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In recent years, the importance of production in cyberphysical systems - CPS characteristic of the new industry concept, which is Industry 4.0 -I 4.0, is gaining importance. Industry 4.0 enforces modification of traditional perception of production. The basis for changes in Industry 4.0 has become Internet of Things - IoT, which gives the opportunity to connect and communicate with each other such areas as mobile solutions, cloud computing, sensors, analytics and cyber security. By new technology, areas that previously operated in enterprises as separate systems can be combined and create new opportunities for industrial production (modernization of production methods and reduce employment). Industry 4.0 brings with it a number of new challenges for producers in the field of environmental protection, and related to the inclusion of cybernetic technology in physical production processes as well as distribution. Production starts and ends on the customer. Industry 4.0 is a collective term for technologies and concepts of value chain organization. The United Nations Organization for Industrial Development indicates the following environmental aspects in the perspective of the development of Industry 4.0, such as: climate change and limited access to resources, primarily to clean energy. It is assumed that changes in the production and functioning of economies will result in a decrease in the emission of harmful compounds into the atmosphere and increase the flexibility of activities for environmental protection. The purpose of this work is to present general directions of changes in the field of environmental protection in Industry 4.0. Authors present the following areas of change: energy management and material management. These areas are opportunities for environmental. In the category of threats, the growing costs of environmental protection and household expenses are pointed out. The work is based on a literature study and statistical data. Statistical data are used: integrated technologies, expenditure and costs of environmental protection, recycling of secondary raw materials and energy consumption for the EU and Poland.
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Tom
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184--194
Opis fizyczny
Bibliogr. 45 poz., rys.
Twórcy
autor
- Silesian University of Technology, ul. Akademicka 2A 44-100 Gliwice, Poland
autor
- Silesian University of Technology, ul. Akademicka 2A 44-100 Gliwice, Poland
autor
- VSB-TUO, Technical University of Ostrava, Czech Republic
autor
- VSB-TUO, Technical University of Ostrava, Czech Republic
Bibliografia
- 1.Accelerating Clean Energy through Industry 4.0. [online], UNIDO, 2017, p. 8. Available at: https://www.unido.org/sites/default/files/2017-08/REPORT_Accelerating_clean_energy_through_Industry_4.0.Final_0.pdf [Accessed:Aug.2017].
- 2. Agenda 21. Proceedings of United Nations Conference on Environment &Development. Brazil, Rio De Janerio, UN, 1992.
- 3. Almado Lobo, F. (2015). The Industry 4.0 revolution and the future of Manufacturing Execution Systems (MES). Journal of Innovation Management, (3-4).
- 4. Analizy statystyczne. Ochrona środowiska/Environmental protection (in Polish). (2018).[online] GUS Warszawa, pp. 156-160. Available at: ochrona_srodowiska_2018.pdf
- 5.Bassi, L. (2017). Industry 4.0: Hope, hype or revolution? In 2017 IEEE 3rd International Forum on Research and Technologies for Society and Industry (RTSI) Italy, pp. 1-6.
- 6. Bonilla , S., Silva Helton R. O., Marcia Terra da Silva, Gonçalves, R, F. and Sacomano J. B. (2018). Industry 4.0 and Sustainability Implications: A Scenario-Based Analysis of the Impacts and Challenges. Sustainability, 10, 3740, pp. 1-24. MDPI. Available at: www.mdpi.com/journal/sustainabili
- 7. Burke, R., Mussomeli, A., Laaper, S., Hartigan, M. and Sniderman, B. (2017). The smart factory: Responsive, adaptive, connected manufacturing. Deloitte Insights, August,31, pp. 1-19.
- 8. Bujak, A. (2017). Rewolucja przemysłowa – 4.0 i jej wpływ na logistykę XXI wieku. Autobusy, 6, pp. 1338-1344.
- 9. Efektywność wykorzystania energii w latach 2006-2016/Efficiency of energy using (in Polish). [online] Statistics Poland. Warsaw. Available at: https://stat.gov.pl/obszary -tematyczne/srodowisko-energia/energia/efektywnosc-wykorzystaniaenergii-w-latach-2006-2016,9,1.html. [Accessed 15 June 2018].
- 10. Dlaczego strat-upy są tak ważne dla energetyki w świetle Industry 4.0. Polski Przemysł.[online] July 2017. Available at:https://polskiprzemysl.com.pl/wpcontent/uploads/inno-energy-PP_39.pdf
- 11. Ford, S., Despeisse, M. (2016). Additive manufacturing and sustainability: An exploratory study of the advantages and challenges. Journal Clean. Production, 137, pp. 1573-1587.
- 12. Fonseca, L. M. (2018). Industry 4.0 and the digital society: Concepts, dimensions and envisioned benefits. In Proceedings of the International Conference on Business Excellence, 12, pp. 386-397.
- 13. Gajdzik, B. (2012). Comprehensive classification of environmental aspects in metallurgical enterprise. Metalurgija, 51 (4), pp. 541-544.
- 14. Gajdzik, B. (2009). Environmental aspects, strategies and waste logistic system based on the example of metallurgical company. Metalurgija, 48 (1), pp. 63-67.
- 15. Gajdzik, B. (2019). Struktura łańcucha dostaw w logistyce 4.0 w przemyśle stalowym. Gospodarka Materiałowa i Logistyka, 71(4). DOI 10.33226/1231-2037.2019.4.2.
- 16. George, D.A., Lin, B.C. and Chen, Y. (2015). A circular economy model of economic growth. Environmental Modelling & Software, 73, pp. 60-63.
- 17. Georgakopoulos, D., Jayaraman, P.P., Fazia, M., Villari, M., and Ranjan, R. (2016).Internet of Things and edge cloud computing roadmap for manufacturing. IEEE Cloud Computing, 3(4), pp. 66-73.
- 18. Ghisellini, P., Cialani, C., Ulgiati, S. (2016). A review on circular economy: the expected transition to a balanced interplay of environmental and economic systems. Journalof Cleaner Production,114, pp. 11-32.
- 19. Hermann, M., Pentek, T. (2015). Design Principles for Industrie 4.0 Scenarios: A Literature Review. Technische Universität Dortmund Fakultät Maschinenbau, Working Paper, No. 01.
- 20. Hermann, M., Pentek, T., and Otto, B. (2016). Design principles for Industrie 4.0 scenarios. In: System Sciences (HICSS), 49th Hawaii International Conference, pp.3928-3937.
- 21. Industry 4.0 w energetyce. [online] Available at: https://polskiprzemysl.com.pl/wpcontent/uploads/inno-energy-PP_39.pdf
- 22. Janikowski, R. (2016). W kierunku ochrony środowiska 4.0. Prace Naukowe Uniwersytetu Ekonomicznego we Wrocławiu, nr 453. Ekonomia środowiska i polityka ekologiczna, pp. 38-50.
- 23. Lee, E. A. (2008). Cyber physical systems: Design challenges, in Object Oriented Real-Time Distributed Computing (ISORC). 11th IEEE International Symposium on.IEEE, 2008, pp. 363-369.
- 24. Lieder, M., Rashid, A. (2016). Towards circular economy implementation: a comprehensive review in context of manufacturing industry. Journal of Cleaner Production, 115, pp. 36-51.
- 25. Lu, Y. (2017). Industry 4.0: A survey on technologies, applications and open research issues. Journal of Industrial Information Integration, 6, pp. 1-10.
- 26. Ochrona środowiska - jedno z największych wyzwań Przemysłu 4.0. P.M.K. [online] 2 May 2018. Elektrotechnik Automatyk. Info Branżowe. Elmodis. Availabe at: https://www.elektrotechnikautomatyk.pl/info-branzowe/Ochrona-srodowiskajedno-z-najwiekszych-wyzwan-Przemyslu-4-0,384,1
- 27. Olszewki, M. (2016). Mechatronizacja produktu i produkcji - przemysł 4.0. Pomiary ,Automatyka, Robotyka, 3, pp. 13-28.
- 28. Paca, D. (2018). Jak wprowadzić circular economy w firmie? Sustainability Insights, 1.Available at: https://www2.deloitte.com/pl/pl/pages/zarzadzania-procesami-istrategiczne/articles/sustainability-insights/jak-wprowadzic-circular-economy-wfirmie.html
- 29. Platforma Celów Zrównoważonego Rozwoju [online] (in Polish). Available at: http://www.un.org.pl/
- 30. Qin, J., Liu, Y., and Grosvenor, R. (2016). A categorical framework of manufacturing for industry 4.0 and beyond. Procedia Cirp, 52, pp. 173-178.
- 31. Rocznik statystyczny przemysłu 2017. Statistics Poland. Warsaw. On the based on:Chemical Review. [online] 26 April 2018. Ochrona środowiska - jedno z największych wyzwań Przemysłu 4.0. Available at: https://chemical.pl/wiadomosci/sp/12856-ochrona-srodowiska-jedno-z-najwiekszych-wyzwan-przemyslu-4-0
- 32. Schwab, K. (2016). The Fourth Industrial Revolution. World Economic Forum. Deloitte.
- 33. Shi, J., Wan, J., Yan, H., and Suo, H. (2011). A survey of cyberphysical systems, in Wireless Communications and Signal Processing (WCSP). International Conference on. IEEE, 2011, pp. 1-6.
- 34. Schneider Electric [online] 18 May 2017. Available at: https://nowaenergia.com.pl/2017/05/18/czy-wykorzystamy-potencjal-przemyslu-4-0/
- 35. Sony, M. (2018). Industry 4.0 and lean management: a proposed integration model and research propositions. Production & Manufacturing Research. An Open Access Journal, (6). Taylor & Francis online. Availabe at: https://www.tandfonline.com/doi/full/10.1080/21693277.2018.1540949
- 36. Stock, T., Seliger, G. (2016). Opportunities of sustainable manufacturing in Industry 4.0.Procedia Cirp, 40, pp. 536-541.
- 37. The Role of ICT in Driving a Sustainable Future, Global e-Sustainability Initiative, The Boston Consulting Group (BCG), Inc, GeSi Smarter2020. [online] December 2012.Available at: http://gesi.org/SMARTer2020
- 38. Transforming Our World: The 2030 Agenda for Global Action. [online] In Polish. Available at: https://www.mos.gov.pl/fileadmin/user_upload/mos/srodowisko/miedzynarodowe_aspekty_zrownowazonego_rozwoju/ Polska_wersja_jezykowa_dokumentu_Przeksztalcamy_nasz_swiat._Agenda_na_rzecz_zrownowazonego_rozwoju_2030.pdf [Accessed: July 2019].
- 39. Wang, D. Wu, H.(2014). Application of BP neural network to power predioction of wind power generation unit in microgrid. Engineering Technology and Applications. London.
- 40. Wieszała, R., Gajdzik, B. (2010). The effectiveness of environmental management in a metallurgical company’s sustainable development. Metalurgija, 49 (4), pp. 353-355
- 41. Xu, L. D., Xu, E. L. and Li, L. (2018). Industry 4.0: State of the art and future trends. International Journal of Production Research, 56(8), pp. 2941-2962
- 42. Yen, C.-T., Liu, Y.-C., Lin, -C.-C., Kao, -C.-C., Wang, W.-B., & Hsu, Y. R. (2014). Advanced manufacturing solution to Industry 4.0 trend through sensing network and Cloud Computing technologies. In: Automation Science and Engineering (CASE), IEEE International Conference, pp. 1150-1152.
- 43. Vranken, H. (2017). Sustainability of bitcoin and blockchains. Current Opinion in Environmental Sustainability, 28, 1-9.
- 44. Zatrudnienie i wynagrodzenie w gospodarce narodowej w 2018 roku (Employmenttable 5). Statistics Poland, Warsaw. Availabe at: https://stat.gov.pl/obszarytematyczne/rynek-pracy/pracujacy-zatrudnieni-wynagrodzenia-koszty-pracy/zatrudnienie-i-wynagrodzenia-w-gospodarce-narodowej-w-2018-roku,1,33.html
- 45. Zanero, S. (2017). Cyber-physical systems. Computer, 50(4), pp. 14-16.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b21cd3d0-947e-4496-b092-16ba739e07f7