This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Sahu, R. L., Dash, R. R. & Pradhan, P. K. (2019). Das Effect of hydrogeological factors on removal of turbidity during river bank filtration: laboratory and field studies. Groundwater for Sustainable Development, 9.SahuR. L.DashR. R.PradhanP. K.2019Das Effect of hydrogeological factors on removal of turbidity during river bank filtration: laboratory and field studiesGroundwater for Sustainable Development9Search in Google Scholar
Torres-Lozada, P., Amezquita-Marroquín, C. P., Agudelo-Martínez, K. D., Ortiz-Benítez, N. & Martínez-Ducuara D. S. (2018). Evaluation of turbidity and dissolved organic matter removal through double filtration technology with activated carbon. Dyna (Medellin), 85(205), 234–239.Torres-LozadaP.Amezquita-MarroquínC. P.Agudelo-MartínezK. D.Ortiz-BenítezN.Martínez-DucuaraD. S.2018Evaluation of turbidity and dissolved organic matter removal through double filtration technology with activated carbonDyna (Medellin)85205234239Search in Google Scholar
Ma, L., Dong, X., Chen, M., Zhu, L., Wang, Ch., Yang, F. & Dong, Y. (2017). Fabrication and water treatment application of carbon nanotubes (CNTs)-based composite membranes: A review. Membranes, 7(1).MaL.DongX.ChenM.ZhuL.WangCh.YangF.DongY.2017Fabrication and water treatment application of carbon nanotubes (CNTs)-based composite membranes: A reviewMembranes71Search in Google Scholar
Ibrahim, M. K. M., Abdel Azeem, M. M. A., Aly, O. H. I., Ahmed & H. M. H (2018). The Application of Dynamic Up – Flow Sand Filtration in Water Sludge Treatment. Australian Journal of Basic and Applied Sciences, 12(12), 61–66.IbrahimM. K. M.Abdel AzeemM. M. A.AlyO. H. I.AhmedH. M. H2018The Application of Dynamic Up – Flow Sand Filtration in Water Sludge TreatmentAustralian Journal of Basic and Applied Sciences12126166Search in Google Scholar
Verma, S., Daverey, A. & Sharma, A. (2017). Slow sand filtration for water and wastewater treatment – a review. Environment Technology Review, 6(1), 47–58.VermaS.DavereyA.SharmaA.2017Slow sand filtration for water and wastewater treatment – a reviewEnvironment Technology Review614758Search in Google Scholar
Wu, C., Wang, Zhou Y. & Zhu, Ch. (2016). Pretreatment of Petrochemical Secondary Effluent by Micro-flocculation and Dynasand Filtration: Performance and DOM Removal Characteristics. Water Air Soil Pollut, 227, 415.WuC.WangZhouY.ZhuCh.2016Pretreatment of Petrochemical Secondary Effluent by Micro-flocculation and Dynasand Filtration: Performance and DOM Removal CharacteristicsWater Air Soil Pollut227415Search in Google Scholar
Hultman, B., Jönsson, K. & Plaza, E. (1994). Combined nitrogen and phosphorus removal in a full-scale continuous up-flow sand filter. Water Science and Technology, 29(10–11), 127–134.HultmanB.JönssonK.PlazaE.1994Combined nitrogen and phosphorus removal in a full-scale continuous up-flow sand filterWater Science and Technology2910–11127134Search in Google Scholar
Castro, M. D. & Priego-Capote, F. (2008). Continous filtration as a separation technique. Trends in Analytical Chemistry, 27(2), 101–107.CastroM. D.Priego-CapoteF.2008Continous filtration as a separation techniqueTrends in Analytical Chemistry272101107Search in Google Scholar
Abuelkhair, N. Y., El Nadi, M. H., Fouad, H. A. & Hefny, R. M. (2022). Dynamic Sand Filter Performance against High Solids Loads in Raw Water. Benha Journal of Applied Sciences 7(4), 97–101.AbuelkhairN. Y.El NadiM. H.FouadH. A.HefnyR. M.2022Dynamic Sand Filter Performance against High Solids Loads in Raw WaterBenha Journal of Applied Sciences7497101Search in Google Scholar
Aly, O. H. I. (2013). The application of the Dynamic up Flow Sand Filter as a Tertiary Treatment in Waste Water Treatment. El Azhar Journal, 10, 1–10.AlyO. H. I.2013The application of the Dynamic up Flow Sand Filter as a Tertiary Treatment in Waste Water TreatmentEl Azhar Journal10110Search in Google Scholar
Guo, Y., Bai, L., Tang, X., Huang, Q., Xie, B., Wang, T., Wang, J., Li, G. & Liang, H., (2018). Coupling continous sand filtration to ultrafiltration for drinking water treatment: Improved performance and membrane fouling control. Journal of Membrane Science, 567, 18–27.GuoY.BaiL.TangX.HuangQ.XieB.WangT.WangJ.LiG.LiangH.2018Coupling continous sand filtration to ultrafiltration for drinking water treatment: Improved performance and membrane fouling controlJournal of Membrane Science5671827Search in Google Scholar
Gregor, J. E., Nokes, C. J. I & Fenton, E. (1997). Optimising natural organic matter removal from low turbidity waters by controlled pH adjustment of alumininum coagulation. Water Research, 31(12), 2949–2958.GregorJ. E.NokesC. J. IFentonE.1997Optimising natural organic matter removal from low turbidity waters by controlled pH adjustment of alumininum coagulationWater Research311229492958Search in Google Scholar
Hong, S. & Elimelech, M. (1997). Chemical and physical aspects of natural organic matter (NOM) fouling of nanofiltration membranes. Journal of Membrane Science, 132, 159–181.HongS.ElimelechM.1997Chemical and physical aspects of natural organic matter (NOM) fouling of nanofiltration membranesJournal of Membrane Science132159181Search in Google Scholar
Kolisch, G. & Schirmer, G. (2004). Lamella separators in the upgrading of a large urban sewage treatment plant. Water Science Technology, 50(7), 205–212.KolischG.SchirmerG.2004Lamella separators in the upgrading of a large urban sewage treatment plantWater Science Technology507205212Search in Google Scholar
Ciuła, J., (2022). Analysis of the effectiveness of wastewater treatment in activated sludge technology with biomass recirculation. Architecture Civil Engineering Environment, 15(2), 123–134.CiułaJ.2022Analysis of the effectiveness of wastewater treatment in activated sludge technology with biomass recirculationArchitecture Civil Engineering Environment152123134Search in Google Scholar
Wiewiórska, I. & Rybicki, S. M (2022). Analysis of a coagulation sludge contamination with metals using X-ray crystallography. Desalination and Water Treatment, 254, 151–159.WiewiórskaI.RybickiS. M2022Analysis of a coagulation sludge contamination with metals using X-ray crystallographyDesalination and Water Treatment254151159Search in Google Scholar
Ciuła, J., Generowicz, A., Gaska, K. & Gronba-Chyła, A. (2022). Efficiency Analysis of the Generation of Energy in a Biogas CHP System and its Management in a Waste Landfill – Case Study. Journal of Ecological Engineering, 23, 143–156.CiułaJ.GenerowiczA.GaskaK.Gronba-ChyłaA.2022Efficiency Analysis of the Generation of Energy in a Biogas CHP System and its Management in a Waste Landfill – Case StudyJournal of Ecological Engineering23143156Search in Google Scholar
Ciuła, J., Kowalski, S. & Wiewiórska, I. (2022). Pollution Indicator of a Megawatt Hour Produced in Cogeneration – The Efficiency of Biogas Purification Process as an Energy Source for Wastewater Treatment Plants. Journal of Ecological Engineering, 24(3), 232–245.CiułaJ.KowalskiS.WiewiórskaI.2022Pollution Indicator of a Megawatt Hour Produced in Cogeneration – The Efficiency of Biogas Purification Process as an Energy Source for Wastewater Treatment PlantsJournal of Ecological Engineering243232245Search in Google Scholar
Regulation of the Minister of Maritime Economy and Inland Navigation of August 29 (2019). (Journal of Laws 2018.1747 of September 13, 2019) [access on 17/03/2023].Regulation of the Minister of Maritime Economy and Inland Navigation of August 29 (2019). (Journal of Laws 2018.1747 of September 13, 2019) [access on 17/03/2023]Search in Google Scholar
Wysowska, E., Wiewiórska, I. & Kicińska, A. (2022). Minerals in tap water and bottled waters and their impact on human health. Desalination and Water Treatment, 259, 133–151.WysowskaE.WiewiórskaI.KicińskaA.2022Minerals in tap water and bottled waters and their impact on human healthDesalination and Water Treatment259133151Search in Google Scholar
Regulation of the Minister of Health of 7 December 2017 on the quality of water intended for human consumption (2017), 2294. [access on 17/03/2023].Regulation of the Minister of Health of 7 December 2017 on the quality of water intended for human consumption (2017), 2294. [access on 17/03/2023]Search in Google Scholar
Council Directive 98/83/EC of 3 November 1998 on the quality of water intended for human consumption.Council Directive 98/83/EC of 3 November 1998 on the quality of water intended for human consumptionSearch in Google Scholar
Directive (EU) 2020/2184 of the European Parliament and of the Council of 16 December 2020 on the Quality of Water Intended for Human Consumption.Directive (EU) 2020/2184 of the European Parliament and of the Council of 16 December 2020 on the Quality of Water Intended for Human ConsumptionSearch in Google Scholar