A. C. Hansen scite author profile

AeroDyn is a set of routines used in conjunction with an aeroelastic simulation code to predict the aerodynamics of horizontal axis wind turbines. These subroutines provide several different models whose theoretical bases are described in this manual. AeroDyn contains two models for calculating the effect of wind turbine wakes: the blade element momentum theory and the generalized dynamic-wake theory. Blade element momentum theory is the classical standard used by many wind turbine designers and generalized dynamic wake theory is a more recent model useful for modeling skewed and unsteady wake dynamics. When using the blade element momentum theory, various corrections are available for the user, such as incorporating the aerodynamic effects of tip losses, hub losses, and skewed wakes. With the generalized dynamic wake, all of these effects are automatically included. Both of these methods are used to calculate the axial induced velocities from the wake in the rotor plane. The user also has the option of calculating the rotational induced velocity. In addition, AeroDyn contains an important model for dynamic stall based on the semi-empirical Beddoes-Leishman model. This model is particularly important for yawed wind turbines. Another aerodynamic model in AeroDyn is a tower shadow model based on potential flow around a cylinder and an expanding wake. Finally, AeroDyn has the ability to read several different formats of wind input, including single-point hub-height wind files or multiple-point turbulent winds.

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Yaw dynamics of horizontal axis wind turbines

Hansen¹

1992

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Prediction of Wind Turbine Rotor Loads Using the Beddoes-Leishman Model for Dynamic Stall

Pierce

Hansen

1995

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The Beddoes-Leishman model for unsteady aerodynamics and dynamic stall has recently been implemented in YawDyn, a rotor analysis code developed at the University of Utah for the study of yaw loads and motions of horizontal axis wind turbines. This paper presents results obtained from validation efforts for the Beddoes model. Comparisons of predicted aerodynamic force coefficients with wind tunnel data and data from the combined experiment rotor are presented. Also, yaw motion comparisons with the combined experiment rotor are presented. In general the comparisons with the measured data are good, indicating that the model is appropriate for the conditions encountered by wind turbines.

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WindPACT Turbine Rotor Design Study: June 2000--June 2002 (Revised)

Malcolm¹,

Hansen²

2006

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Table 3-1. Summary of Cost Models Used for Major Components in Baseline Designs 6 th row, first column should read-Pitch bearings Not used for final costing 7 th row, first column should read-Pitch bearings (Tasks #2, #3, #5) 7 th row, fourth column should read-See text 12 th row, second column should read-Bearing mass = (D x 8/600-0.033) x 0.00920 x D^2 .5 Where D = rotor diam (m) 12 th row, third column, delete "U of Sunderland [6] and" Page 14 Table 3-1 Continued 13 th row, second column should read $/kW = 3.38E-7 * Rating 2 + 9.84E-4 * Rating + 31.57

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Validation of the AeroDyn Subroutines Using NREL Unsteady Aerodynamics Experiment Data

Laino

Hansen

Minnema

2002

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Completion of the full-scale wind tunnel tests of the NREL Unsteady Aerodynamics Experiment (UAE) Phase VI allowed validation of the AeroDyn wind tuxbine aerodynamics software to commence. Detailed knowledge of the inflow to the UAE was the bane of prior attempts to accomplish any in-depth validation in the past. The wind tunnel tests permitted unprecedented control and measurement of inflow to the UAE rotor. The data collected from these UAE tests are currently under investigation as part of an effort to better understand wind turbine rotor aerodynamics in order to improve aero-elastic modeling techniques. Preliminary results from this study using the AeroDyn subroutines are presented, pointing to several avenues toward improvement. Test data indicate that rotational effects cause more static stall delay over a larger portion of the blades than predicted by current methods. Despite the relatively stiff properties of the UAE, vibration modes appear to influence the aerodynamic forces and system loads. AeroDyn adequately predicts dynamic stall hysteresis loops when appropriate steady, 2-D airfoil tables are used. Problems encountered include uncertainties in converting measured inflow angle to angle of attack for the UAE phase VI. Future work is proposed to address this angle of attack problem and to analyze a slightly more complex dynamics model that incorporates some of the structural vibration modes evident in the test data.

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A. C. Hansen

AeroDyn Theory Manual

Yaw dynamics of horizontal axis wind turbines

Prediction of Wind Turbine Rotor Loads Using the Beddoes-Leishman Model for Dynamic Stall

WindPACT Turbine Rotor Design Study: June 2000--June 2002 (Revised)

Validation of the AeroDyn Subroutines Using NREL Unsteady Aerodynamics Experiment Data

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