Investigation of guide baffles for wind turbine installations in an urban region

Szerzők

  • Csaba Hetyei Óbuda University - Doctoral School on Safety and Security Sciences
  • Ferenc Szlivka Óbudai Egyetem, Bánki Donát Gépész és Biztonságtechnikai Mérnöki Kar http://orcid.org/0000-0002-3298-4142

Kulcsszavak:

Wind energy, wind turbine, simulation, cfd, BAWT

Absztrakt

Due the nowadays increasing energy demands, the renewable energy sources and their utilization are more and more emphasized. In this article, we review the wind energy utilization, especially for the smile size wind turbines for BAWT (Building Augmented Wind Turbine). After this review we will present a flow simulation around a 10 floor building’s roof. Next this analysis, we will increase the fluid velocity with guide baffle and we will choose an optimal configuration for wind turbine installation.

Hivatkozások

Frankfurt School – UNEP Collaborating Centre for Climate & Sustainable Energy Finance (2018). Global trends in renewable energy investment 2018, https://europa.eu/capacity4dev/file/71900/download?token=57xpTJ4W p. 15. (2018.09.30.)
Y. Ozmen, E. Baydar, J.P.A.J. van Beeck (2016). Wind flow over the low-rise building models with gabled roofs having different pitch angles, Building and Environment, 95, p.63-74, DOI: http://dx.doi.org/10.1016/j.buildenv.2015.09.014
Islam Abohela, Neveen Hamza, Steven Dudek (2013). Effect of roof shape, wind direction, building height and urban configuration on the energy yield and positioning of roof mounted wind turbines, Renewable Energy, 50, p. 1106-1118, DOI: http://dx.doi.org/10.1016/j.renene.2012.08.068
L. Ledo, P.B. Kosasih, P. Cooper (2011). Roof mounting site analysis for micro-wind turbines, Renewable Energy, 36, p.1379-1391, DOI: http://dx.doi.org/10.1016/j.renene.2010.10.030
Wind energy, https://en.wikipedia.org/wiki/Wind_power (2018.09.30.)
European Wind Energy Association (2014). Wind energy scenarios for 2020, p.4. http://www.ewea.org/fileadmin/files/library/publications/scenarios/EWEA-Wind-energy-scenarios-2020.pdf (2018.09.29.)
WindEurope (2017) Wind energy in Europe: Scenarios for 2030 p.17-18. https://windeurope.org/wp-content/uploads/files/about-wind/reports/Wind-energy-in-Europe-Scenarios-for-2030.pdf (2018.09.29.)
U.S. Department of Energy (2008). 20% Wind Energy by 2030, p.2. https://www.nrel.gov/docs/fy08osti/41869.pdf (2018.09.29.)
International Energy Agency (2011) Technology Roadmap - China Wind Energy Development Roadmap 2050 p. 23-25 https://www.iea.org/publications/freepublications/publication/china_wind.pdf (2018.09.29.)
World Wind Energy Association (2017). 2017 Small Wind World Report https://www.wwindea.org/wp-content/uploads/filebase/small_wind_/SWWR2017-SUMMARY.pdf (2018.09.29.)
Canadian Wind Energy Association (2006). Small Wind Siting And Zoning - Study Development Of Sitting Guidelines And A Model Zoning By-Law For Small Wind Turbines (Under 300 kW) p. 3. http://www.toolkit.bc.ca/sites/default/files/Small_Wind_Siting_Bylaw%20and%20Guidelines.pdf (2018.09.30.)
Szélturbina méretek és a hozzájuk tartozó jellemző magasság https://electrical-engineering-portal.com/wp-content/uploads/wind-turbine-sizes.gif (2018.10.07.)
Wind turbine https://en.wikipedia.org/wiki/Wind_turbine (2018.12.27.)
Savonius wind turbine https://en.wikipedia.org/wiki/Savonius_wind_turbine (2018.10.03.)
Georges Jean Marie Darrieus https://en.wikipedia.org/wiki/Georges_Jean_Marie_Darrieus (2018.10.03.)
Savonius turbine elvi vázlata http://www.savonius.net/uploads/7/2/7/6/7276038/2989902.gif (2018.10.01.)
Szlivka Ferenc, Molnár Ildikó (2012). Víz- és szélenergia hasznosítás, Edutus Főiskola Kiadó, http://www.tankonyvtar.hu/hu/tartalom/tamop412A/2010-0017_10_viz_es_szelenergia/ch03s06.html (2017.04.07.)
Casini, M (2016). Small Vertical Axis Wind Turbines for Energy Efficiency of Buildings. Journal of Clean Energy Technologies, 4(1), p.56-65.
Nelson C. Batista, Rui Melicio, Victor M.F. Mendes (2018). Darrieus vertical axis wind turbines: methodology to study the self-start capabilities considering symmetric and asymmetric airfoils. Research on Engineering Structures and Materials, 4(3), 189-217. DOI: http://dx.doi.org/10.17515/resm2017.39ds0108
Szélturbinával kiegészített épület https://inhabitat.com/files/swift_commercial.jpg (2018.10.07.)
Bahreini Világkereskedelmi Központ http://lh3.googleusercontent.com/-KK_pVixjmX4/VlaSjOBN_9I/AAAAAAABI-E/JmGCwdnQGrs/bahrain-world-trade-center-9%25255B6%25255D.jpg (2018.10.07.)
Pearl River torony http://smithgill.com/media/images/project_images/534/pearl_5.jpg (2010.10.07.)
Szélturbina a Pearl River toronyban https://www.som.com/FILE/17902/pearlriver_sustainable_700x800_som_07.jpg (2018.10.07.)
Hetyei Cs., Dr. Szlvika F. (2018). Lapátszög-szabályzás hatása a nyomatékra. Bánki Közlemények, 1(1) p. 83-88.
Tóth Gábor (2005). Energia célú szélmérés, p. 91. http://phd.szie.hu/JaDoX_Portlets/documents/document_3450_section_4085.pdf (2018.10.18.)

##submission.downloads##

Megjelent

2019-06-12

Folyóirat szám

Évf. 2 szám 2 (2019): Bánki Közlemények Autumn/Winter (2019)

Rovat

Renewable Energies (Megújuló Energiák)

License

Bánki Közlemények is loyal to open access for academic work. All the original articles and review papers published in this journal are free to access immediately from the date of publication. We don’t charge any fees for any reader to download articles and reviews for their own scholarly use.

The Bánki Közlemények also operates under the Creative Commons Licence CC-BY-NC-ND. This allows for the reproduction of articles, free of charge, for non-commercial use only and with the appropriate citation information. All authors publishing with the Bánki Közlemények accept these as the terms of publication.