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Analiza stabilności chemicznej wody wodociągowej pod kątem wymaganego poziomu bezpieczeństwa technologicznego
Języki publikacji
Abstrakty
The main goal of this work is to show the new approach to determining safety technological levels (SLs) in terms of water quality and its chemical stability, as well as issues of water corrosion properties in water distribution systems (WDSs), due to the fact that water supply pipes are prone to corrosion. In the paper the methodology of determining the risk associated with threat to technical infrastructure was considered. The concept was studied on the basis of real operational data from the water treatment plant. The probability of exceeding the individual parameters for WTPI is slightly larger than for WTPII, which means that this water treatment process may cause lack of chemical stability in the water supply network. Operators should anticipate in the process of designing water distribution system, using proper materials, as to ensure an adequate level of safety from the water source to the water recipient. It should be noted that it is necessary to adjust the material of internal installation of water supply networks to the parameters of the water. At present, there are no correlations between the designing step and water parameters. It was concluded that to protect the water supply infrastructure, which belongs to critical infrastructure, water company should put more emphasis on distribution of stable water that has not potentially corrosion properties. Some suggestions were made for the protection of WDS and to ensure safety of system functioning and long-term usability of water pipes.
Głównym celem pracy jest przedstawienie nowego podejścia do określania poziomów technologicznych bezpieczeństwa (SL) w zakresie jakości wody i jej stabilności chemicznej, a także właściwości korozyjnych wody w systemach dystrybucji wody (WDS), ze względu na fakt, iż przewody wodociągowe są podatne na korozję. W pracy przedstawiono metodologię określania ryzyka związanego z wystąpieniem zagrożeń dla infrastruktury technicznej. Analiza została wykonana na podstawie uzyskanych danych eksploatacyjnych ze stacji uzdatniania wody. Prawdopodobieństwo przekroczeń poszczególnych parametrów w przypadku WTPI jest nieznacznie większe od WTPII, co oznacza iż ten proces uzdatniania wody może powodować brak zachowania stabilności chemicznej w sieci wodociągowej. Operatorzy powinni przewidzieć w procesie projektowania systemu dystrybucji wody, użycie odpowiednich materiałów, tak aby zapewnić odpowiedni poziom bezpieczeństwa od źródła wody do odbiorcy. Należy zauważyć, że niezbędne jest dostosowanie materiału wewnętrznej instalacji sieci wodociągowej do parametrów wody nie odwrotnie. W chwili obecnej nie ma korelacji pomiędzy etapem projektowania, a parametrami wody. W celu ochrony infrastruktury wodociągowej, które należą do infrastruktury krytycznej, przedsiębiorstwo wodociągowe powinna położyć większy nacisk na dystrybucję stabilnej wody, która nie ma właściwości korozyjnych. W pracy zaproponowano podjęcie działań zapewniających ochronę systemu dystrybucji wody przed utratą stabilności chemicznej wody.
Czasopismo
Rocznik
Tom
Strony
3--12
Opis fizyczny
Bibliogr. 33 poz., tab., wykr.
Twórcy
autor
- Rzeszow University of Technology, Faculty of Civil, Environmental Engineering and Architecture, Department of Water Supply and Sewerage Systems
autor
- Rzeszow University of Technology, Faculty of Civil, Environmental Engineering and Architecture, Department of Water Supply and Sewerage Systems
autor
- Rzeszow University of Technology, Faculty of Civil, Environmental Engineering and Architecture, Department of Water Purifi cation and Protection
autor
- Rzeszow University of Technology, Faculty of Civil, Environmental Engineering and Architecture, Department of Geodesy and Geotechnics
Bibliografia
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- [6]. Ferrandez-Gamot, L., Busson, P., Blesa, J., Tornil-Sin, S., Puig, V., Eric, D. & Soldevila, A. (2015). Leak localization in water distribution networks using pressure residuals and classifiers original, Water Resources, 48, pp. 220-225.
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- [8]. Gerke, T.L., Maynard, J.B., Schock, M.R. & Lytle, D.L. (2008). Physiochemical characterization of five iron tubercles from a single drinking water distribution system: possible new insights on their formation and growth, Corrosion Science, 50, pp. 2030-2039.
- [9]. Gorka, A., Papciak, D., Zamorska, J. & Antos, D. (2008). The influence of biofilm on the effectiveness of ion exchange process, Industrial & Engineering Chemistry Research, 47, pp. 7456-7464.
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- [13]. Królikowska, J. (2011). Application of PHA method for assessing risk of failure on the example of sewage system in the city of Krakow, Rocznik Ochrona Srodowiska, 13, pp. 693-710.
- [14]. Kutylowska, M. & Orlowska-Szostak, M. (2016). Comparative analysis of water-pipe network deterioration-case study, Water Practice and Technology, 11(1), pp. 148-156.
- [15]. Kiedryńska, L., Papciak, D. & Granops, M. (2006). Sanitary Chemistry, Warsaw University of Life Sciences - SGGW (WULS-SGGW), Warsaw 2006. (in Polish)
- [16]. Lia, X., Wanga, H., Hua, C., Yanga, M., Hub, H. & Niuc, J. (2014). Characteristics of biofilms and iron corrosion scales with ground and surface waters in drinking water distribution systems, Corrosion Science, 90, pp. 331-339.
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- [21]. Ondrejka-Harbulakova, V., Purcz, P., Estokova, A., Luptakova, A. & Repka, M. (2015). Using a statistical method for the concrete deterioration assessment in sulphate environment, Chemical Engineering Transaction, 43, pp. 2221-2226.
- [22]. Pietrzyk, A. & Papciak, D. (2016). Organic Matter in Natural Water-Forms of Occurring and Methods of Purifying, Czasopismo Inżynierii Lądowej, Środowiska i Architektury - Journal of Civil Engineering, Environment and Architecture, JCEEA, 63 (2/I), pp. 241-252. DOI: 10.7862/rb.2016.126
- [23]. Radzka, E., Rymuza, K. & Jankowska, J. (2015). The assessment of drinking water quality using zero unitarization method, Archives of Environmental Protection, 41, pp. 91-95. DOI: 10.1515/aep-2015-0043
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- [27]. Suna, H. & Wanga, X. (2016). NH4 + adsorption and adsorption kinetics by sediments in a drinking water reservoir, Archives of Environmental Protection, 42, pp. 90-95. DOI: 10.1515/aep-2016-0039
- [28]. Tchórzewska-Cieslak, B. & Szpak, D. (2015). Proposed method of analysis and assessment of water supply safety, Ochrona Środowiska, 37(3), pp. 43-47. (in Polish)
- [29]. Tchorzewska-Cieslak, B. & Rak, J. (2009). Method of identification of operational states of water supply system, Conf. Proc. of 3rd Congress Environmental Engineering, Lublin, Poland, pp. 521-526.
- [30]. Tchorzewska-Cieslak, B., Boryczko, K. & Eid, M. (2012). Failure scenarios in water supply system by means of fault tree analysis, Advances in Safety, Reliability and Risk Management - Proceedings of the European Safety and Reliability Conference, ESREL 2011, pp. 2492-2499.
- [31]. Volk, C., Dundore, E., Schiermann, J. & Lechevallier, M. (2000). Practical evaluation of iron corrosion control in a drinking water distribution system, Water Resources, 34, pp. 1967-1974.
- [32]. Zhang, H., Tian, Y., Wan, J. & Zhao, P. (2015). Study of biofilm influenced corrosion on cast iron pipes in reclaimed water, Applied Surface Science, 357, pp. 236-247.
- [33]. Zhang, Y., Griffin, A. & Edwards, M. (2010). Effect of nitrification on corrosion of galvanized iron, copper, and concrete, Journal of American Water Works Association, 102, pp. 83-93.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-bd507274-d64f-41a1-9fd5-9d64f024a77c