CN102332861A - Method for controlling active power of double-fed wind power generator - Google Patents
Method for controlling active power of double-fed wind power generator Download PDFInfo
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- CN102332861A CN102332861A CN201110279529A CN201110279529A CN102332861A CN 102332861 A CN102332861 A CN 102332861A CN 201110279529 A CN201110279529 A CN 201110279529A CN 201110279529 A CN201110279529 A CN 201110279529A CN 102332861 A CN102332861 A CN 102332861A
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Abstract
The invention discloses a method for controlling the active power of a double-fed wind power generator. The double-fed wind power generator has a double-fed motor, wherein the double-fed motor has a stator and a driving rotor; the stator supplies power to a power grid; the power grid has a voltage with a rated value; the driving rotor is coupled with the stator; one end of the driving rotor is connected to a wind turbine through a speed-changing gear; rotor windings are three-phase coiling type rotor windings; the power grid supplies power to the driving rotor through a converter; and by decomposing a stator voltage and a rotor flux linkage on a synchronously rotary dq coordinate axis, the active power which is output by the stator of the generator can be controlled by regulating a rotor current. The method has the advantages that: the complicated conversion and calculation of vector rotation change and the like are not required; a current control module is relatively lower in control sensitivity; current control is less influenced by circuit parameters of a converter system and measurement delay; a control technology is simple; the cost of a controller is reduced; and the method is applicable to a low-power wind power generator.
Description
Technical field
The present invention relates to a kind of wind-driven generator, particularly be connected to the control method of electrical network double-fed wind power generator active power.
Background technology
Receive the generally attention of countries in the world as the wind energy of renewable green energy resource growing in energy resource consumption, that environmental pollution is day by day serious today, and wind generating technology also becomes the focus that various countries scholar in recent years competitively studies.Wind energy is a kind of frequent energy at random that changes; The variable-speed constant-frequency wind power generation technology can guarantee that the wind energy under most wind speed is caught to greatest extent and utilized; And have traditional constant-speed and constant-frequency wind generating technology incomparable superiority; And double-fed wind power generator can satisfy the specification requirement of variable-speed constant-frequency wind power generation well, becomes a kind of control strategy of relatively optimizing at present.It is to apply three-phase alternating current through two PWM current transformers in the rotor-side of double-fed generator to carry out excitation, through regulating effective value, phase place and the frequency of exciting current, realizes the meritorious control with reactive power of stator side output.
Double-fed wind power generator the basic hardware topology as shown in Figure 1, the stator of generator is directly connected to electrical network, the rotor winding links to each other with electrical network through current transformer through collector ring; Through frequency, the effective value of control rotor current, phase place and phase sequence are utilized two PWM current transformers; Through the SPWM control technology; Can obtain sinusoidal wave rotor current,, realize that stator side output is gained merit and the control of reactive power to reduce the harmonic torque in the generator.
Because there is the coupling on the magnetic circuit in the circuit of double-fed generator, and the Mathematical Modeling its three phase coordinate system under be non-linear, the time change high order system.For realize gaining merit, idle decoupling zero control; Usually adopt vector control method; Vector control is theoretical according to transform vector; Adopting and press stator field direction orientation, is the rotor current resolution of vectors two mutually perpendicular current components in synchronous rotating frame, realizes the decoupling zero of generator active power and reactive power is regulated.But realize decoupling zero for making motor; Need to simplify motor model; Also to carry out complicated conversion and calculating such as vector rotation change; And current control module control susceptibility is higher, and the circuit parameter of converter system, measurement time-delay and phase-locked loop performance all have bigger influence to Current Control, and these factors have caused the robustness of vector control method on the low side.Work as circuit parameter, when measurement time-delay and other system factor changed, the obvious change can take place in controller stability, strengthened the debugging difficulty of controller parameter.
Summary of the invention
The objective of the invention is to overcome the deficiency of existing double-fed wind power generator active power control method, a kind of conversion of complicacies such as vector rotation change and double-fed wind power generator active power control method of calculating of need not carrying out is provided.
If the stator voltage of generator, electric current, flux linkage vector be
and
rotor voltage, electric current, flux linkage vector for
and
then when steady operation, the electric moter voltage equation is:
Wherein Rs, Rr, ω
s, ω
rBe respectively motor stator, the every phase resistance of rotor, the angular velocity of rotation of the synchronous rotating magnetic field of stator, rotor rotating magnetic field, vector is static relatively in the space in the formula, all with the synchronizing speed rotation, under synchronously rotating reference frame dq axle system
U
sd=R
sI
sd+ω
sψ
sq (3)
U
sq=R
sI
sq-ω
sψ
sd (4)
ψ wherein
Sd, ψ
SqFor
Component on d, q axle, its value is:
ψ
sd=L
sI
sd+L
MI
rd (5)
ψ
sq=L
sI
sq+L
MI
rq (6)
Wherein, I
Sd, I
SqBe respectively
Component on d, q axle, I
Rd, I
RqBe respectively
Component on d, q axle.L
sBe stator winding self-induction, L
MBe the rotor winding mutual inductance, can get by formula (3), (4):
(7), (8) substitution (5), (6) can be got
And the active power P of stator side is:
P=U
sdI
sd+U
sqI
sq (11)
Formula (9), (10) substitution (11) are got:
If X
2=ψ
SdI
Rq-ψ
SqI
Rd
Then
When motor parallel arrived infinitely great electrical network, Us was constant, ψ
sCan be approximately constant, R
s, L
s, L
M, ω
sAlso be constant, so the active power of generator unit stator output only and X
2Relevant, control X
2Just can realize that Fig. 2 is a stator magnetic linkage to the meritorious control of stator output, the distribution of rotor current vector on the dq synchronization rotational coordinate ax can be known by Fig. 2,
Wherein A, B are respectively
and the angle of d axle;
is the angle between stator magnetic linkage and rotor current vector, then double-fed wind power generator active power control method such as Fig. 3.
The given in advance rotor excitation current I of generator
r, drag down at wind turbine, be connected to the grid, then can measure voltage, electric current U, the I of stator output, and calculate the active power P of stator output, according to the magnetic linkage model, can calculate stator magnetic linkage.
It is P* that given stator output has power; The active power P that compares the output of P* and stator; Obtain the two difference; Set-point
controller that utilizes PI adjusting algorithm can obtain rotor excitation current Ir is regulated the current transformer control impuls according to set-point
, obtains the output of rotor excitation current.
Because the present invention adopts technique scheme, in the wind power generation steady operation, need not to carry out complicated conversion and calculating such as vector rotation change; Current control module control susceptibility is lower; The circuit parameter of converter system, to measure time-delay less to the influence that Current Control all has, though the real-time and the precision of control decrease, control technology is very simple; Therefore the cost of controller also reduces, and is fit to the application of low power wind driven generator.
Description of drawings
Fig. 1 be double-fed wind power generator the basic hardware topological structure;
Fig. 2 is according to double-fed aerogenerator stator magnetic linkage of the present invention, rotor current vector correlation figure;
Fig. 3 is according to double-fed wind power generator active power control block diagram of the present invention.
Embodiment
Below in conjunction with specific embodiment the present invention is done further detailed description.
The basic hardware topological structure of double-fed wind power generator is as shown in Figure 1, and electrical network is the rotor power supply of double-fed wind power generator through current transformer, and generator is under blower fan drives, and its stator is meritorious and idle to electrical network output.It is to utilize zero load and locked rotor test to measure the parameter of electric machine that generator parameter mensuration has a lot of known method, the most frequently used method.Utilize the method in the document 1, also can obtain the parameter of this generator, for example stator resistance R
s, stator winding inductance L s, rotor winding mutual inductance L
MEtc. parameter.
Document 1: " estimation of asynchronous motor parameter and measurement in the vector control system ", Ma Xiaoliang, electric drive, 2010 the 40th the 7th phases of volume.
Can detect generator rotor position through photoelectric coded disk, and then can obtain rotor speed, thereby obtain motor slip frequency ω through differential
2And observation stator magnetic linkage
has three class methods: direct Detection Method, indirect calculation method, and based on the method for high-frequency signal injection.Direct Detection Method is to embed magneto sensor at the air gap place of stator α axle and β axle, directly detects the component ψ of stator magnetic linkage at stator α axle and β axle
α sAnd ψ
β sCan try to achieve the effective value ψ of stator magnetic linkage in view of the above
sAnd with the angle of α axle.The indirect calculation method is set up the flux observation model through physical quantitys such as stator voltage, electric currents, in control, calculates the effective value and the phase place of stator magnetic linkage in real time.Traditional method is to adopt voltage model to observe stator magnetic linkage, and obtains stator magnetic linkage through the integral and calculating to back-emf signal.Owing to this method have the parameter of electric machine that needs few with do not need the advantage of rotary speed information to obtain extensive use, its expression formula is:
ψ
s=∫(U
s-i
sR
s)dt
Method based on high-frequency signal injects need be injected high-frequency signal at the stator winding of asynchronous machine, and non-ideal characteristic through motor such as magnetic saturation effect etc. obtain the effective value and the direction of motor magnetic linkage.
When double-fed wind power generator active power is controlled, at first utilize zero load and locked rotor test to measure the motor stator resistance R
s, stator winding inductance L s, rotor winding mutual inductance L
MEtc. parameter, the given in advance rotor excitation current of generator
Drag down at wind turbine, be connected to the grid, then can measure voltage, electric current U, the I of stator output, and calculate the active power P of stator output,, can calculate the effective value ψ of stator magnetic linkage according to the magnetic linkage model
sWith in α β reference axis phase place, it is transformed on the dq rotating shaft, with given in advance rotor excitation current
Also be mapped on the dq rotating shaft, then on this reference axis, the angle that can obtain stator magnetic linkage and rotor excitation current does
Order
Given stator active power of output is P
*, compare P
*With the active power P of stator output, obtain the poor Δ P=P of the active power of given stator active power of output and the actual output of stator
*-P utilizes PI incremental adjustments algorithm can obtain X
2Increment Delta X
KValue,
Wherein, K
pBe proportionality coefficient, T
pBe integration time constant, can confirm through conventional parameter tuning method.And Δ P
K, Δ P
K-1Be active power poor of given stator active power of output and the actual output of stator in the K time and the K-1 time sampling period, T is the time in a sampling period.The controlled quentity controlled variable that then should import is X
K=X
2+ Δ X
K, order
At X
KDuring for certain value, unlikely too big for making the rotor current effective value, can be given
Be unspecified angle between 30 to 90 degree
Because the phase place of stator magnetic linkage draws according to the magnetic linkage model, making its d axle clamp angle with synchronous rotating shaft is A,
Be the angle between stator magnetic linkage on the dq axle and rotor current vector, therefore can obtain the phase place of rotor current on the dq axle,, can know that it and d axle clamp angle do according to Fig. 2
And rotor current vector effective value does
Thereby, under the control action of current-variable controller, with d axle clamp angle do to the output of rotor winding
Effective value does
The rotor current of slip frequency, the i.e. active power of exportable needs.
Claims (4)
1. the control method of a double-fed wind power generator active power, said double-fed wind power generator has double feedback electric engine, and this motor has the stator to mains supply, and said electrical network has the voltage of rated value; Driving rotor with said stator coupling; Said rotor one end is connected to wind turbine through change-speed gearing; Said rotor winding is a three-phase phase-wound rotor winding; Electrical network is the rotor power supply through current transformer, and said current transformer is connected with the rotor winding with collector ring through brush, and said method comprises the steps:
(a) utilize zero load and locked rotor test to measure the motor stator resistance R
s, stator winding inductance L s, rotor winding mutual inductance L
MEtc. parameter, change step (b);
(b) a given in advance rotor excitation current
drags down at wind turbine; Be connected to the grid, change step (c);
(c) given stator active power of output is P
*, change step (d);
(d) given sampling period T detects generator rotor position through photoelectric coded disk, and then can obtain rotor speed through differential, thereby obtains motor slip frequency ω
2, measure voltage, the current phasor U of the K time output of stator
K, I
K, and calculate the active power P that stator is exported for the K time
K(K=1,2 ...), compare P
*With P
K, obtain P
*With P
KPoor Δ P
K=P
*-P
K, and with Δ P
KStore in the memory cell of controller, measure or, calculate the effective value ψ of stator magnetic linkage according to the magnetic linkage model
sAnd the phase place on static α β reference axis, it is converted on the dq synchronization rotational coordinate ax, obtain the stator magnetic linkage vector and d axle clamp angle is A, with rotor excitation current
Also be mapped on the dq rotating shaft, on this reference axis, can obtain the angle of stator magnetic linkage and rotor excitation current
Order
Change step (e);
(e) at Δ P
KThe basis on, utilize PI incremental adjustments algorithm can obtain X
2Increment Delta X
K, change step (f);
(f) obtain X
K=X
2+ Δ X
K, change step (g);
(g) given
For unspecified angle between 30 to 90 degree, under the control action of current-variable controller, go up and d axle clamp angle does to synchronization rotational coordinate ax dq to rotor winding output transform
Effective value does
Frequency is slip frequency ω
2Rotor current, change step (h);
2. the control method of double-fed wind power generator active power as claimed in claim 1, wherein in the step (e), PI incremental adjustments algorithm obtains X
2Increment Delta X
KMethod be:
Wherein, K
pBe proportionality coefficient, T
pBe integration time constant, can confirm through conventional parameter tuning method.And Δ p
K, Δ p
K-1Be active power poor of given stator active power of output and the actual output of stator in the K time and the K-1 time sampling period, T is the time in a sampling period.
3. the control method of double-fed wind power generator active power as claimed in claim 1; Wherein in the step (c), the magnetic linkage model is
electric current and voltage model.
4. the control method of double-fed wind power generator active power as claimed in claim 1 wherein in the step (c), embeds magneto sensor at the air gap place of stator α axle and β axle, directly detects the component ψ of stator magnetic linkage at stator α axle and β axle
α sAnd ψ
β sCan try to achieve the effective value β of stator magnetic linkage in view of the above
sAnd with the angle of α axle.
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Cited By (3)
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---|---|---|---|---|
CN103886791A (en) * | 2012-12-19 | 2014-06-25 | 沈阳工业大学 | Dynamic-simulation bidirectional wind power energy conversion experiment table based on doubly-fed generator and experiment method |
CN103944478A (en) * | 2014-04-08 | 2014-07-23 | 东北大学 | Alternating-current excitation synchronous machine control device and method |
CN111289894A (en) * | 2018-12-10 | 2020-06-16 | 广东威灵汽车部件有限公司 | Locked rotor detection method, system and device of motor and storage medium |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103886791A (en) * | 2012-12-19 | 2014-06-25 | 沈阳工业大学 | Dynamic-simulation bidirectional wind power energy conversion experiment table based on doubly-fed generator and experiment method |
CN103944478A (en) * | 2014-04-08 | 2014-07-23 | 东北大学 | Alternating-current excitation synchronous machine control device and method |
CN103944478B (en) * | 2014-04-08 | 2016-05-11 | 东北大学 | A kind of AC excitation synchronous motor control device and method |
CN111289894A (en) * | 2018-12-10 | 2020-06-16 | 广东威灵汽车部件有限公司 | Locked rotor detection method, system and device of motor and storage medium |
CN111289894B (en) * | 2018-12-10 | 2022-02-25 | 广东威灵汽车部件有限公司 | Locked rotor detection method, system and device of motor and storage medium |
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