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Industrial Symbiosis for the Circular Economy Implementation in the Raw Materials Sector—The Polish Case

  • Joanna Kulczycka
  • Ryszard Uberman
  • Ewa DziobekEmail author
Chapter
  • 19 Downloads
Part of the Strategies for Sustainability book series (STSU)

Abstract

Raw materials used across the entire supply chain play a crucial role in the global economy. However, different types of mining and processing waste are generated in the production process. Waste from the extractive industry is one of the largest waste streams in Poland as well as in the EU (29% of total waste). With the development of new technology most of these wastes can be a potential source of new materials, often critical ones, or can serve as a substitute for building or construction materials. Moreover, by-products occur in many geological deposits, which can then be separated, usually with the consumption of a significant amount of energy, at various stages in the production processes of the main raw materials. This study aims to develop a proposal for the prioritisation of the management of the different types of waste and by-products generated based on the MoSCoW method during the implementation of the concept of industrial symbiosis. The analysis takes economic, financial and environmental (Life Cycle Assessment) conditions into consideration, and there is a literature review to assess the legal incentives for and barriers to the development of a strategy for a circular economy for the mining industry. A case study is presented showing how industrial symbiosis can minimise waste flow in the brown coal industry in Poland.

Keywords

Industrial symbiosis Circular economy Raw materials sector Mining waste Brown coal LCA 

References

  1. Adiansyah JS, Haque N, Rosano M, Biswas W (2017) Application of a life cycle assessment to compare environmental performance in coal mine tailings management. J Environ Manage 199:181–191CrossRefGoogle Scholar
  2. Central Statistical Office (2011–2018) Environment. https://stat.gov.pl/en/topics/environment-energy/environment/
  3. Chertow MR (2000) Industrial symbiosis: literature and taxonomy. Annu Rev Energy Environ 25(1):313–337CrossRefGoogle Scholar
  4. European Commission Decision (2009/359/EC). https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32009D0359&from=GA. Accessed 25 Apr 2019
  5. European Commission Decision (2014/955/EU). https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:32014D0955&from=EN. Accessed 25 Apr 2019
  6. European Commission, Roadmap to a Resource Efficient Europe (2011) https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:52011DC0571&from=EN. Accessed 14 Jan 2019. Accessed 25 Apr 2019
  7. Directive 2006/21/EC of the European Parliament and of the Council of 15 March 2006 on the management of waste from extractive industries and amending Directive 2004/35/EC. http://data.europa.eu/eli/dir/2006/21/oj
  8. European Parliament legislative resolution on the proposal for a European Parliament and Council directive on the management of waste from the extractive industries. http://www.europarl.europa.eu/meetdocs/2004_2009/documents/com/p5_ta(2004)0240_/p5_ta(2004)0240_en.pdf
  9. Golev A (2016) The contribution of mining to the emerging circular economy. https://www.ausimmbulletin.com/feature/the-contribution-of-mining-to-the-emerging-circular-economy/. Accessed 14 Jan 2019
  10. Guide to Cost-Benefit Analysis of Investment Projects for Cohesion Policy 2014–2020. https://ec.europa.eu/regional_policy/en/information/publications/guides/2014/guide-to-cost-benefit-analysis-of-investment-projects-for-cohesion-policy-2014-2020. Accessed 14 Jan 2019
  11. Haughey D (2019) Moscow method. https://www.projectsmart.co.uk/moscow-method.php. Accessed 14 Jan 2019
  12. Haywood L (2018), Legislative challenges hindering mine waste entering the circular economy in South Africa. Sustainability Science and Resource Economic Research Group, 6 June 2018. http://sustainabilityweek.co.za/assets/files/Day%202%20-%20CSIR%20-%20Mining.pdf. Accessed 14 Jan 2019
  13. Kasztelewicz Z (2018) Raport o stanie branży węgla brunatnego w Polsce i w Niemczech wraz z diagnozą działań dla rozwoju tej branży w I połowie XXI wieku (in Polish). https://www.cire.pl/pliki/2/2018/raport_o_stanie_branzy_wegla_brunatnego_w_polsce_i_w_niemczech.pdf. Accessed 14 Jan 2019
  14. Kulczycka J (2010) The proposal for new technology appraisal using LCA on the example of ZG Trzebionka S.A. Zeszyty Naukowe, Uniwersytet Ekonomiczny w Poznaniu 151:71–80Google Scholar
  15. Kulczycka J, Smol M (2016) Environmentally friendly pathways for the evaluation of investment projects using life cycle assessment (LCA) and life cycle cost analysis (LCCA). Clean Technol Environ Policy 18(3):829–842CrossRefGoogle Scholar
  16. Kulczycka J, Uberman R, Cholewa M (2012) Analiza kosztów i korzyści zagospodarowania odpadów górnictwa węgla kamiennego (Hard coal mining waste management cost—benefit analysis—in Polish). https://www.ue.katowice.pl/fileadmin/_migrated/content_uploads/25_J.Kulczycka__R.Uberman__M.Cholewa__Analiza_kosztow_i_korzysci….pdf. Accessed 14 Jan 2019
  17. KWK Bełchatów homepage. https://kwbbelchatow.pgegiek.pl/Oferta/Kopaliny-i-kruszywa. Accessed 14 Jan 2019
  18. Lombardi RD, Laybourn P (2012) Redefining industrial symbiosis crossing academic—practitioner boundaries.  https://doi.org/10.1111/j.1530-9290.2011.00444.x. Accessed 14 Jan 2019CrossRefGoogle Scholar
  19. Mancini L, Sala S (2018) Social impact assessment in the mining sector: review and comparison of indicators frameworks.  https://doi.org/10.1016/j.resourpol.2018.02.002CrossRefGoogle Scholar
  20. Minerals Policy Guidance for Europe—policy and innovation for raw materials and minerals in Europe—challenges, characteristics and good practices, Nov 2018. https://www.min-guide.eu/sites/default/files/project_result/d1.3_final_web.pdf. Accessed 14 Jan 2019
  21. Salmi O (2007) Eco-efficiency and industrial symbiosis a counterfactual analysis of a mining community. J Clean Prod 15:1696–1705CrossRefGoogle Scholar
  22. Szczygielski T (2017) Zero-Waste Coal Power (ZWCP) as element of the practical implementation of the circular economy in Poland. http://cima.ibs.pw.edu.pl/wp-content/uploads/zerowastecoalenergy.pdf. Accessed 14 Jan 2019
  23. Twardowska I, Stefaniak S, Szczepańska J (2004), Solid waste: assessment, monitoring and remediation in waste management series. https://www.sciencedirect.com/topics/earth-and-planetary-sciences/mining-waste. Accessed 14 Jan 2019
  24. Uberman R (2017) Kopaliny towarzyszące w złożach węgla brunatnego. Tom II. Prawno-ekonomiczne oraz górnicze aspekty zagospodarowania kopalin towarzyszących. IGSMiE PAN, KrakówGoogle Scholar
  25. Woźniak J, Pactwa K (2018) Overview of Polish mining wastes with circular economy model and its comparison with other wastes. Sustainability 10:3994CrossRefGoogle Scholar

Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  • Joanna Kulczycka
    • 1
  • Ryszard Uberman
    • 2
  • Ewa Dziobek
    • 2
    Email author
  1. 1.AGH University of Science and TechnologyCracowPoland
  2. 2.The Mineral and Energy Economy Research Institute of the Polish Academy of SciencesCracowPoland

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