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library.bib
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% This file was created with JabRef 2.10.
% Encoding: UTF8
@TechReport{Acharya2000,
Title = {Investigation of Incipient Dynamic Stall at High Reynolds Numbers},
Author = {Mukund Acharya and John W. Kiedaisch and Angelis Bizos},
Institution = {Fluid Dynamics Research Center, Illinois Institute of Technology},
Year = {2000},
File = {:Fluid Mechanics, of Foils/Acharya et al, 2000, Investigation of incipient dynamic stall at high Re.pdf:PDF},
Owner = {pete},
Timestamp = {2013.11.20}
}
@Article{Adaramola2006,
Title = {Turbulent wake of a finite circular cylinder of small aspect ratio},
Author = {M.S. Adaramola and O.G. Akinlade and D. Sumner and D.J. Bergstrom and A.J. Schenstead},
Journal = {Journal of Fluids and Structures},
Year = {2006},
Pages = {919-928},
Volume = {22},
File = {:Turbulence\\Adaramola, 2006, Turbulent wake of a finite circular cylinder of small aspect ratio.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.11.18}
}
@Article{Afgan2013,
Title = {Turbulent flow and loading on a tidal stream turbine by LES and RANS},
Author = {I. Afgan and J. McNaughton and S. Rolfo and D.D. Apsley and T. Stallard and P. Stansby},
Journal = {International Journal of Heat and Fluid Flow},
Year = {2013},
File = {:Turbines, Modeling\\Afgan et al, 2013, Turbulent flow and loading on a tidal stream turbine by LES and RANS.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.09.12}
}
@Article{Ainslie1988,
Title = {Calculating the flowfield in the wake of wind turbines},
Author = {J.F. Ainslie},
Journal = {Journal of Wind Engineering and Industrial Aerodynamics},
Year = {1988},
Pages = {213-224},
Volume = {27},
File = {:home/pete/Google Drive/Library/Turbines, Wakes/Ainslie, 1988, Calculating the flowfield in the wake of wind turbines.pdf:PDF},
Owner = {pete},
Timestamp = {2014.09.21}
}
@Article{Akbari2003,
Title = {Simulation of dynamic stall for a {NACA} 0012 airfoil using a vortex method},
Author = {M. Akbari and S. Price},
Journal = {Journal of Fluids and Structures},
Year = {2003},
Pages = {855--874},
Volume = {17},
__markedentry = {[Pete:]},
File = {:Fluid Mechanics, of Foils\\Akbari, Price, 2003, Simulation of dynamic stall for a NACA 0012 airfoil using a vortex method.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.06.19}
}
@Electronic{AlaskaEnergyWiki,
Title = {HYDROKINETIC ENERGY (In-River, Tidal, and Ocean Current)},
Author = {{Alaska Energy Wiki}},
Url = {http://energy-alaska.wikidot.com/hydrokinetic},
Year = {2014},
Owner = {Pete},
Timestamp = {2014.03.24}
}
@Article{Alfredsson1982,
Title = {A Comparison Between Predicted and Measured Data from Wind Turbine Wakes.},
Author = {P. Henrik Alfredsson and Jan-Ake Dahlberg and Paul E.J. Vermeulen},
Journal = {Wind Engineering},
Year = {1982},
Pages = {149-155},
Volume = {6},
File = {:Turbines, Wakes\\Alfredsson et al, 1982, A Comparison Between Predicted and Measured Data from Wind Turbine Wakes.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.11.01}
}
@TechReport{Amaral2011,
Title = {Evaluation of Fish Injury and Mortality Associated with Hydrokinetic Turbines},
Author = {Amaral, S. and Perkins, N. and Giza, D. and McMahon, B.},
Institution = {Electric Power Research Institute},
Year = {2011},
Number = {1024569},
Owner = {Pete},
Timestamp = {2014.03.24}
}
@Article{Amet2009,
Title = {2D Numerical Simulations of Blade-Vortex Interaction in a Darrieus Turbine},
Author = {E. Amet and T. Maitre and C. Pellone and J.-L. Achard},
Journal = {Journal of Fluids Engineering},
Year = {2009},
Volume = {131},
File = {:Turbines, Cross-Flow\\Amet et al, 2009, 2D Numerical simulations of blade-vortex interaction in a Darrieus turbine.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.09.09}
}
@Book{Anderson1995,
Title = {Computational Fluid Dynamics: The Basics with Applications},
Author = {John D. Anderson},
Publisher = {McGraw-Hill},
Year = {1995},
File = {:CFD\\Anderson, Computational fluid dynamics - the basics with applications.djvu:Djvu},
Owner = {Pete},
Timestamp = {2013.10.19}
}
@Article{Antheaume2008,
Title = {Hydraulic Darrieus turbines efficiency for free fluid flow conditions versus power farms conditions},
Author = {Sylvain Antheaume and Thierry Maıtre and Jean-Luc Achard},
Journal = {Renewable Energy},
Year = {2008},
Pages = {2186-2198},
Volume = {33},
Abstract = {The present study deals with the efficiency of cross flow water current turbine for free stream conditions versus power farm conditions. In the first part, a single turbine for free fluid flow conditions is considered. The simulations are carried out with a new in house code which couples a Navier–Stokes computation of the outer flow field with a description of the inner flow field around the turbine. The latter is based on experimental results of a Darrieus wind turbine in an unbounded domain. This code is applied for the description of a hydraulic turbine. In the second part, the interest of piling up several turbines on the same axis of rotation to make a tower is investigated. Not only is it profitable because only one alternator is needed but the simulations demonstrate the advantage of the tower configuration for the efficiency. The tower is then inserted into a cluster of several lined up towers which makes a barge. Simulations show that the average barge efficiency rises as the distance between towers is decreased and as the number of towers is increased within the row. Thereby, the efficiency of a single isolated turbine is greatly increased when set both into a tower and into a cluster of several towers corresponding to possible power farm arrangements.},
File = {:Turbines, Cross-Flow\\Antheaume, 2008, Hydraulic darrieus turbines efficiency for free fluid flow conditions versus power farm conditions.pdf:PDF},
Owner = {pete},
Review = {Actuator line method},
Timestamp = {2013.07.11}
}
@InProceedings{Antheaume2007,
Title = {A innovative modelling approach to investigate the efficiency of cross flow water turbine farms},
Author = {Sylvain Antheaume and Thierry Maıtre and Jean-Luc Achard},
Booktitle = {Proceedings of the 2nd IAHR International Meet 282 ing of the Workgroup on Cavitation and Dynamic Problems in Hydraulic Machinery and Systems},
Year = {2007},
File = {:Turbines, Arrays\\Antheaume et al, 2007, Innovative modelling approach to investigate the efficiency of cross flow water turbine farms.pdf:PDF},
Keywords = {Arrays, RANS, BEM},
Owner = {Pete},
Review = {Use a combination of RANS (Fluent, k-epsilon) and BEM techniques},
Timestamp = {2013.07.30}
}
@InProceedings{Aranake2013,
Title = {Computational Analysis of Shrouded Wind Turbine Configurations},
Author = {Aniket C. Aranake and Vinod K. Lakshminarayan and Karthik Duraisamy},
Booktitle = {Proceedings of 51st AIAA Aerospace Sciences Meeting including the New Horizons Forum and Aerospace Exposition},
Year = {2013},
File = {:Turbines, Axial-Flow\\Aranake et al, 2013, Computational analysis of shrouded wind turbine configurations.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.12.04}
}
@Article{Archer2013,
Title = {Quantifying the sensitivity of wind farm performance to array layout options using large-eddy simulation},
Author = {Cristina L. Archer and Sina Mirzaeisefat and Sang Lee},
Journal = {Geophysical Research Letters},
Year = {2013},
Pages = {4963-4970},
Volume = {40},
Abstract = {This paper attempts to quantify the effects of array layout on the performance of offshore wind farms. Array layout is characterized by the spacing between wind turbines (along and across the prevailing wind direction) and by their alignment (aligned or staggered). A large-eddy simulation code is utilized to create a turbulent boundary layer and is coupled with an actuator line model to simulate the effects of the rotating wind turbine blades. A control case (simulating the Lillgrund farm) and sensitivity runs are performed with various combinations of increased spacing, with and without staggering. Staggering every second row was found to be the simplest method to improve the capacity factor from 0.3 to 0.34 and array losses from 36% to 27%. The highest capacity factor (0.4) and the lowest array losses (14%) were obtained with a staggered layout with spacing across the prevailing wind direction that was twice the original. Smart layout choices can improve the array performance by 13%–33%.},
File = {:Turbines, Arrays\\Archer et al, 2013, Quantifying the sensitivity of wind farm performance to array layout options using Large-Eddy Simulation.pdf:PDF},
Keywords = {SOWFA},
Owner = {Pete},
Timestamp = {2013.10.31}
}
@Article{Armstrong2012,
Title = {Flow separation on a high Reynolds number, high solidity vertical axis wind turbine with straight and canted blades and canted blades with fences},
Author = {Shawn Armstrong and Andrzej Fiedler and Stephen Tullis},
Journal = {Renewable Energy},
Year = {2012},
Pages = {13-22},
Volume = {41},
Abstract = {The aerodynamics of a high solidity vertical axis wind turbine was investigated through wind tunnel tests of a full size turbine operating at Reynolds numbers of Re 500,000 (where the power production has been shown to be Re independent). Flow visualization using light-weight tufts attached to the inner surface of a blade was used to gain insight on the operating aerodynamics, which is related to the measured power performance. The tufts proved to be an effective and simple technique to observe the flow characteristics on the large scales involved where other flow measurement techniques like particle image velocimetry or laser Doppler velocimetry would be challenging and expensive. Straight blades on the HeDarrieus turbine operating at peak power showed large regions of flow separation on the upwind blade pass extending from early in the upwind pass from an azimuthal angle q ¼ 40e50 (where the blade is moving directly upwind at q ¼ 0) to over 60 into the downwind pass. The effect of preset blade pitch was also investigated where a 6 leading edge toe-out pitch showed a delay in separation initiation and a reduction in the maximum fraction of chord with flow reversal as well as increased power performance. The overall separation behaviour of the straight blades shows the importance of dynamic stall and the interaction of the separated vortex with the blade as mechanisms in lift generation. Performance and flow separation results are presented for canted blades. The flow separation behaviour was considerably different from straight blades, with canted blades experiencing less flow reversal on their upwind pass, and recovering attached flow before q ¼ 180. The installation of fences on the canted blades increased the power and reduced the blade speed ratio at which peak power occurred, suggestive of a reduction in spanwise flow on the swept blades (so that they locally behave more like straight blades). However, the location and amount of flow separation did not trend toward that seen with the straight blades, but rather the fences further reduced the amount of separation.},
File = {:Turbines, Cross-Flow\\Armstrong et al, 2012, Flow separation on a high Re, high solidity VAWT with straight and canted blades.pdf:PDF},
Owner = {Pete},
Review = {Claim Re independence of power production at 500,000 Fences on blades?},
Timestamp = {2013.07.25}
}
@InProceedings{Asher2010,
Title = {A Low Order Model for Vertical Axis Wind Turbines},
Author = {Asher, Isaac M. and Mark Drela and Jaime Peraire},
Booktitle = {Proceedings of the 28th AIAA Applied Aerodynamics Conference},
Year = {2010},
Address = {Chicago, Illinois},
Month = {June},
Abstract = {A new computational model for initial sizing and performance prediction of vertical axis wind turbines is presented. The model uses a 2D hybrid dynamic vortex and blade element momentum approach. Each airfoil is modeled as a single vortex of time varying strength with an analytical model for the influence of the shed vorticity. The vortex strengths are calculated by imposing a flow tangency condition at the three-quarter chord location on each airfoil, modified in the case of stall. The total blade forces and the momentum-based streamtube deceleration are then obtained using pre-computed c[subscript d] and c[subscript m] 2D blade profile characteristics. Model fidelity is improved over previous models because flow curvature, dynamic vortices, blade interactions, static stall, and streamtube changes are all taken into account. Fast convergence is obtained for a large range of solidity and tip speed ratio, which allows optimization of various parameters, including blade pitch angle variation.},
File = {:Turbines, Cross-Flow\\Asher et al, 2010, A Low Order Model for Vertical Axis Wind Turbines.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.08.24}
}
@Article{Ashok2012,
Title = {Hot-wire spatial resolution effects in measurements of grid-generated turbulence},
Author = {A. Ashok and S. C. C. Bailey and M. Hultmark and A. J. Smits},
Journal = {Exp. Fluids},
Year = {2012},
Pages = {1713-1722},
Volume = {53},
File = {:Experimental Fluid Mechanics\\Ashok et al, 2012, Hot-wire spatial resolution effects in measurements of grid-generated turbulence.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.04}
}
@Article{Ashuri2012,
Title = {Development and validation of a computational model for design analysis of a novel marine turbine},
Author = {Turaj Ashuri and Gerard van Bussel and Stefan Mieras},
Journal = {Wind Energy},
Year = {2012},
File = {:Turbines, Cross-Flow\\Ashuri et al, 2012, Development and validation of a computational model for design analysis of a novel marine turbine.pdf:PDF},
Keywords = {Fatigue},
Owner = {Pete},
Timestamp = {2013.07.30}
}
@Standard{ASME2009,
Title = {Standard for Verification and Validation in Computational Fluid Dynamics and Heat Transfer},
Institution = {ASME},
Organization = {American Society of Mechanical Engineers},
Author = {ASME},
File = {:CFD\\ASME, 2009, Standard for Verification and Validation in Computational Fluid Dynamics and Heat Transfer.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.04}
}
@Article{Aubrun2013,
Title = {Wind turbine wake properties: Comparison between a non-rotating simplified wind turbine model and a rotating model},
Author = {S. Aubrun and S. Loyer and P.E. Hancock and P. Hayden},
Journal = {J. Wind Eng. Ind. Aerodyn.},
Year = {2013},
Pages = {1-8},
Volume = {120},
File = {:Turbines, Wakes\\Aubrun et al, 2013, Wind turbine wake properties - Comparison between a non-rotating simplified wind turbine model and a rotating model.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.12}
}
@Misc{Vortexje,
Title = {Vortexje},
Author = {Baayen and Heinz},
HowPublished = {http://vortexje.org},
Owner = {Pete},
Timestamp = {2014.08.09}
}
@MastersThesis{Bachant2011MS,
Title = {Experimental Investigation of Helical Cross-Flow Axis Hydrokinetic Turbines, Including Effects of Waves and Turbulence},
Author = {Peter Bachant},
School = {University of New Hampshire},
Year = {2011},
File = {:Turbines, Cross-Flow\\Bachant, 2011, Experimental investigation of cross-flow axis hydrokinetic turbines, including effects of waves and turbulence, MS thesis.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.26}
}
@Article{Bachant2014_JOT,
Title = {Characterizing the near-wake of a cross-flow turbine},
Author = {Peter Bachant and Martin Wosnik},
Journal = {Journal of Turbulence},
Year = {Under review},
Owner = {Pete},
Timestamp = {2014.06.11}
}
@Article{Bachant2015,
Title = {Performance measurements of cylindrical- and spherical-helical cross-flow marine hydrokinetic turbines, with estimates of exergy efficiency},
Author = {Peter Bachant and Martin Wosnik},
Journal = {Renewable Energy},
Year = {2015},
Owner = {Pete},
Timestamp = {2014.06.11}
}
@InProceedings{Bachant2014,
Title = {Reynolds Number Dependence of Cross-Flow Turbine Performance and Near-Wake Characteristics},
Author = {Peter Bachant and Martin Wosnik},
Booktitle = {Proceedings of the 2nd Marine Energy Technology Symposium METS2014},
Year = {2014},
Address = {Seattle, WA},
Month = {April},
File = {:Turbines, Cross-Flow\\Bachant and Wosnik, 2014, Reynolds number dependence of cross-flow turbine performance and near-wake characteristics.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.05.05}
}
@Misc{Bachant2014_CAD,
Title = {{UNH-RVAT CAD models}},
Author = {Peter Bachant and Martin Wosnik},
HowPublished = {fig\textbf{share}. http://dx.doi.org/10.6084/m9.figshare.1062009},
Year = {2014},
Doi = {10.6084/m9.figshare.1062009},
Owner = {Pete},
Timestamp = {2014.06.19},
Url = {http://dx.doi.org/10.6084/m9.figshare.1062009}
}
@Misc{Bachant2014_data,
Title = {{UNH-RVAT} baseline performance and near-wake measurements: Reduced dataset and processing code},
Author = {Peter Bachant and Martin Wosnik},
HowPublished = {fig\textbf{share}. http://dx.doi.org/10.6084/m9.figshare.1080781},
Year = {2014},
Doi = {10.6084/m9.figshare.1080781},
Owner = {Pete},
Timestamp = {2014.06.25},
Url = {http://dx.doi.org/10.6084/m9.figshare.1080781}
}
@Misc{Bachant2014_OF-AS,
Title = {{OpenFOAM} cylindrical actuator surface case files},
Author = {Peter Bachant and Martin Wosnik},
HowPublished = {fig\textbf{share}. http://dx.doi.org/10.6084/m9.figshare.1080780},
Year = {2014},
Owner = {Pete},
Timestamp = {2014.08.09}
}
@Misc{Bachant2014_vortexje,
Title = {{UNH-RVAT} {Vortexje} simulation code},
Author = {Peter Bachant and Martin Wosnik},
HowPublished = {fig\textbf{share}. http://dx.doi.org/10.6084/m9.figshare.1037707},
Year = {2014},
Owner = {Pete},
Timestamp = {2014.08.09}
}
@InProceedings{Bachant2013,
Title = {Performance and near-wake measurements for a vertical axis turbine at moderate {R}eynolds number},
Author = {Bachant, Peter and Wosnik, Martin},
Booktitle = {Proceedings of the ASME Fluids Engineering Division Summer Meeting},
Year = {2013},
Address = {Incline Village, NV},
Month = {July},
Number = {FEDSM2013-16575},
File = {:Turbines, Cross-Flow\\Bachant, Wosnik, 2013, Performance and near-wake measurements for a vertical axis turbine at moderate Reynolds number.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.30}
}
@InProceedings{Bachant2011AJK,
Title = {Experimental Investigation of Helical Cross-Flow Axis Hydrokinetic Turbines, Including Effects of Waves and Turbulence},
Author = {Peter Bachant and Martin Wosnik},
Booktitle = {Proceedings of ASME-JSME-KSME Joint Fluids Engineering Conference 2011},
Year = {2011},
Address = {Hamamatsu, Shizuoka, JAPAN},
Month = {July},
Number = {AJK2011-07020},
Doi = {10.1115/AJK2011-07020},
File = {:Turbines, Cross-Flow\\Bachant and Wosnik, 2011, Experimental investigation of cross-flow axis hydrokinetic turbines, including effects of waves and turbulence.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.26}
}
@InProceedings{Bahaj2007b,
Title = {Characterising the wake of horizontal axis marine current turbines},
Author = {A.S. Bahaj and L.E Meyers and M.D Thomson and N. Jorge},
Booktitle = {Proceedings of the 7th European wave and tidal energy conference},
Year = {2007},
File = {:Turbines, Wakes\\Bahaj et al, 2007, Characterising the wake of horizontal axis marine current turbines.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.09.18}
}
@Article{Bahaj2007,
Title = {Power and thrust measurements of marine current turbines under various hydrodynamic flow conditions in a cavitation tunnel and a towing tank},
Author = {Bahaj, A. and Molland, A. and Chaplin, J. and Batten,W.},
Journal = {Renewable Energy},
Year = {2007},
Pages = {407-426},
Volume = {32(3)},
Abstract = {The results of cavitation tunnel and tank tests on an 800 mm diameter model of a marine current turbine (MCT) are presented. The tests were carried out in a 2.4 m x 1.2 m cavitation tunnel and the 60 m towing tank. Results for power and thrust coefficients are presented for a range of tip speed ratio and pitch settings for various conditions. The results of this investigation provided an insight into the operation of a singe turbine in straight or yawed flow, the effect on performance of changes in the tip immersion of the rotor, the interference between twin rotors and the likely areas of cavitation inception. In addition, the analysed results presented provide useful information for the hydrodynamic design of MCTs and detailed data for the validation of numerical models.},
File = {:Turbines, Blockage Corrections\\Bahaj et al, 2007, Power and thrust measurements of marine current turbines under various hydrodynamic flow conditions in a cavitation tunnel and a towing tank.pdf:PDF},
Keywords = {Axial flow turbines, blockage corrections, cavitation},
Owner = {Pete},
Timestamp = {2011.12.26}
}
@Article{Bai2013,
Title = {Numerical investigations of the effects of different arrays on power extractions of horizontal axis tidal current turbines},
Author = {Guanghui Bai and Jun Li and Pengfei Fan and Guojun Li},
Journal = {Renewable Energy},
Year = {2013},
Pages = {180-186},
Volume = {53},
File = {:Turbines, Arrays\\Bai et al, 2013, Numerical investigations of the effects of different arrays on power extractions of horizontal axis tidal current turbines.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.12}
}
@Article{Bai2014,
Title = {Numerical simulation of a marine current turbine in free surface flow},
Author = {X. Bai and E.J. Avital and A. Munjiza and J.J.R. Williams},
Journal = {Renewable Energy},
Year = {2014},
Volume = {63},
File = {:Turbines, Modeling\\Bai et al, 2014, Numerical simulation of a marine current turbine in free surface flow.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.08.18}
}
@Electronic{Barnard2014,
Title = {Offshore Vertical Axis Wind Turbines Are Sinking Not Swimming},
Author = {Mike Barnard},
Month = {March},
Organization = {Clean Technica},
Url = {http://cleantechnica.com/2014/03/25/offshore-vertical-axis-wind-turbines-sinking-swimming/},
Year = {2014},
Owner = {Pete},
Timestamp = {2014.03.31}
}
@Electronic{Barnard2013,
Title = {Opinion: Are "school of fish" turbine arrays a red herring?},
Author = {Mike Barnard},
Month = {July},
Url = {http://www.gizmag.com/dabiri-fish-school-wind-farms/28355/},
Year = {2013},
Keywords = {Dabiri},
Owner = {pete},
Timestamp = {2013.11.10}
}
@TechReport{Barone2011,
Title = {Reference Model 2: ``Rev 0'' Rotor Design},
Author = {Matt Barone and Todd Griffith and Jonathan Berg},
Institution = {Sandia National Laboratories},
Year = {2011},
Month = {November},
Number = {SAND2011-9306},
File = {:Turbines, Cross-Flow\\Barone et al, 2011, Reference model 2 - Rev 0 rotor design.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.02.16}
}
@InProceedings{Barthelmie2009b,
Title = {Modelling the impact of wakes on power output at Nysted and Horns Rev},
Author = {R.J. Barthelmie and S.T. Frandsen and K. Hansen and J.G. Schepers and K. Rados and W. Schlezand A. Neubert and L.E. Jensen and S. Neckelmann8},
Booktitle = {Proceedings of European Wind Energy Conference},
Year = {2009},
File = {:Turbines, Wakes\\Barthelmie et al, 2009, Modelling the impact of wakes on power output at Nysted and Horns Rev.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.09.18}
}
@Article{Barthelmie2009,
Title = {Modelling and Measuring Flow and Wind Turbine Wakes in Large Wind Farms Offshore},
Author = {R.J. Barthelmie and K. Hansen and S.T. Frandsen and O. Rathman and J.G Schepers and W. Schlez and J. Phillips and K. Rados and A. Zervos and E.S. Politis and P.K. Chaviaropolous},
Journal = {Wind Energy},
Year = {2009},
Pages = {431-444},
Volume = {12},
File = {:Turbines, Arrays\\Barthelmie et al, 2009, Wind turbine wakes in large wind farms offshore.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.11.06}
}
@TechReport{Barthelmie2009c,
Title = {Wp4: An overview of wind turbine wakes and short-term forecasting},
Author = {Rebecca J. Barthelmie},
Institution = {Risoe DTU},
Year = {2009},
Month = {February},
Number = {POWWOWwakesreport},
File = {:home/pete/Google Drive/Library/Turbines, Wakes/Barthelmie, 2009, Wp4 - An overview of wind turbine wakes and short-term forecasting.pdf:PDF},
Owner = {pete},
Timestamp = {2014.09.21}
}
@Article{Barthelmie2006,
Title = {Comparison of Wake Model Simulations with Offshore Wind Turbine Wake Profiles Measured by Sodar},
Author = {R. J. Barthelmie and L. Folkerts and G. C. Larsen and K. Rados and S. C. Pryor and S. T. Frandsen and B. Lange and G. Schepers},
Journal = {Journal of Atmospheric and Oceanic Technology},
Year = {2006},
Pages = {888-901},
Volume = {23},
File = {:Turbines, Arrays\\Barthelmie et al, 2006, Comparison of Wake Model Simulations with Offshore Wind Turbine Wake Profiles Measured by Sodar.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.13}
}
@Article{Batten2008,
Title = {The prediction of the hydrodynamic performance of marine current turbines},
Author = {W.M.J. Batten and A.S. Bahaj and A.F. Molland and J.R. Chaplin},
Journal = {Renewable Energy},
Year = {2008},
Pages = {1085-1096},
Volume = {33},
File = {:Turbines, Axial-Flow\\Batten, Bahaj, Molland, Chaplin, 2008, Performance prediction of marine current turbines.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.25}
}
@InProceedings{Batten2011,
Title = {The accuracy of the actuator disc-RANS approach for predicting the performance and far wake of a horizontal axis tidal stream turbine},
Author = {William M. J. Batten and Matt Harrison and AbuBakr S. Bahaj},
Booktitle = {Proceedings of the 9th European Wave and Tidal Energy Conference},
Year = {2011},
File = {:Turbines, Axial-Flow\\Batten et al, 2011, The accuracy of the actuator disk-RANS approach for predicting performance and far-wake of a horizontal axis tidal stream turbine.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.09.19}
}
@Article{Battisti2011,
Title = {Aerodynamic Measurements on a Vertical Axis Wind Turbine in a Large Scale Wind Tunnel},
Author = {L. Battisti and L. Zanne and S. Dell'Anna and V. Dossena and G. Persico and B. Paradiso},
Journal = {Journal of Energy Resources Technology},
Year = {2011},
Volume = {133},
File = {:Turbines, Cross-Flow\\Battisti et al, 2011, Aerodynamic measurements on a vertical axis wind turbine in a large scale wind tunnel.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.05.01}
}
@TechReport{Beam2011,
Title = {Power Take-Off System Design {SNL} Reference Turbine 2},
Author = {Michael J. Beam and Brain R. Elbing and Todd K. Fetterolf and Brian L. Kline and Daniel F. Kerstetter and James A. Mickey and Arnold A. Fontaine and William A. Straka},
Institution = {Penn State Applied Research Lab},
Year = {2011},
File = {:Turbines, Cross-Flow\\Beam et al, 2011, Power Take-Off System Design, SNL Reference Turbine 2.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.10.27}
}
@InProceedings{Beaucage2012,
Title = {Overview of six commercial and research wake models for large offshore wind farms},
Author = {Philippe Beaucage and Michael Brower and Nick Robinson and Chuck Alonge},
Booktitle = {Proceedings of European Wind Energy Association},
Year = {2012},
File = {:Turbines, Arrays\\Beaucage et al, 2012, Overview of six commercial and research wake models for large offshore wind farms.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.09.18}
}
@Article{Bedon2014,
Title = {Evaluation of the different aerodynamic databases for vertical axis wind turbine simulations},
Author = {Gebriele Bedon and Enrico G.A. Antonini and Stefano De Betta and Marco Raciti Castelli and Ernesto Benini},
Journal = {Renewable and Sustainable Energy Reviews},
Year = {2014},
Volume = {40},
File = {:Turbines, Cross-Flow\\Bedon et al, 2014, Evaluation of different aerodynamic databases for vertical axis wind turbine simulations.pdf:PDF},
Keywords = {Beddoes},
Owner = {Pete},
Timestamp = {2014.08.24}
}
@Article{Bedon2013,
Title = {Optimization of a Darrieus vertical-axis wind turbine using blade element – momentum theory and evolutionary algorithm},
Author = {Gabriele Bedon and Marco Raciti Castelli and Ernesto Benini},
Journal = {Renewable Energy},
Year = {2013},
Pages = {184-192},
Volume = {59},
File = {:Turbines, Cross-Flow\\Bedon et al, 2013, Optimization of Darrieus VAWT using BEM theory and evolutionary algorithms.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.25}
}
@Article{Bejan1979,
Title = {A Study of Entropy Generation in Fundamental Convective Heat Transfer},
Author = {A. Bejan},
Journal = {Journal of Heat Transfer},
Year = {1979},
Pages = {718-725},
Volume = {101},
Abstract = {The second law aspects of heat transfer by forced convection are illustrated in terms of four fundamental flow configurations: pipe flow, boundary layer over flat plate, single cylinder in cross-flow, flow in the entrance region of a flat rectangular duct. The interpla_, between irreversibility due to heat transfer along finite temperature gradients and, on the other hand, irreversibility due to viscous effects is analyzed in detail. The spatial distribution of irreversibility, entropy generation profiles or maps, and those flow features acting as strong sources of irreversibility are presented. It is shown how the flow geometric parameters may be selected in order to minimize the irreversibility associated with a specific convective heat transfer process.},
File = {:Heat Transfer\\Bejan, 1979, A study of entropy generation in fundamental convective heat transfer.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.06.25}
}
@Article{Benedict1996,
Title = {Towards better uncertainty estimates for turbulence statistics},
Author = {L. H. Benedict and R. D. Gould},
Journal = {Experiments in Fluids},
Year = {1996},
File = {:Experimental Fluid Mechanics\\Benedict and Gould, 1996, Towards better uncertainty estimates for turbulence statistics.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.08.27}
}
@Article{Beri2011,
Title = {Double Multiple Stream Tube Model and Numerical Analysis of Vertical Axis Wind Turbine},
Author = {Habtamu Beri and Yingxue Yao},
Journal = {Energy and Power Engineering},
Year = {2011},
Pages = {262-270},
Volume = {3},
File = {:Turbines, Cross-Flow\\Beri and Yao, 2011, Double Multiple Streamtube Model and Numerical Analysis of Vertical Axis Wind Turbine.pdf:PDF},
Owner = {Pete},
Review = {Compare DMST to CFD},
Timestamp = {2014.03.09}
}
@Article{Bernard1993,
Title = {Vortex dynamics and the production of {R}eynolds stress},
Author = {Peter S. Bernard and James M. Thomas and Robert A. Handler},
Journal = {Journal of Fluid Mechanics},
Year = {1993},
Pages = {385-419},
Volume = {253},
File = {:Turbulence\\Bernard et al, 1993, Vortex dynamics and the production of Reynolds stress.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.12.10}
}
@Article{Betz1920,
Title = {Das Maximum der theoretisch moglichen Austnutzung des Windes durch Windmotoren},
Author = {Betz, A.},
Journal = {Zeitschrift für das gesamte Turbinenwesen},
Year = {1920},
Pages = {307-309},
File = {:Turbines, General Theory\\Betz, 1920, Efficiency of wind motors.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.19}
}
@Article{Birjandi2013,
Title = {Power measurement of hydrokinetic turbines with free-surface and blockage effect},
Author = {Amir Hossein Birjandi and Eric Louis Bibeau and Vijay Chatoorgoon and Anurag Kumar b},
Journal = {Ocean Engineering},
Year = {2013},
Pages = {9-17},
Volume = {69},
File = {:Turbines, Cross-Flow/Birjandi et al, 2013, Power measurements of hydrokinetic turbines with free-surface and blockage effect.pdf:PDF},
Owner = {pete},
Quality = {1},
Timestamp = {2013.07.31}
}
@TechReport{Bjork2000,
Title = {DYNSTALL: Subroutine Package with a Dynamic stall model},
Author = {Anders Björk},
Institution = {Flygtekniska Försöksanstalten},
Year = {2000},
Address = {Sweden},
Month = {June},
Number = {FFAP-V-110},
File = {:home/pete/Google Drive/Library/Fluid Mechanics, of Foils/Bjork, 2000, DYNSTALL - Subroutine package with a dynamic stall model.pdf:PDF},
Owner = {pete},
Timestamp = {2014.09.21}
}
@TechReport{Blackwell1976,
Title = {Wind Tunnel Performance Data for the {Darrieus} Wind Turbine with {NACA} 0012 Blades},
Author = {B. Blackwell and R. Sheldahl and L. Feltz},
Institution = {Sandia National Laboratories},
Year = {1976},
Address = {Albuquerque, {NM}},
Month = {May},
Number = {SAND76-0130},
Type = {Report},
File = {:Turbines, Cross-Flow\\Blackwell et al, 1976, Wind Tunnel Performance Data for the Darrieus Wind Turbine with NACA 0012 Blades.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.06.19}
}
@Article{Blusseau2012,
Title = {Gyroscopic effects on a large vertical axis wind turbine mounted on a floating structure},
Author = {Pierre Blusseau and Minoo H. Patel},
Journal = {Renewable Energy},
Year = {2012},
Pages = {31-42},
Volume = {46},
Abstract = {This paper presents an analysis technique for investigating the effects of gyroscopic couples on the behaviour of a large vertical axis wind turbine mounted on a floating semi-submersible vessel. Equations of motion in 6 degrees of freedom are formulated in the frequency domain. Time domain aerodynamic loads are derived from a double multiple stream tube model based Paraschivoiu [13]. These loads are transposed to the frequency domain and integrated with a formulation of the gyroscopic moments acting for the wind turbine rotating and the semi-submersible rotating in roll and pitch due to ocean waves. The paper uses this model to explore the effect of gyroscopic effects on the motions of the turbine and semisubmersible. It is shown that the gyroscopic effect has negligible effects on some modes of motion but that it introduces significant motions at key frequencies related to rotor speed.},
File = {:Turbines, Cross-Flow\\Blusseau and Patel, 2012, Gyroscopic effects on a large vertical axis wind turbine mounted on a floating structure.pdf:PDF},
Keywords = {Unsteady, cross-flow},
Owner = {Pete},
Review = {Nothing about power output as far as I can see...},
Timestamp = {2013.11.02}
}
@Article{Bornmann2013,
Title = {What Is Societal Impact of Research and How Can It Be Assessed? A Literature Survey},
Author = {Lutz Bornmann},
Journal = {JOURNAL OF THE AMERICAN SOCIETY FOR INFORMATION SCIENCE AND TECHNOLOGY},
Year = {2013},
Pages = {217-233},
Volume = {64},
File = {:Research, General\\Bornmann, 2013, What is societal impact of research and how can it be assessed.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.05.05}
}
@Article{Brahimi1995b,
Title = {Darrieus Rotor Aerodynamics in Turbulent Wind},
Author = {M.T. Brahimi and I. Paraschivoiu},
Journal = {Journal of Solar Energy Engineering},
Year = {1995},
Pages = {128-136},
Volume = {117},
File = {:Turbines, Cross-Flow\\Brahimi and Paraschivoiu, 1995, Darrieus rotor aerodynamics in turbulent wind.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.11.02}
}
@Article{Brahimi1995,
Title = {Aerodynamic Analysis Models for Vertical-Axis Wind Turbines},
Author = {M. T. Brahimi and A. Allet and I. Paraschivoiu},
Journal = {International Journal of Rotating Machinery},
Year = {1995},
Pages = {15-21},
Volume = {2},
File = {:Turbines, Cross-Flow/Brahimi, Allet, Paraschivoiu, 1995, Aerodynamic analysis models for VAWTs.pdf:PDF},
Owner = {pete},
Quality = {1},
Timestamp = {2013.07.31}
}
@InProceedings{Bravo2007,
Title = {Performance Testing of a Small Vertical-Axis Wind Turbine},
Author = {Bravo, R. and Tullis, S. and Ziada, S.},
Booktitle = {Proceedings of the 21st Canadian Congress of Applied Mechanics CANCAM},
Year = {2007},
File = {:Turbines, Cross-Flow\\Bravo et al, 2007, Performance Testing of a Small Vertical-Axis Wind Turbine.pdf:PDF},
Owner = {Pete},
Review = {* Damn huge experimental setup. High Re_c -- Up past 1e6. * Cited by Armstrong et al. as showing Re indepence of power production},
Timestamp = {2013.08.02}
}
@Article{Braza2006,
Title = {Turbulence properties in the cylinder wake at high {R}eynolds numbers},
Author = {M. Braza and R. Perrina and Y. Hoaraub},
Journal = {Journal of Fluids and Structures},
Year = {2006},
Pages = {757-771},
Volume = {22},
File = {:Fluid Mechanics, Flow Behind Cylinders\\Braza et al, 2006, Turbulence properties in the cylinder wake a high Reynolds numbers.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.03.09}
}
@Article{Breuer2013,
Title = {Comparison of {DES}, {RANS}, and {LES} for the separated flow around a flate plate at high incidence},
Author = {M. Breuer and N. Jovicic and K. Mazaev},
Journal = {Int. J. Numer. Meth. Fluids},
Year = {2003},
Pages = {357-388},
Volume = {41},
File = {:CFD\\Breuer et al, 2003, Comparison of DES, RANS, and LES for the separated flow around a flat plat at high incidence.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.09.18}
}
@Article{Brochier1986,
Title = {Water Channel Experiments of Dynamic Stall on Darrieus Wind Turbine Blades},
Author = {G. Brochier and P. Fraunie and C. Beguier and I. Paraschivoiu},
Journal = {AIAA Journal of Propulsion and Power},
Year = {1986},
Month = {September--October},
Number = {5},
Pages = {46--510},
Volume = {2},
__markedentry = {[Pete:]},
File = {:Turbines, Cross-Flow\\Brochier et al, 1986, Water Channel Experiments of Dynamic Stall on Wind Turbine Blades.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.06.19}
}
@Article{Brown2012,
Title = {Turbulent shear layers and wakes},
Author = {Garry L. Brown and Anatol Roshko},
Journal = {Journal of Turbulence},
Year = {2012},
Pages = {1-32},
Volume = {13},
File = {:Turbulence\\Brown and Roshko, 2012, Turbulent shear layers and wakes.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.05.03}
}
@Article{Brown2000,
Title = {Rotor Wake Modeling for Flight Dynamic Simulation of Helicopters},
Author = {Richard E. Brown},
Journal = {AIAA Journal},
Year = {2000},
Pages = {57-63},
Volume = {38},
File = {:Helicopters\\Brown, 2000, Rotor Wake Modeling for Flight Dynamic Simulation of Helicopters.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.08}
}
@MastersThesis{Brownlee1988,
Title = {A vortex model for the vertical axis turbine},
Author = {Baron Gene Brownlee},
School = {Texas Tech University},
Year = {1988},
File = {:Turbines, Cross-Flow\\Brownlee, 1988, A vortex model for the vertical axis wind turbine, MS thesis.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.04}
}
@TechReport{Buchhave1979,
Title = {The measurement of turbulence with the laser {D}oppler anemometer},
Author = {P. Buchhave and W. K. George and John L. Lumley},
Institution = {Turbulence Research Laboratory},
Year = {1979},
File = {:Experimental Fluid Mechanics\\Buchhave et al, 1979, The measurement of turbulence with the laser Doppler anemometer.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.08.27}
}
@Article{Bugnon1991,
Title = {Acoustic {D}oppler Current Meter},
Author = {Franqois J. Bugnon and Ian A. Whitehouse},
Journal = {IEEE Journal of Oceanic Engineering},
Year = {1991},
Pages = {420-426},
Volume = {16},
File = {:Experimental Fluid Mechanics\\Acoustic flow measurement\\Bugnon, Whitehouse, 1991, Acoustic doppler current meter.pdf:PDF},
Keywords = {ADCP},
Owner = {Pete},
Timestamp = {2013.07.28}
}
@InProceedings{vanBussel2004,
Title = {The development of Turby, a small VAWT for the built environment},
Author = {Gerard J. W. van Bussel},
Booktitle = {Global Wind Energy Conference},
Year = {2004},
File = {:Turbines, Cross-Flow/van Bussel, 2004, The development of Turby, a small VAWT for the built environment.pdf:PDF},
Owner = {pete},
Quality = {1},
Timestamp = {2013.07.31}
}
@InProceedings{vanBussel2004b,
Title = {TURBY®: concept and realisation of a small VAWT for the built environment},
Author = {G. J. W. van Bussel and S. Mertens and H. Polinder and H. F. A. Sidler},
Booktitle = {Proceedings of the EAWE/EWEA Special Topic conference “The Science of making Torque from Wind”},
Year = {2004},
File = {:Turbines, Cross-Flow/van Bussel et al, 2004, TURBY concept and realisation of a small VAWT for the built environment:PDF},
Owner = {pete},
Quality = {1},
Timestamp = {2013.07.31}
}
@Article{Cal2010,
Title = {Experimental study of the horizontally averaged flow structure in a model wind-turbine array boundary layer},
Author = {Raul Bayoan Cal and Jose Lebron and Luciano Castillo and Hyung Suk Kang and Charles Meneveau},
Journal = {Journal of Renewable and Sustainable Energy},
Year = {2010},
Volume = {2},
File = {:Turbines, Arrays\\Cal et al, 2010, Experimental study of the horizontally averaged flow structure in a model wind-turbine array boundary layer.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.11.13}
}
@Article{Calaf2010,
Title = {Large eddy simulation study of fully developed wind turbine array boundary layers},
Author = {Marc Calaf and Charles Meneveau and Johan Meyers},
Journal = {Physics of Fluids},
Year = {2010},
Volume = {22},
Abstract = {It is well known that when wind turbines are deployed in large arrays, their efficiency decreases due to complex interactions among themselves and with the atmospheric boundary layer (ABL). For wind farms whose length exceeds the height of the ABL by over an order of magnitude, a “fully developed” flow regime can be established. In this asymptotic regime, changes in the streamwise direction can be neglected and the relevant exchanges occur in the vertical direction. Such a fully developed wind-turbine array boundary layer (WTABL) has not been studied systematically before. A suite of large eddy simulations (LES), in which wind turbines are modeled using the classical “drag disk” concept, is performed for various wind-turbine arrangements, turbine loading factors, and surface roughness values. The results are used to quantify the vertical transport of momentum and kinetic energy across the boundary layer. It is shown that the vertical fluxes of kinetic energy are of the same order of magnitude as the power extracted by the forces modeling the wind turbines. In the fully developed WTABL, the kinetic energy extracted by the wind turbines is transported into the wind-turbine region by vertical fluxes associated with turbulence. The results are also used to develop improved models for effective roughness length scales experienced by the ABL. The effective roughness scale is often used to model wind-turbine arrays in simulations of atmospheric dynamics at larger (regional and global) scales. The results from the LES are compared to several existing models for effective roughness lengths. Based on the observed trends, a modified model is proposed, showing improvement in the predicted effective roughness length.},
File = {:Turbines, Arrays\\Calaf et al, 2010, Large eddy simulation study of fully developed wind turbine array boundary layers.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.21}
}
@Book{Carlton2007,
Title = {Marine Propellers and Propulsion},
Author = {John S. Carlton},
Publisher = {Elsevier},
Year = {2007},
File = {:Propulsion\\Carlton, 2007, Marine propellers and propulsion.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.07.28}
}
@MastersThesis{Carrigan2010,
Title = {Aerodynamic shape optimization of a vertical axis wind turbine},
Author = {Travis Justin Carrigan},
School = {The University of Texas at Arlington},
Year = {2010},
Abstract = {The purpose of this study is to introduce and demonstrate a fully automated process for optimizing the airfoil cross-section of a vertical axis wind turbine (VAWT). The objective is to maximize the torque while enforcing typical wind turbine design constraints such as tip speed ratio, solidity, and blade prole. Byxing the tip speed ratio and solidity of the wind turbine, there exists an airfoil cross-section for which the torque can be maximized, requiring the development of an iterative design system. The design system required to maximize torque incorporates rapid geometry generation and automated hybrid mesh generation tools with viscous, unsteady computational uid dynamics (CFD) simulation software. The exibility and automation of the modular design and simulation system allows for it to easily be coupled with a parallel dierential evolution algorithm used to obtain an optimized blade design that maximizes the eciency of the wind turbine.},
File = {:Turbines, Cross-Flow\\Carrigan, 2010, Aerodynamic shape optimization of a VAWT, MS thesis.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.08.02}
}
@Article{Carrigan2012,
Title = {Aerodynamic Shape Optimization of a Vertical-Axis Wind Turbine Using Differential Evolution},
Author = {Travis J. Carrigan and Brian H. Dennis and Zhen X. Han and Bo P. Wang},
Journal = {ISRN Renewable Energy},
Year = {2012},
Volume = {2012},
File = {:Turbines, Cross-Flow\\Carrigan et al, 2012, Aerodynamic Shape Optimization of a Vertical-Axis Wind Turbine Using Differential Evolution.pdf:PDF},
Owner = {Pete},
Timestamp = {2014.03.09}
}
@Article{Castellani2013,
Title = {A practical approach in the CFD simulation of off-shore wind farms through the actuator disc technique},
Author = {Francesco Castellani and Arne Gravdahl and Giorgio Crasto and Emanuele Piccioni and Andrea Vignaroli},
Journal = {Energy Procedia},
Year = {2013},
Pages = {274-284},
Volume = {35},
File = {:Turbines, Arrays\\Castellani et al, 2013, A practical approach in the CFD simulation of offshore wind farms through the actuator disk technique.pdf:PDF},
Owner = {Pete},
Timestamp = {2013.10.12}
}
@Article{Castellani2013b,
Title = {An application of the actuator disc model for wind turbine wakes calculations},
Author = {Francesco Castellani and Andrea Vignaroli},
Journal = {Applied Energy},
Year = {2013},
Pages = {432-440},
Volume = {101},
File = {:Turbines, Wakes\\Castellani and Vignaroli, 2013, An application of the actuator disc model for wind turbine wakes calculations.pdf:PDF},