Selected Thermal Waste Treatment Plants In Europe, Case Study

Olejnik, Dorota; Krupa, Marcin

doi:10.59440/ceer/175240

Artykuł - szczegóły

Tytuł artykułu

Selected Thermal Waste Treatment Plants In Europe, Case Study

Autorzy

Olejnik Dorota , Krupa Marcin

Treść / Zawartość

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Identyfikatory

DOI

10.59440/ceer/175240

Warianty tytułu

Języki publikacji

Abstrakty

The functioning of societies involves the generation of large amounts of municipal waste. This study analyses the amounts of pollutants emitted during waste incineration at selected waste incineration plants in 2022. Four plants were analyzed, including three with the highest waste processing efficiency (Copenhagen, Poznan and Kraków) and one with the lowest efficiency (Konin). The choice of the factory in Copenhagen was also dictated by its strategic location in the city center. Analysing the emissions from the selected plants it can be concluded that environmental safety was maintained and none of the plants exceeded the permissible emissions value.

Słowa kluczowe

thermal waste treatment plants incineration permissible value pollutant emission

utylizacja odpadów zakład utylizacji spalanie emisja zanieczyszczeń

Wydawca

Oficyna Wydawnicza Uniwersytetu Zielonogórskiego

Czasopismo

Civil and Environmental Engineering Reports

Rocznik

2023

Tom

Vol. 33, no. 3

Strony

1--18

Opis fizyczny

Bibliogr. 26 poz., fot., tab.

Twórcy

autor

Olejnik Dorota

dorota.olejnik@p.lodz.pl

Institute of Environmental Engineering and Building Services, Lodz University of Technology, Lodz, Poland

autor

Krupa Marcin

Veolia Energia Łódź S.A., Lodz, Poland

Bibliografia

1. Lemann, MF 2008. Waste Management. Peter Lang AG. Bern.
2. Wielgosiński, G and Czerwińska, J 2019. [Municipal waste incineration plants in Poland]. Nowa Energia 4, 1-14.
3. Wielgosiński, G 2020. [Thermal waste treatment]. Nowa Energia. Racibórz: https://www.eastcham.fi/finnishwastemanagement/municipal-solid-waste/history-of-waste-management/
4. RenoSam and Ramboll Co. 2006. The most efficient waste management system in Europe: waste-to-energy in Denmark. RenoSam and Ramboll Company report. RenoSam and Ramboll Co. Copenhagen.
5. Nadziakiewicz, J et al. 2007. [Thermal processes of waste disposal]. Wydawnictwo Politechniki Śląskiej. Gliwice.
6. Sala, D and Bieda, B 2020. The Thermal Waste Treatment Plant in Kraków, Poland: A Case Study. Innovation in Global Green Technologies. IntechOpen.
7. Regulation of the Minister of Development of January 21, 2016, on the requirements for conducting the thermal transformation of waste and methods of dealing with waste generated as a result of this process. Journal of Laws 2016 Pos. 108.
8. Waste to Energy 2022/2023 Technologies, plants, projects, players and backgrounds of the global thermal waste treatment business 15th edition, 2022.ecoprog GmbH. https://www.cewep.eu/waste-to-energy-plants-in-europe-in-2020/
9. Reimann, DO 2013. CEWEP Energy Report III, Results of Specific Data for Energy, R1 Plant Efficiency Factor and NCV of 314 European Waste-to-Energy (WtE) Plants.
10. Scarlat, N et all 2018. Status and opportunities for energy recovery from municipal solid waste in Europe. Waste Biomass Valorization 10(9), 2425-2444.
11. Su, D. et all. 2023. Thermal integration of waste to energy plants with Post-combustion CO2 capture. Fuel. 332. 126004.
12. Wielgosiński, G et all. 2021. Solid Waste Mass Balance as a Tool for Calculation of the Possibility of Implementing the Circular Economy Concept. Energies. 14,1811.
13. Kępys, W and Jaszczura, K 2020. [Thermal waste treatment installations in Poland].. Inżynieria Mineralna. 1(1). 47-50.
14. Wojtowicz-Wrobel, A 2001. From Technology to a Landmark - Selected Thermal Waste Processing Plants in Europe. IOP Conf. Ser.: Mater. Sci. Eng. 471. 112004.
15. European Parliament and Council. 2008. Directive 2008/98/EC of the European Parliament and of the Council of 19 November 2008 on waste and repealing certain directives. Off J Eur Union. 312, 3-30.
16. Bien, JD 2021. [Fuel from waste and potential possibilities of its management in the form of alternative fuel, Renewable energy sources]. Wydawnictwo Politechniki Częstochowskiej. Częstochowa. 109-134.
17. European Commision Directorate General Environment Refuse Derived Fuel Current Practice and Perspectives. 2003. Final Report. 2-23.
18. Nadziakiewicz, J et al. 2012. [Thermal processes of waste disposal]. Wydawnictwo Politechniki Śląskiej. Gliwice.
19. https://www.poznan.pl/mim/wortals/wortal,285/-,p,51601,51602,51614.html
20. https://prezero-zielonaenergia.pl
21. www.mzgok.konin.pl
22. www.khk.krakow.pl/pl/ekospalarnia
23. Edo, M 2021. Waste-to-energy and social acceptance. Copenhill Waste-to-Energy plant in Copenhagen. IEA Bioenergy.
24. https://www.worldbuildingsdirectory.com/entries/copenhill-amager-bakke .
25. Regulation on emission standards for certain types of installations, fuel combustion sources and appliances for waste incineration or co-incineration. 2020. Journal of Laws 2020 Pos. 1860
26. Czerwińska, J and Wielgosiński, G 2020. Functioning of the flue gas treatment system in Polish municipal waste incineration plants. Scientific Review Engineering and Environmental Sciences. 29(1).108-119.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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