The present invention refers to a loads reduction method in a wind turbine and specially, to a loads reduction method in a wind turbine during a controlled emergency stop when a power-grid disconnection is combined during the action of a wind gust. The loads reduction method is based on adjusting the speed at which the wind turbine blades are moved into the featured position.
Variable speed wind turbines with control means for blades pitch change are well known in the state-of-the-art. These control means generally include at least a pitch change motor and a transmission, connected to control devices that receive data from the wind turbine's components and send signals to the pitch change motor to rotate the blade around its longitudinal shaft according to some strategies that allow to optimize the produced power and at the same time to protect the wind turbine itself in the cases of wind gusts or emergencies.
In the case of extreme wind gusts and/or emergencies such as the disconnection of the generator from the power-grid, the malfunction of any of its components, etc., the known state-of-the-art contemplates control systems to stop the wind turbine taking the blades to feathered position as quickly as possible, and therefore emergency stops, even though often very short, are uncontrolled and harmful for some of the wind turbine's components.
The following documents show a wide range of techniques and methods used in the state-of-the-art to reduce loads or vibration, sometimes occurring during operation in normal wind turbine conditions, and in others, during emergency stops:
Application WO2005083266, contemplates a method for insulating vibrations in the nacelle and tower of a wind turbine in normal operating conditions, based on measuring nacelle acceleration with accelerometers fixed to it, and the subsequent processing for calculating the blade angle used to obtain the necessary wind thrust to cancel these vibrations.
Publication WO06007838, refers to a linear wind turbine blade feathering system with two speeds during an emergency stop caused by a wind gust. With a first quick speed of around 10°/s, the blades are quickly positioned away from the wind direction to prevent a rotation speed in the generator shaft exceeding the established safety margins. Then, with another, slower, pitch change speed, of around 5°/s, the blades are positioned in the feathered position away from wind thrust.
Document WO05116445, describes a pitch control system that when a wind speed is detected above a given limit, the wind turbine responds positioning the blades away from wind direction and varying the nacelle's azimuthal angle a preset range.
Publication U.S. Pat. No. 4,435,647, refers to a method to reduce the first frequency of a wind turbine's tower oscillations at the same time as maintaining the generator's power constant during wind intensity variations during normal wind turbine operating conditions.
Documents U.S. Pat. No. 6,619,918 and US20040057828, deal with two control systems to keep a safety distance between the wind turbine's blade tip and tower, by means of the instantaneous control of the mechanical loads that affect the blades, deducting the blade tip position and acting on blade yaw with respect to the wind to maintain this safety distance at all times.
The main difference between the applications found in the state-of-the-art and the present invention, lies in this case contemplating an emergency stop during the blade feathering process, when the wind turbine is disconnected from the power-grid by a wind gust: one of the worst assumptions when certifying a wind turbine.
The objective of the present invention is to protect the wind turbine against loads that generate forces and/or fatigue beyond a desired level on the structure and mechanical components of a wind turbine. It is also designed to find an operating method for an emergency stop in the case of a wind gust affecting the wind turbine combined with it being disconnected from the power-grid.
According to the method in the present invention, the aforementioned criteria are fulfilled in failures that disconnect the wind turbine from the power-grid during a wind gust. This is achieved by firstly reducing the excessive speed the generator rotor reaches to safety margins, and secondly, reducing the vibrations that cause fatigue in the wind turbine's structure and mechanical components during an emergency stop. The latter is achieved with a quick blade feathering, which is controlled at all times, varying the pitch change speed to make the most of the thrust of the wind in the blades so that it offers resistance to tower vibration: in this way the forces and momentum generated on the root of the blades, the first bearing, the base and the top of the tower are minimized.
The method for reducing loads in a wind turbine when the power-grid is disconnected during a wind gust has been developed with the aim of resolving one of the most harmful loads cases for current wind turbine certification, but which is applicable to the rest of normal operating conditions. This obtains a reduction in loads and vibrations of all the wind turbine's components, a reduction in loads for certifying the machine, increasing the fatigue life of all the components not only for certified loads, but also for the rest of real cases. It also reduces tower oscillations, improving its availability and it is possible to optimize both the wind turbine tower and other components, reducing the amount of material used and therefore also lowering costs. The machine's safety margin can also be chosen to be increased instead of changing the design of the elements.
Mexican hat wind gusts are characterized by a slight decrease in the initial wind speed at the start of the phenomenon, followed be a sudden increase in the speed, another quick reduction underneath the initial speed and a recovery to the initial value of the wind speed at the end of the phenomenon. One of the worst assumptions for certifying a wind turbine faced with extreme loads arises when in addition of a Mexican hat wind gust, the wind turbine is also disconnected from the power-grid during this gust. Most of the wind turbine's mechanical components are sized for this event.
As can be seen in
As shown in
Extreme loads in the wind turbine's mechanical components are even more serious when the disconnection from the power-grid occurs during a wind gust. In this case, the rotor rotation in addition to accelerating due to increased wind speed, also accelerated due to the loss of electric torque that offers resistance to generator rotation, so that the forces and momentum in the base and top of-the tower (8) increase greatly, ditto for the blade root, the blade itself, first bearing and damaged caused by excessive generator speed. Furthermore, the tower's swing can be even worse depending on in which moment of the gust the disconnection occurs, and therefore fatigue damage should be especially taken into account when dimensioning not only the tower but also the rest of the wind turbine's mechanical components (14). Therefore, the present invention proposes a control system to reduce loads in the wind turbine's (14) mechanical components at the same time as reducing the amplitude of the tower's oscillation and allows for optimising the design of its components or increasing the safety margins.
The difficulty for solving this problem mainly lies in, on the one hand, the wind gusts not having linear effects, and on the other, in that it is not possible to predict when the wind turbine (14) will be disconnected from the power-grid in a real case. Therefore, the present invention attempts to tackle these two degrees of freedom with a control system, as shown in
In this sense, the system's open loop (9) comprises blade yaw control during wind turbine (14) normal operating conditions to adjust the generator rotor's power and rotation, and also includes a controlled stop or feathering process of the blades for emergencies. As can be seen in the curve (12) in
Likewise, as can be seen in curve (13) of
And finally, the second closed loop (11) demarcates the curve (13) in
The application of the aforementioned method, shows an improvement in the wind turbine's response compared to the state-of-the-art published to date, regarding minimising wind turbine component loads and vibrations, reducing extreme loads for wind turbine certification, increasing the fatigue life of all the components, not only for certified loads but also for the rest of real cases, reducing oscillation in the tower and consequently improving its availability and making it possible to optimize both the thickness of its walls and the rest of the wind turbine's components, so reducing the amount of material used, and consequently the cost. Or machine safety margins are increased.
Number | Date | Country | Kind |
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ES200602931 | Nov 2006 | ES | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/ES2007/000649 | 11/13/2007 | WO | 00 | 11/30/2009 |