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Global Assessment of Industrial Expansion for Minimizing Environmental Impacts Utilizing the Principles of Mining and Logistics

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This article addresses research into the effective expansion of industrial activity, taking into account environmental needs. The aim is to analyse and assess the possibilities for further development of industrial activity in a particular region of Slovakia. The objective of the geological task is to verify 5 million m3 of building stone of category Z-2. In terms of environmental requirements important factors include safety, stability, habitat, logistics and the emissions factor. In terms of further utilization, the emissions factor is particularly important. The emissions factor for drilling, loading, unloading and for aggregate moisture of 0-0.5% is 9.4 g of PM per tonne of aggregate, which for extraction of 300 000 tons per year gives an output of 2 820 kg/year and 1.41 kg/h. The emission factor for primary and secondary aggregate processing with aggregate moisture of 2-3% with application of water spray is 14.6 g of PM per ton of aggregate, giving emissions of 657 kg of PM per year and 0.3285 kg of PM per hour. For the tertiary aggregate processing, at aggregate moisture of 2-3%, the emission factor is 230.2 g of PM per tonne of aggregate, giving emissions of 690.6 kg of PM per year and 0.3453 kg of PM per hour. The total annual emissions are 4 167.6 kg of PM, i.e. 2.0838 kg/h. In order to secure the ecological stability of the land area, it is necessary to respect and protect the elements of the national network of protected areas. The solution for the Hradová quarry is located outside of protected areas. For this reason, no impact on large-scale or small-scale protected areas or protective zones is expected.
Rocznik
Strony
14--28
Opis fizyczny
Bibliogr. 30 poz., tab., rys.
Twórcy
  • Technical University of Kosice, Slovakia
  • Technical University of Kosice, Slovakia
  • EUROVIA – Kameňolomy, s.r.o. Košice, Slovakia
Bibliografia
  • 1. Amirshenava, S., Osanloo, M. (2019). A hybrid semi-quantitative approach for impact assessment of mining activities on sustainable development indexes. Journal of Cleaner Production, 218(May), 823-834.
  • 2. Aung, T.S., Shengji, L., Condon, S. (2019). Evaluation of the environmental impact assessment (EIA) of Chinese EIA in Myanmar: Myitsone Dam, the Lappadaung Copper Mine and the Sino-Myanmar oil and gas pipelines. Impact Assessment and Project Appraisal, 37(1), 71-85.
  • 3. Bergstrom, R.D. (2017). The curious case of Cuyuna: Re–Envisioning former extractive sites to stimulate local communities. Extractive Industries and Society, 4(4), 860-868.
  • 4. Betancur-Corredor, B., Loaiza-Usuga, J.C., Denich, M., Borgemeister, C. (2018). Gold mining as a potential driver of development in Colombia: Challenges and opportunities, Journal of cleaner production, 199(October), 538-553.
  • 5. Dias, A.M.D.S., Fonseca, A., Paglia, A.P. (2019). Technical quality of fauna monitoring programs in the environmental impact assessments of large mining projects in southeastern Brazil. Science of the Total Environment, 650 Part 1(February), 216-223.
  • 6. Dilský, M. (2012). Sanácia svahu na ceste III/547002. Technická správa 2012. (Original in Slovak)
  • 7. EUROVIA – Kameňolomy, s.r.o. Košice (2010). Záverečná správa geologickej úlohy, Košice – Hradová, vyhľadávací geologický prieskum, stavebný kameň, Košice. (Original in Slovak)
  • 8. EUROVIA – Kameňolomy, s.r.o. Košice (2017). LOM KOŠICE IV - HRADOVÁ – ROZŠÍRENIE ŤAŽBY, Správa o hodnotení navrhovanej činnosti podľa zákona č. 24/2006 Z. z. o posudzovaní vplyvov na životné prostredie a o zmene a doplnení niektorých zákonov, Banská Bystrica. (Original in Slovak)
  • 9. Gallo, P., Tausova, M., Gonos, J. (2016). Leadership style model based on managerial grid. Actual Problems of Economics, 178(4), 246-252.
  • 10. Gawałkiewicz, R. (2018). Threats to water bodies resulting from human activity: A case study of Płaszów Pond in Cracow. Przeglad Geologiczny, 66(1), 38-47.
  • 11. Grzesik, K., Kossakowska, K., Bieda, B., Kozakiewicz, R. (2019). Screening Life Cycle Assessment of beneficiation processes for Rare Earth Elements recovery from secondary sources. IOP Conference Series: Earth and Environmental Science, 214(1), 1-11.
  • 12. Haverland, J., Besta, P. (2018). Determination of importance of ore raw materials evaluation criteria. Acta logistica, 5(2), 39-43.
  • 13. Kozioł, W., Machniak, Ł., Borcz, A., Baic, I. (2016). Mining of aggregates in Poland - Opportunities and threats. Inzynieria Mineralna, 17(2), 175-182.
  • 14. Loučanová, E., Olšiaková, M. (2019). Distribution flow identification in cooperation and support for ecological innovation introduction in Slovak enterprises. Acta logistica, 6(1), 5-8.
  • 15. Malindzak, D., Zimon, D., Bednarova, L., Pitonak, M. (2017). Homogeneous production processes and approaches to their management. Acta Montanistica Slovaca, 22(2), 153-160.
  • 16. Menéndez, J., Loredo, J., Galdo, M., Fernández-Oro, J.M. (2019). Energy storage in underground coal mines in NW Spain: Assessment of an underground lower water reservoir and preliminary energy balance. Renewable Energy, 134(C), 1381-1391.
  • 17. Mitchell, R.E., Leach, B. (2019). Knowledge coproduction in environmental impact assessment: Lessons from the mining industry in Panama. Environmental Policy and Governance, 29(2), 87-96.
  • 18. Nkyekyer, E.W., Dannenberg, A.L. (2019). Use and effectiveness of health impact assessment in the energy and natural resources sector in the United States, 2007-2016. Impact Assessment and Project Appraisal, 37(1), 17-32.
  • 19. Ocampo-Melgar, A., Sagaris, L., Gironás, J. (2019). Experiences of voluntary early participation in Environmental Impact Assessments in Chilean mining. Environmental Impact Assessment Review, 74(January), 43-53.
  • 20. Parviainen, A., Loukola-Ruskeeniemi, K. (2019). Environmental impact of mineralized black shales. Earth-Science Reviews, 192(May), 65-90.
  • 21. Pell, R., Tijsseling, L., Palmer, L.W., Glass, H.J., Yan, X., Wall, F., Zeng, X., Li, J. (2019). Environmental optimisation of mine scheduling through life cycle assessment integration. Resources, Conservation and Recycling, 142(March), 267-276.
  • 22. Pell, R., Wall, F., Yan, X., Li, J., Zeng, X. (2019). Temporally explicit life cycle assessment as an environmental performance decision making tool in rare earth project development. Minerals Engineering, 135(May), 64-73.
  • 23. Pohrebennyk, V., Dzhumelia, E. (2020). Environmental Assessment of the Impact of Tars on the Territory of the Rozdil State Mining and Chemical Enterprise "Sirka" (Ukraine). In: Królczyk G., Wzorek M., Król A., Kochan O., Su J., Kacprzyk J. (eds) Sustainable Production: Novel Trends in Energy, Environment and Material Systems. Studies in Systems, Decision and Control, vol 198. Springer, Cham.
  • 24. Qian, D., Yan, Ch., Xiu, L., Feng, K. (2018). The impact of mining changes on surrounding lands and ecosystem service value in the Southern Slope of Qilian Mountains. Ecological Complexity, 36(December), 138-148.
  • 25. Sajinkumar, K.S., Sankar, G., Rani, V.R., Sundarajan, P. (2014). Effect of quarrying on the slope stability in Banasuramala: an offshoot valley of Western Ghats, Kerala, India, Environmental Earth Sciences, 72(7), 2333-2344.
  • 26. Sarupria, M., Manjare, S.D., Girap, M. (2019). Environmental impact assessment studies for mining area in Goa, India, using the new approach. Environmental Monitoring and Assessment, 191(18), 1-17.
  • 27. Straka, M., Cehlar, M., Khouri, S., Trebuna, P., Rosova, A., Malindzakova, M. (2016). Asbestos exposure and minimization of risks at its disposal by applying the principles of logistics. Przemysl Chemiczny, 95(5), 963-970.
  • 28. Trebuna, P., Kliment, M., Edl, M., Petrik, M. (2014). Creation of simulation model of expansion of production in manufacturing companies. Procedia Engineering, Modelling of Mechanical and Mechatronic Systems, 96, 477-482.
  • 29. Trubetskoy, K., Rylnikova, M., Esina, E. (2017). Ensuring the Environmental and Industrial Safety in Solid Mineral Deposit Surface Mining. E3S Web of Conferences, Volume 21, Article number 02008, 2017.
  • 30. Vilamova, S., Besta, P., Kozel, R., Janovska, K., Piecha, M., Levit, A., Straka, M., Sanda, M. (2016). Quality quantification model of basic raw materials. Metalurgija, 55(3), 375-378.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2a5d5295-f1ac-4618-894e-c1da999a575f
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