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This paper describes identification and components of destructiveness of energy, economic and ecologic profits and outlays during life cycle of offshore wind electric power plants as well as the most useful models for their design, assembly and use. There are characterized technical conditions ( concepts, structures, processes) indispensable for increasing profits and/or decreasing energy, economic and ecological outlays on their operation as well as development prospects for global, European and domestic markets of offshore wind electric power industry. A preliminary analysis was performed for an impact of operators, processed objects, living and artificial environmental objects of a 2MW wind electric power plant on possible increase of profits and decrease of outlays as a result of compensation of destructiveness of the system, environment and man.
Czasopismo
Rocznik
Tom
Strony
132--139
Opis fizyczny
Bibliogr. 29 poz., rys., tab.
Twórcy
autor
- University of Technology and Science in Bydgoszcz Mechanical Engineering Faculty al. Prof. S. Kaliskiego 7 85-796 Bydgoszcz Poland
autor
- University of Technology and Science in Bydgoszcz Mechanical Engineering Faculty al. Prof. S. Kaliskiego 7 85-796 Bydgoszcz Poland
autor
- University of Technology and Science in Bydgoszcz Mechanical Engineering Faculty al. Prof. S. Kaliskiego 7 85-796 Bydgoszcz Poland
autor
- University of Technology and Science in Bydgoszcz Mechanical Engineering Faculty al. Prof. S. Kaliskiego 7 85-796 Bydgoszcz Poland
autor
- University of Technology and Science in Bydgoszcz Mechanical Engineering Faculty al. Prof. S. Kaliskiego 7 85-796 Bydgoszcz Poland
autor
- University of Technology and Science in Bydgoszcz Mechanical Engineering Faculty al. Prof. S. Kaliskiego 7 85-796 Bydgoszcz Poland
autor
- Lviv National Agrarian University, Ukraine
Bibliografia
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- 2. Breton, S. P. i Moe, G.: Status, plans and technologies for offshore wind turbines. Renewable Energy. 34 (3), (2009). pp. 646-654
- 3. Chakrabarti, S.: Handbook of offshore engineering, Elsevier, Amsterdam 2005.
- 4. Crawford, R. H.: Life cycle energy and greenhouse emissions analysis of wind turbines and the effect of size on energy yield. Renewable and Sustainable Energy Reviews. 13 (9), (2009), pp. 2653-2660
- 5. Flizikowski J., Kruszelnicka W., Michałowski M., Szala G., Tomporowski A. : Bulkhead door - critical evacuation states. Polish Maritime Research, 24 (1), (2017), pp. 66-71.
- 6. Flizikowski J., Topoliński T., Opielak M., Tomporowski A., Mroziński A. : Research and analysis of operating characteristics of energetic biomass micronizer, Eksploat. i Niezaw. ( Mainten. Reliab.)17 (1), (2015), pp. 19–26
- 7. Flizikowski, J., Piasecka, I., Kruszelnicka, W., Tomporowski, A., Mroziński, A. : Destruction assessment of wind power plastics blade. Polimery, 63(5), (2018), pp. 55-60.
- 8. Flizikowski, J., Sadkiewicz, J., Tomporowski, A. : Functional characteristics of a six-roller mill for grainy or particle materials used in chemical and food industries. Przemysl Chemiczny, 94(1), (2015), pp. 69-75.
- 9. Garrett P., & Rendc, K.: Life cycle assessment of wind power: comprehensive results from a state-of-the-art approach. The International Journal of Life Cycle Assessment, 18(1), (2013), pp. 37-48.
- 10. Gill, A.B. : Offshore renewable energy: ecological implications of generating electricity in the coastal zone, Journal of Applied Ecology, 4, (2005), pp. 605-615.
- 11. Haapala, K. R., Prempreeda, P. Comparative life cycle assessment of 2.0 MW wind turbines. Int. J. Sustainable Manufacturing, 3 (2), (2014). pp.170-185
- 12. Kasner, R.: Assessment of benefits and investments for wind farm life cycle, Dissertation. Poznan: Poznan University of Technology (2016)
- 13. Kłos, Z., Lewicki, R., Koper, K. : Application of environmental characteristics of materials in sustainable development. In: I. Horvath, F. Mandorli, Z. Rusak (Ed.), Tools and methods of competitive engineering, Vol. 1-2 (pp. 1319-1320). Delft University of Technology, Delft 2010.
- 14. Kong, C., Bang, J., Sugiyama, Y. : Structural investigation of composite wind turbine blade considering various load cases and fatigue life. Energy. 30 (11), (2005), pp. 2101-2114
- 15. Kowalik, K., Sykut, B., Marczak, H., Opielak, M. : A method of evaluating energy consumption of the cutting process based on the example of hard cheese. Eksploatacja i Niezawodnosc (Maintenance and Reliability), 15(3), (2013), pp. 241-245.
- 16. Marczuk, A., Caban, J., Savinykh, P., Turubanov, N., Zyryanov, D. : Maintenance research of a horizontal ribbon mixer. Eksploatacja i Niezawodnosc (Maintenance and Reliability), 19(1), (2017), pp. 121-125.
- 17. Mattar, C., Guzmán-Ibarra, M. C. : A techno-economic assessment of offshore wind energy in Chile. Energy, 133, (2017), pp.191-205.
- 18. Mearns, K., Whitaker, S.M., Flin, R. : Safety climate, safety management practice and safety performance in offshore environments, Safety Science, 8, (2003), pp. 641-680.
- 19. Mroziński, A., Piasecka, I. : Selected aspects of building, operation and environmental impact of offshore wind power electric plants. Polish Maritime Research, 22(2), (2015), pp. 86-92.
- 20. Nguyen, Tuyet, T. A., Chou, S. : Maintenance strategy selection for improving cost-effectiveness of offshore wind systems. Energy Conversion and Management, 157, (2018), pp. 86-95.
- 21. Otremba Z., Andrulewicz E. : Physical fields during construction and operation of wind farms by example of Polish maritime areas, Polish Maritime Research, 21(4), (2014), pp.113-122.
- 22. Piecuch, T., Kowalczyk, A., Dąbrowski, T., Dąbrowski, J., Andriyevska, L. : Reduction of Odorous Noxiousness of Sewage Treatment Plant in Tychowo. Rocznik Ochrona Srodowiska, 17, (2015), pp. 646-663.
- 23. Rudnicki J. : Application issues of the semi-Markov reliability model, Polish Maritime Research, 22 (1), (2015), pp. 55-64.
- 24. Szyszlak-Barglowicz, J., Zajac, G., Slowik, T.: Hydrocarbon emissions during biomass combustion. Polish Journal of Environmental Studies, 24(3), (2015), pp.1349–1354.
- 25. Thomson, R. C., Harrison, G. P. Life Cycle Costs and Carbon Emissions of Offshore Wind Power. ClimateXChange, Edinburgh 2015
- 26. Tomporowski, A., Flizikowski, J, Kasner, R., Kruszelnicka, W. : Environmental control of wind power plant technology ( in Polish). Rocznik Ochrona Środowiska, 19, (2017), pp. 694-714.
- 27. Tomporowski, A., Flizikowski, J, Opielak, M., Kasner, R., Kruszelnicka, W. : Assessment of energy use and elimination of CO2 emissions in the life cycle of an offshore wind power plant farm. Polish Maritime Research, 24(4), (2017), pp. 93-101.
- 28. Yang, J.,Chang, Y.,Zhang, L.,Hao, Y., Yan, Q.,Wang, C. : The life-cycle energy and environmental emissions of a typical offshore wind farm in China. Journal of Cleaner Production. 80, (2018), pp. 316-324.
- 29. Zajac, G., Wegrzyn, A. : Analysis of work parameters changes of diesel engine powered with diesel fuel and FAEE blends. Eksploatacja i Niezawodnosc (Maintenance and Reliability), 2, (2008), pp. 17–24.
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e72179c8-ebab-4746-851d-08d82e54bd38