Convective heat transfer and experimental icing aerodynamics of wind turbine blades

dc.contributor.authorWang, Xin
dc.contributor.examiningcommitteeOrmiston, Scott (Mechanical and Manufacturing Engineering) Hanesiak, John (Environment & Geography) Lozowski, Edward (University of Alberta)en
dc.contributor.supervisorBibeau,Eric (Mechanical and Manufacturing Engineering) Naterer,Greg (Faculty of Engineering and Applied Science,UOIT)en
dc.date.accessioned2008-09-12T22:26:12Z
dc.date.available2008-09-12T22:26:12Z
dc.date.issued2008-09-12T22:26:12Z
dc.degree.disciplineMechanical and Manufacturing Engineeringen_US
dc.degree.levelDoctor of Philosophy (Ph.D.)en_US
dc.description.abstractThe total worldwide base of installed wind energy peak capacity reached 94 GW by the end of 2007, including 1846 MW in Canada. Wind turbine systems are being installed throughout Canada and often in mountains and cold weather regions, due to their high wind energy potential. Harsh cold weather climates, involving turbulence, gusts, icing and lightning strikes in these regions, affect wind turbine performance. Ice accretion and irregular shedding during turbine operation lead to load imbalances, often causing the turbine to shut off. They create excessive turbine vibration and may change the natural frequency of blades as well as promote higher fatigue loads and increase the bending moment of blades. Icing also affects the tower structure by increasing stresses, due to increased loads from ice accretion. This can lead to structural failures, especially when coupled to strong wind loads. Icing also affects the reliability of anemometers, thereby leading to inaccurate wind speed measurements and resulting in resource estimation errors. Icing issues can directly impact personnel safety, due to falling and projected ice. It is therefore important to expand research on wind turbines operating in cold climate areas. This study presents an experimental investigation including three important fundamental aspects: 1) heat transfer characteristics of the airfoil with and without liquid water content (LWC) at varying angles of attack; 2) energy losses of wind energy while a wind turbine is operating under icing conditions; and 3) aerodynamic characteristics of an airfoil during a simulated icing event. A turbine scale model with curved 3-D blades and a DC generator is tested in a large refrigerated wind tunnel, where ice formation is simulated by spraying water droplets. A NACA 63421 airfoil is used to study the characteristics of aerodynamics and convective heat transfer. The current, voltage, rotation of the DC generator and temperature distribution along the airfoil, which are used to calculate heat transfer coefficients, are measured using a Data Acquisition (DAQ) system and recorded with LabVIEW software. The drag, lift and moment of the airfoil are measured by a force balance system to obtain the aerodynamics of an iced airfoil. This research also quantifies the power loss under various icing conditions. The data obtained can be used to valid numerical data method to predict heat transfer characteristics while wind turbine blades worked in cold climate regions.en
dc.description.noteOctober 2008en
dc.format.extent3444597 bytes
dc.format.mimetypeapplication/pdf
dc.identifier.urihttp://hdl.handle.net/1993/3082
dc.language.isoengen_US
dc.rightsopen accessen_US
dc.subjecticed airfoilen
dc.subjectaerodynamicsen
dc.subjectice shapesen
dc.subjectheat transferen
dc.subjectpower lossesen
dc.subjectexperimenten
dc.titleConvective heat transfer and experimental icing aerodynamics of wind turbine bladesen
dc.typedoctoral thesisen_US
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