Evaluation of the ecological effect of biodegradable waste processing in a comprehensive municipal waste management system

• Autorzy: Generowicz Agnieszka

Identyfikatory

DOI

10.21307/ACEE-2020-010

• Języki publikacji: EN

Abstrakty

EN

Recycling of biodegradable waste is one of the trends in the recovery of organic matter together with its use for reclamation, but most importantly the reduction of biodegradable waste and the reduction of waste for disposal. The paper presents the use of the decision analysis method in the selection of the most advantageous organic recycling solution in a large agglomeration. The proposed method uses the tool of life cycle analysis (LCA) and decisional analysis.

Słowa kluczowe

EN

municipal biodegradable waste; composting; methane fermentation; LCA analysis; decision analysis

PL

odpady komunalne biodegradowalne; kompostowanie; fermentacja metanowa; analiza LCA; analiza decyzyjna

• Wydawca: Silesian University of Technology
• Czasopismo: Architecture Civil Engineering Environment
• Rocznik: 2020
• Tom: Vol. 13, no. 1
• Strony: 121--128
• Opis fizyczny: Bibliogr. 35 poz.

Twórcy

autor

Generowicz Agnieszka

• PhD Eng. Assoc. Prof.; Cracow University of Technology, Warszawska 24, 31-155 Cracow, Poland

Bibliografia

• [1] Council Directive 2008/98/EC of the European Parliament and of the Council of 19 November 2008 on waste and repealing certain Directives (OJ EU.L.08.312.3).
• [2] Council Directive 2018/851 of the European Parliament and of the Council (EU) of 30 May 2018 amending Directive 2008/98/EC on waste.
• [3] Council Directive 1999/31/EC, on the landfill of waste (OJ L 182, as amended).
• [4] Gaska, K., Generowicz, A., Zimoch I., Ciuła, J., Iwanicka, Z. (2017a). A high-performance computing (HPC) based integrated multithreaded model predictive control (MPC) for water supply networks, Architecture Civil Engineering Environment, 4, 141-151.
• [5] Gaska, K., & Generowicz, A. (2017b). Advanced computational methods in component-oriented modelling of municipal solid waste incineration processes, Architecture Civil Engineering Environment, 10(1), 117-130.
• [6] Czop, M., & Kajda-Szczes􀀀niak, M. (2013). Evaluation of Basic Fuel Properties of Waste from Renovation and Construction Selected from Municipal Wastes. Rocznik Ochrona S􀀀 rodowiska, 15, 1426-1440.
• [7] Seveyn, H., & Eder, P. (2013). End-of-waste criteria for biodegradable waste subjected to biological treatment (compost & digestate), Technical proposals, Final report European Commission.
• [8] https://stat.gov.pl/obszary-tematyczne/srodowiskoenergia/ srodowisko/ochrona-srodowiska-2018, 1,19.html
• [9] Preparatory study on food waste across EU27, Technical report - 2010-054, European Communities (2011).
• [10] Jędrczak, A, & Haziak, K. (2005). Determining the requirements for composting and other biological waste treatment methods, Zielona Góra, http://www.toensmeier.pl/index.php/publisher/file/act ion/view/frmAssetID/16 (accessed: 25.11.2019).
• [11] Jędrczak, A. (2008). Biological waste treatment, Warszawa. Wydawnictwo Naukowe PWN.
• [12] Sonesson, U., Björklund, A., Carlsson, M., Dalemo, M. (2000). Environmental and economic analysis of management systems for biodegradable waste, Resources, Conservation and Recycling, 28(1-2), 29-53.
• [13] Garcia, A.J., Esteban, M.B., Marquez, M.C., Ramos, P. (2005). Biodegradable municipal solid waste: Characterization and potential use as animal feedstuffs, Waste Management, 25(8), 780-787.
• [14] Gómez Palacios, J.M., Ruiz de Apodaca, A., Rebollo, C., Azcárate, J. (2002). European policy on biodegradable waste: a management perspective, Water Science Technology 46(10), 311-318.
• [15] Koval, V., Petrashevska, A.D., Popona, O., Mikhno, I., Gaska, K. (2019). Methodology of ecodiagnostic on example of rural areas, Architecture Civil Engineering Environment 12(1), 139-144.
• [16] Werle, S. (2015). Sewage sludge-to-energy management in eastern Europe: a Polish perspective, Ecological chemistry and engineering S 22(3), 459-469.
• [17] Werle, S. (2014). Impact of feedstock properties and operating conditions on sewage sludge gasification in a fixed bed gasifier, Waste Management & Research 32(10), 954-960.
• [18] Werle, S., & Dudziak, M. (2014). Gaseous fuels production from dried sewage sludge via air gasification, Waste Management & Research 32(7), 601-607.
• [19] Smol, M., & Generowicz, A. (2018). Tretament of the municipal landfill leachate including selection of the best management solution, Desalination and Water Treatment, 117, 229-238.
• [20] White, P.R., Franke, M., Hindle, P. (1996). Integrated Solid Waste Management. A Life Cycle Inventory. London, McGraw-Hill.
• [21] McDougall, F. (2001). Life Cycle Tools for Integrated Waste Management systems, Warmer Bulletin, 76(4).
• [22] McDougall, F., & Hruska, J.P. (2000). The use of Life Cycle Inventory tools to support an integrated approach to solid waste management, Waste Management & Research, 18(6), 590-594.
• [23] McDougall, F. (2001). Life Cycle Inventory tools: supporting the development of sustainable solid waste management systems, Corporate Environmental Strategy 8(2), 142-147.
• [24] McDougall, F., & Ryu, Y.K. (2002). The Role of Landfill Within A Sustainable Solid Waste Management Strategy, Proceedings of the 2nd Asian Pacific Landfill Symposium, Seoul, Korea.
• [25] McDougall, F.R., Hruska J., (2002). The use of Life Cycle Invertory tools to support an integrated approach to solid waste management, Waste Management & Research 18(6), 590-594.
• [26] ORyu, Y.K., McDougall, F.R., Peng, C-G., Arakaki, T., Ahn, J.W. (2000). Integrated Waste Management and the Tool of Life Cycle Inventory: A Route to Sustainable Waste Management for Asia, Korean Journal of LCA, 2, 2, 41-48.
• [27] den Boer, E., den Boer, J., Jager, J. (2005). Waste management planning and optimization. Stuttgart. Ibidem.
• [28] Generowicz, A., Kowalski, Z., Kulczycka, J., Banach, M. (2011). Assessment of technological solutions of municipal waste management using technology quality indicators and multicriteria analysis, Przemysł Chemiczny 90(5), 747-753.
• [29] Kowalski, Z., Kulczycka, J., Góralczyk, M. (2007). Ecological life cycle assessment of manufacturing processes. Warszawa. Wydawnictwo Naukowe PWN.
• [30] Cossu, R. (2009). From triangles to cycles, Waste Management, 29(12), 2915-2917.
• [31] Babalola, M.A. (2015). A Multi-Criteria Decision Analysis of Waste Treatment Options for Food and Biodegradable Waste Management in Japan, Environments 2, 471-488; doi:10.3390/environments2040471.
• [32] Generowicz, A., Gaska, K., Hajduga, G. (2018). Multi-criteria Analysis of the Waste Management System in a Metropolitan Area, E3S Web of Conferences 44, 00043, EKODOK2018, 10th Conference on Interdisciplinary Problems in Environmental Protection and Engineering, doi: 10.1051/e3sconf/20184400043.
• [33] http://www.iwm-model.uwaterloo.ca/
• [34] http://www.environment-agency.gov.uk/research/ commercial/102922.aspx
• [35] IWM-2 an LCI computer model for solid waste management - model guide.

Uwagi

PL

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).