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Use of quantitative and qualitative wastewater monitoring in water protection on the example of Lodz

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Języki publikacji
EN
Abstrakty
EN
Widely understood protection of water, and in particular surface waters, most exposed to direct pollution, requires many operations carried out both in the catchment area and in sewage systems as well as wastewater treatment plants. Due to its character and working conditions, it should be monitored not only in terms of hydraulics, but also in terms of the quality of transported wastewater. During atmospheric precipitation, large volumes of domestic and industrial wastewater as well as rainwater in various proportions flow through the canals, changing not only their quantity but also their composition. In such cases, the issue of monitoring becomes particularly vital. The article presents an analysis of the needs and tasks resulting from the application of quantitative and qualitative monitoring in the assessment of the functioning of sewage systems. Methods and tools used in Lodz that may be useful in water protection are presented. The benefits of using this type of solutions as well as the limitations and difficulties are discussed.
Twórcy
  • Lodz University of Technology Institute of Environmental Engineering and Building Installations, Al. Politechniki 6, 90-924 Lodz
  • Lodz University of Technology Institute of Environmental Engineering and Building Installations, Al. Politechniki 6, 90-924 Lodz
Bibliografia
  • [1] Hochedlinger M., Hofbauer P., Wandl G., Meyer S., Rauch W., Kroiss H. and Heindl M., 2006, Online UV VIS measurements - the basis for future pollution based sewer real time control in Linz”, 2nd Int. Conf. on Sewer Operation and Maintenance,Vienna.
  • [2] Lacour C., Joannis C., Chebbo G., 2009, Assessment of annual pollutant loads in combined sewers from continuous turbidity measurements: sensitivity to calibration data, Water Research, 43, 8, 2179-2190.
  • [3] Palasuek R., Seesa-ard T., Kunarak C., Kerdcharoen T., 2015, Electronic nose for water monitoring: The relationship between wastewater quality indicators and odor”, in Proc. of the 2015 12th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON), 24-27 June, Hua Hin, Thailand, 1-5.
  • [4] Lvovaa L., Guanais Gonçalvesa C., Petropoulosa K., Michelia L., Volpea G., Kirsanovb D., Leginb A., Viaggiud E., Congestrid R., Guzzellae L., Pozzonie F., Palleschia G., Di Nataleb C., Paolesse R., 2016, Electronic tongue for microcystin screening in waters,” Biosensors and Bioelectronics, Vol. 80, 154-160.
  • [5] Di Lecce V., Petruzzelli D., Guaragnella C., Cardellicchio A., Dentamaro G., Quarto A., Soldo D., Dario R., 2017, Real-time monitoring system for urban wastewater, July 2017, Conference: 2017 IEEE Workshop on Environmental, Energy, and Structural Monitoring Systems (EESMS).
  • [6] Langeveld J.G., Schilperoort R.P.S., Weijers S.R., 2013, Climate change and urban wastewater infrastructure: there is more to explore, Journal of Hydrolology, 476, 112-119.
  • [7] Zawilski M., Brzezińska A., 2014, Areal rainfall intensity distribution over an urban area and its effect on a combined sewerage system, Urban Water Journal, 11, 7, 532-542.
  • [8] Casadio A., Maglionico M., Bolognesi A., Artina S., 2010, Toxicity and pollutant impact analysis in an urban river due to combined sewer overflows loads, Water Science and Technology, 61, 1, 207-21.
  • [9] Bi E.G., Monette F., Gasperi J., Perrodin Y., 2014, Assessment of the ecotoxicological risk of combined sewer overflows for an aquatic system using a coupled substance and bioassay approach, Environmental Science of Pollution Research, 1-15.
  • [10] Caissie D., Kurylyk B.L., St-Hilaire A., El-Jabi N., MacQuarrie K.T., 2014, Streambed temperature dynamics and corresponding heat fluxes in small streams experiencing seasonal, ice cover, Journal of Hydrology, 519, 1441-1452.
  • [11] Brzezińska A., Sakson G., Zawilski M, 2016, Assessment of pollutant load emission from combined sewer overflows based on the online monitoring, Environmental Monitoring and Assessment, 188, 9, 502.
  • [12] Phillips P.J., Chalmers A.T., Gray J.L., Kolpin D.W., Foreman W.T., Wall G.R., 2012, Combined sewer overflows: an environmental source of hormones and wastewater micropollutants, Environmental Science and Technology, 46, 10, 5336-5343.
  • [13] Bi E.G., Monette F., Gachon P., Gaspéri J., Perrodin Y., 2015, Quantitative and qualita- tive assessment of the impact of climate change on a combined sewer overflow and its receiving water body, Environmental Science and Pollution Research, 22, 11905-11921.
  • [14] Keupers I., Willems P., 2013, Impact of urban WWTP and CSO fluxes on river peak flow extremes under current and future climate conditions, Water Science and Technology, 67, 12, 2670-2676.
  • [15] Vanrolleghem, P.A. and Lee, D.S., 2003, On-line monitoring equipment for wastewater treatment processes: state of the art. Water Science and Technology, 47, 2, 1-34.
  • [16] Torres A. and Bertrand-Krajewski J.L., 2008, Partial Least Squares local calibration of a UV-visible spectrometer used for in situ measurements of COD and TSS concentrations in urban drainage systems, Water Science and Technology, 57, 4, 581-588.
  • [17] Thompson K. E., Vamvakeridou-Lyroudia L., Kapelan Z., Savic D., 2011, Optimal macro-location methods for sensor placement in urban water systems,” Exeter, UK.
  • [18] Arnbjerg-Nielsen K., 2011, Past, Present and future design of urban drainage systems with focus on Danish experience, Water Science and Technology, 63, 3, 527-535.
  • [19] Sandoval S., Torres A., Pawlowsky-Reusing E., Riechel M., Caradot N., 2013, The evaluation of rainfall influence on combined sewer overflows characteristics: the Berlin case study, Water Science and Technology, 68, 12, 2683-2690.
  • [20] Campisano A., Cabot J., Muschalla D., Pleau M., Vanrolleghem P.A.,2013, Potential and limitations of modern equipment for real time control of urban wastewater system, Urban Water Journal, 10, 300-31.
  • [21] Bertrand-Krajewski J.L., Bardin J.P., Mourad M., Béranger Y., 2003, Accounting for sensor calibration, data validation, and measurement and sampling uncertainties in monitoring of urban drainage systems, Water Science and Technology, 47, 2, 95-102.
  • [22] Wierzbicki P., Waack-Zając A., Koska T., 2010, Hydrographic system of the city of Lodz, Scientific Notebooks of the Lodz University of Technology, Civil Engineering, 1066, pp. 61, 1-13.
  • [23] Kożuchowski, K., 2011. Polish climate: a new look. PWN Scientific Publisher, Warsaw, 1-292.
  • [24] Regulation of the Minister of the Environment of November 18, 2014 on the conditions which must be met during discharging wastewater into water or into the ground,, and on substances that are particularly harmful to the aquatic environment.
  • [25] Zawilski M. 2012, Analysis of the hydraulic load of the sewage system on a large urban catchment scale, Scientific Papers of Rzeszów University of Technology, Civil and Environmental Engineering, z. 59, 2/I, 237-247.
  • [26] Brzezińska A., 2019, Emission of pollutants from combined sewer ovelflows, Monographs of the Lodz University of Technology, No. 2279.
  • [27] Dziedziela B., 2016, Research on pollution emissions from storm water drainage in urbanized areas on the example of Lodz, PhD thesis, Lodz University of Technology, Faculty of Civil Engineering, Architecture and Environmental Engineering.
  • [28] Hannouche, A., Joannis, C. & Chebbo, G., 2017, Assessment of total suspended solids (TSS) event load and its uncertainties in combined sewer system from continuous turbidity measurements. Urban Water Journal, 17, 8, 789-796.
  • [29] Montserrat A., Hofer T., Poch, M., Muschalla D., Corominas L., 2017, Using the duration of combined sewer overflow events for the calibration of sewer hydrodynamic models. Urban Water Journal, 14, 8, 782-788.
  • [30] Brzezińska A., Sakson G., Zawilski M., 2018, Predictive model of pollutant loads discharged by combined sewer overflows, Water Science and Technology, 77, 7-8, 1819-1828.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-57fbe8c5-7327-445d-98db-e0699f03dc9f
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