilt: 77 Sayı: EK-4, 49 - 56, 01.05.2020

Öz

Amaç: Son yıllarda gelişen teknoloji ve ekonomi koşulları sayesinde kentsel atıksu arıtma tesisi AAT inşaatları hızlanmıştır. Atıksu arıtma tesislerinin planlanmasında genellikle atıksu özellikleri ve arıtma gereksinimleri dikkate alınmaktadır. Ancak, arıtma tesisinin sürdürülebilirliği için en az yatırım maliyeti kadar işletme maliyetleri de önem arz etmektedir. Arıtma ünitelerinde işletme sırasında kullanılan ekipmanın performansı ve atık su arıtma tesislerinin başarısı ve sürdürülebilirliği için atık su özellikleri oldukça önemlidir. Bu çalışmada, 108.000 nüfuslu yerleşim için tasarlamış ileri bir biyolojik arıtma olarak tasarlanan kentsel atıksu arıtma tesisinin işletme maliyetlerinin ayrıntılı incelenmesi ve gerçek işletme verilerinin belirlenmesi amaçlanmıştır.Yöntem: Söz konusu arıtma tesisinin işletme maliyet analizinde elektrik tüketimi, kullanılan kimyasal ajan, personel sayısı, bakım-onarım ve tesisin her birimindeki diğer giderler dikkate alınmıştır. İlk olarak, her arıtma ünitesinin bireysel işletme maliyetleri çalışma koşullarına ve ekipman özelliklerine göre hesaplanmıştır. Ardından toplam işletme maliyetleri günlük, aylık ve yıllık olarak belirlenmiştir. Then, total operating costs were determined daily, monthly and yearly. According to determined operating costs, treatment costs both per volume and pollution load of wastewater were calculated. Lastly, these data were compared with the previous studies.Results: The total operating costs of the plant have been calculated as about 592 740 $/year. The electricity requirement is 42% of the total operating costs. The highest operating cost in the plant is at the activated sludge unit and calculated as 223 437 $/year. It is determined that total energy requirements are 0.88 kWh, 58.75 kWh and 2.22 kWh for per m3 wastewater, per person, and per kg COD Chemical Oxygen Demand , respectively.Conclusion: The operating costs and total costs calculated in this study are compatible with the costs obtained from previous studies. Generally, it may be said that operating costs in the WWTP are most affected by electricity and staff expenses. Since this study was conducted on a medium-sized WWTP, the energy costs of the equipment in the activated sludge unit have a higher percentage than other expenses

Kaynakça

  • 1. Frison N, Chiumenti A, Katsou E, Malamis S, Bolzonella D, Fatone F. Mitigating off-gas emissions in the biological nitrogen removal via nitrite process treating anaerobic effluents. J Clean Prod, 2015; 93:126-33.
  • 2. Longo S, d’Antoni BM, Bongards M, Chaparro A, Cronrath A, Fatone F, et al. Monitoring and diagnosis of energy consumption in wastewater treatment plants. a state of the art and proposals for improvement. Appl Energ, 2016; 179:1251-68.
  • 3. Hernandez-Sancho F, Molinos-Senante M, & Sala-Garrido R. Cost modelling for wastewater treatment processes. Desalination 2011; 268(1- 3):1-5.
  • 4. Brandt MJ, Middleton RA, Wang S. Energy efficiency in the water industry: a compendium of best practices and case studies-global report. London: IWA Publishing, 2012.
  • 5. EPA. Energy efficiency in water and wastewater facilities, Local Government Climate and Energy Strategy Guides, EPA-430-R-09-038. Washington DC: United States Environmental Protection Agency, 2013.
  • 6. Chae KJ, Kang J. Estimating the energy independence of a municipal wastewater treatment plant incorporating green energy resources. Energ Convers Manage, 2013; 75:664- 72.
  • 7. Shizas I, Bagley DM. Experimental determination of energy content of unknown organics in municipal wastewater streams. J Energ Eng, 2004; 130(2):45-53.
  • 8. Tchnobanoglous G, Bourton FL, Stensel HD. Wastewater engineering, treatment and reuse. 4th ed. Hongkong: Metcalf & Eddy, Inc. 2003.
  • 9. Panepinto D, Fiore S, Zappone M, Genon G, & Meucci L. Evaluation of the energy efficiency of a large wastewater treatment plant in Italy. Appl Energ 2016; 161: 404-11.
  • 10. Trapote A, Albaladejo A, Simón P. Energy consumption in an urban wastewater treatment plant: the case of Murcia Region (Spain). Civ Eng Environ Syst, 2014; 31(4):304-10.
  • 11. Vera I, Sáez K, Vida G. Performance of 14 fullscale sewage treatment plants: comparison between four aerobic technologies regarding effluent quality, sludge production and energy consumption. Environ Technol, 2013; 34(15):2267- 75.
  • 12. Foladori P, Gatti GB, Groff M. Analisi ed efficientamento energetico dell’impianti di depurazione di Folgaria (TN). Atti della 49° Giornata di Studio di Ingegneria Sanitaria Ambientale, Ottobre, 23, Genova. 2013.
  • 13. Guglielmi L, Belli R. Riduzione dei consumi energetici nell’impianto di depurazione di Mancasale (RE), Atti della 49° Giornata di Studio di Ingegneria Sanitaria Ambientale, Ottobre, 23, Genova. 2013.
  • 14. Frijns J, Hofman J, Nederlof M. The potential of (waste) water as energy carrier. Energy Convers Manag, 2013; 65:357-63.

Investigation of Operating Costs at an Urban Wastewater Treatment Plant

Yıl 2020, Cilt: 77 Sayı: EK-4, 49 - 56, 01.05.2020

Öz

Objective: In recent years, thanks to improving technology and economic conditions urban wastewater treatment plant WWTP constructions have accelerated. Wastewater characteristics and treatment requirements usually are taken into account for the planning of wastewater treatment plants. But, operation costs also are important as the least investment costs for the sustainability of the treatment plant. The performance of equipment used in the treatment units during the operation is important as well as the wastewater characteristics for the accomplishment and sustainability of wastewater treatment plants designed. In this study, it has been aimed investigation as detailed of operation costs of an urban wastewater treatment plant that is designed as an advanced biological treatment for a settlement of 108.000 populations, and determination of real operation data.Methods: Electricity consumption, the chemical agent used, staff number, maintenance-repair, and other expenses at each unit of the plant have been considered at the operation cost analysis of the aforementioned plant. Firstly, the individual operating costs of each treatment unit were calculated according to its running conditions and equipment properties. Then, total operating costs were determined daily, monthly and yearly. According to determined operating costs, treatment costs both per volume and pollution load of wastewater were calculated. Lastly, these data were compared with the previous studies.Results: The total operating costs of the plant have been calculated as about 592 740 $/year. The electricity requirement is 42% of the total operating costs. The highest operating cost in the plant is at the activated sludge unit and calculated as 223 437 $/year. It is determined that total energy requirements are 0.88 kWh, 58.75 kWh and 2.22 kWh for per m3 wastewater, per person, and per kg COD Chemical Oxygen Demand , respectively.Conclusion: The operating costs and total costs calculated in this study are compatible with the costs obtained from previous studies. Generally, it may be said that operating costs in the WWTP are most affected by electricity and staff expenses. Since this study was conducted on a medium-sized WWTP, the energy costs of the equipment in the activated sludge unit have a higher percentage than other expenses

Kaynakça

  • 1. Frison N, Chiumenti A, Katsou E, Malamis S, Bolzonella D, Fatone F. Mitigating off-gas emissions in the biological nitrogen removal via nitrite process treating anaerobic effluents. J Clean Prod, 2015; 93:126-33.
  • 2. Longo S, d’Antoni BM, Bongards M, Chaparro A, Cronrath A, Fatone F, et al. Monitoring and diagnosis of energy consumption in wastewater treatment plants. a state of the art and proposals for improvement. Appl Energ, 2016; 179:1251-68.
  • 3. Hernandez-Sancho F, Molinos-Senante M, & Sala-Garrido R. Cost modelling for wastewater treatment processes. Desalination 2011; 268(1- 3):1-5.
  • 4. Brandt MJ, Middleton RA, Wang S. Energy efficiency in the water industry: a compendium of best practices and case studies-global report. London: IWA Publishing, 2012.
  • 5. EPA. Energy efficiency in water and wastewater facilities, Local Government Climate and Energy Strategy Guides, EPA-430-R-09-038. Washington DC: United States Environmental Protection Agency, 2013.
  • 6. Chae KJ, Kang J. Estimating the energy independence of a municipal wastewater treatment plant incorporating green energy resources. Energ Convers Manage, 2013; 75:664- 72.
  • 7. Shizas I, Bagley DM. Experimental determination of energy content of unknown organics in municipal wastewater streams. J Energ Eng, 2004; 130(2):45-53.
  • 8. Tchnobanoglous G, Bourton FL, Stensel HD. Wastewater engineering, treatment and reuse. 4th ed. Hongkong: Metcalf & Eddy, Inc. 2003.
  • 9. Panepinto D, Fiore S, Zappone M, Genon G, & Meucci L. Evaluation of the energy efficiency of a large wastewater treatment plant in Italy. Appl Energ 2016; 161: 404-11.
  • 10. Trapote A, Albaladejo A, Simón P. Energy consumption in an urban wastewater treatment plant: the case of Murcia Region (Spain). Civ Eng Environ Syst, 2014; 31(4):304-10.
  • 11. Vera I, Sáez K, Vida G. Performance of 14 fullscale sewage treatment plants: comparison between four aerobic technologies regarding effluent quality, sludge production and energy consumption. Environ Technol, 2013; 34(15):2267- 75.
  • 12. Foladori P, Gatti GB, Groff M. Analisi ed efficientamento energetico dell’impianti di depurazione di Folgaria (TN). Atti della 49° Giornata di Studio di Ingegneria Sanitaria Ambientale, Ottobre, 23, Genova. 2013.
  • 13. Guglielmi L, Belli R. Riduzione dei consumi energetici nell’impianto di depurazione di Mancasale (RE), Atti della 49° Giornata di Studio di Ingegneria Sanitaria Ambientale, Ottobre, 23, Genova. 2013.
  • 14. Frijns J, Hofman J, Nederlof M. The potential of (waste) water as energy carrier. Energy Convers Manag, 2013; 65:357-63.
Toplam 14 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Bölüm Araştırma Makalesi
Yazarlar

Sureyya Altın Bu kişi benim

Ahmet Altın Bu kişi benim

Sevcan Doğru Bu kişi benim

Yayımlanma Tarihi 1 Mayıs 2020
Yayımlandığı Sayı Yıl 2020 Cilt: 77 Sayı: EK-4

Kaynak Göster

APA Altın, S., Altın, A., & Doğru, S. (2020). Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi. Türk Hijyen Ve Deneysel Biyoloji Dergisi, 77(EK-4), 49-56.
AMA Altın S, Altın A, Doğru S. Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi. Turk Hij Den Biyol Derg. Mayıs 2020;77(EK-4):49-56.
Chicago Altın, Sureyya, Ahmet Altın, ve Sevcan Doğru. “Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi”. Türk Hijyen Ve Deneysel Biyoloji Dergisi 77, sy. EK-4 (Mayıs 2020): 49-56.
EndNote Altın S, Altın A, Doğru S (01 Mayıs 2020) Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi. Türk Hijyen ve Deneysel Biyoloji Dergisi 77 EK-4 49–56.
IEEE S. Altın, A. Altın, ve S. Doğru, “Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi”, Turk Hij Den Biyol Derg, c. 77, sy. EK-4, ss. 49–56, 2020.
ISNAD Altın, Sureyya vd. “Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi”. Türk Hijyen ve Deneysel Biyoloji Dergisi 77/EK-4 (Mayıs 2020), 49-56.
JAMA Altın S, Altın A, Doğru S. Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi. Turk Hij Den Biyol Derg. 2020;77:49–56.
MLA Altın, Sureyya vd. “Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi”. Türk Hijyen Ve Deneysel Biyoloji Dergisi, c. 77, sy. EK-4, 2020, ss. 49-56.
Vancouver Altın S, Altın A, Doğru S. Bir Evsel Atıksu Arıtma Tesisinde İşletme Maliyetlerinin İncelenmesi. Turk Hij Den Biyol Derg. 2020;77(EK-4):49-56.