• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    This invention relates to a wind turbine having an additional mass each placed between a mounting end and a free end of at least two rotor blades.
    公开号:DK201270416A
    申请号:DKP201270416
    申请日:2012-07-09
    公开日:2013-05-05
    发明作者:Birk Jens
    申请人:Envision Energy Denmark Aps;
    IPC主号:
    专利说明:

    Wind Turbine with Additional Rotor Moment of Inertia Field of the Invention
    This invention relates to a partial-pitch wind turbine comprising: - a wind turbine tower with an upper end and a lower end, which lower end is provided on a wind turbine foundation; - a wind turbine nacelle provided at an upper end of said tower; - a hub provided at said nacelle; - at least two wind turbine rotor blades each with a blade weight and a blade length of at least 35 meters between a mounting end and a free end, which mounting end is mounted on the hub for rotation in a rotational plane around an axis that is extended by shaft coupled to a generator or a gearbox; - grid connection for feeding produced electricity from the generator to a grid, which grid connection has voltage detection means for detecting changes in the voltage on the grid; - a mass each placed between the mounting end and the free end of at least two rotor blades.
    Background of the Invention
    In electric power generation and particularly in the field of electric power generation by wind turbines, the electric power generation as a unit is required to interact or interface with a grid. This also means that the electric power generator is, and this is defined, required, requested or otherwise determined mainly by regulations, that the electric power generator is capable of adjusting or responding to the changes on the grid.
    In general, the grid is defined as a transmission network that interconnects sources of electric power generators and sinks of electric power consumptions. The number of power sources, such as power stations, is often outnumbered by the number of power sinks, being individual households, commercial or industrial enterprises, public facilities or utilities.
    In principle, a grid can also be a so-called stand-alone system with only one electric power generator as the source and just one electric power consuming unit as a sink.
    Hence an electric power generator is a single unit that interacts with other sources or sinks also connected to the same grid.
    The grid code sets requirements for grid connections of producers e.g. wind turbines for how to react to certain events on the grid.
    As such the interaction between a power producing unit, or for that matter a power drawer unit, i.e. the connectors and the grid operator, is determined by a code determining and defining the grid. This code is the grid code.
    Of technical importance are the voltage on the grid side and the voltage on the connectors side.
    When the voltage on the grid side is normal, a wind turbine connected to the grid is designed to operate and be connected to the grid within a certain voltage range of the normal voltage condition. That is, the wind turbine will rotate at a certain speed and be controlled to generate power within the range of the normal voltage conditions.
    However, at times there is change of voltage on the grid. One such event is a so-called Low Voltage (LV) event. During such LV event the wind turbine needs to be able to respond and act to stay connected to the grid.
    Left uncontrolled, an LV event will result in the rotor increasing its rotational speed; two over speed.
    One way to reduce or eliminate the effect of an LV event is to reduce the rotational speed of the rotor of the wind turbine to reduce or eliminate the over speed.
    One solution is to mechanically brake the rotor to avoid over speed.
    Another solution is to have an electric power generator system that includes a brake chopper, which brake chopper will simply bum energy into a dump, such as a resistor, thereby reducing the rotational speed of the rotor.
    Brake choppers are know from patent applications, such as US 2007/0279815, in which a brake chopper for de-energizing the generator in the wind turbine is disclosed.
    Another example is disclosed in patent application WO 2010/085988, in which a method for allowing a wind turbine to remain electrically connected to a grid during a low voltage event is described. The method described relies on boosting a rotor current of the synchronous generator in response to the detected low voltage event.
    The electrical brake system disclosed adds complexity and thereby requires extra resources during the production and operation of the wind turbine.
    Furthermore, the requirements of larger wind turbines increase the need for larger brake systems. A person skilled in the art of making blades for a wind turbine has traditionally been occupied with making the blade lighter and stronger, whilst having the required flexibility. As the desire for making wind turbines even bigger, the need for blades, which are even lighter, continues.
    To such a skilled person in the art, the optimal or ideal blade for a wind turbine is considered a shell and optimally just a skin shell forming a surface with the desired aerodynamic properties and structural stability.
    Likewise, the designer and producer of wind turbines will ideally ask for such ideal blades.
    Over time blades for wind turbines have developed from being made of wood and with solid profiles, over blades made of glass fibers with hollow profiles towards carbon fiber blade structures.
    Over the same time development systems and controls for operating a wind turbine with such optimized blades have been developed. Efforts to compensate for abnormal operation, including emergency operation, have been devised as add-ons systems, elements usually placed in the hub, the tower or on the foundation or even adjacent from the wind turbine.
    Object of the Invention
    An object of this invention is to disclose a wind turbine and configuration of such a wind turbine that eliminates the need for a brake chopper.
    Another object of this invention is to disclose a method for operating a wind turbine without a brake chopper during a fault on the grid. A further object of this invention is to disclose a wind turbine and / or a method for operating such a wind turbine which will require a brake chopper or a reduced size brake system.
    Description of the Invention
    An object of the invention is achieved by a partial-pitch wind turbine comprising: - a wind turbine tower with an upper end and a lower end, which lower end is provided on a wind turbine foundation; - a wind turbine nacelle provided at an upper end of said tower; - a hub provided at said nacelle; - at least two wind turbine rotor blades each with a blade weight and a blade length of at least 35 meters between a mounting end and a free end, which mounting end is mounted on the hub for rotation in a rotational plane around an axis that is extended by shaft coupled to a generator; - grid connection for feeding produced electricity from the generator to a grid, which grid connections has voltage detection means for detecting changes in the voltage on the grid; - at least two masses each placed between the mounting end and the free end of at least two rotor blades and where each mass is between 10% and 40% of blade weight of each rotor blade.
    Thereby the masses will increase the inertia of the rotor as compared to a rotor without the additional masses. During a low voltage event the grid will not provide normal resistance or brake to the rotor via the generator and without the extra inertia, the rotor would start to rotate with a higher rotational speed, it will over speed, and possibly get out of control or to cause damage to components in the wind turbine.
    According to this invention, the increased inertia of the rotor will reduce the rotational speed increase and reduce or even prevent such over speed.
    As a consequence and compared to prior art, where wind turbines use blades designed to be as light as possible and grid faults are handled by a brake chopper, a turbine according to the invention is a wind turbine where the brake chopper is redundant and consequently a wind turbine can be produced with fewer elements at lower costs during production as well as operation.
    This is contrary to prior art where a brake is used to increase the torque on the shaft, the de-rating according to the invention is due to the increased inertia of the blades.
    As such, a partial-pitch wind turbine disclaiming a brake system or a brake chopper is disclosed.
    It is understood that the masses can be placed as a continuum or discretely on each blade but balanced, so that the center of gravity in the rotational plane co-insides with the axis of the rotor. It does not introduce any loads on the turbine during rotation.
    In principle an additional mass can be added as a continuum on one blade and as discrete masses on another blade.
    In the case of discrete masses the inertia is determined as the sum of each mass multiplied by the squared radial distance from the axis. For a rotor with V symmetrically angular spaced blades and i-additional masses m, placed at an radius; the additional rotor moment of inertia Im is
    Generally the summation is replaced in the continuum by integration.
    According to an embodiment of the invention, the wind turbine is special in the masses placed with a center of gravity that, when projected onto the rotational plane coincides with the axis.
    The rotor is balanced and no mechanical loads are on the wind turbine. The person skilled in the art will be able to distribute masses according to hereto.
    It is noted that according to the invention, the wind turbine is special in that each mass is between 10% and 40% of blade weight of each rotor blade.
    Thereby the masses allow for an adjustment of the moment of inertia of the rotor according to an LV event according to a particular grid code.
    According to an embodiment, the blade is configured to receive a variable mass, so that the moment of inertia of the rotor can be varied and matched to handle LV events according to different grid codes.
    In cases where the grid code defines LV events that are smaller will require larger moments of inertia.
    It is understood that any mass increase of each blade would otherwise have been unnecessary.
    According to an embodiment of the blade, the blade means for receiving such additional masses.
    According to an embodiment of the invention, the wind turbine is special in that each mass radial extends no more than 10% of the blade length of each rotor blade, preferably no more than 5%.
    Thereby each blade can have discrete masses installed and positioned in the blade.
    According to an embodiment of the invention, each wind turbine blade has means for positioning, adjusting and / or fixing a mass radially in the blade. Complementary, each mass has means for positioning, adjusting and / or fixing the mass in a blade.
    According to an embodiment of the invention, each blade has sections adapted to be closed sealed and filled with a mass that can be a fluid, such as water, antifreeze liquid or particles, such as sand or metal pieces. Complementary, each mass is a fluid such as water, antifreeze liquid or oil. Likewise each mass is lots of particles, such as sand or metal pieces, such as lead balls.
    According to an embodiment of the invention, the wind turbine is special in that the rotor blade has an inner blade section and an outer blade section separated by a pitching system, which is located between the mounting end and the free end and configured to pitch said outer blade section relative to said inner blade section, which pitching system has a weight and radial extend no more than the weight and radial extend of a mass.
    Such pitching system includes a pitch bearing.
    As such an embodiment of the invention is a wind turbine with two partial pitch blades without a brake chopper.
    According to an embodiment of the invention, the wind turbine is special in that further to the pitching system; at least an additional sub-mass is placed in the blade to constitute a total mass.
    Thereby a pitching system can be installed as required and supplementary or additional masses, here termed sub-masses, can be installed as disclosed. This results in a moment of inertia of the rotor as required thereby enabling the wind turbine to handle a low voltage event without damaging over speed.
    According to an embodiment of the invention, the wind turbine is special in that the wind turbine further comprises a dynamic brake, such as an electric brake chopper.
    Thereby the wind turbine has additional means to handle a low voltage event.
    In addition, the wind turbine can have standard means of protection, control and procedures, but with smaller elements such as the dump resistor and auxiliary brake chopper components.
    An object of the invention is achieved according to a method for controlling a wind turbine with a pitch system for pitching a blade at a pitch angle and with blades with an additional mass for increased inertia, which wind turbine is operated in a normal operation mode in which generator has a generator speed at a generator torque, and which wind turbine is to remain electrically coupled to a grid during a low voltage condition and with supplied current specifications, torque reference, power reference or according to a grid code; The method comprises the steps of: - detecting a low voltage condition with voltage detection means, which voltage detection means after detecting a low voltage condition send a request for: - a rotor de-rate procedure in a wind turbine controller; which de-rate procedure includes: - LVRT pitching the rotor blades to an LVRT pitch angle; - detecting a normal voltage condition with voltage detection means, which normal voltage condition is within a voltage range of the normal voltage condition; which voltage detection means after detecting a normal voltage condition send a request for: - normal operation mode of the wind turbine; which normal operation mode has an initial phase where: - the generator torque is increased to a desired torque reference, and - pitching the rotor blades from the LVRT pitch angle to a normal or freely controlled pitch angle.
    By de-rating the rotor it is understood that the rotor speed is reduced to avid over speed. If such a de-rating is the accelerate, decrease the rotor speed and in particular to avoid over speed.
    Contrary to prior art where a brake is used to increase the torque on the shaft, the derating according to the invention is due to the increased inertia of the blades.
    The LYRT method prevents the rotor blades of the wind turbine from over speed during the low voltage condition. This allows the generator of the wind turbine to remain connected to the grid during a low voltage condition.
    As a consequence and compared to prior art, where wind turbines use that blades are designed to be as light as possible and grid faults are handled by a brake chopper, a turbine according to the invention is a wind turbine where the brake chopper is redundant, and consequently a wind turbine can be produced with fewer elements at lower costs during production as well as operation.
    According to an embodiment of the invention, a method for controlling a wind turbine is special in that it includes a step where the LVRT pitching of the rotor blades to an LVRT pitch angle is performed at a speed of between 2 to 10 deg / sec , and preferably at a speed of 5 deg / sec; during which initial period the generator speed will increase about 10 - 20% and a maximum of 30%; and thereafter start to decrease.
    Thereby the wind turbine will be able to operate in a controlled way and without large mechanical loads in such a way that the rotor speed will de-rate or decrease speed. In this embodiment, the rotor speed will de-rate without the forces from a brake system or a brake chopper.
    According to an embodiment of the invention, a method for controlling a wind turbine is special in that it includes a step where the control of supply of active and reactive currents in the generator is regulated according to supplied current specifications, torque references, power references , or from a grid code.
    In addition, the wind turbine will be able to operate according to grid codes and in particular a specific grid code.
    One such specific grid code is the E.ON. Network, Grid Code; High and Extra High Voltage (2006) by E.ON. Network GmH, Bayreuth.
    It is understood that a person skilled in the art adjusts the settings to meet the standards given by design and specifications in such grid codes which are hereby incorporated by reference.
    In particular the person skilled in the art is drawn to sections regarding requirements for active and reactive power. For the E.ON. grid code this could be section 3.2.4 and for faults on the grid section 3.2.6.2 but not limited hereto.
    According to an embodiment of the invention, a method for controlling a wind turbine is special in that it includes a step where the detection of a normal voltage condition with voltage detection means is when said normal voltage condition is within a voltage range of the normal voltage condition. The normal voltage condition can be determined as being between a Low Voltage threshold and a High Voltage threshold.
    Thereby a normal voltage condition can be determined. Furthermore, the normal condition can be adjusted according to requirements of a different grid code or different sections or requirement of a particular grid code.
    The normal voltage condition, and the abnormal voltage condition such as a low voltage event, is determined by the RMS or a Positive Sequence of the voltage.
    Similarly, a normal or abnormal voltage condition can be detected by voltage condition means that measure gradients, spikes or other abnormal voltage events, such as drift and phase changes.
    The voltage condition means can be based on either or combinations of one, two, or three phase detection.
    According to an embodiment of the invention, a method for controlling a wind turbine is special in that it includes a step, whereby the voltage detection means after detecting a normal voltage condition send a request for pitching the rotor blades from the LVRT pitch angle to a normal or freely controlled pitch angle and preferably at a pitch speed of less than 5 deg / sec.
    Thereby the wind turbine is regulated back to normal operation without undue mechanical loads on the wind turbine.
    By normal or freely controlled pitch angle control it is understood that the LVRT or fault control or procedures are not controlling the wind turbine. It is understood that other normal controls, main controls or power optimization, load minimizing controls do control the wind turbine.
    Description of the Drawing
    The invention will be described in relation to the drawings and figures, FIG. 1 shows a slim designed three bladed wind turbine; FIG. 2 shows a cleverly designed two bladed wind turbine; FIG. 3 shows a graph of a low voltage event with voltage against time; FIG. 4 shows a two bladed wind turbine with loads placed at different distances from the axle or rotational shaft; FIG. 5 shows a two bladed partial pitch wind turbine with masses placed as the pitching system; FIG. 6 shows a schematic diagram of components connecting the wind turbine structure with the grid; FIG. 7 shows a connection or enabling sequence and a disconnecting or disabling sequence; FIG. 8 shows a schematic flow diagram for action braking torque; and FIG. 9 shows a schematic flow chart for handling a LVRT in Prior Art and for handling a LVRT, according to the invention.
    Detailed Description of the Invention


    Figure 1 shows a general wind turbine 100. The wind turbine 100 has a tower 101 which is configured to raise from a foundation 102 and which tower 101 has a nacelle 103 mounted. The wind turbine 101 has a rotor 104 with at least one blade 105, in this case three blades 105 ', 105 ", 105"'. The rotor 104 includes the blades 105 mounted in a hub 106, so that the rotor 104 can rotate and circumscribe a rotor circle 107 with a rotor radius equivalent to blade lengths 108.
    Each blade 105 has a mounted end 109 or an inner end for mounting the blade 105 at the hub 105 and opposite a free end 109 or outer end.
    Each blade has a blade weight 111. The sum of the blade weights 111 ', 111 ", ... add up to a rotor weight 112.
    The rotor 103 rotates in a rotational plane 113 around an axis 114, which is extended in a shaft 115 (not shown in this figure) connected to a generator 116 (not shown in this figure). FIG. 2 shows a slim designed two bladed (105 ', 105 ") wind turbine (100) with references from Fig. 1.
    Figure 3 shows a graph of examples of fault events where the voltage is plotted against time.
    There is an example of a low voltage drive through (LVRT) event 301 and an example of a high voltage drive through (HVRT) event 302. The LVRT event 301 and the HVRT event 302 separate a normal voltage event 303 defined as +/- a certain percent from a normal voltage 304 indicated as 100%. The onset time T0 is where the LVRT event 301 or the HVRT event 302 begins. The end time Ti is the end of both events and shown here for the LVRT event 301.
    The LVRT event 301 ends when the voltage is within the normal voltage range.
    The low voltage (LV) threshold 305 is here 15% of the normal voltage 304, and the high voltage (HV) threshold 306 is here 120% of the normal voltage 304. FIG. 4 shows a two bladed 105 wind turbine 100 with masses 400, placed at different distances or radii, R 401 from axis 114. These masses are distinct masses 400 and additional masses that would not be from a purely aerodynamic and mechanical load point of views there. These masses 400 do technically contribute to increase the moment of inertia 403 of the rotor 104.
    In this embodiment a first mass 400 'is placed at first radii 40Γ. A second mass 400 "is placed at second radius 401". A third mass 400 "" is placed at third radius 401 "". Likewise more masses 400 or sub-masses 400 'can be placed at different radii, and at different intervals D 402, individually contributing to the moment of inertia 403 of the rotor 104.
    It is understood that there are means for holding each mass 400 at a particular position on each blade 105. Furthermore, there can be means for adjusting the position of the center of gravity of each mass 400 thereby adjusting the radii 401, so that the masses 400 on each blade 105 can be balanced so that rotor 104 has a center of gravity of masses 400 in its projection onto rotational plane of rotor 104 which coincides with axis 114.
    It is further understood that if the blades 105 ', 105 "differ and have an off-axis center of gravity, then the masses 400 can be distributed on the blades 105', 105" to balance or re-balance, so that the center of gravity of the blades 105 ', 105 "and the masses 400', 400", ... have a projection onto the rotational plane of the rotor 104 which coincides with the axis 114. FIG. 5 shows a two bladed partial pitch wind turbine 500 with masses 400 according to the invention and Figure 4. Each mass 400 includes at least the pitching system 501, but can be extended by additional sub-masses 400 'to ad up to a mass 400 A blade 105 on a partial pitch wind turbine 500 comprises an inner blade section 105a towards the hub 106 and an outer blade section 105b towards the outer end 110.
    The inner blade section 105a and outer blade section 105b are partitioned by the pitching system 501. On the two bladed partial pitch wind turbine 500 shown in this embodiment, each blade 105 ', 105 "has an inner blade section 105'a, 105 "a and an outer blade section 105'b, 105" b divided by a partial pitching system 50Γ, 501 ".
    Each outer blade section 105b can rotate relative to the inner blade section 105a by the pitching system 501; that is to pitch in a pitching angle 502.
    The pitching angle 502 can have a normal pitching angle 503, which is variable according to the actual control of the blade 105 and the control of the wind turbine 100. As such the normal pitching angle 503 is a result of operating the pitch wind turbine in a normal operation mode 504 (not shown on the figure) or state. The normal operating mode 504 is when the wind turbine 100 operates or rotates when the normal voltage event 303 is present.
    Likewise, pitching angle 502 may have an LVRT pitching angle 505, which is variable but primarily an extreme angle or a fixed angle according to the actual control of the blade 105 and the control of the wind turbine 100. As such, the LVRT pitching angle 505 is a result of operating the pitch wind turbine in an LVRT operation mode 506 (not shown on the figure) or state.
    The LVRT operation mode 506 or state is when the wind turbine 100 operates or rotates when the LVRT event 301 is present. FIG. 6 shows a schematic diagram of components connecting the wind turbine 100 structure with a grid 600.
    The grid 600 is a coupled network for transmitting power between power sources and power sinks that are interconnected and each linked to the grid by a grid connection.
    Conditions to stay connected to the gird are defined by a grid code 600 '.
    One such grid 600 with a grid code 600 'is the E.ON. Network, Grid Code; High and Extra High Voltage (2006) by E.ON. Network GmH, Bayreuth.
    Between the generator 116 of the wind turbine 100 and the grid 600 there is a grid connection 601.
    In this embodiment and from the generator 116 towards the grid 600 side there is generator connector 613, a generator side converter 610, a brake chopper 611, and a grid side connector 601 connecting the generator 116 of the wind turbine 100 to the grid 600 via appropriate cables, being AC or DC cables as required.
    In this embodiment, the generator side converter 610 is an AC / DC converter, and the grid side converter 612 is a DC / AC converter.
    In between the generator side converter 610 and the grid side converter 612 there is a brake chopper 611 or just a brake, a dynamic brake, which in the shown embodiment consists of a dump load resistor 614, which can be combined, as shown here , with capacitors and contacts / switches.
    The generator side converter 610 is controlled by a current controller 615 with input from the output of generator 116 and from torque controller 616.
    The torque controller 616 is controlled by an overall controller 617 receiving input from at least the generator 116. The overall controller 617 further controls a yaw controller 618 and a pitch controller 619. The yaw controller 618 controls the wind turbine 100 as does the pitch controller 619th
    The grid side converter 612 is controlled by a grid side current controller 612 with input from at least the grid 600 and a DC link Voltage controller 621, which again receives input from a DC comparator 622.
    In an embodiment there is further an LVRT protector 630 receiving input from the grid 600 by means of AC comparator 631. FIG. 7 shows a connection or an enable sequence 701 and a disconnecting or disable sequence 702.
    The connection sequence 701 has an initial condition step 703, where data for determining if the initial conditions are fulfilled are collected and compared. This is followed by a connect grid-side step 704, in which the grid side converter 611 is connected to the grid 600. This is followed by a charge step 705, during which capacitors 612 are charged. This is followed by a connect generator side step 706, during which the generator side converter connects to generator 116 in the wind turbine 100.
    This is followed by a regulated torque step 707, during which the torque is regulated.
    The disconnection sequence 702 has a ramp down torque step 710. This is followed by a disconnect generator side step 711, during which the generator 116 is disconnected. This is followed by a disconnect grid side step 712, during which the grid side converter 611 is disconnected from the grid 600. FIG. 8 shows a schematic flow diagram for action braking torque, a braking torque controller 801.
    This illustrates how the dynamic brake such as a brake chopper is controlled in the case when there is a dynamic brake such as a brake chopper of a reduced size as needed when there is a wind turbine the are additional masses or a rotor with an increased inertia as compared to a wind turbine with a rotor that is designed with a low or normal rotational inertia.
    The breaking torque flow diagram 801 begins with a breaking torque issued routines 802 handling the initialization and controls the state when a breaking torque command has been issued.
    This is followed by a braking torque detection and decision routines 803, which routines determine if the breaking power is less than rated output power.
    In the case of a positive answer during the breaking torque detection and decision routines 803, the breaking torque controller 801 enters a power converter handler routine 804. These routines essentially activate that the power converter handles the braking power and that the dump load resistor is not engaged.
    This is followed by a first grid status detection and decision routines 805, which routines essentially detect, receive, and / or determine the status of the grid 600. The grid status detection and decision routines 805 determine if the grid 600 is available and if the grid converter is healthy.
    In the case of a positive answer to the grid status detection and decision routines 805, the braking torque controller 801 enters a first feeding braking power routines 806. In the case of a negative answer, the braking torque controller 801 enters a first dynamic brake routines 807 .
    The first braking power routines 806 controls the feeding of braking power to the grid 600 and that the dynamic brake is disabled.
    The first dynamic brake routines 807 is enabled.
    In the case of a negative answer during the breaking torque detection and decision routines 803, the breaking torque controller 801 enters a dump load routines 810.
    The dump load routine 810 ensures that the dump load is engaged and that the power converter handles the remaining braking power.
    This is followed by second grid status detection and decision routines 811, and subordinated to a second feeding braking power routines 812, and second dynamic brake routines 813.
    In an embodiment, the first and second grid status detection and decision routines 805, 811 are identical. In another embodiment they are variants. Likewise for the first and second feeding braking power routines 806, 812 and the first and second dynamic brake routines 807, 813. FIG. 9 shows a schematic flow diagram for handling a LVRT in Prior Art and for handling a LVRT according to the invention.
    The A-part shows a simplified schematic of the Prior Art when an LVRT condition 900 is detected. The LVRT condition 900 triggers actions for the overall wind turbine control and actions for the converter.
    The actions for the over all wind turbine control include a routine that starts a rapid increase of pitch angle 901 followed by a routine that regulates pitch angle so that rotor speed does not exceed nominal speed 902.
    The action for the converter includes a routine that feeds current to the grid according to the grid code 910, followed by routines that monitor if there is excess energy from the generator 911, and that is the case routines that engage the brake chopper 912 which bums energy in the dump load resistor 614.
    The B-part shows a simplified schematic according to the invention and for direct comparison with the A-part. The routines 901, 902 for the overall wind turbine control are the same as in the Prior Art in Part A.
    Similarly, the B-part includes a routine that feeds current to the grid according to grid code 910. A distinguishing feature is that there is no need for routines 911, 912 that monitor the excess energy 911 nor the routine that engages the brake chopper 912th
    Example:
    To illustrate the effect of the invention as disclosed, three wind turbines in the 3.6 MW class are compared. All three wind turbines have a rotor diameter of 128 m (approximately a blade length of 64 m).
    The first wind turbine is a three bladed active pitch turbine as illustrated in figure 1. A blade for this type of wind turbine will have a weight of about 11,000 kg.
    The second wind turbine is a two bladed active pitch turbine as illustrated in figure 2. A blade for this type of wind turbine will have a weight of about 23,000 kg.
    The third wind turbine is a two bladed partial pitch turbine as illustrated in figure 5. This is a special embodiment of the disclosure illustrated in figure 4. A blade for this third type of wind turbine will have a weight of about 23,000 kg and a pitching system, or pitch bearing, of about 5,000 kg placed at a radius of about 20 m from the axis.

    It is clear that the rotor moment of inertia of the third type of wind turbine is larger than that of the first and second types. Therefore, the rotor of the third wind turbine type will, all things equal, not accelerate towards or to a maximum rotor speed during a grid fault, such as low voltage conditions. On this basis it has been found that a wind turbine of this third type will not need a brake chopper or any other brake system.
    As such a wind turbine with two partial pitch blades without a brake chopper has been realized according to this invention.
    Similar methods for controlling such wind turbine and without the control for the brake chopper have been realized according to this invention.
    权利要求:
    Claims (7)
    [1] 1. A partial-pitch wind turbine (500) comprising: - a wind turbine tower (101) with an upper end and a lower end, which lower end is provided on a wind turbine foundation (102); - a wind turbine nacelle (103) provided at an upper end of said tower (101); - a hub (106) provided at said nacelle (103); - at least two wind turbine rotor blades (105) each with a blade weight (111) and a blade length (108) of at least 35 metres between a mounting end (109) and a free end (110), which mounting end (109) is mounted on the hub (106) for rotation in a rotational plane (113) around an axis (114) that is extended by shaft (115) coupled to a generator (116) or a gearbox; - grid connection (601) for feeding produced electricity from the generator to a grid (600), which grid connection (601) has voltage detection means (630, 631) for detecting changes in the voltage on the grid (600); - at least two masses (400) each placed between the mounting end (109) and the free end (110) of at least two rotor blades (105’, 105”) where each mass (400) is between 10 % and 40 % of blade weight (111) of each rotor (104) blade (105).
    [2] 2. A wind turbine according to claim 1, characterised in that said masses (400) are placed with a centre of gravity that projected onto the rotational plane (113) coincides with the axis (114).
    [3] 3. A wind turbine according to claim 1 or 2, characterised in that each blade (105) is configured to receive a variable mass (400), so that the moment of inertia (403) of the rotor (104) can be varied and matched to handle LV-events according to different grid codes (600’).
    [4] 4. A wind turbine according to any of claims 1 to 3, characterised in that each mass (400) radial extends no more than 10 % of the blade length (108) of each rotor (104) blade (105), preferably no more than 5 %.
    [5] 5. A wind turbine according to any of claims 1 to 4, characterised in that the rotor blade (105) has a inner blade section (105a) and an outer blade section (105b) separated by a pitching system (501), that is located between the mounting end (109) and the free end (110) and configured to pitch said outer blade section (105b) relative to said inner blade section (105a), which pitching system (501) has a weight and radial extend no more than the weight and radial extend of a mass (400).
    [6] 6. A wind turbine according to claim 5, characterised in that further to the pitching system (501); at least an additional sub-mass (400’) is placed in the blade (105) to constitute a total mass (400).
    [7] 7. A wind turbine according to any of claims 1 to 6, characterised in that, the wind turbine (100) further comprises a dynamical brake, such as an electrical brake chopper (611).
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    同族专利:
    公开号 | 公开日
    US20130119663A1|2013-05-16|
    CN103104415B|2015-04-22|
    US8878376B2|2014-11-04|
    CA2794725A1|2013-05-04|
    DK177555B1|2013-10-07|
    EP2589798A2|2013-05-08|
    CN103104415A|2013-05-15|
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    法律状态:
    2019-06-14| PBP| Patent lapsed|Effective date: 20181104 |
    优先权:
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    DK201170605|2011-11-04|
    DKPA201170605A|DK201170605A|2011-11-04|2011-11-04|Method for Controlling a Wind Turbine with Additional Rotor Moment of Inertia and a Wind Turbine with Additional Rotor Moment of Inertia|
    DK201270416|2012-07-09|
    DKPA201270416A|DK177555B1|2011-11-04|2012-07-09|Wind Turbine with Additional Rotor Moment of Inertia|DKPA201270416A| DK177555B1|2011-11-04|2012-07-09|Wind Turbine with Additional Rotor Moment of Inertia|
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    US13/668,903| US8878376B2|2011-11-04|2012-11-05|Wind turbine with additional rotor moment of inertia and a method for controlling a wind turbine with additional rotor moment of inertia|
    CN201210437284.1A| CN103104415B|2011-11-04|2012-11-05|Wind turbine with additional rotor moment of inertia and a method for controlling a wind turbine with additional rotor moment of inertia|
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