References

  1. H. Ødegaard, B. Eikebrokk, R. Storhaug, Processes for the removal of humic substances from water — an overview based on Norwegian experiences, Water Sci. Technol., 40 (1999) 37–46.
  2. M. Perchuć, Iron and humic acids in colored groundwater, Gaz, Woda i Technika Sanitarna, 11 (2003) 394–397 (in Polish).
  3. Y. Ouyang, Simulating dynamic load of naturally occurring TOC from watershed into a river, Water Res., 37 (2003) 823–832.
  4. A. Pietrzyk, D. Papciak, Organic matter in natural waters - occurrence forms and determination methods, JCEEA, 33 (2016) 241–252.
  5. I. Zimoch, A. Stolatczyk, Raman spectroscopy in estimating THM formation potential in water pipe network, Environ. Prot. Eng., 36 (2010) 55–64.
  6. J. Szymik-Gralewska, I. Zimoch, Optimization of the Drinking Water Coagulation and Filtration System as a Result of Reliability Analysis and Life Cycle Costing, Safety and Reliability: Methodology and Applications - Proceedings of the European Safety and Reliability Conference, ESREL, 2014, pp. 487–496.
  7. I. Zimoch, Modeling of trihalomethane concentrations in tap water, Ochrona Środowiska, Environ. Prot., 33 (2011) 35–42 (in Polish).
  8. J. Duan, J. Wang, N. Graham, F. Wilson, Coagulation of humic acid by aluminium sulphate in saline water conditions, Desalination, 150 (2002) 1–14.
  9. C. Melia, W. Becker, K. Au, Removal of humic substances by coagulation, Water Sci. Technol., 40 (1999) 47–54.
  10. I. Zimoch, Monitoring of the quality of the water in water-pipe networks: reliability interpretation of the results, Ochrona Środowiska, Environ. Prot., 31 (2009) 51–55 (in Polish).
  11. H. Wienberg, Disinfection by-products in drinking water: the analytical challenge, Anal. Chem., 71 (1999) 801A–808A.
  12. I. Zimoch, E. Bartkiewicz, Analysis of disinfectant decay in a water supply system based on mathematical model, Desal. Water Treat., 134 (2018) 272–280.
  13. I. Zimoch, Operational safety of the water supply system under conditions of water quality variations in the water-pipe network, Ochrona Środowiska, Environ. Prot., 31 (2009) 51–55 (in Polish).
  14. World Health Organization (WHO), Guidelines for Drinking– Water Quality, 4th ed., WHO 2011.
  15. J.M. Montgomery, Water Treatment Principles and Design, A Wiley and Sons, Inc., Intersci. Publ., New York, 1985.
  16. J.C. Hoff, E.E. Geldereich, Comparison of the biocidal efficiency of alternative disinfectants, J. AWWA, 1 (1981) 40.
  17. S. Richardson, Disinfection by-products and other emerging contaminants in drinking water, Trends Anal. Chem., 22 (2003) 666–684.
  18. S. Richardson, M. Plewa, E. Wagner, R. Schoeny, D. DeMarini, Occurrence, genotoxicity, and carcinogenicity of regulated and emerging disinfection by-products in drinking water: a review and roadmap for research, Mutat. Res., 636 (2007) 178–242.
  19. J. Kaleta, A. Puszkarewicz, D. Papciak, Evaluation of Effectiveness of Pre-hydrolyzed Coagulants in Removing Humic Substances From Aqueous Solutions, Z. Dymczewski, J. Jeż-Walkowiak, N. Mariusz, Eds., Water Supply and Water Quality, Press by PZITS Odz. Wielkopolski, Poznań, 2014, pp. 664–660 (in Polish).
  20. T. Karanfil, M.A. Schlautman, I. Erdogan, Survey of DOC and UV measurement practices with implications for SUVA determination, J. AWWA, 94 (2002) 68–80.
  21. M. Mołczan, M. Szlachta, A. Karpińska, A. Biłyk, Water quality assessment in terms of specific UV absorbance. Ochrona Środowiska, Environ. Prot., 28 (2006) 11–16 (in Polish).
  22. Regulation of the Minister of Health of 7th December 2017 Concerning the Quality of Water Intended for Human Consumption (Journal of Laws of 2017, Item 2294).
  23. M. Bonalam, L. Mathieu, S. Fass, J. Cavard, D. Gatel, Relationship between coliform culturability and organic matter in low nutritive waters, Water Res., 36 (2002) 2618–2626.
  24. J. Chandy, M. Angles, Determination of nutrients limiting biofilm formation and the subsequent impact on disinfectant decay, Water Res., 35 (2001) 2677–2682.
  25. C. Volk, C. Renner, P. Roche, H. Paillard, J.C. Joret, Effects of ozone on the production of biodegradable organic carbon (BDOC) during water treatment, Ozone-Sci. Eng., 15 (1994) 389–404.