• V. G. Novikov Institute of Engineering Thermophysics of the National Academy of Sciences of Ukraine
Keywords: wind flow, the boundary layer of the atmosphere, CFD-model, turbulence model, threedimensional field


Presented the results of numerical modeling of transport processes in the interaction of wind flow in the surface layer of the atmosphere with the buildings and structures located within the compact urban development. In the target area calculated three-dimensional velocity field of wind power density of the wind flow and turbulence characteristics in order to determine the most appropriate places of location of wind power installations for power supply pilot house passive type.



Giorgio Crasto. Numerical Simulations of the Atmospheric Boundary Layer. http:// presentations/thesis/0702 Giorgio Crasto.pdf.

Roger Garcia Barcely Mesh sensitivity analysis on wind farms using CFD wind flow models and cfd wake models MONTREAL, AUGUST 28, 2012.

Stangroom Paul. CFD modeling of wind flow over terrain. Thesis submitted to the University of Nottingham for degree of Doctor of Philosophy, January 2004, 298 p. http://etheses.

Fallo Daniele. Wind energy resource evaluation in a site of central Italy by CFD simulations Universita Degli Studi di Cagliari Facolta di Ingegneria Corso di Laurea specialistica in
Ingegneria Meccanica Anno Accademico 20062007/ 129 p.

Franke Jorg, Hellsten Antti, Schlunzen Heinke, Carissimo Bertrand. Best practice guideline for the CFD simulation of flows in the urban environment cost action 732 quality assurance and improvement of microscale meteorological models May 2007

Mertens Sander. Wind Energy in the Built Environment. Published by: Multi-Science 5 Wates Way, Brentwood Essex, CM15 9TB, United Kingdom. 170 p.

Renewables Global Futures Report (Paris: REN21). REN21. 2013.

Islam Abohela, Neveen Hamza, Steven Dudek Urban Wind Turbines Integration in the Built Form and Environment. FORUM Ejournal 10 (June 2011): 23 39 © 2011 by Newcastle University.

Naglaa Ali Megahed Welcoming the wind: the potential for urban wind turbines to reshape the built environment. 2nd International Conference on Energy Systems and Technologies 18 21 Feb. 2013, Cairo, Egypt.

Urban wind turbines-Guidelines for small wind turbines in the built environment. www.

Basok B.I. Chislennoe modelirovanie vetrovih potokov v zone gorodskoi zastroiki / B.I. Basok, B.V Davidenko V.G. Novikov // Vidnovlyuvalna energetika. -2014. №2 -37. P. 46 59.

Cabezon D., Sanz J., Beeck J.Van. Sesitivity analysis on turbulence model for the ABL in complex terrain. 2007 /allfiles2/134_Ewec2007 fullpaper.pdf

Illyustrirovannii Spravochnik po Vozobnovlyaemoi Energetike ENERGIYA VETRA. http:// 3-5. pdf.

Cabezon D., Iniesta A., Ferrer E., Marti I. Comparing linear and non linear wind flow models php? page=searchresult&auteur = Cabezon.

Wieringa J., Davenport A.G., Grimond B., Oke Tim R. New revision of Davenport roughness classification. 3rd European & African Conference on Wind Engineering. Eindhoven, Netherlands, July 2001. published papers/DavenportRoughness 2.pdf.

Blocken Bert, Stathopoulos Ted, Carmeliet Jan. CFD simulation of the atmospheric boundary layer: wall function problems Atmospheric Environment 41(2): 238 252. © Elsevier 2007.

Richards P., Hoxey R., Appropriate boundary conditions for computational wind engineering models using the k-e turbulence model. Journal of Wind Engineering and Industrial Aerodynamics 46-471993, P.145 153.

ANSYS FLUENT Theory Guide. Release 14.0, November 2011.

Dutton A.G., Halliday J.A., Blanch M.J. The feasibility of building-mounted wind turbines (BUWTs): Achieving their potential for carbon emission reductions. Final report, 2005, 109 p. final v004_full. pdf.

Abstract views: 86
PDF Downloads: 62
How to Cite
Novikov, V. (2015). ENERGY AND TURBULENT WIND FLOW CHARACTERISTICS IN THE BUILT ENVIRONMENT. Thermophysics and Thermal Power Engineering, 37(2), 20-31.
Heat and Mass Exchange Processes