Wpływ solanki z regeneracji zmiękczania wody na działanie przydomowej oczyszczalni ścieków oraz przewodność hydrauliczną gruntu

• Autorzy: Pawlak Maciej , Pilarska Agnieszka A. , Zimnicka Katarzyna , Kałuża Tomasz
• Języki publikacji: PL

Słowa kluczowe

PL

twardość wody; przydomowe oczyszczalnie ścieków; przewodność hydrauliczna; jakość wody

EN

water hardness; home sewage treatment plants; hydraulic conductivity; water quality

• Wydawca: Wydawnictwo 2K TECHNOLOGIE s.c.
• Czasopismo: Technologia Wody
• Rocznik: 2023
• Tom: Nr 4 (82)
• Strony: 76--81
• Opis fizyczny: Bibliogr. 24 poz., rys.

Twórcy

autor

Pawlak Maciej

• Uniwersytet Przyrodniczy w Poznaniu, Katedra Inżynierii Wodnej i Sanitarnej

autor

Pilarska Agnieszka A.

• Uniwersytet Przyrodniczy w Poznaniu, Katedra Inżynierii Wodnej i Sanitarnej

autor

Zimnicka Katarzyna

• Uniwersytet Przyrodniczy w Poznaniu, Katedra Inżynierii Wodnej i Sanitarnej

autor

Kałuża Tomasz

• Uniwersytet Przyrodniczy w Poznaniu, Katedra Inżynierii Wodnej i Sanitarnej

Bibliografia

• [1] Gallagher, J.; Gill, L.W. (2021): The Life Cycle Environmental Performance of On-Site or Decentralised Wastewater Treatment Systems for Domestic Homes. Water, 13, 2542.
• [2] D'Amato, V.A.; Bahe, A.; Bounds, T.; Comstock, B.; Konsler, T.; Liehr, S.K.; Long, S.K.; Ratanaphruks, K.; Rock, C.A.; Sherman, K. (2008): Factors Affecting the Performance of Primary Treatment in Decentralized Wastewater Systems; Raport WERF M-DEC-7; IWA Publishing: London,
• [3] Saeed, T; Afrin, R.; AI-Muyeed, A.; Miach, J.; Jahan, H. (2021): Bioreactor septic tank for on-site wastewater treatment: Floating constructed wetland integration. J. Environ. Chem. Eng., 9,105606.
• [4] Adhikari, J.R.; Lohani, S.P. (2019]: Design, installation, operation and experimentation of septic tank-UASB wastewater treatment system. Renew. Energy, 143,1406-1415.
• [5] Pishgar, R.; Morin, D.; Young, S.J.; Schwartz, J.; Chu, A. (2021): Characierization of domestic wastewater released from 'green' households and field study of the performance of onsite septic tanks retrofitted into aerobic bioreactors in cold climate. Sci. Total Environ., 755, 142446.
• [6] Chandra, S.; Jagdale, P.; Medha, i.; Tiwari, A.K.; Bartoli, M.; Nino, A.D.; Olivito, F. (2021): Biochar-Supported TiO2-Based Nanocomposites for the Photocatalytic Degradation of Sulfamethoxazole in Water - A Review. Toxics, 9, 313.
• [7] Pawlak M., Skiba M., Spychała M., Nieć J. (2015): The investigation of density currents and rate of out flow from a septic tank; Journal of Ecological Engineering, 16, (4), 103-110.
• [8] Sanchez, L; Carrier, M.; Cartier, J.; Charmette, C.; Heran, M.; Steyer, J.P.; Lesage, G. (2022): Enhanced organic degradation and biogas production of domestic wastewater at psychrophilic temperature through submerged granular anaerobic membrane bioreactor for energy-positive treatment. Bioresour. Technol. 353,127145.
• [9] D'Amato V.A., Bahe A., Bounds T., Comstock B., Konsler t, Liehr S K., Long S. K., Ratanaphruks K., Rock Ch. A., Sherman K. (2008): Factors affecting the performance of primary treatment in decentralized wastewater systems. Raport WERF 04-DEC-7. Wyd. IWA Pub.
• [10] https://www.bamartech.pl (data użycia 15.11.2023 r).
• [11] https://aquahome.pl/blog/polsce-woda-najtwardsza
• [12] https://www.aquanet.pl/strefa-wiedzy/twardosc-wody (data użycia 15.11.2023 r).
• [13] Parsons, S.A. (2000): The effect of domestic ion-exchange water softeners on the microbiological quality of drinking water. Water Res., 34, 2369-2375.
• [14]. Koul, B.; Yadav, D.; Singh, S.; Kumar. M.; Song, M. (2022): Insights into the Domestic Wastewater Treatment (DWWT) Regimes: A Review. Water, 14,3542.
• [15] Sanchez-Aldana, D.; Ortega-Corral, N.; Rocha-Gutiérres, B.A.; Ballinas-Casarrubias, L; Perez-Dominguez, EJ.; Newárez-Moorillon, G.V; Soto-Salcido, L.A.; Ortega-Hernández, S.; Cardenas-Felix, G.; Gonzáles-Sánchez, G. (2018): Hypochlorite generation from s water softener spent brine. Water 10, 1733.
• [16] Gross, M.; Bounds, T. (2007): The effect of water softener backwash brine in onsite wastewater treatment systems. In Proceedings of the Eleventh Individual and Small Community Sewage Systems Conference Proceedings, Warwick, Rl, USA, 20-24 October 2007; pp. 72-105.
• [17] Higgins, M.I.; Novak, J.T. (1997): Dewatering and settling of activated sludges: The case for using cation analysis. Water Environ. Res., 69, 225-232.
• [18] Pawlak, M.; Pilarska, A.A.; Zimnicka, K.; Kujawiak, S.; Matz, R. (2023): Water Softener Regeneration Effects on the Operation of Domestic Wastewater Treatment Plants: A Preliminary Study. Appl. Sci., 13, 2853
• [19] Semaha, P.; Lei, Z.; Yuan, T; Zhang, 2.; Shimizu, K. (2023): Transition of biological wastewater treatment from flocculent activated sludge to granular sludge systems towards circular economy. Bioresour. Technol. Rep., 21,101294.
• [20] Liu, C.; Lin, F.; Andersen, M.N.; Wang, G.; Wu, K.; Zhao, Q.; Ye, Z. (2021): Domestic wastewater infiltration process in desert sandy soil and its irrigation prospect analysis. Ecotoxicol. Environ. Saf., 208,111419.
• [21] Murthy, S.N.; Novak, J.T.; De Haas, R.D. (1998): Monitoring cations to predict and improve activated sludge settling and dewatering properties of industrial wastewaters. Water Sci. Technol., 38,119-126.
• [22] Davis, M,L. (2011): Water and Wastewater Engineering: Design Principles and Practice; The McGraw-Hill Companies, Inc.: New York, NY.
• [23] WQRF Softened Water Benefits Study-Energy Savings (Issue VI, Article 1) In: WQA Recertification Kit 2012. Available online: https://wqa.org/wp-content/uploads/2022/09/Article-l-Softened-Water-Benefits-Study-Vol.-VI-Copy.pdf.
• [24] Toor, G.S.; Lusk, M.; Obreza, T. Onsite Sewage Treatment and Disposal Systems: An Overview. University of Florida l FAS Extension. 2011. Available online: https://edis.ifas. utl.edu/pdffiles/SS/SS54900.pdf (accessed on l5 June 2011).