CN100385111C - Blade pitch angle control device and wind turbine generator - Google Patents

Blade pitch angle control device and wind turbine generator Download PDF

Info

Publication number
CN100385111C
CN100385111C CNB2004800227452A CN200480022745A CN100385111C CN 100385111 C CN100385111 C CN 100385111C CN B2004800227452 A CNB2004800227452 A CN B2004800227452A CN 200480022745 A CN200480022745 A CN 200480022745A CN 100385111 C CN100385111 C CN 100385111C
Authority
CN
China
Prior art keywords
command value
pitch angle
blade
pitch
wind
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CNB2004800227452A
Other languages
Chinese (zh)
Other versions
CN1833103A (en
Inventor
井手和成
林义之
柴田昌明
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Mitsubishi Heavy Industries Ltd
Original Assignee
Mitsubishi Heavy Industries Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Mitsubishi Heavy Industries Ltd filed Critical Mitsubishi Heavy Industries Ltd
Publication of CN1833103A publication Critical patent/CN1833103A/en
Application granted granted Critical
Publication of CN100385111C publication Critical patent/CN100385111C/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2270/00Control
    • F05B2270/30Control parameters, e.g. input parameters
    • F05B2270/328Blade pitch angle
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/72Wind turbines with rotation axis in wind direction

Abstract

A blade-pitch-angle control device includes a memory unit (10) in which predetermined parameters that affect the load fluctuation of blades, azimuth angles, and pitch-angle command values are stored in association with each other; an azimuth-angle detecting unit (11) that detects the azimuth angle of each of the blades; a parameter-detecting unit (12) that detects the predetermined parameters; a command-value receiving unit (13) that receives pitch-angle command values for each of the blades from the memory unit (10), the pitch-angle command values being selected on the basis of the azimuth angle of each blade detected by the azimuth-angle detecting unit (11) and the predetermined parameters detected by the parameter-detecting unit (12); and a pitch-angle-control command-value generating unit (14) that generates pitch-angle-control command values for individually controlling the pitch-angle of each blade on the basis of the pitch-angle command values and a common-pitch-angle command value.

Description

Blade-pitch-angle control and wind generating unit
Technical field
The present invention relates to wind generating unit, particularly the blade-pitch-angle control of control air vane pitch angle.
Background technique
In the past, at the propeller-type windmill that uses in the wind generating unit shown in the External view of Figure 11, by a plurality of blades, for example 3 blades constituting of the 1st blade the 1, the 2nd blade the 2, the 3rd blade 3, as formations such as the rotor 5 of the bindiny mechanism that connects 3 blades and pylons 4.
In the past, this propeller-type windmill will be controlled each blade according to wind regime, so that obtain predetermined generator speed and output.
For example, Figure 12 has shown an example of the structure of pitch angle controller in the past.As shown in the drawing, pitch angle controller in the past is provided with general pitch angle command value generating unit 15, and it is used for generating general pitch angle command value according to the difference of the setting value of generator speed or output and current controlled quentity controlled variable.Then, actuator controls each blade according to the general pitch angle command value that is generated by general pitch angle command value generating unit 15 with identical pitch angle, realizes the control of each blade-pitch-angle thus.
But, shown in Figure 13 (a), the wind speed that flows into windmill can be subjected to the influence of landform (below, the wind speed characteristics that is subjected to the influence of topography is called " wind shear characteristic ".), in addition, shown in Figure 13 (b), also can be subjected to supporting the pylon of windmill influence (below, the wind speed characteristics that influenced by pylon is called " pylon characteristic ".)。Add wind speed dispersing spatially and disperse, shown in Figure 13 (c), in the blade rotary area, have different wind speed profile with temporal.Under the different environment of this wind speed, because the aerodynamic force of each blade output momentary value is different, therefore, the thrust of each blade and moment etc. are all got mutually different value.As a result, can make the load change of each blade, thereby shorten the life-span of blade.
At this problem, for example, shown to disclose in the 2001-511497 communique (patent documentation 1) angle of attack, the load of measuring the wind that flows into each blade, the technology of each blade being controlled separately according to these values the spy.
Patent documentation 1 special table 2001-511497 communique
The patent documentation 2 international pamphlets that disclose No. 01/86141
In above-mentioned patent documentation 1 in the invention disclosed, according to checkout value from a plurality of sensors, instantaneously calculate the load that acts on the wind generating unit each several part, flow into the angle of attack etc. of the wind of blade, and the pitch angle is controlled to reduce the change of this instantaneous load.In order to effectively reduce load change, must roughly carry out a series of processing that detect feedback control in real time herein, from sensor.
But,, be difficult to draw rapidly the problem of instantaneous load because foregoing invention according to each checkout value and by calculating instantaneous load, therefore, exists and handles complexity.In addition, this long time treatment can cause feedback control to postpone, thereby reduces the precision of pitch angle control.
Moreover, in foregoing invention, must a plurality of wind sensors and and resistance strain gauge be set at each blade.But,, therefore, have the cost problem owing to, need to adopt the high price sensor to the exigent reliability of these sensors.
And for the measurement of wind speed, owing to be in the downstream of blade recording anemometer to be set to come measuring wind, therefore, existence can be subjected to the influence of the wind speed change that caused by the blade rotation, thus problem that can not the correct measurement wind speed.
Summary of the invention
The present invention makes for addressing the above problem, and its purpose is to provide a kind of pitch angle controller that further reduces the load change that produces by the precision that improves the control of pitch angle in wind generating unit.
In order to address the above problem, the present invention has adopted with lower device.
The invention provides a kind of blade-pitch-angle control, in having the wind generating unit of a plurality of blades, use, wherein, have: storage device is used to make predefined parameter, orientation angles and the pitch angle command value of the above-mentioned blade loads change of influence to set up association mutually and stored; The orientation angles detection device is used to detect the orientation angles of above-mentioned each blade; Parameter detection device is used to detect above-mentioned predefined parameter; The command value obtaining device, be used for above-mentioned each blade, obtain pitch angle command value from above-mentioned storage device respectively, this pitch angle command value is selected according to the orientation angles of above-mentioned each blade that is detected by above-mentioned orientation angles detection device with by the predefined parameter that the above-mentioned parameter detection device detects; And pitch angle control command value generating apparatus, according to above-mentioned pitch angle command value of obtaining by above-mentioned command value obtaining device and the general pitch angle command value used by each blade pass that the output information of above-mentioned wind generating unit is obtained, generate and be used for pitch angle control command value that the pitch angle of above-mentioned blade is controlled separately.
According to the present invention, the various optimum pitch angle command value that influence the parameter of blade loads change have been considered in storage in advance in storage device.Therefore, when controlling, the command value obtaining device only needs to read from storage device by the selected optimum pitch angle command value of various parameters, just can obtain the optimum pitch angle control of the most suitable windmill operation conditions.
Like this,, can obtain optimum pitch angle command value at once, therefore, make processing procedure simple, rapidly from various parameters owing to need not to carry out the processing etc. of all load changes that are used to calculate blade.
Thus, owing to can control in real time, therefore, can tackle the dynamic change of wind generating unit operation conditions rapidly, thereby further reduce load change the pitch angle.As a result, can prolong the life-span of each blade, and obtain stable generating output.
Pitch angle control command value generating apparatus, the optimum pitch angle command value that the windmill operation conditions that consideration is obtained by the command value obtaining device is obtained, be reflected to the pitch angle command value that each blade pass of generating for feedback control is carried out in the generating of wind generating unit output is used--in the general pitch angle command value, and each blade is generated the pitch angle control command value of the pitch angle that is used to control each blade respectively.Thus, can control each blade with the output change of having considered wind generating unit and the optimum pitch angle of operation conditions.
In Ji Zai the blade-pitch-angle control, preferably, the above-mentioned pitch angle control command value that is stored in the above-mentioned storage device is set at the value that the above-mentioned wind generating unit of reflection is provided with wind shear characteristic in the place in the above.
Though the output of wind speed, air density, wind generating unit etc. is moment dynamic change, the wind shear that is determined by the geographical conditions that the wind generating unit place is set is identical.
Like this, the information that is stored in the storage device has not only been considered the parameter of dynamic change, and has considered the information such as wind shear that similarly determined according to geographical conditions, therefore, can carry out the control of the very high pitch angle of precision.
In the above in Ji Zai the blade-pitch-angle control, the parameter of afore mentioned rules is a wind speed, the above-mentioned parameter detection device is preferably the wind speed estimating unit, this wind speed estimating unit has makes wind speed set up related chart attirbutes with the output of above-mentioned wind generating unit, and infers wind speed by reading from above-mentioned chart attirbutes with the output corresponding air speed of above-mentioned wind generating unit.
Wind speed is one of selected necessary important parameter of pitch angle command value.Owing to can effectively reduce load change and output change, depend on the precision that wind speed detects to a great extent, therefore, must detect wind speed with highi degree of accuracy.
But, come in the method in the past of measuring wind in the downstream that recording anemometer is arranged on windmill, can be subjected to the influence of the wind speed change that causes because of blade rotation, thus measuring wind correctly.
According to the present invention, the wind speed detection device is not that wind speed is carried out physical measurement, but according to having the output of the wind generating unit of substantial connection with wind speed, obtains wind speed by the simple process on the software.Thus, not only can obtain very correct wind speed, but also can reduce cost.
In addition, replace above-mentioned wind speed estimating unit, also can use the recording anemometer (for example, laser Doppler anemometer) that before flowing into windmill, carries out measuring wind speed.Thus, owing to be not subjected to the influence in blade downstream, therefore, can obtain high-precision wind speed.
Using under the situation of laser Doppler anemometer, can be provided with and make trace particle from the upstream side of the windmill moving device of wagon flow aweather.Perhaps, also can be with the dust of in flowing into the air of windmill, sneaking into, water vapor as tracer, obtain scattered light and measure from dust or water vapor by laser-Doppler.In this case, the device that trace particle is flowed needn't be set in addition.
Preferably, the blade-pitch-angle control of putting down in writing above has: frequency content extraction apparatus, any frequency content of extracting the blade quantity integral multiple from generating output, generator speed or the rotor speed of above-mentioned wind generating unit; And computing device, calculate the pitch angle that is used to remove the load change that is caused by this frequency variation according to this frequency content of extracting, above-mentioned pitch angle control command value generating apparatus will be reflected to by the pitch angle that the aforementioned calculation device calculates in the above-mentioned pitch angle control command value.
Obtain pitch angle controlling value though consider the change of various parameters such as wind speed, because the time lags that cause because of error and because of feedback control etc. are difficult to remove fully load change, generating output change.
On the other hand, since output change significantly appear at the blade quantity frequency band corresponding in.Therefore, can it be reflected in the pitch angle control command value, and further reduce the output change by obtaining the pitch angle of the output change that is used to remove this remarkable appearance.
That is, in the wind generating unit that uses the constant speed windmill, the frequency content extraction apparatus extracts the frequency content of blade integral multiple from the output of wind generating unit.On the other hand, in the wind generating unit that uses the speed change windmill, the frequency content extraction apparatus extracts the frequency content of blade integral multiple from generator speed or rotor speed.
Computing device is for example by the regulation algorithm, the frequency content of being extracted by the frequency content extraction apparatus is calculated, thereby calculate the change pitch angle of frequency field, again this change pitch angle is carried out frequency inverse and resolve to draw the change pitch angle of time zone.
Its result, the change pitch angle that is obtained becomes the pitch angle that is used to remove remarkable load change.
Afterwards, the pitch angle control command value generating apparatus pitch angle that will be used for removing this remarkable output change is reflected to pitch angle control command value.
Thus, owing to can accurately remove the generating output change of remarkable appearance, therefore, can obtain more stable generating output.
The invention provides a kind of wind generating unit, have a plurality of blades, wherein, has blade-pitch-angle control, this blade-pitch-angle control has: storage device is used to make regulation parameter, orientation angles and the pitch angle command value of the above-mentioned blade loads change of influence to set up association mutually and stored; The orientation angles detection device is used to detect the orientation angles of above-mentioned each blade; Parameter detection device is used to detect above-mentioned predefined parameter; The command value obtaining device, be used for above-mentioned each blade, obtain pitch angle command value from above-mentioned storage device respectively, this pitch angle command value is selected according to the orientation angles of above-mentioned each blade that is detected by above-mentioned orientation angles detection device with by the predefined parameter that the above-mentioned parameter detection device detects; And pitch angle control command value generating apparatus, according to above-mentioned pitch angle command value of obtaining by above-mentioned command value obtaining device and the general pitch angle command value used by each blade pass that the output information of above-mentioned wind generating unit is obtained, generate and be used for pitch angle control command value that the pitch angle of above-mentioned blade is controlled separately.
The invention provides a kind of blade-pitch-angle control, use in having the wind generating unit of a plurality of blades, wherein have: load-measuring device is used for measuring above-mentioned blade or constituting load on the mechanical parts of windmill with the orientation angles of regulation; Adjust pitch angle command value generating apparatus, above-mentioned each blade is generated the adjustment pitch angle command value that is used to reduce the load measured by above-mentioned load-measuring device respectively; And pitch angle control command value generating apparatus, to be reflected to the general pitch angle command value that is used for above-mentioned blade is carried out identical control to the above-mentioned adjustment pitch angle command value that above-mentioned each blade generates, thereby above-mentioned each blade will be generated pitch angle control command value.
Because load-measuring device is not the time lag in accordance with regulations, but orientation angles is in accordance with regulations measured load, therefore, is not only applicable to the constant speed windmill, is applicable to the speed change windmill that changes the rotational speed of blade by operation conditions yet.
Adjust pitch angle command value generating apparatus, for example each blade is calculated the optimum pitch angle that is used to reduce the load measured by above-mentioned load-measuring device, and generate and adjust pitch angle command value.Afterwards, pitch angle control command value generating apparatus is reflected to the pitch angle control command value of controlling blade-pitch-angle by adjusting pitch angle command value, and the change that can reduce to load.
The invention provides a kind of pitch angle controller, in having the wind generating unit of a plurality of blades, use, wherein have: load-measuring device is used for measuring load on the mechanical parts that act on above-mentioned blade or constitute windmill respectively with the orientation angles of regulation; Computing device is obtained above-mentioned load period change according to the measured value of being measured by above-mentioned load-measuring device; Adjust pitch angle command value generating apparatus, above-mentioned each blade is generated the adjustment pitch angle command value that is used to reduce load change respectively according to the result of calculation of aforementioned calculation device; And pitch angle control command value generating apparatus, to be reflected to the general pitch angle command value that is used for above-mentioned blade is carried out identical control to the above-mentioned adjustment pitch angle command value that above-mentioned each blade generates, thereby above-mentioned each blade will be generated pitch angle control command value.
This point can periodically significantly appear in the load change that the inventor is conceived to blade.Therefore, as revolve the device that how detection load changes in the process that turns around at rotor, load-measuring device and computing device are set.
Load-measuring device is measured the load that acts on each blade with the orientation angles of regulation.Like this, owing to be not in accordance with regulations time lag, but orientation angles is in accordance with regulations measured load, therefore, also is applicable to the speed change windmill that the blade rotational speed changes.
Computing device is guaranteed the measured value of each orientation angles of being measured by load-measuring device of the amount (for example, rotation 1 circle) of specified period, and obtains the characteristic of load according to these measured values.Thus, know which kind of load change in each blade, to occur.
And, to adjust pitch angle command value generating apparatus and obtain the pitch angular adjustment command value that is used to remove this load change, pitch angle control command value generating apparatus will be adjusted pitch angle command value and be reflected in the control of each blade-pitch-angle.Thus, can reduce the periodically significantly load change of appearance.
Like this,, therefore, compare, can more effectively reduce load change by very simply handling with the pitch angle control in the past of the load change that reduces instantaneous appearance owing to be conceived to the load change that periodically occurs and reduced this load change.Thus, each blade can be controlled at best pitch angle, thereby prolong the life-span of the mechanical parts of blade and formation windmill.
In addition, in the present invention, though because after the measured value of guaranteeing one-period at least, carrying out feedback control according to these measured values can postpone by generation time, but, because the load change that the present invention has in mind is periodically to occur in orientation angles much at one, therefore, even have the time lag that causes by feedback, still can remove load change with highi degree of accuracy.
In Ji Zai the blade-pitch-angle control, preferably, above-mentioned load-measuring device has in the above: the orientation angles measuring device, measure the orientation angles of each blade with specific time interval; Trigger generating means, generation trigger signal when the orientation angles of measurement result and regulation is consistent; And measuring device, measure load according to above-mentioned trigger signal.
Like this, can constitute load-measuring device, thereby can at a low price and realize load-measuring device simply by well-known common mechanism.
Above-mentioned measuring device can use resistance strain gauge, dynamometer, optical fiber transducer etc.
In Ji Zai the blade-pitch-angle control, preferably, above-mentioned load-measuring device has encoder that produces triggering when orientation angles arrives predetermined angle and the measuring device of measuring load according to above-mentioned triggering in the above.
Encoder and measuring device are well-known mechanism.Like this, because load-measuring device is made of well-known mechanism, therefore, can at a low price and realize load-measuring device simply.
Above-mentioned measuring device can use resistance strain gauge, dynamometer, optical fiber transducer etc.
The invention provides a kind of blade-pitch-angle control, use in having the wind generating unit of a plurality of blades, wherein have: acceleration measurement device is used for measuring above-mentioned blade or constituting the acceleration of the mechanical parts of windmill with the orientation angles of regulation; Adjust pitch angle command value generating apparatus, above-mentioned each blade is generated the adjustment pitch angle command value that is used to reduce the acceleration of measuring by above-mentioned acceleration measurement device respectively; And pitch angle control command value generating apparatus, to be reflected to the general pitch angle command value that is used for above-mentioned blade is carried out identical control to the above-mentioned adjustment pitch angle command value that above-mentioned each blade generates, thereby above-mentioned each blade will be generated pitch angle control command value.
Adjust pitch angle command value generating apparatus, for example can calculate the optimum pitch angle that is used to reduce the acceleration of measuring by acceleration measurement device, and generate adjustment pitch angle command value each blade.Afterwards, pitch angle control command value generating apparatus will be adjusted pitch angle command value and be reflected in the pitch angle control command value that blade-pitch-angle is controlled, thereby reduce acceleration.
And, because acceleration and load change have incidence relation, therefore, can be by reducing the change that acceleration reduces to load.
The invention provides a kind of wind generating unit, have a plurality of blades, wherein, have blade-pitch-angle control, this blade-pitch-angle control has: load-measuring device is used for measuring above-mentioned blade or constituting load on the mechanical parts of windmill with the orientation angles of regulation; Adjust pitch angle command value generating apparatus, above-mentioned each blade is generated the adjustment pitch angle command value that is used to reduce the load measured by above-mentioned load-measuring device respectively; And pitch angle control command value generating apparatus, to be reflected to the general pitch angle command value that is used for above-mentioned blade is carried out identical control to the above-mentioned adjustment pitch angle command value that above-mentioned each blade generates, thereby above-mentioned each blade will be generated pitch angle control command value.
Owing to be provided with this blade-pitch-angle control, therefore, can control each blade and reach the optimum pitch angle, thereby can realize blade and constitute the wind generating unit of the mechanical parts life-span of windmill than length.
Description of drawings
Fig. 1 is a block diagram, and it has shown the structure of the blade-pitch-angle control of first embodiment of the invention.
Fig. 2 is the view that is used to illustrate orientation angles.
Fig. 3 has shown an example that makes the wind speed and the output of wind generating unit set up related chart attirbutes.
Fig. 4 has shown example of the chart attirbutes under the constant speed wind (wind speed in time, identical on the plane).
Fig. 5 shown when changing wind speed, is used to eliminate the pitch angle correction value of influence of the wind that is caused by the inclination angle and an example that has reflected the chart attirbutes of this correction value.
Fig. 6 has shown when changing wind speed, is used to eliminate the pitch angle correction value of the influence that is produced by wind deflection and an example that reflects the chart attirbutes of this correction value.
Fig. 7 has shown an example of the chart attirbutes when air density is variable.
Fig. 8 has shown an example of the chart attirbutes when wind generating unit is output as variable.
Fig. 9 has shown that the output that is applicable to when using the constant speed windmill changes the structure of removing device.
Figure 10 has shown the block diagram of the blade-pitch-angle control structure of second embodiment of the invention.
Figure 11 has shown the External view of the propeller-type windmill that uses in wind generating unit.
Figure 12 is a block diagram, and it has shown an example of the structure of the blade-pitch-angle control that uses prior art.
Figure 13 is the view that is used to illustrate wind shear characteristic, pylon characteristic and wind speed profile.
Embodiment
Below, with reference to accompanying drawing, embodiments of the present invention are described with the order of first mode of execution, second mode of execution.
First mode of execution
Fig. 1 is a block diagram, and it has shown the structure of the blade-pitch-angle control that is applicable to the wind generating unit that has used the constant speed windmill.
As shown in Figure 1, the blade-pitch-angle control of present embodiment is provided with memory section (storage device) 10, orientation angles detection unit (orientation angles detection device) 11, parameter detecting portion (parameter detection device) 12, command value acquisition unit (command value acquisition device) 13, pitch angle control command value generating unit (pitch angle control command value generating apparatus) 14 and general pitch angle command value generating unit (general pitch angle command value generating apparatus) 15.
In memory section 10, set up regulation parameter, orientation angles and pitch angle command value that the output that stores wind speed, temperature, above-mentioned wind generating unit etc. influences the blade loads change relatedly.
Herein, as shown in Figure 2, orientation angles is meant the angle of cut that Vertical direction became with windmill, and when blade was positioned at the topmost part of windmill, this orientation angles was 0 °, and when being positioned at foot, this orientation angles is 180 °.In addition, will narrate in the back for the details that is stored in content in the memory section 10.
Orientation angles detection unit 11 detects the orientation angles of each blade respectively with predetermined distance, and they are outputed to command value acquisition unit 13.For example, can obtain orientation angles by the output that is arranged on the rotating coder in the rotatingshaft.
The wind generating unit output detection unit 123 that parameter detecting portion 12 is provided with wind speed detection unit (wind speed detection device) 121, the air density detection unit 122 that detects air density that is used to detect wind speed and detects wind generating unit output.
Wind speed detection unit 121 is provided with in inside and makes wind speed set up related chart attirbutes (referring to Fig. 3) with the output of wind generating unit.Wind speed detection unit 121 obtains the output of wind generating unit with predetermined distance, from wind generating unit output detection unit 123, and read and the output corresponding air speed that obtained from chart attirbutes, thereby infer wind speed, and the wind speed of inferring is outputed to command value acquisition unit 13.In addition, replace the method for this supposition wind speed, also can be at the distinguished and admirable recording anemometer (for example, laser Doppler anemometer) that uses measuring wind before going into windmill.Like this, owing to be not subjected to the influence in the downstream of blade, can obtain high-precision wind speed.
Using under the situation of laser Doppler anemometer, can be provided with and make trace particle from the upstream side of the windmill moving device of wagon flow aweather.Perhaps, also the dust and the water vapor of sneaking into can be used as tracer in the air that flows into windmill, obtain to measure from the scattered light of dust or water vapor and by laser-Doppler.In this case, the device that trace particle is flowed needn't be set in addition.
Air density detection unit 122 detects temperature, air pressure in accordance with regulations at interval, and obtains air density according to the characteristic of air density, temperature, air pressure by this checkout value.This is because air density is unique definite by temperature and air pressure.For example, air density detection unit 122 has makes temperature, air pressure and air density set up related mapping in advance, obtains from mapping by the selected air density of the measured value of temperature, air pressure, thereby obtains air density.The relation that perhaps can have temperature, air pressure and air density, and, calculate air density by in the measured value substitution relation with temperature and air pressure.
Command value acquisition unit 13 is obtained pitch angle command value from memory section 10, this pitch angle command value, according to and (for example from the various parameters of parameter detecting portion 12 inputs from the orientation angles of each blade of above-mentioned orientation angles detection unit 11 inputs, wind speed, air density, generating output etc.) and select, and the pitch angle command value of each blade that will obtain, promptly the 1st blade-pitch-angle command value, the 2nd blade-pitch-angle command value, the 3rd blade-pitch-angle command value output to pitch angle control command value generating unit 14 respectively.
Poor by between the setting value of generator speed (generating output information) or generating output (generating output information) and the current controlled quentity controlled variable, general pitch angle command value generating unit 15 calculates the general pitch angle command value that is used for controlling jointly the pitch angle of the 1st~the 3 three blade, so that the generating of wind generating unit output is consistent with specified output (setting value), and should general pitch angle command value output to pitch angle control command value generating unit 14.For example, general pitch angle command value generating unit 15 can be made of well-known PID control system.
According to respectively from command value acquisition unit 13 input at each pitch angle command value of each blade and from the general pitch angle command value of general pitch angle command value generating unit 15 inputs, pitch angle control command value generating unit 14 generates the pitch angle control command value of the pitch angle that is used for controlling separately each blade.Specifically, by with each pitch angle command value and the addition of general pitch angle command value, generate the pitch angle control command value of each blade.Afterwards, the pitch angle control command value that corresponding each blade is obtained respectively outputs to the actuator as the mechanism of the pitch angle of controlling each blade.Actuator is oil hydraulic cylinder or the electric motor that is installed in each blade, and it is well-known device.
Below, the content that is stored in the memory section 10 is elaborated.
At first, output of wind speed, air density, wind generating unit etc. as parameter, is set at various values with these parameters,, obtains the optimum pitch angle in the various test patterns by computer simulation.
For example, as a kind of test pattern, wind speed setting A (m/s), air density B (g/m 3), generating output C (kW), be captured in the data of the variable load when changing the pitch angle under this condition.
Then, analyze this data result, the pitch angle when selecting to obtain the minimum change load is made the pitch angle and the orientation angles corresponding characteristics chart that make selection.
By changing above-mentioned each parameter (wind speed A (m/s), air density B (g/m 3), generating output C (kW)) value and carry out above-mentioned work repeatedly, thereby produce the chart attirbutes under the various environment.Afterwards, make the setting value (setting values such as wind speed, air density, generating output) of each parameter in these chart attirbuteses and the test pattern set up corresponding and they are write in the memory section 10.
Like this, by the decision parameter value, can obtain only pitch angle under this environment.
In addition, carrying out above-mentionedly when simulating, by preestablishing wind shear characteristic or pylon characteristic (referring to Figure 13 (a) and Figure 13 (b)), thereby can obtain more suitably pitch angle as fixed value.
For example, though parameters such as above-mentioned wind speed are moment dynamic change, wind shear characteristic or pylon characteristic but are constant by the structures shape of the place that this windmill is set, windmill.Therefore, after having considered these characteristics,, can obtain the optimum pitch angle specific, thereby can carry out the control of more high-precision blade-pitch-angle this windmill by simulating.
Below, illustrate the concrete form of above-mentioned chart attirbutes.
At first, in Fig. 4, shown chart attirbutes under the constant speed wind (wind speed in time, identical on the plane).As shown in the drawing, the transverse axis of chart attirbutes is orientation angles (degree), and the longitudinal axis is pitch angle (degree), and, form cosine wave (Cosine wave), on 0 ° of orientation angles, get maximum pitch angle (for example 1 °) and on 180 ° of orientation angles, get minimum pitch angle (for example ,-1 °).Certainly, the angle among this figure means relative value.
Its reason is: reach at the wind speed that blade is accepted on the position of 0 ° of maximum orientation angles, must increase the pitch angle in order to reduce aerodynamic quality, and reach at the wind speed that blade is accepted on the position of 180 ° of minimum orientation angles, must reduce the pitch angle in order to improve the air performance.
Identical substantially by the chart attirbutes under the above-mentioned various environment that simulate acquisition also chart attirbutes basic shape with shown in Figure 4, but amplitude, phase place difference.
For example, the generating of air density, wind generating unit output is only being changed under the situation of wind speed as fixed value, wind speed is big more, to the influence of blade loads change just big more (load and wind speed square be directly proportional).
Therefore, when changing wind speed, wind speed is big more, and the cosine wave amplitude shown in Fig. 4 is just big more.
Below, in order to ensure the gap so that blade not with tower collision, the blade of windmill had the angle that makes progress that is called inclination angle (being generally about 5 °) originally.Be subjected to the influence at this inclination angle, the wind that flows into windmill is generally the wind that raises up.
Under the less situation of wind speed, because the influence of above-mentioned wind speed self is very little, therefore, can not consider, but along with the rising of wind speed, the influence at this inclination angle also strengthens.Be used to eliminate described inclination angle the pitch angle correction value of the influence of wind has been shown characteristic shown in Figure 5.
In Fig. 5, line A is the waveform of basic screw-pitch angle shown in Figure 4, and line B is the waveform that is used to eliminate the correction value of the influence that is produced by the inclination angle, and line C is added to the waveform of the pitch angle command value on the waveform of line A for the correction value with line B.
Like this, in simulating, the chart attirbutes that is obtained when wind speed is risen has considered to be subjected to the wind that raises up of above-mentioned inclination effect, therefore, compares with characteristic shown in Figure 4, and not only amplitude difference, and phase place is also different.
In addition, wind direction is also influential to the load change of blade.
For example, when the wind upside, if wind is blown into from the left side, then the influence of the wind of being accepted on 0 ° of orientation angles can increase from the windmill surface of position, and the influence of the wind of being accepted on 180 ° of orientation angles reduces.
Therefore, the pitch angle correction value that is used to eliminate the influence that is produced by described wind deflection has shown the characteristic shown in Fig. 6.
In Fig. 6, line A is the waveform of basic screw-pitch angle shown in Figure 4, and line B is the waveform that is used to eliminate the correction value of the influence that is produced by wind deflection, and line C is added to the waveform of the pitch angle command value on the waveform of line A for the correction value with line B.
Like this, in simulating, the chart attirbutes that is obtained when changing wind direction is the chart of increase and decrease basic screw-pitch angle amplitude shown in Figure 4.
In addition, the generating of wind speed, wind generating unit is exported as fixed value, under the situation that only changes air density, air density is big more, and the influence of blade loads change is also just big more.Therefore, in simulation, changing under the situation of air density, amplitude that can the big more characteristic shown in Figure 4 of air density is big more chart attirbutes just also.Chart attirbutes when Fig. 7 has shown air density as variable.In Fig. 7, line A is the waveform of the pitch angle command value of air density when big, and line B is the waveform of the pitch angle command value of air density hour.
Then, make wind speed, air density be decided to be fixed value, when only changing the output of wind generating unit, if output is greater than setting value (requiring output), the Air Force ratio that then acts on the blade is big when output value is moved on request, in addition, also can act on bigger change Air Force load.Therefore, output greater than the situation that requires to export under, can obtain to have strengthened the chart attirbutes of the amplitude of basic screw-pitch angle shown in Figure 4.Fig. 8 has shown the chart attirbutes when output with wind generating unit is as variable.In Fig. 8, line A is the waveform of the pitch angle command value of output when big, and line B is the waveform of output pitch angle command value hour.
Below, the effect of the blade-pitch-angle control of above-mentioned present embodiment is described.
At first, if command value acquisition unit 13 is obtained orientation angles, obtained wind speed, air density, electricity generating device output from parameter detecting portion 12 from orientation angles detection unit 11, then obtain according to the wind speed of obtaining, air density, electricity generating device output optional features chart from memory section 10.
Afterwards, in the chart attirbutes that obtains, obtain and the corresponding pitch angle command value of importing from orientation angles detection unit 11 of each blade orientation angles.
Thus, can obtain corresponding with the 1st, the 2nd, the 3rd blade respectively pitch angle command value.
The pitch angle command value that command value acquisition unit 13 will obtain in this way outputs to pitch angle control command value generating unit 14.
Pitch angle control command value generating unit 14 is by will be from the pitch angle command value of command value acquisition unit 13 input and the general pitch angle command value addition based on wind generating unit generating output from general pitch angle command value generating unit 15 inputs, thereby generate the pitch angle control command value corresponding, and these pitch angle control command value are outputed to the actuator that corresponding each blade is provided with each blade.
Thus, the pitch angle of each blade can be controlled to be the angle of the most suitable each moment wind generating unit operation conditions.
In addition, if not storage and the on all four chart attirbutes of importing from parameter detecting portion 12 of parameter value in memory section 10 then can be selected the chart attirbutes the most close with these parameter values.Perhaps, also can read a plurality of close chart attirbuteses and these characteristics of interpolation, thereby obtain pitch angle command value.
Above, the blade-pitch-angle control that is applicable to the wind generating unit that has used the constant speed windmill is described.Blade-pitch-angle control of the present invention also can be used for using the wind generating unit of speed change windmill.
Below, the blade-pitch-angle control that is applicable to the wind generating unit that has used the speed change windmill is described.
Under the situation of using the speed change windmill, control the rotating speed of rotor according to the output of wind generating unit.By changing rotational speed (rotating speed), the load change of each blade also can change.Therefore, under the situation of using the speed change windmill,, must also consider the rotating speed of rotor as above-mentioned parameter.Specifically, in the structure of blade-pitch-angle control shown in Figure 1, the parameter as input command value acquisition unit 13 will add rotor speed, and store the chart attirbutes of also having considered rotor speed in memory section 10.
Afterwards, command value acquisition unit 13 is obtained according to the wind speed, air density, electricity generating device output, rotor speed of input and the optional features chart from memory section 10.In the chart attirbutes of obtaining, obtain and the corresponding pitch angle command value of importing from orientation angles detection unit 11 of each blade orientation angles.Afterwards, these pitch angle command value are outputed to pitch angle control command value generating unit 14 respectively.Processing afterwards is identical with above-mentioned first mode of execution.
Though can extremely reduce the load change that in blade, produces by above-mentioned blade-pitch-angle control, still can produce some output changes.This output change significantly appear at the blade quantity frequency band corresponding in.Therefore, can be by obtaining the pitch angle of the output change that is used to remove this remarkable appearance, and it is reflected in the blade-pitch-angle control command value, further reduce the output change with this.
Therefore, in the present embodiment, in blade-pitch-angle control shown in Figure 1, appended output change and removed device with following function.
Fig. 9 has shown that the output that is suitable for when using the constant speed windmill changes the structure of removing device.
As shown in Figure 9, the output change is removed device and is provided with frequency resolution portion (frequency content extraction apparatus) 21, control algorithm portion (computing device) 22, frequency inverse analysis unit (computing device) 23 and calculating part 24.
Frequency resolution portion 21 extracts the frequency content suitable with the blade quantity integral multiple from the output of wind generating unit, and the frequency content of output extraction.For example, when use has the windmill of 3 blades, extract 3N composition (N=integer) out.
Control algorithm portion 22 can will obtain as input signal from the frequency content of frequency resolution portion 21 outputs and the orientation angles that detects by orientation angles detection unit shown in Figure 1 11, and algorithm calculates these information according to the rules, thus, calculate the change pitch angle delta θ (ω) of frequency field and with its output.
Frequency inverse analysis unit 23 can obtain the change pitch angle delta θ (ω) that calculates by control algorithm portion 22 as input signal, and it is carried out change pitch angle delta θ (t) and the output of frequency inverse parsing to calculate time zone.
Calculating part 24 can obtain as input signal with the change pitch angle delta θ (t) of the time zone that calculates by frequency inverse analysis portion 23 with by the general pitch angle command value of general pitch angle command value generating unit 15 (with reference to Fig. 1) output, and their additions, thus general pitch angle command value is finely tuned, the general pitch angle command value after the fine setting is outputed to pitch angle control command value generating unit 14 (with reference to Fig. 1).
Like this, from the output of wind generating unit, extract the frequency content that the load change of each blade is had appreciable impact by frequency analysis portion 21, obtain the pitch angle that can remove this frequency content by control algorithm portion 22 and frequency inverse analysis portion 23, calculating part 24 will be reflected to the general pitch angle command value from the change pitch angle of frequency inverse analysis unit 23 outputs again.
Thus, significant output change can be only accurately removed, thereby stable generating output can be kept.
In addition, under the situation of using the speed change windmill, remove in the device in output change shown in Figure 9, as input signal, input rotor speed.That is,, can become output and carry out the frequency resolution of rotor speed, thereby obtain change pitch angle delta θ (t) in order in the speed change windmill, to export by rotor speed control.Thus, for the speed change windmill, also can carry out the control of more high-precision blade-pitch-angle.
Above, though have been described in detail with reference to the blade-pitch-angle control of accompanying drawing to first embodiment of the invention, concrete structure should not be limited to this mode of execution, it also comprises the design change that does not break away from the aim scope of the present invention.
For example, various parameters are not limited to output, the spinner velocity (rotating speed) of above-mentioned wind speed, air density, wind generating unit, also comprise when carrying out wind-power electricity generation influential any parameters such as outputs.
In addition, also can use the pitch angle of having considered in these parameters all parameters changes, perhaps can only consider the control of pitch angle of the part (for example only considering wind speed) of these parameters.
In addition, parameter also is not limited to detect synchronously the parameter that obtains, and for example, wind speed and orientation angles can detect by predetermined interval, and change little air density etc. in time, and its assay intervals can be longer than the interval of wind speed, orientation angles.
Second mode of execution
Below, the blade-pitch-angle control of second embodiment of the invention is described.
Figure 10 is a block diagram, and it has shown the structure of the blade-pitch-angle control that is applicable to the wind generating unit that has used the speed change windmill.
As shown in figure 10, the blade-pitch-angle control of present embodiment is provided with load measurement portion (load-measuring device) 30, frequency resolution portion (computing device) 31, adjustment pitch angle generating unit (adjusting pitch angle command value generating apparatus) 32, pitch angle control command value generating unit (pitch angle control command value generating apparatus) 36 and general pitch angle command value generating unit 15.
Load measurement portion 30 orientation angles (for example, per 6 °) is in accordance with regulations measured the load that acts on each blade respectively, and measurement result is exported as electrical signal.
For example, this load measurement portion 30 has: orientation angles measuring appliance (orientation angles measuring device), with each blade orientation angles of scheduled time interval measurement; Circuit (triggering generating means) trigger to take place, and produces trigger signal when the measurement result of orientation angles measuring appliance is consistent with predetermined orientation angles (for example, the angle of 6 multiple); And sensor (measuring device), measure load according to triggering the trigger signal that circuit takes place.Herein, the sensor of measuring load can be the resistance strain gauge that is installed on root of blade or the windmill each several part, dynamometer, optical fiber transducer etc.
Frequency resolution portion 31 can obtain the measured value of measuring from load measurement portion 30 with the regulation orientation angles (load) as input signal, and according to this measured value, obtains the cyclical movement that load acts on blade.Specifically,, use calculating formula (1.1), (1.2) shown below, obtain the orientation angles characteristic of load by when guaranteeing to revolve the measured value that turns around.Can represent this orientation angles characteristic by the cosine composition Zic and the sinusoidal composition Zis of load.
[mathematical expression 1]
{ Z ic } n = 2 K Σ k = 1 K zi ( nkΔΨ ) cos ( nkΔΨ ) - - - ( 1.1 )
[mathematical expression 2]
{ Z is } n = 2 K Σ k = 1 K zi ( nkΔΨ ) sin ( nkΔΨ ) - - - ( 1 . 2 )
In above-mentioned (1.1), (1.2) formula, i represents the blade numbering, under the situation that 3 blades are arranged, and i=1,2,3.N is the integer value of the period changing of the corresponding load change of considering, it means: if n=3, then expression has considered to revolve at rotor the load of change when turning around 3 times.The number of times of K for measuring in 0 ° to 360 ° of orientation angles for example, revolves when carrying out 12 load measurements when turning around " K=12 " at rotor 5.Δ Ψ is 360 ° of values divided by K.
Zi (nk Δ Ψ) is that conduct is from the load measurement value in each orientation angles of the input signal of load measurement portion 30.
Then, adjustment pitch angle command value generating unit 32 obtains the analysis result of frequency analysis portion 31 as input information, according to this analysis result, each blade is generated the adjustment pitch angle command value that is used to reduce load change respectively.This adjustment pitch angle command value generating unit 32 has the command value calculating part 33 of adjustment and frequency inverse analysis portion 34.
The cosine composition Zic and the sinusoidal composition Zis that adjust the load change that command value calculating part 33 will obtain by frequency analysis portion 31 obtain as input signal, and calculate this input signal Zic, Zis, thereby respectively each blade is obtained the adjustment command value θ dem that is used to eliminate the remarkable load change that periodically occurs by the transfer function of regulation.Herein, the adjustment command value θ that obtains 1Dem, θ 2Dem, θ 3Dem is the value on the frequency field.
In addition,, can adopt by supposing that various load changes simulate, and analyze this and simulate the result and obtain the best command value of adjusting, obtain the method etc. of transfer function again from this result as obtaining the method for adjusting the transfer function that command value calculating part 33 uses.
Perhaps, also can set a plurality of transfer functions, use according to the selected optimal transfer function of the operation conditions of windmill again according to the operation conditions of windmill.Thus, can obtain the adjustment command value that comparatively is fit to.
Then, frequency inverse analysis unit 34 will be as the adjustment command value θ of the value on the frequency field of obtaining by adjustment command value calculating part 33 1Dem, θ 2Dem, θ 3Dem is transformed to the value on the time zone.
That is, this adjustment command value is the value of obtaining with the measured load of regulation orientation angles according to load measurement portion 30 originally.Therefore, frequency resolution portion 31, adjustment command value calculating part 33 handled information become the characteristic that changes with angle or adjust command value.
On the other hand, because the described general pitch angle command value of obtaining by general pitch angle command value generating unit 15 in back is the command value that changes in time, promptly therefore the command value on the time shaft, must be integrated these command value.
Therefore, frequency inverse analysis unit 34 is used the current orientation angles information and the function of regulation, will adjust command value θ 1Dem, θ 2Dem, θ 3Dem is converted to the value θ on the time zone 1(t), θ 2(t), θ 3(t).
Afterwards, with the adjustment command value θ after the conversion 1(t), θ 2(t), θ 3(t) as adjusting pitch angle command value, be delivered to pitch angle control command value generating unit 36.
In pitch angle control command value generating unit 36, from adjusting the adjustment pitch angle command value that 32 inputs of pitch angle command value generating unit are used to reduce load change, be used to make the general pitch angle command value of the current output feedback control amount consistent from general pitch angle command value generating unit 15 input conducts with desired value.This general pitch angle command value is the command value that each blade pass is used.Pitch angle control command value generating unit 36 is by the general pitch angle command value that will import and the adjustment pitch angle command value θ of each blade 1(t), θ 2(t), θ 3(t) respectively addition generates and is used for pitch angle control command value that the pitch angle of each blade is controlled separately, and each pitch angle control command value is outputed to the actuator of the pitch angle that is used to control each blade.
Thus, by actuator, control each blade-pitch-angle according to control command value.
As mentioned above, the blade-pitch-angle control of present embodiment can obtain following effect.
The 1st because no matter the rotational speed of blade how, load is all measured with the orientation angles of regulation by load measurement portion 30, therefore, its advantage is not to be only applicable to the constant speed windmill, also is applicable to the speed change windmill of blade rotational speed with the operation conditions variation.
The 2nd, load measurement portion 30 acts on load on each blade with the orientation angles measurement of regulation, the change characteristic of frequency resolution portion 31 analytical cycle loads, according to this analysis result, adjust pitch angle command value generating unit 32 and obtain the adjustment pitch angle command value that is used to eliminate this load change, pitch angle control command value generating unit 36 will be adjusted pitch angle command value and be reflected in the control of each blade-pitch-angle.Thus, can reduce the periodically significantly load change of appearance.
The 3rd, owing to be conceived to the blade loads change that periodically significantly occurs, and be purpose to reduce this periodic load change, therefore,, still can remove load change with highi degree of accuracy even cause time lag by feedback control.Thus, compare, can reduce load change effectively by the processing of simplifying greatly with the pitch angle control in the past of the load change that reduces instantaneous appearance.As a result, each blade can be controlled to be best pitch angle, thereby prolong the life-span of the mechanical parts of blade and formation windmill.
The 4th, because load measurement portion 30 constitutes by produce the triggering generator of trigger signal and measurement is loaded according to trigger signal sensor with the orientation angles measuring appliance of each blade orientation angles of scheduled time interval measurement, when measurement result is consistent with predetermined orientation angles, therefore, be easy to realize load measurement device 30.In addition, for example, load measurement device 30 also can constitute by the encoder that produce to trigger when orientation angles reaches predetermined angle with according to the sensor that load is measured in above-mentioned triggering.Because these encoders and sensor are well-known mechanisms, therefore, can realize load-measuring device in simple mode.
Above, with reference to accompanying drawing second mode of execution of the present invention being had been described in detail, concrete structure is not limited to this mode of execution, also is included in the design variations etc. in the scope that does not break away from purport of the present invention.
The 1st, replace the load measurement portion 30 of above-mentioned mode of execution, also can adopt the acceleration analysis portion that is used to measure the blade acceleration, the blade acceleration in the measuring gage orientation angle, and calculate the optimum pitch angle that is used to reduce this acceleration.Thus, can reduce the acceleration of the mechanical parts of blade or formation windmill.In addition, owing to have when bearing load change, vibration can take place and produce this incidence relation of acceleration in the mechanical parts of blade and formation windmill, therefore, by reducing acceleration in the above described manner, also can correspondingly reduce load change.
The 2nd, in the above-described embodiment, though the situation that is applicable to the speed change windmill is illustrated,, the blade-pitch-angle control of present embodiment also is applicable to the wind generating unit that has used the constant speed windmill.For the constant speed windmill, the information of input is not the rotational speed of generator in general pitch angle command value generating unit 15, and becomes the output of generator, and general pitch angle command value is to make the generator output command value consistent with desired value.
The 3rd, also can adopt such structure, that is: realize the contents processing that said frequencies analysis unit 31, adjustment command value calculating part 33, frequency inverse analysis unit 34, general pitch angle command value generating unit 15, pitch angle control command value generating unit 36 each several parts carry out respectively by a computer installation.This structure can realize that each functional programs is stored in the storage medium that computer-readable is got with being used for, and the program in this storage matrix of will being recorded in reads in the computer system and carry out, thereby handles.

Claims (5)

1. a blade-pitch-angle control uses in having the wind generating unit of a plurality of blades, wherein, has:
Storage device is used to make predefined parameter, orientation angles and the pitch angle command value of the described blade loads change of influence to set up association mutually and stored;
The orientation angles detection device is used to detect the orientation angles of described each blade;
Parameter detection device is used to detect described predefined parameter;
The command value obtaining device, be used for described each blade, obtain pitch angle command value from described storage device respectively, this pitch angle command value is selected according to the orientation angles of described each blade that is detected by described orientation angles detection device with by the predefined parameter that described parameter detection device detects; And
Pitch angle control command value generating apparatus, according to described pitch angle command value of obtaining by described command value obtaining device and the general pitch angle command value used by each blade pass that the output information of described wind generating unit is obtained, generate and be used for pitch angle control command value that the pitch angle of described blade is controlled separately.
2. blade-pitch-angle control according to claim 1 wherein, is set at the value that the described wind generating unit of reflection is provided with wind shear characteristic in the place with the described pitch angle control command value that is stored in the described storage device.
3. blade-pitch-angle control according to claim 1, wherein,
Described predetermined parameter is a wind speed,
Described parameter detection device is the wind speed estimating unit, this wind speed estimating unit has makes wind speed set up related chart attirbutes with the output of described wind generating unit, and infers wind speed by reading from described chart attirbutes with the output corresponding air speed of described wind generating unit.
4. blade-pitch-angle control according to claim 1 wherein, has:
The frequency content extraction apparatus, any frequency content of extracting the blade quantity integral multiple from generating output, generator speed or the rotor speed of described wind generating unit; With
Computing device calculates the pitch angle that is used to remove the load change that is caused by this frequency variation according to this frequency content of extracting,
Described pitch angle control command value generating apparatus will be reflected to by the pitch angle that described computing device calculates in the described pitch angle control command value.
5. a wind generating unit has a plurality of blades, wherein, has blade-pitch-angle control, and this blade-pitch-angle control has:
Storage device is used to make regulation parameter, orientation angles and the pitch angle command value of the described blade loads change of influence to set up association mutually and stored;
The orientation angles detection device is used to detect the orientation angles of described each blade;
Parameter detection device is used to detect described predefined parameter;
The command value obtaining device, be used for described each blade, obtain pitch angle command value from described storage device respectively, this pitch angle command value is selected according to the orientation angles of described each blade that is detected by described orientation angles detection device with by the predefined parameter that described parameter detection device detects; And
Pitch angle control command value generating apparatus, according to described pitch angle command value of obtaining by described command value obtaining device and the general pitch angle command value used by each blade pass that the output information of described wind generating unit is obtained, generate and be used for pitch angle control command value that the pitch angle of described blade is controlled separately.
CNB2004800227452A 2003-09-10 2004-09-09 Blade pitch angle control device and wind turbine generator Active CN100385111C (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
JP318312/2003 2003-09-10
JP2003318312A JP4064900B2 (en) 2003-09-10 2003-09-10 Blade pitch angle control device and wind power generator
JP143642/2004 2004-05-13

Related Child Applications (1)

Application Number Title Priority Date Filing Date
CN2008100837576A Division CN101270724B (en) 2003-09-10 2004-09-09 Blade-pitch-angle control device and wind power generator

Publications (2)

Publication Number Publication Date
CN1833103A CN1833103A (en) 2006-09-13
CN100385111C true CN100385111C (en) 2008-04-30

Family

ID=34417624

Family Applications (2)

Application Number Title Priority Date Filing Date
CNB2004800227452A Active CN100385111C (en) 2003-09-10 2004-09-09 Blade pitch angle control device and wind turbine generator
CN2008100837576A Active CN101270724B (en) 2003-09-10 2004-09-09 Blade-pitch-angle control device and wind power generator

Family Applications After (1)

Application Number Title Priority Date Filing Date
CN2008100837576A Active CN101270724B (en) 2003-09-10 2004-09-09 Blade-pitch-angle control device and wind power generator

Country Status (2)

Country Link
JP (1) JP4064900B2 (en)
CN (2) CN100385111C (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101892954A (en) * 2010-07-20 2010-11-24 上海德重科技有限公司 Continuous positioning mode-based wind power variable-pitch driving method

Families Citing this family (37)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20080112807A1 (en) * 2006-10-23 2008-05-15 Ulrich Uphues Methods and apparatus for operating a wind turbine
BE1017458A3 (en) * 2007-02-06 2008-10-07 Hansen Transmissions Int WIND TURBINE.
EP2153062B1 (en) 2007-05-31 2010-12-01 Vestas Wind Systems A/S A method for operating a wind turbine, a wind turbine and use of the method
US20110020136A1 (en) 2008-06-10 2011-01-27 Mitsubishi Heavy Industries, Ltd. Blade pitch-angle control apparatus and wind turbine generator
JP5400161B2 (en) * 2008-09-18 2014-01-29 サムスン ヘヴィ インダストリーズ カンパニー リミテッド Pitch control device and system for wind power generator
SE533325C2 (en) * 2008-10-24 2010-08-31 Hm Power Ab Removable wind turbine (Control circuit)
KR101063112B1 (en) * 2008-11-17 2011-09-07 두산중공업 주식회사 Wind power generation system
KR101204551B1 (en) 2009-04-10 2012-11-23 미츠비시 쥬고교 가부시키가이샤 Pitch drive device of wind-driven generator and wind-driven generator
KR101168529B1 (en) 2009-08-19 2012-07-27 미츠비시 쥬고교 가부시키가이샤 Windmill, and method of removing ice from windmill blades
BRPI1000022A2 (en) * 2010-02-08 2017-01-17 Mitsubishi Heavy Ind Ltd wind turbine generator and method for controlling the angle of inclination of the blade.
GB2479415A (en) * 2010-04-09 2011-10-12 Vestas Wind Sys As Wind Turbine Independent Blade Control Outside The Rated Output
JP5703685B2 (en) * 2010-10-27 2015-04-22 シンフォニアテクノロジー株式会社 Wind power generator and blade pitch angle control device thereof
AU2011202348A1 (en) * 2011-03-11 2012-09-27 Mitsubishi Heavy Industries, Ltd. Blade pitch control system, wind turbine generator, and blade pitch control method
KR101304402B1 (en) 2011-03-11 2013-09-05 삼성중공업 주식회사 Variable speed wind turbine system
EP2694807B1 (en) * 2011-04-07 2016-08-17 Siemens Aktiengesellschaft Method of controlling pitch systems of a wind turbine
CN102777318B (en) * 2011-05-11 2016-03-02 许继集团有限公司 A kind of MW class wind turbine group pitch-variable system motion control method
CN102230453A (en) * 2011-06-22 2011-11-02 三一电气有限责任公司 Fan, fan wind wheel, fan wind wheel blade and fan control device
CN102562450B (en) * 2012-01-12 2014-04-02 三一电气有限责任公司 Wind driven generator and pitch control method and pitch control system thereof
CN102900609B (en) * 2012-10-26 2014-08-20 华北电力大学 Giant magnetostrictive flap wind turbine blade vibration reduction system and control method
DE102012222323A1 (en) * 2012-12-05 2014-06-05 Wobben Properties Gmbh Wind energy plant and method for operating a wind energy plant
KR101379268B1 (en) 2013-01-11 2014-03-28 삼성중공업 주식회사 Wind power generating system to operate using wind speed compensation
US20140203560A1 (en) * 2013-01-22 2014-07-24 General Electric Company Wind turbine and method for adjusting rotor blade pitch angle in wind turbine
JP5984791B2 (en) * 2013-12-20 2016-09-06 三菱重工業株式会社 Wind power generator monitoring system and monitoring method
JP6165053B2 (en) * 2013-12-27 2017-07-19 株式会社日立製作所 Wind power generator
CN103850876B (en) * 2014-03-14 2016-03-09 华北电力大学 A kind of Wind turbines independent pitch control method being applicable to no-load and measuring
DE102014206884A1 (en) * 2014-04-09 2015-10-15 Wobben Properties Gmbh Method for feeding electrical energy by means of a wind energy plant
TWI626370B (en) 2014-11-06 2018-06-11 Hitachi Ltd Method of controlling a wind power generation device
KR101651414B1 (en) * 2015-01-09 2016-08-26 두산중공업 주식회사 Method and method for performance enhancement of wind turbine
CN104632524B (en) * 2015-02-03 2017-07-21 北京金风科创风电设备有限公司 The control device and method of wind power generating set
JP6436808B2 (en) * 2015-02-06 2018-12-12 株式会社日立製作所 Wind power generator and operation method thereof
CN105626377B (en) * 2015-12-23 2018-02-06 安徽理工大学 A kind of directly driven wind-powered unit allocation method of distributing based on memory
DE102016103254A1 (en) * 2016-02-24 2017-08-24 Wobben Properties Gmbh Method for determining an equivalent wind speed
KR101894975B1 (en) * 2016-07-22 2018-09-06 (주)설텍 Control system of Wind turbin
CN107762739B (en) * 2016-08-18 2018-12-25 北京金风科创风电设备有限公司 The azimuthal measurement method of impeller and device
DE102016125045A1 (en) * 2016-12-20 2018-06-21 Wobben Properties Gmbh Method for controlling a wind energy plant
DE102019113044A1 (en) * 2019-05-17 2020-11-19 Wobben Properties Gmbh Process for the design and operation of a wind energy installation, wind energy installation and wind farm
CN113738579B (en) * 2021-09-27 2023-10-20 国电联合动力技术有限公司 Wind generating set control method and device and electronic equipment

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2067247A (en) * 1980-01-10 1981-07-22 Erno Raumfahrttechnik Gmbh A device for determining the wind energy in order to control wind generators
US4339666A (en) * 1980-12-24 1982-07-13 United Technologies Corporation Blade pitch angle control for a wind turbine generator
US4656362A (en) * 1982-11-08 1987-04-07 United Technologies Corporation Blade pitch angle control for large wind turbines
JPH06117353A (en) * 1992-10-05 1994-04-26 Yamaha Motor Co Ltd Wind power generating device
US20020047275A1 (en) * 1997-07-25 2002-04-25 Aloys Wobben Wind energy installation
JP2003113769A (en) * 2001-10-03 2003-04-18 Mitsubishi Heavy Ind Ltd Blade pitch angle control device and wind force power generating device

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2002048050A (en) * 2000-08-07 2002-02-15 Mitsubishi Heavy Ind Ltd Method and device for controlling pitch angle of wind power plant
JP2002349412A (en) * 2001-05-28 2002-12-04 Ebara Corp Windmill for wind power generation and its control method
JP4183406B2 (en) * 2001-09-06 2008-11-19 三菱重工業株式会社 Wind power generation control device and control method thereof

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2067247A (en) * 1980-01-10 1981-07-22 Erno Raumfahrttechnik Gmbh A device for determining the wind energy in order to control wind generators
US4339666A (en) * 1980-12-24 1982-07-13 United Technologies Corporation Blade pitch angle control for a wind turbine generator
US4656362A (en) * 1982-11-08 1987-04-07 United Technologies Corporation Blade pitch angle control for large wind turbines
JPH06117353A (en) * 1992-10-05 1994-04-26 Yamaha Motor Co Ltd Wind power generating device
US20020047275A1 (en) * 1997-07-25 2002-04-25 Aloys Wobben Wind energy installation
JP2003113769A (en) * 2001-10-03 2003-04-18 Mitsubishi Heavy Ind Ltd Blade pitch angle control device and wind force power generating device

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101892954A (en) * 2010-07-20 2010-11-24 上海德重科技有限公司 Continuous positioning mode-based wind power variable-pitch driving method
CN101892954B (en) * 2010-07-20 2012-12-19 上海德重科技有限公司 Continuous positioning mode-based wind power variable-pitch driving method

Also Published As

Publication number Publication date
JP2005083308A (en) 2005-03-31
JP4064900B2 (en) 2008-03-19
CN101270724A (en) 2008-09-24
CN101270724B (en) 2013-07-17
CN1833103A (en) 2006-09-13

Similar Documents

Publication Publication Date Title
CN100385111C (en) Blade pitch angle control device and wind turbine generator
EP2562415B1 (en) Blade-pitch-angle control device and wind power generator
CN102072965B (en) Wind sensor system using blade signals
CN101495747B (en) Calibration method
KR101476986B1 (en) Control device for a wind power plant
Bottasso et al. Wind tunnel testing of scaled wind turbine models: Beyond aerodynamics
US20140167415A1 (en) Method of wind turbine yaw angle control and wind turbine
CN101625260B (en) Method for detecting high speed rotating blade synchronous vibration parameters under speed change
US11313351B2 (en) Methods and systems of advanced yaw control of a wind turbine
CN115544883A (en) Online measurement method and system for load and platform deformation of floating type offshore wind turbine generator
Bottasso et al. Cascading kalman observers of structural flexible and wind states for wind turbine control
CN211085467U (en) A calibration system for taking hat blade vibration measurement
WO2022064038A1 (en) Method and system for wind speed determination using vibration data
Mankowski et al. Real-time Monitoring of Wind Turbine Blade Alignment Using Laser Measurement
WO2020127324A1 (en) A method and a system for determining the wind speed or the wind direction experienced by a wind turbine
Vermeer et al. Velocity measurements in the near wake of a model rotor and
MXPA06001804A (en) Blade pitch angle control device and wind turbine generator
JP4822742B2 (en) Wind-up angle measuring method and horizontal axis windmill
Hemon et al. Experimental investigation of horizontal axis wind turbine dynamic stall in a wind tunnel
Connell Basic principles and recent observations of rotationally sampled wind

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
CI02 Correction of invention patent application

Correction item: Priority

Correct: 2004.05.13 JP 143642/2004

False: Lack of priority second

Number: 37

Page: The title page

Volume: 22

COR Change of bibliographic data

Free format text: CORRECT: PRIORITY; FROM: MISSING THE SECOND ARTICLE OF PRIORITY TO: 2004.5.13 JP 143642/2004

C14 Grant of patent or utility model
GR01 Patent grant