• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    Method of control of a wind turbine. The present invention relates to a wind turbine control method that allows detecting situations in which the machine is not working at its maximum performance point, where, furthermore, once these situations are detected, the control method of the present invention allows carry out an automatic correction of the control parameters and return the wind turbine to its optimum operating point. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2563092A1
    申请号:ES201431304
    申请日:2014-09-10
    公开日:2016-03-10
    发明作者:Teresa Arlabán Gabeiras;Diego Otamendi Claramunt;José Miguel García Sayés;Alfonso Ruiz Aldama;Alberto García Barace;Óscar LUQUÍN HERMOSO DE MENDOZA;Alejandro GONZÁLEZ MURUA;Miguel Núñez Polo
    申请人:Acciona Windpower SA;
    IPC主号:
    专利说明:

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    METHOD OF CONTROL OF AN AEROGENERATOR
    D E S C R I P C I O N
    OBJECT OF THE INVENTION
    The present invention relates to a method of controlling a wind turbine that allows detecting situations in which the machine is not working at its maximum performance point.
    In addition, once these situations have been detected, the control method of the present invention allows automatic correction of the control parameters and returns the wind turbine to its optimum operating point.
    BACKGROUND OF THE INVENTION
    Nowadays, the use of renewable energies for electricity generation is common, being among them wind energy one of the most efficient. Wind energy allows electricity to be generated from the wind by wind turbines. These wind turbines basically consist of a tower, a gondola that houses the electric generator, a rotor formed in turn by at least two blades, and a power train that transmits power from the rotor to the electric generator. The power train may comprise a multiplier with a low speed shaft connected to the rotor and a high speed shaft connected to the electric generator.
    In multi-megawatt wind turbines, there is a tendency towards larger rotors, which provide energy at a lower cost. In these configurations there is an increasing importance of the control system. This system allows maximizing the energy production while limiting the mechanical loads produced by the wind. For this, the control system acts on the pitch angle (often called pitch angle) and on the torque demanded from the generator.
    On the one hand, the pitch angle is controlled by actuators arranged at the root of each blade, which rotate the blade around its longitudinal axis. This action can vary the aerodynamic behavior of the blade, while
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    on the other hand, the control system modulates the torque demanded to the generator from the converter.
    The production capacity of a wind turbine under different wind conditions begins its energy production above a certain wind speed usually known as Vcut-in, so that with higher winds the wind turbine starts spinning producing energy, and with lower winds the wind turbine it remains paused with a safety pitch angle of 90 °, which causes the rotor's rotational speed to be substantially zero. In addition there is a wind speed for which the wind turbine reaches the rated power Vrated.
    The graph of the demand for electric torque T as a function of the speed of the electric generator w, shows a variable speed section in which a state of the art monitoring system determines the demand for electric torque T as a function of the speed of rotation of the generator w, in order to keep the blade speed ratio (Tip Speed Ratio or A) constant at an optimum that maximizes wind power capture.
    A = (wxR) / v, where w: rotor rotation speed R: rotor radius v: incident wind speed
    In order to carry out the previous control of maintaining the constant blade tip speed ratio at an optimum value that maximizes the wind's aerodynamic power capture, there are antecedents that pose a closed loop control of A acting on the generator torque.
    This is the case of the international application WO2008119994A2, which describes a controller that modifies the rotational speed of the rotor by means of acting on the electric torque depending on the measured local wind speed to maintain the blade tip speed ratio within predetermined limits. If it is observed, for example, that the maximum energy efficiency is given for A = 3.5, the controller is programmed to maintain the blade speed ratio between 3.5 and 4.5 (value
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    preset or optimal). An anemometer measures the instantaneous wind speed at the frequency of 2 to 4 Hz and is sent to the controller, which calculates the instantaneous A with respect to the preset or optimal value.
    However, it is not optimal to directly use a measure of A, since it requires a measure of the wind speed of an anemometer placed in the gondola, which is a very noisy signal and sensitive to environmental effects such as wind cutting (windshear), inclination upflow, etc. In addition, the usual location of the anemometer at the back of the gondola causes its measurement to be disturbed by the rotor.
    To avoid this inconvenience, it is usual to control the speed of the wind turbine by means of actuation on the electric torque so that the wind turbine operates in the variable speed zone according to the established T / w ratio.
    Due to various effects related to the wind turbine or the environmental conditions of the surrounding environment, the machine can start working in non-optimal conditions, either from the point of view of energy production or from the structural integrity of the machine, so that the power generated by the wind turbine for a given wind speed is less than that which would be had in ideal conditions with that same wind speed.
    Among the effects related to the wind turbine are:
    - misalignment with respect to wind direction. This may be due to mounting errors of the steering sensor (wind vane), wind flow distortion in the wind vane caused by the rotor, etc ...
    - dirt, ice or degradation of the blades. Reduce wind turbine efficiency.
    - degradation of components. It reduces the performance of components affecting the total efficiency of the machine.
    Among the effects related to the environment of the machine that affect its operation, are:
    - density variations.
    - inclined flow.
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    - cutting profile.
    In the state of the art, the control parameters of the wind turbine control system are calculated theoretically or with the help of simulation tools. In addition, the anomalous conditions detection methods are based on the comparison of the power generated with a given wind and the theoretical power that should be generated with that wind. These methods have the disadvantage that, for comparisons to be valid, only data corresponding to wind speeds in relatively small wind intervals (0.5 m / s - 1 m / s) can be considered.
    Both in the case of the international application WO2008119994A2 and in that of the patent with publication number CA1245283A1, which describes a wind energy conversion system that describes a closed loop control system based on an error signal which is a measure of the difference between a desired or reference value of the blade tip speed ratio (Aopt) and the A associated with when the wind turbine receives a gust of wind, when the rotation speed is modified based on the comparison of values instantaneous of the blade tip speed ratio with the optimum blade tip speed ratio, these controls assume that the instantaneous differences in A are due to the fact that the wind speed has varied, for example due to a gust of wind, with what you have to change the speed of rotation to be in that optimal area. However, as explained, there are conditions of the environment or the wind turbine itself that cause it to operate outside its maximum performance point, which are not corrected with a rotation speed modification of the rotor.
    The present invention aims at a control method to detect situations in which the machine is not working at its optimum operating point overcoming the drawbacks of the state of the art mentioned above.
    In addition, once these situations have been detected, the control method of the present invention allows automatic correction of the control parameters and returns the wind turbine to its optimum operating point.
    DESCRIPTION OF THE INVENTION
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    The present invention relates to a method of controlling a wind turbine comprising the wind turbine:
    - a control system,
    - a rotor with at least one blade,
    - a gondola, and
    where the control system is configured to regulate the rotational speed of the rotor (w) within a variable speed zone between a minimum value (wmin) and a maximum value (wmax) of rotor rotation speed (w) of such that a blade tip speed ratio, A, remains substantially equal to an objective value (Aopt) of the blade tip speed ratio, and
    where the method comprises:
    - a step of calculating the average value (Amed) of a parameter indicative of the blade tip speed ratio, A, in the variable speed zone, from a rotor speed signal w and a signal from the wind speed
    - a step of comparing the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone with the target value (Aopt) of the parameter indicating the blade tip speed ratio, and
    - a modification stage of at least one parameter of the control system based on the result of the comparison stage between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the value target (Aopt) of the parameter indicative of the blade tip speed ratio.
    The mean value (Amed) of the parameter indicative of the blade tip speed ratio, A, in the lambda variable speed zone can be calculated from instantaneous values of the parameter indicating the blade tip speed ratio, A, calculated from the rotor rotation speed signal w and the wind speed signal, v, or from average values, for example minute or tenminutal, of rotor rotation speed w and wind speed , v.
    In this way, and by means of comparing the average value (Amed) of a parameter indicative of the blade tip speed ratio in the variable speed zone with the target value (Aopt), it is determined whether or not the wind turbine is
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    working at its point of maximum performance, this stage not being associated to the instantaneously a gust of wind, as in the state of the art, but to the fact that the wind turbine is not working at its optimum operating point in a sustained manner, for later modify at least one parameter of the control system based on the result of the comparison stage.
    Optionally, the step of comparing the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone with the target value (Aopt) of the parameter indicating the blade tip speed ratio comprises a sub-stage of calculating a difference between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicating the blade tip speed ratio, and where the step of modifying at least one parameter of the control system is carried out if the value of the difference calculated between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the blade tip speed ratio is above a first threshold value, since due to the uncertainty of the measurement it is advisable to have a band Average dispersion value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone where no control parameter is modified.
    Optionally, the control method of the present invention comprises a step of filtering the values of the parameter indicative of the blade tip speed ratio, A, prior to the calculation stage of the average value (Amed) of the parameter indicating the speed ratio of tip of tip of shovel in the zone of variable speed.
    Therefore, in the steps described above, the control method detects that there is at least one control parameter unsuitable for existing environmental or machine conditions.
    Optionally, the step of modifying at least one parameter of the control system further comprises an identification sub-stage of at least one control parameter to be modified, where the inappropriate parameter is identified.
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    This identification sub-stage of at least one control parameter to be modified comprises, in turn, a comparison sub-stage of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at least one adjacent wind turbine.
    The value of the control parameter is not adequate because it has a different value than the one that would provide the greatest generation of electrical energy or lower charges. That is why at least one operational parameter related to the control parameter of a wind turbine is compared with the equivalent operational parameter of an adjacent wind turbine.
    More likely, the control parameters likely to be improved are:
    • the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone, and
    • the relationship between the pitch angle and the generated electrical power,
    • the offset of orientation of the gondola,
    by ceasing to be adequate and therefore it is necessary to modify as a result of variations in density, dirt or degradation of the blades, etc.
    As an alternative to the identification sub-stage, it can be established that a predetermined control parameter is modified, which may be, among others, the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed ( w2) in the variable speed zone or even a predetermined sequential modification of control parameters: for example, the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone first and then the relationship between the pitch angle and the generated electrical power.
    Optionally, if the control system determines that the wind turbine is not working at its optimum operating point, that is, it is not capturing as much energy as possible for the existing environmental and wind turbine conditions because a control parameter does not have its value suitable, the control method optionally comprises a step of automatic identification of the correct value of the control parameter to be modified.
    BRIEF DESCRIPTION OF THE DRAWINGS
    Figure 1 shows a flow chart of the control method of a wind turbine 5 of the present invention.
    Figure 2 shows a graph of the torque curve demanded from the electric generator of the wind turbine as a function of the speed of rotation of the generator, where the variable speed range of the wind turbine of the present invention is defined.
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    Figure 3 shows different Cp / A curves for different pitch angle values.
    Figure 4 shows a graph of the temporal evolution of the mean value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone 15 in a wind turbine that incorporates the method of controlling the invention.
    Figure 5 shows a power curve of a wind turbine.
    Figure 6 shows the relationship between the blade pitch angle and the electric power 20 generated before applying the control method of a wind turbine of the present invention.
    Figure 7 shows the relationship between the blade pitch angle and the electric power generated before applying, in dashed lines, and after applying, in continuous lines, the control method of a wind turbine of the present invention.
    Figure 8 shows a flow chart of the step of modifying at least one parameter of the control system.
    30 Figure 9 shows a block diagram of a regulator used to calculate the new value of the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the area Variable speed
    Figure 10 shows a block diagram of a regulator used for the regulation of the gondola orientation.
    PREFERRED EMBODIMENT OF THE INVENTION
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    Figure 1 shows the flow chart of the control method of the present invention. The invention relates to a method of controlling a wind turbine comprising the wind turbine:
    - a control system,
    10 - a rotor with at least one blade,
    - a gondola, and
    where the control system is configured to regulate the rotational speed of the rotor (w) within a variable speed zone between a minimum value (wmin) and a maximum value (wmax) of rotor rotation speed (w), that in this preferred embodiment example 15 shown in Figure 2, they correspond to the values of 1.2wmin and 0.8wnom respectively, so that a blade tip speed ratio, A, remains substantially equal to a value objective (Aopt) of the blade tip speed ratio, where the method comprises:
    - a step of calculating the average value (Amed) of a parameter indicative of the ratio of 20 blade tip speed, A (2) in the variable speed zone, from the signal
    of the rotational speed of the rotor, w, and the wind speed signal, v, which in this preferred embodiment is carried out according to the formula A = (wxR) / v, where R is the radius of the rotor,
    - a step of comparing (3) the average value (Amed) of the parameter indicative of the blade speed ratio 25 in the variable speed zone with the target value
    (Aopt) of the parameter indicative of the blade tip speed ratio, and
    - a modification stage (4) of at least one parameter of the control system based on the result of the comparison stage between the average value (Amed) of the parameter indicative of the parameter indicative of the blade tip speed ratio
    30 in the variable speed zone and the target value (Aopt) of the blade tip speed ratio.
    The target value (Aopt) of the parameter indicative of the blade tip speed ratio in the variable speed zone corresponds to the value of the speed ratio of
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    blade tip that provides greater generation of electric power in the variable speed zone.
    In the variable speed zone, the control system regulates the torque to the generator (T) as a function of the generator's rotation speed (w), so that the value of A is as close as possible to the value of Aopt.
    Figure 2 shows the relationship between T / w in the entire work area of the wind turbine, in it the following sections are identified:
    - a first vertical section of the curve in which the speed of rotation of the generator remains substantially constant and equal to wmin
    - a second section in which the speed of rotation of the wind turbine varies between the values Wmin and Wnom
    - a third vertical section in which the speed of rotation of the generator remains substantially constant and equal to wnom
    In a possible realization, the relationship between T and w in the variable speed zone is governed by the expression:
    T = Kopt • a> 2
    where,
    Kopt
    p 'k' R • Cpmax 2 ■ fipt-G *
    being:
    p: air density R: rotor radius
    Cpmax: maximum power coefficient
    G: relationship between generator and rotor rotation speeds
    As can be seen in Figure 3, where different curves of the wind turbine's power coefficient (Cp) are shown when it is perfectly oriented with respect to the wind direction, Cp depends on the blade tip speed ratio (A) and the blade pitch angle. The power coefficient (Cp) and therefore the generation of electric power, reach its maximum value for a determined value of the blade pitch angle and a determined value of the blade tip speed ratio (A) than in the case of Cp max will be Aopt. Therefore, in the variable speed zone, the
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    machine varies the speed of rotation of the rotor to try to work with values of A close to the target value (Aopt).
    To carry out the described method, the control system keeps record of the average value of the average value (Amed) of the parameter indicative of the blade tip speed ratio, A, in the variable speed zone in the periods in which the wind turbine It is not working in that area. Once the wind turbine operates again in the variable speed zone, the average value (Amed) of the parameter indicative of the blade tip speed ratio registered to carry out the calculation stage of the average value (2) is rescued, a from the rotor speed signal, u and the wind speed signal, v. The control system imposes a minimum measurement time in the variable speed zone before calculating a first Amed value that is used in the comparison with Aopt.
    The step of comparing (3) the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone with the target value (Aopt) of the parameter indicating the blade tip speed ratio comprises a sub-stage of calculation (5) of a difference between the average value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the tip speed ratio of blade, and where the modification stage (4) of at least one parameter of the control system is carried out if the value of the difference calculated between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the blade tip speed ratio is above a first threshold value (first threshold value with respect to the target value (Aopt) of the parameter indicative of r blade speed speed). Thus, after detecting a situation in which the machine is not working at its maximum performance point, the control method carries out a modification of at least one control parameter that allows the wind turbine to return to its optimum operating point. .
    Figure 4 shows the temporal evolution of the average value (Amed) of the parameter indicative of the speed ratio of the blade tip in the variable speed zone (continuous line), the objective value (Aopt) of the parameter indicative of the speed ratio blade tip (dotted lmea) and the first threshold value used to start the
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    modification stage (4) of at least one parameter of the control system. It can be seen as in the instant A, the value of the difference calculated between the average value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the Blade tip speed ratio is above a first threshold value. It is at that moment when an identification sub-stage (7) of at least one control parameter to be modified and an automatic identification stage (10) of the correct value of said parameter will be described, which will be described later. Once the control parameter to be modified and its correct value have been identified, at time B the modification (4) of the control parameter to its appropriate value takes place. As a consequence, the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone is observed from the instant B again approaches the target value (Aopt) of the speed ratio Shovel tip.
    The control method of the present invention further comprises a filtering stage (6) of the values of the parameter indicative of the blade tip speed ratio, A, prior to the calculation stage of the average value (Amed) of the parameter indicative of the blade tip speed ratio (2) in the variable speed zone.
    Preferably, the step of calculating the average value (Amed) of the parameter indicative of the blade speed ratio, A, (2) in the variable speed zone, is performed with values of the parameter indicative of the tip speed ratio of blade corresponding to rotor rotation speeds (w) greater than 1.1 times the minimum rotation speed (wmin) of the rotor variable speed zone and less than 0.9 times the maximum rotation speed (wmax) of the variable speed zone of the rotor, limiting the range of data used in the calculation stage of the mean value (Amed) of the parameter indicative of the blade tip speed ratio (2) in the variable speed zone.
    Preferably, the control parameter to be modified in the modification stage is at least one of the following:
    • a relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone,
    • a gondola orientation offset, or
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    • a relationship between the pitch angle (P) and the generated electrical power (P).
    A deviation from the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone with respect to the target value (Aopt) of the parameter indicating the blade tip speed ratio in said operating zone can due, among other factors, to a modification of environmental conditions, ie the density of the air or a variation in the aerodynamic characteristics of the blade and therefore of the Cp and the electric power produced for certain environmental conditions (temperature, density and pressure). Said variation of the aerodynamic characteristics of the blade may in turn be a consequence of the deposition of particles on the surface of the blade, both dirt and ice or due to frictional wear of the surface. In these circumstances, the described control method establishes that a modification of at least the control parameter that gives the relationship (Kopt) between the torque demanded to the wind turbine (T) and the square of the wind turbine's rotation speed (w2) is required. ) in the variable speed zone, passing from an initial value (Kopt1) of the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) that was inadequate to a new value (Kopt2) that causes the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone (continuous line) to approximate the target value (Aopt) of the parameter indicative of the speed ratio of blade tip in said zone of operation after the update of the control parameter to the new selected value.
    In one embodiment, it is ruled out that the difference in the mean value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone with respect to the target value (Aopt) of the parameter indicative of the tip speed ratio of blade in said area of operation is due to an error in the orientation of the wind turbine gondola (for having calibrated the wind vane for example in the start-up of the wind turbine) and it is assumed that the difference is due to a variation of the Cp or environmental conditions According to said embodiment, it is preset that the control parameter to be modified is at least the ratio (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone.
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    Figure 5 shows the wind turbine power curve, in it two distinct zones are distinguished:
    - the area of partial power corresponding to wind speeds in which the power generated is below the nominal power, and
    - the nominal power zone, corresponding to wind speeds in which the power generated by the wind turbine is substantially equal to the nominal power.
    In wind turbines of the state of the art, in the partial power zone, the optimum pitch angle or pitch angle is calculated, which is the one that provides the greatest generation of energy, for each value of generated electric power, where the system Control measures the electrical power generated and applies the corresponding pitch angle at all times. Figure 6 shows the relationship between pitch angle and the generated electrical power. In the nominal power zone, the control system regulates the pitch angle to maintain the generated power substantially equal to the nominal power.
    Optionally, when the control parameter to be modified is the ratio (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone, the relationship between the angle of pitch and the generated electric power is modified proportionally to the modification of the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone.
    A modification of the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone as a consequence of the described method is indicative of a variation in Cp and by both of the electric power produced for certain environmental conditions. The variation of the electric power produced for certain conditions also affects the relationship between the pitch angle and the generated electric power, so that the angle set by the control system would no longer be adequate to the existing environmental conditions. That is why in order to compensate for this effect, the present invention applies a modification to the relationship between the pitch angle and the generated electric power proportional to that obtained for the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the
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    wind turbine rotation speed (w2) in the variable speed zone, since the cause of the deviation is the same for both parameters. Figure 7 shows the relationship between the pitch angle and the electrical power generated before and after the modification.
    Alternatively, it cannot be ruled out that the difference in the mean value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone with respect to the target value (Aopt) of the parameter indicative of the tip speed ratio of blade in said zone of operation is due to an error in the orientation of the wind turbine gondola, the modification stage (4) of at least one parameter of the control system also comprises an identification sub-stage (7) of at least one control parameter to be modified, where the inappropriate parameter is identified, as can be seen in the flow chart of Figure 8.
    This identification sub-stage (7) of at least one control parameter to be modified in turn comprises a comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of At least one adjacent wind turbine.
    Preferably, the operational parameter is one of the following:
    • the average value (Amed) of a parameter indicative of the blade tip speed ratio, where the parameter indicative of the blade tip speed ratio can be the same as that used in the comparison stage with the target value (Aopt ) of the parameter indicative of the blade tip speed ratio, or a different one,
    • the orientation of the gondola,
    • a signal indicative of the efficiency of the wind turbine, which can be the power coefficient (Cp) in the variable speed zone.
    In the event that the operational parameter to be compared between two wind turbines is the orientation of the gondola, the comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at less an adjacent wind turbine comprises:
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    • calculate a difference between the orientation of the gondola of the wind turbine and the orientation of the gondola of an adjacent wind turbine, and
    • compare the difference between the orientation of the gondola of the wind turbine with the orientation of the gondola of the adjacent wind turbine with a second threshold value.
    In a preferred embodiment, the comparison sub-stage (8) of the at least one operational parameter of the wind turbine with the same operational parameter of at least one adjacent wind turbine comprises the following steps:
    - at least two wind turbines whose operational parameters are to be compared, send the values of the operational parameters to the park control system,
    - the park control makes comparisons of the operational parameters and identifies the machine and the at least one control parameter to be modified,
    - the park control system sends to the machine control system indications about whether they should modify any parameter of the control system and which.
    In an alternative embodiment, the comparison sub-stage (8) of the at least one operational parameter of the wind turbine with the same operational parameter of at least one adjacent wind turbine comprises the following steps:
    - the at least one adjacent wind turbine sends the values of the operational parameters to the park control system
    - the park control system sends the values of the operational parameters of the at least one wind turbine adjacent to the wind turbine whose control system is executing the identification sub-stage (7) of at least one control parameter to be modified
    - the wind turbine control system whose control system is executing the identification sub-stage (7) of at least one control parameter to be modified makes comparisons of the operational parameters and identifies the parameter to be modified first in the modification stage (4) of at least one parameter of the control system.
    If when comparing the difference between the orientation of the gondola of the wind turbine with the orientation of the gondola of the adjacent wind turbine and the second threshold value, said difference is below the second threshold value, in the identification sub-stage (7 ) of at least one control parameter to be modified, it is identified that the parameter to be modified in the modification stage (4) of at least one parameter of the control system is at least the ratio (Kopt) between the torque demanded from the wind turbine ( T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone.
    10 On the contrary, if the difference between the orientation of the gondola of the wind turbine and the orientation of the gondola of the adjacent wind turbine is above the second threshold value, the comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at least one adjacent wind turbine comprises 15 in addition:
    • calculate a difference between a signal indicative of wind turbine efficiency and a signal indicative of the efficiency of an adjacent wind turbine, or calculate a difference between the average value (Amed) of a parameter indicative of the wind turbine blade tip speed ratio and the average value (Amed) of a parameter indicative of the blade tip speed ratio
    of the adjacent wind turbine,
    where if the difference between the signal indicative of the efficiency of the wind turbine with the signal indicative of the efficiency of an adjacent wind turbine is above a third threshold value or the difference between the average value (Amed) of the parameter indicative 25 of the speed ratio of blade tip of the wind turbine with the average value (Amed) of the parameter indicative of the speed ratio of blade tip of the adjacent wind turbine is above a fourth threshold value, in the identification sub-stage (7) of at least one parameter of control to modify it is identified that the parameter to be modified in the modification stage (4) of at least one parameter of the control system is at least one orientation offset of the gondola having the lowest value of the signal indicative of efficiency of the wind turbine or the lower value of the average value (Amed) of the parameter indicative of the blade tip speed ratio.
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    The parameter indicative of the blade tip speed ratio used in this stage may be the same as that used in the comparison stage with the target value (Aopt) of the parameter indicating the blade tip speed ratio, or a different one,
    Alternatively, the comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at least one adjacent wind turbine comprises:
    • calculate a difference between a signal indicative of wind turbine efficiency and a signal indicative of the efficiency of an adjacent wind turbine, or calculate a difference between the average value (Amed) of a parameter indicative of the wind turbine blade tip speed ratio and the average value (Amed) of a parameter indicative of the blade tip speed ratio of the adjacent wind turbine,
    where if the difference between the signal indicative of the efficiency of the wind turbine with the signal indicative of the efficiency of an adjacent wind turbine is below a third threshold value or the difference between the average value (Amed) of the parameter indicative of the speed ratio of wind turbine blade tip with the average value (Amed) of the parameter indicative of the adjacent wind turbine blade speed ratio is below a fourth threshold value, in the identification sub-stage (7) of at least one control parameter to modify it is identified that the parameter to be modified first in the modification stage (4) of at least one parameter of the control system is the relationship (Kopt) between the torque demanded from the generator (T) and the square of the speed of rotation of the rotor (w2) in the variable speed zone.
    In the latter case, the method detects that there is an inadequate control parameter and by comparison with an adjacent wind turbine, it is seen that the situation affects both wind turbines equally, with which it is associated with causes such as variation in the density of the air, dirt or ice on the blades, etc ... since these causes would similarly affect adjacent wind turbines. All these causes produce deviations of A with respect to Aopt that are corrected by modifying the relationship (Kopt) between the torque demanded from the generator (T) and the square of the rotational speed of the rotor (w2) in the variable speed zone.
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    If the control system determines that the wind turbine is not working at its optimum operating point, that is, it is not capturing as much energy as possible for the existing environmental and wind turbine conditions and the control parameter to be modified has been identified to correct this situation, the control method comprises an automatic identification step (10) of the correct value of the control parameter to be modified, comprising the following sub-stages:
    • an operation sub-stage (12) of the wind turbine alternating periods of similar duration in which the control parameter takes different values and in which the wind speed data and operational parameters are recorded for each of the periods of the wind turbine, and
    • a sub-stage of selection (13) of the value of the control parameter to be modified taking into account the wind speed data and operational parameters of the wind turbine.
    The new selected value of the control parameter to be modified is the one that provides the highest efficiency of the wind turbine or the indicative value of loads in the most suitable wind turbine.
    Operation modes (12) define operating modes in which the control parameter takes a value for each mode of operation. These operating modes alternate sequentially during periods of similar duration until sufficient information is available for each period.
    For a first example of realization, the automatic identification step (10) of the correct value of the control parameter to be modified further comprises:
    • a sub-stage for calculating a difference (14) between the average value (Amed) of a parameter indicative of the blade speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the speed ratio of blade tip in the periods in which the control parameter takes each of the different values, and
    • where the automatic identification stage (10) of the correct value of the control parameter to be modified is repeated until at least a difference between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the speed zone variable and the target value (Aopt) of
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    Parameter indicative of the blade tip speed ratio in the periods in which the control parameter takes each of the different values east below a fifth threshold value, and
    • where at each stage of automatic identification (10) of the correct value of the control parameter to be modified, at least part of the values taken by the control parameter are different from those of the previous stage of automatic identification (10) of the correct value of the control parameter to modify.
    In this exemplary embodiment, the parameter indicative of the blade tip speed ratio is the same as that used in the initial stage of comparison with the target value (Aopt) of the parameter indicating the blade tip speed ratio, although it could be another one,
    For a second embodiment, in the operating sub-stage (12) of the wind turbine alternating periods of similar duration in which the control parameter takes different values, and in which the registration is made, for each of the periods, of wind speed data and operational parameters of the wind turbine of the automatic identification stage (10) of the correct value of the control parameter to be modified, the control parameter takes at least three values, and the automatic identification stage (10) of the value The correct control parameter to be modified further includes:
    • a sub-stage of calculation of an indicative value (15) of the efficiency of the wind turbine or of an indicative value of loads in the wind turbine in the periods in which the control parameter takes each of the different values,
    • where the automatic identification stage (10) of the correct value of the control parameter to be modified is repeated until the value of the control parameter that provides the indicative value of the efficiency of the largest wind turbine or an indicative value of loads in the preset wind turbine , is one of the central values of the control parameter, that is, it is not one of the two extreme values of the at least three values that the control parameter takes, and
    where at each stage of automatic identification (10) of the correct value of the control parameter to be modified, at least part of the values taken by the control parameter are different from those of the stage of automatic identification (10) of the correct value of the
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    control parameter to be modified above, the value of the control parameter providing the indicative value of the efficiency of the wind turbine being greater or the indicative value of loads in the wind turbine preset in the repetition of the previous automatic identification stage (10), one of the central values of the control parameter values in the new repetition of the automatic identification stage (10) of the correct value of the control parameter to be modified,
    In the second embodiment, at the stage of automatic identification of a new value of the control parameter to be modified, the control parameter preferably takes three values.
    When the value of the control parameter that provides the indicative value of the efficiency of the largest wind turbine or the indicative value of loads in the preset wind turbine is one of the central values of the control parameter, the automatic identification stage (10) of the correct value of the control parameter to be modified further includes:
    • a sub-stage of calculation of the average value (Amed) of the parameter indicative of the blade tip speed ratio (16) in the variable speed zone in the periods in which the control parameter takes the value of the control parameter it provides the indicative value of the efficiency of the greater wind turbine or an indicative value of loads in the preset wind turbine, and
    • an assignment sub-stage (17) to the target value (Aopt) of the parameter indicative of the blade speed ratio the average value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone in the periods in which the control parameter takes the value of the control parameter that provides the indicative value of the greater wind turbine efficiency or an indicative value of loads in the preset wind turbine.
    In a third embodiment, the automatic identification step (10) of the correct value of the control parameter to be modified comprises a sub-stage of analytical calculation (18) of the new value of the control parameter that is carried out from the average value (Amed) of a parameter indicative of the blade tip speed ratio, A, in the variable speed zone, or from a value indicative of wind turbine efficiency or a value indicative of wind turbine loads.
    5
    When the control parameter to be modified is the ratio (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone, the analytical calculation of the new Kopt value (Kopt_new) is made from the previous value of Kopt (previous Kopt) according to the
    following expression:
    Koptjnew ^ opt_anterior
    ^ ■ med, ^ opt
    3
    In a fourth example of realization, the automatic identification step (10) of the correct value of the control parameter to be modified comprises a regulation loop 10 that monitors the average value (Amed) of a parameter indicative of the blade tip speed ratio in the variable speed zone and regulates the control parameter based on the difference between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the blade tip speed ratio.
    fifteen
    Figure 9 shows a regulation loop for the case in which the control parameter to be modified is the relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone.
    twenty
    After the automatic identification stage (10) of the correct value of the control parameter to be modified, the control method additionally comprises an update stage (11) of the control parameter to the value selected in the automatic identification stage.
    25
    Figure 10 shows a block diagram of a regulator used for the regulation of the gondola orientation.
    The invention also relates to the control system of a wind turbine which comprises a wind turbine control method as detailed above and a wind turbine comprising said control system.
    权利要求:
    Claims (27)
    [1]
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    R E I V I N D I C A C I O N E S
    1. - Control method of a wind turbine comprising the wind turbine:
    - a control system,
    - a rotor with at least one blade,
    - a gondola, and
    where the control system is configured to regulate the rotational speed of the rotor (w) within a variable speed zone between a minimum value (wmin) and a maximum value (wmax) of rotor rotation speed (w) of such that a blade tip speed ratio, A, remains substantially equal to an objective value (Aopt) of the blade tip speed ratio, and the method being characterized in that it comprises:
    - a step of calculating the average value (Amed) of a parameter indicative of the blade tip speed ratio, A, (2) in the variable speed zone, from a signal of the rotational speed of the rotor, w and a wind speed signal, v,
    - a step of comparing (3) the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone with the target value (Aopt) of the parameter indicating the blade tip speed ratio, Y
    - a modification stage (4) of at least one parameter of the control system based on the result of the comparison stage between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the blade tip speed ratio.
    [2]
    2. - Control method of a wind turbine according to revindication 1 characterized in that the objective value (Aopt) of the parameter indicative of the blade tip speed ratio corresponds to the value of the parameter indicative of the blade tip speed ratio that provides greater generation of electric energy in the variable speed zone.
    [3]
    3. - Control method of a wind turbine according to any of the preceding claims characterized in that the comparison stage (3) of the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone with the target value (Aopt) of the parameter indicative of the blade tip speed ratio, comprises a sub-stage of calculation (5) of a difference between the value
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    mean (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the blade tip speed ratio, and where the modification stage (4) of at least one parameter of the control system is carried out if the value of the difference calculated between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the blade tip speed ratio is above a first threshold value.
    [4]
    4. - Control method of a wind turbine according to any of the
    previous claims characterized in that it comprises a filtering stage (6) of the values of the parameter indicative of the blade tip speed ratio, A, prior to the calculation stage of the average value (Amed) of the parameter indicative of the speed ratio of blade tip tip (2) in the variable speed zone.
    [5]
    5. - Control method of a wind turbine according to any of the
    previous claims characterized in that the step of calculating the average value (Amed) of the parameter indicative of the speed ratio of blade tip, A, (2) in the variable speed zone, is performed with values of the parameter indicative of the speed ratio blade tip corresponding to rotor rotation speeds (w)
    greater than 1.1 times the minimum turning speed (wmin) of the speed zone
    variable rotor and less than 0.9 times the maximum turning speed (wmax) of the variable speed zone of the rotor.
    [6]
    6. - Control method of a wind turbine according to any of the
    previous claims characterized in that the parameter indicative of the blade tip speed ratio is calculated from a rotor speed signal, w, and a wind speed signal, v, according to formula A = ( wxR) / v, where R is the radius of the rotor.
    [7]
    7. - Control method of a wind turbine according to any of the
    previous claims characterized in that the control parameter to be modified in the modification step (4) is at least one of the following:
    • a relationship (Kopt) between the torque demanded from the wind turbine (T) and the square of the wind speed of rotation (w2) in the variable speed zone,
    • a gondola orientation offset,
    • a relationship between the pitch angle and the generated electrical power.
    [8]
    8. - Control method of a wind turbine according to claim 7, characterized in that when the control parameter to be modified is the ratio (Kopt) between the torque
    demanded from the wind turbine (T) and the square of the wind turbine's rotation speed (w2) in the variable speed zone, the relationship between the pitch angle and the generated electric power is modified proportionally to the modification of the ratio (Kopt) between the torque demanded from the wind turbine (T) and the square of the 10 speed of rotation of the wind turbine (w2) in the variable speed zone.
    [9]
    9. - Control method of a wind turbine according to any of the preceding claims characterized in that the modification step (4) of at least one parameter of the control system further comprises a sub-stage of
    15 identification (7) of at least one control parameter to be modified.
    [10]
    10. - Control method of a wind turbine according to claim 9 characterized in that the identification sub-stage (7) of at least one control parameter to be modified comprises in turn:
    20 • a comparison sub-stage (8) of at least one operational parameter of the
    wind turbine related to at least one control parameter, with the same operational parameter of at least one adjacent wind turbine.
    [11]
    11. - Control method of a wind turbine according to claim 10, characterized in that the operational parameter is one of the following:
    • the average value (Amed) of a parameter indicative of the blade tip speed ratio,
    • the orientation of the gondola,
    • a signal indicative of wind turbine efficiency.
    30
    [12]
    12. - Control method of a wind turbine according to claim 11 characterized in that the comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at least one adjacent wind turbine understands:
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    • calculate a difference between the orientation of the gondola of the wind turbine and the orientation of the gondola of an adjacent wind turbine, and
    • compare the difference between the orientation of the gondola of the wind turbine with the orientation of the gondola of the adjacent wind turbine with a second threshold value.
    [13]
    13. - Control method of a wind turbine according to claim 12 characterized in that if the difference between the orientation of the gondola of the wind turbine and the orientation of the gondola of the adjacent wind turbine is below the second threshold value, in the identification sub-stage (7 ) of at least one control parameter to be modified, it is identified that the parameter to be modified in the modification stage (4) of at least one parameter of the control system is at least one relation (Kopt) between the torque demanded from the wind turbine (T ) and the square of the wind turbine's rotation speed (w2) in the variable speed zone.
    [14]
    14. - Control method of a wind turbine according to claim 12 characterized in that if the difference between the orientation of the gondola of the wind turbine and the orientation of the gondola of the adjacent wind turbine is above the second threshold value, the comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at least one adjacent wind turbine further comprises:
    • calculate a difference between a signal indicative of wind turbine efficiency and a signal indicative of the efficiency of an adjacent wind turbine, or calculate a difference between the average value (Amed) of a parameter indicative of the wind turbine blade tip speed ratio and the average value (Amed) of a parameter indicative of the blade tip speed ratio of the adjacent wind turbine,
    where if the difference between the signal indicative of the efficiency of the wind turbine with the signal indicative of the efficiency of an adjacent wind turbine is above a third threshold value or the difference between the average value (Amed) of the parameter indicative of the speed ratio of wind turbine blade tip with the average value (Amed) of the parameter indicative of the adjacent wind turbine blade speed ratio is above a fourth threshold value, in the identification sub-stage (7) of at least one control parameter to be modified it is identified that the parameter to be modified in the modification stage (4) of at least one parameter of the system of
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    control is at least one offset orientation of the gondola that has the lowest value of the signal indicative of wind turbine efficiency or the lowest value of the average value (Amed) of the parameter indicative of the blade tip speed ratio.
    [15]
    15. - Control method of a wind turbine according to claim 11 characterized in that the comparison sub-stage (8) of at least one operational parameter of the wind turbine related to at least one control parameter, with the same operational parameter of at least one wind turbine adjacent comprises:
    • calculate a difference between a signal indicative of wind turbine efficiency and a signal indicative of the efficiency of an adjacent wind turbine, or calculate a difference between the average value (Amed) of a parameter indicative of the wind turbine blade tip speed ratio and the average value (Amed) of a parameter indicative of the blade tip speed ratio of the adjacent wind turbine,
    where if the difference between the signal indicative of the efficiency of the wind turbine with the signal indicative of the efficiency of an adjacent wind turbine is below a third threshold value or the difference between the average value (Amed) of the parameter indicative of the speed ratio of wind turbine blade tip with the average value (Amed) of the parameter indicative of the adjacent wind turbine blade speed ratio is below a fourth threshold value, in the identification sub-stage (7) of at least one control parameter to modify it is identified that the parameter to be modified first in the modification stage (4) of at least one parameter of the control system is a relationship (Kopt) between the torque demanded from the generator (T) and the square of the speed of rotation of the rotor (w2) in the variable speed zone.
    [16]
    16. - Control method of a wind turbine according to any of the preceding claims characterized in that it additionally comprises an automatic identification step (10) of the correct value of the control parameter to be modified.
    [17]
    17. - Control method of a wind turbine according to claim 16 characterized in that the automatic identification stage (10) of the correct value of the control parameter to be modified comprising, in turn:
    • a working sub-stage (12) of the wind turbine alternating periods of similar duration in which the control parameter takes different values and
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    in which the wind speed data and operational parameters of the wind turbine are recorded for each of the periods, and
    • a selection sub-stage (13) of the value of the control parameter to be modified taking into account the wind speed data and operational parameters of the wind turbine registered with each of the values of the control parameter to be modified.
    [18]
    18. - Control method of a wind turbine according to claim 17 characterized in that the automatic identification stage of the correct value (10) of the control parameter to be modified further comprises:
    • a sub-stage for calculating a difference (14) between the average value (Amed) of a parameter indicative of the blade speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the speed ratio of blade tip in the periods in which the control parameter takes each of the different values, and
    • where the automatic identification stage (10) of the correct value of the control parameter to be modified is repeated until at least a difference between the average value (Amed) of the parameter indicative of the blade tip speed ratio in the speed zone variable and the target value (Aopt) of the parameter indicative of the blade tip speed ratio in the periods in which the control parameter takes each of the different values east below a fifth threshold value, and
    • where at each stage of automatic identification (10) of the correct value of the control parameter to be modified, at least part of the values taken by the control parameter are different from those of the previous stage of automatic identification (10) of the correct value of the control parameter to modify.
    [19]
    19. - Control method of a wind turbine according to claim 17 characterized in that in the operating sub-stage (12) of the wind turbine alternating periods of similar duration in which the control parameter takes different values, and in which the registration is carried out , for each of the periods, of wind speed data and operational parameters of the wind turbine, the control parameter takes at least three values, and because the automatic identification stage (10) of the correct value of the control parameter to be modified additionally it includes:
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    • a sub-stage of calculation of an indicative value (15) of the efficiency of the wind turbine or of an indicative value of loads in the wind turbine in the periods in which the control parameter takes each of the different values,
    • where the automatic identification stage (10) of the correct value of the control parameter to be modified is repeated until the value of the control parameter that provides the indicative value of the efficiency of the largest wind turbine or an indicative value of loads in the preset wind turbine , is one of the central values of the control parameter, and
    where at each stage of automatic identification (10) of the correct value of the control parameter to be modified, at least part of the values taken by the control parameter are different from those of the stage of automatic identification (10) of the correct value of the parameter of control to be modified above, the value of the control parameter providing the indicative value of the efficiency of the wind turbine being greater or the indicative value of loads in the wind turbine preset in the repetition of the previous automatic identification stage (10), one of the central values of the control parameter values in the new repetition of the automatic identification stage (10) of the correct value of the control parameter to be modified.
    [20]
    20. Control method of a wind turbine according to claim 19, characterized in that when the value of the control parameter that provides the indicative value of the efficiency of the largest wind turbine or the indicative value of loads in the preset wind turbine is one of the central values of the control parameter, the automatic identification step (10) of the correct value of the control parameter to be modified further comprises:
    • a sub-stage for calculating the mean value (Amed) of a parameter indicative of the blade tip speed ratio (16) in the variable speed zone in the periods in which the control parameter takes the value of the control parameter that provides the indicative value of the efficiency of the greater wind turbine or an indicative value of loads in the preset wind turbine, and
    • an assignment sub-stage (17) to the target value (Aopt) of the parameter indicative of the blade speed ratio the average value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone in the periods in which the control parameter takes the value of the control parameter that provides the indicative value of the efficiency of the
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    larger wind turbine or an indicative value of loads in the preset wind turbine.
    [21]
    21. - Control method of a wind turbine according to claim 16
    characterized in that the automatic identification stage (10) of the correct value of the control parameter to be modified comprises a sub-stage of analytical calculation (18) of the new value of the control parameter.
    [22]
    22. - Control method of a wind turbine according to claim 21
    characterized in that the analytical calculation sub-stage (18) of the new value of the control parameter is carried out from the average value (Amed) of a parameter indicative of the blade tip speed ratio, A, in the speed zone variable.
    [23]
    23. - Control method of a wind turbine according to claim 21
    characterized in that the analytical calculation sub-stage (18) of the new value of the control parameter is carried out based on a value indicative of the efficiency of the wind turbine or an indicative value of loads on the wind turbine.
    [24]
    24. - Control method of a wind turbine according to claim 16
    characterized in that the automatic identification stage (10) of the correct value of the control parameter to be modified comprises a regulation loop that monitors the average value (Amed) of a parameter indicative of the blade tip speed ratio in the speed zone variable and regulates the control parameter based on the difference between the mean value (Amed) of the parameter indicative of the blade speed ratio in the variable speed zone and the target value (Aopt) of the parameter indicative of the speed ratio Shovel tip.
    [25]
    25. - Control method of a wind turbine according to claim 16 characterized in that it additionally comprises an update stage (11) of the control parameter to the value selected in the automatic identification stage (10) of the correct value of the control parameter to be modified.
    [26]
    26. - A wind turbine control system characterized in that it comprises a wind turbine control method according to any of the preceding claims.
    [27]
    27.- Wind turbine characterized in that it comprises a control system according to revindication 26.
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    同族专利:
    公开号 | 公开日
    ES2696303T3|2019-01-15|
    EP2995810B1|2018-08-15|
    US20160069323A1|2016-03-10|
    EP2995810A1|2016-03-16|
    US10094360B2|2018-10-09|
    ES2563092B1|2016-12-19|
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