Abstract:
An adjustable lift regulating device ( 30, 32, 40, 50, 52, 56, 60, 68, 72, 76 ) on an inboard portion of a wind turbine blade ( 28 ). The lift regulating device is activated to reduce lift on the inboard portion of the blade by causing flow separation ( 41 ) on the suction side ( 22 ) of the blade. To compensate for the lost lift, the blade pitch is increased to a running pitch that facilitates stalling on the outer portion of the blade in gusts. This provides passive reduction of fatigue and extreme loads from gusts while allowing full power production under non-gust conditions.

Description:
[0001]    This application is a continuation-in-part of U.S. patent application Ser. No. 14/164,879 filed on 27 Jan. 2014 (attorney docket 2013P25541 US) and international patent application number PCT/US2013/064060 filed on 9 Oct. 2013 (attorney docket 2013P09700US), both of which are incorporated herein by reference. 
     
    
     FIELD OF THE INVENTION 
       [0002]    This invention relates generally to the field of wind turbines, and more specifically to methods and apparatus for reducing cyclic fatigue and extreme loads on wind turbine blades. 
       BACKGROUND OF THE INVENTION 
       [0003]    Wind turbines can encounter excess wind speeds beyond their structural design capacity or beyond what is needed for maximum rated power output. The “rated wind speed” of a wind turbine is the lowest wind speed at which it produces power at its rated capacity. Damaging blade loads can be sustained above this rated wind speed in what is called the ‘post-rated’ regime, typically 12-25 m/s or 15-20 m/s for example, depending on the turbine. To maximize efficiency before reaching rated power and to regulate power to a fixed level above rated wind speed, the turbine varies the blade pitch depending on torque/power output. Beyond the safe operating wind speed, the blades are feathered, and the rotor may be stopped or idled. 
         [0004]    To maintain power production in the post-rated wind speed regime, the blade is pitched progressively towards feather with increasing wind speed. As a result, the outboard parts of the blade may have a near zero or negative angle of attack, at which they are at or near idle or are in a negative lift or “braking” state. In such conditions, most or all of the rotor torque is generated by inboard parts of the blade ( FIG. 1 ). 
         [0005]    When operating at rated wind speed or less, the blade pitch is set for an angle of attack that maximizes power production and is associated with lift being generated at all blade radial positions. A sudden gust increases the angle of attack to a stall condition that reduces lift temporarily, thus protecting the blade from lift overloads and rapid load changes. However in the post-rated wind configuration with zero or negative angle of attack on parts of the blade, this natural load alleviation mechanism is reduced because the outboard blade sections are operating far from stall. In this configuration, a gust initially increases the angle of attack toward maximum lift, causing a large and rapid load increase on the outer portion of the blade, leading to higher amplitude fatigue load cycles.  FIG. 2  illustrates that a relatively small increase in lift coefficient  25  causes stalling in normal operation compared to a larger increase  26  needed to stall at a low angle of attack as conventionally used in high winds. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0006]    The invention is explained in the following description in view of the drawings that show: 
           [0007]      FIG. 1  illustrates the relative density of power conversion by radius on a conventional wind turbine blade as a function of wind speed. 
           [0008]      FIG. 2  illustrates the lift coefficient of a conventional wind turbine blade as a function of angle of attack. 
           [0009]      FIG. 3  is a suction side view of a wind turbine blade with lift regulating devices on an inboard portion of the blade. 
           [0010]      FIG. 4  is a transverse sectional profile of a wind turbine blade airfoil with a suction side spoiler. 
           [0011]      FIG. 5  is a system chart showing a control unit that activates a lift regulator responsive to a wind condition. 
           [0012]      FIG. 6  shows a spoiler extending linearly from a suction side inboard portion of a wind turbine blade. 
           [0013]      FIG. 7  shows a leading edge shell pivoting from the bottom edge thereof to cause flow separation on the suction side of the blade. 
           [0014]      FIG. 8  shows a leading edge shell pivoting from the top edge thereof to cause flow separation on the suction side of the blade. 
           [0015]      FIG. 9  shows a leading edge shell pivoting from an outboard end thereof to cause flow separation on the suction side of the blade. 
           [0016]      FIG. 10  shows a sliding front section of the blade that slides upward causing flow separation on the suction side of the blade. 
           [0017]      FIG. 11  is a suction side view of a row of vortex generators configured to enhance lift. 
           [0018]      FIG. 12  shows the vortex generators of  FIG. 11  rotated into a spoiler position. 
           [0019]      FIG. 13  shows the row of vortex generators of  FIG. 11  rotated perpendicular to the airflow in the spoiler position along an inboard portion of the blade. 
           [0020]      FIG. 14  shows a tube that transfers air from the pressure side to the suction side, ejecting a jet on the suction side that causes flow separation there. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0021]    The inventors devised a method for reducing fatigue and extreme loads on a wind turbine in strong gusty winds by 1) increasing airflow separation on an inboard part of the blades, thus reducing lift during a steady state airflow; 2) increasing blade, pitch to restore the reduced lift during the steady state airflow, thus moving the angle of attack closer to the point of maximum lift and enhancing a stall response to gusts on the outboard portion of the blades. This allows the outboard blade portion to safely provide power in high winds, because it stalls in gusts that increase the angle of attack beyond its stall angle, thus unloading it. The angle of attack of an operating wind turbine blade is a function of the pitch angle of the blade, the rotational speed of the turbine, and the wind speed. When the wind speed increases as a result of a gust of wind, the angle of attack increases. A lift regulating device (or lift regulator) other than pitch is installed on the inboard blade portion, and is activated to reduce lift responsive to wind condition indicators such as wind speed and variability, blade pitch, and blade loading. After or during activating the lift regulator, the blade pitch is increased to restore the lift, thus increasing the angle of attack, and making the stall response more rapid because the blade is operating closer to the stall point on the outboard sections than it would operate without activation of the lift regulator. A gust that increases the angle of attack is more quickly unloaded because stall occurs sooner than in the prior art position. This reduces fatigue and extreme loads, especially when operating beyond rated wind speed. The method is enabled by various embodiments of the lift regulation device herein. Any embodiment may be activated in proportion to the wind condition. The lift regulating device may be a slow-acting device, thus minimizing activation stress and actuator power requirements. Alternately, activation of the lift regulating device may be delayed so as to take at least 5 or 10 times longer than the pitch response to avoid feedback between the two. Alternately, activation may be delayed by at least 5 or more seconds. 
         [0022]      FIG. 1  shows the relative density of power conversion along a blade radius as a function and wind speed. Contours illustrating low, medium, high, and highest power densities are shown. The highest power density in high winds occurs along the inboard 10-50% of the blade as shown by dashed lines in this example. In high winds the outboard portion of the blade is feathered to near zero or negative pitch. It experiences high load changes when gusts suddenly increase the angle of attack toward maximum lift. The inventors recognized that if the inboard power is reduced, the blade pitch can be increased to move the outboard portion away from the feathered position and to cause stalls on the outer blade in gusts that increase the angle of attack. 
         [0023]      FIG. 2  shows the lift coefficient of a wind turbine blade as a function of angle of attack. Gusts can quickly and repeatedly increase both the wind speed and angle of attack. Cyclic fatigue and extreme stresses are avoided during normal operation with a normal running pitch because a gust causes a stall after a small increase in lift  25 . During post-rated (high wind) operation, the angle of attack is reduced to a first post-rated or more feathered pitch to reduce lift. However, this enables a greater increase in lift  26  before stall occurs, which causes frequent peaks and valleys in aerodynamic loads, causing fatigue. The method and apparatus herein increases the angle of attack to a second post-rated pitch greater than the first post-rated pitch during post-rated operation, thus protecting the blade from cyclic stress via a rapid stall response during gusts. 
         [0024]      FIG. 3  shows a suction side  22  of a wind turbine blade  28  with one or more lift regulating devices  30 ,  32  along one or more inboard portions of the blade, such as along the inboard 20% to 50% of the blade in some embodiments. A pitch controller  33  operates as described herein. The outboard portion of the blade, for example the outboard 50% to 80% in some embodiments, may be without such lift regulators. 
         [0025]      FIG. 4  shows a transverse sectional profile of a wind turbine blade  28  with a pressure side  35  and a suction side  22 . A chord line Ch spans between the leading edge LE and the trailing edge TE. The length of the chord line Ch is the airfoil chord length. Vector Vw represents the wind velocity outside the influence of the rotor. An axial free-stream vector Va represents the axial component of the air inflow at the blade  20  after reduction of the wind velocity Vw by an axial induction factor as known in the art. “Axial” herein means parallel with the turbine rotor axis (not shown). Combining Vs with a tangential velocity component Vt gives a relative wind vector  36  at an angle φ relative to the rotation plane  38  of the rotor. The angle of attack AoA is the angle between the relative wind vector  36  and the chord line Ch. The absolute pitch angle θ is the angle between the chord line Ch and the rotation plane  38 . Positive pitch (+) and positive angle of attack (+) are clockwise in this view, so increasing pitch by rotation of the leading edge LE toward the suction side  22 , increases the angle of attack AoA. The lift vector L is perpendicular to the relative inflow vector  36 . The drag vector D is directed aft parallel to the relative wind vector  36 . The resultant load vector R of lift and drag is shown. 
         [0026]    An inboard lift regulator may be embodied as a suction side spoiler  40  that causes flow separation  41  when deployed. The spoiler may be a hinged plate as shown, and may be actuated by known means such as hydraulics or electric motors. Flow separation reduces  41  lift. 
         [0027]      FIG. 5  shows a system with a control logic unit  44  and exemplary inputs of wind speed  45 , blade pitch  46 , and rotor speed  47 , which may be used to analyze wind conditions and compare them to one or more limits that determine when to activate a lift regulator. For example, the lift regulator may be activated when the wind reaches or exceeds a predetermined condition such as a combination of wind speed and variability. Wind variability may be derived for example from instantaneous changes in wind speed or by derived metrics such as statistical variance, or higher order wind speed derivatives. Alternately, secondary indicators of the wind condition may be used such as aerodynamic loading, rotor speed, or a minimum blade pitch when pitch is reduced in high winds. 
         [0028]      FIG. 6  shows a lift regulator embodied as a suction side spoiler  50  that extends linearly along the suction side  22  on an inboard portion of the blade, and causes flow separation  41  when deployed. 
         [0029]      FIG. 7  shows a lift regulator embodied as a leading edge shell  52  hinged along a bottom edge  53  thereof below the blade leading edge LE. It has a distal edge  54  that extends forward and outward from the airfoil to a deployed position above the leading edge LE. This configuration causes reliable flow separation  41  all along the suction side  22 . In the retracted position, the shell may be flush with the airfoil. It can optionally wrap far enough around the leading edge to serve as a replaceable shield against damage from hail and bird strikes. This can be done by placing the hinge point  53  below a stagnation zone  55  of the impinging relative wind  36 . 
         [0030]      FIG. 8  shows a lift regulator embodied as a leading edge shell  56  hinged along a top edge  57  thereof above the blade leading edge LE. It has a distal edge  58  that separates from below the leading edge, and pivots upward to a deployed position forward of and above the leading edge LE. This configuration causes reliable flow separation  41  all along the suction side  22 . 
         [0031]      FIG. 9  shows a lift regulator embodied as a leading edge shell  60  with a radially inboard end  61 , a lower edge  62 , an upper edge  63 , and a radially outboard end  64 . The outboard end may pivot on an axis  63  that separates the inboard end  62  from the leading edge LE This provides a gradient of lift reduction—greater reduction at the inboard end and less reduction at the outboard end of the shell  60 . An actuator  66  such as a hydraulic piston may be close to the rotor hub for short hydraulic lines. The upper edge  63  may deploy to a position forward and above the leading edge LE. The lower edge  62  may deploy to a position below the leading edge LE of the blade and aft of the upper edge  63  of the shell. This configuration causes reliable flow separation all along the suction side  22  proportional to the degree of separation of the shell  60  from the leading edge. 
         [0032]      FIG. 10  shows a lift regulator embodied as a sliding front section  68  of the blade  28 , that slides upward to extend above the suction side  22 , and retracts flush with the blade airfoil. The lower edge  69  of the sliding section may retract to a position below the leading edge LE. The upper edge  70  of the sliding section may extend above the suction side  22 . This configuration causes reliable flow separation  41  all along the suction side  22 . 
         [0033]      FIG. 11  shows a lift regulator embodied as a row of vortex generators  72  that are rotatable between a lift enhancing and/or separation delay configuration and a spoiler configuration. In the lift enhancing position of  FIG. 11 , they create vortices that pull free stream energy into the boundary layer. This reduces flow separation on the suction side  22  of the blade  28  as known in the art, increasing lift.  FIG. 12  shows the vortex generators  72  rotated into a spoiler position perpendicular to the airflow  74 , which causes flow separation. Rotation may be done by actuators such as piezoelectric, electric motor, pneumatics or hydraulics.  FIG. 13  shows the row of vortex generators perpendicular to the airflow in the spoiler position along an inboard portion of the blade. 
         [0034]      FIG. 14  shows a lift regulator embodied as a tube  76  that transfers air from the pressure side  35  to the suction side  22 , ejecting an air jet  77  on the suction side when a valve  78  is opened. The tube may start at or near the highest pressure point on the pressure side. 
         [0035]    The method and apparatus herein enable longer blade designs by reducing cyclic fatigue and extreme loads, which may enable larger rotors to be placed on the same nacelle/drivetrain. Longer blades provide higher annual energy production. The invention also reduces wear on the blade pitch system by eliminating the need for continuous fast pitch responses in high winds. The increased angle of attack causes local stalling that unloads each gust without the need for a fast mechanical response. 
         [0036]    While various embodiments of the present invention have been shown and described herein, it will be obvious that such embodiments are provided by way of example only. Numerous variations, changes and substitutions may be made without departing from the invention herein. Accordingly, it is intended that the invention be limited only by the spirit and scope of the appended claims.