The present invention generally relates to a wind farm. More particularly, it relates to a method to suppress the unbalanced voltage at the Point of Common Coupling of wind farm.
Wind generation grows rapidly around the world due to its merits such as economic, environmental and technological issues. The curtailment of power is a common phenomenon in the large-scale centralized wind farms because the export and local consumption problems cannot be solved completely, especially in Northwest, Northern, and Northeast China. Recently, several policies are released to encourage the development of DWF in China, because the DWF can achieve the balancing and consumption of the electricity locally compared to the large-scale centralized wind farm. Generally, most DWFs are built in the remote area (i.e., the end of regional grid) owing to the limitation of the topographical and wind resources conditions. Therefore, the wind power from DWF should be transferred to the load centers via a relatively long transmission line, which makes the grid weak. The short-circuit ratio (SCR) is defined by short-circuit capacity over installed capacity of wind farm, always used to describes the strength of the grid.
A grid connection can be regarded as weak when SCR is less than 3, and very weak when SCR is less than 2. In a weak grid, the voltage unbalance phenomenon often occurs due to various grid faults or variation of unbalance and impact loads, such as high-speed train.
The voltage at the point of common coupling (PCC) of DWF can be kept stable, because the doubly fed induction generator (DFIG) and permanent magnetic synchronous generator (PMSG) can regulate reactive power independently by controlling inverter. In other words, the DWF with DFIG or PMSG has the low-voltage ride through ability, which can meet the grid code. A static synchronous compensator (STATCOM) is a standard configuration in the DWF because it can provide dynamic reactive power to support the voltage at the PCC in a short time. In fact, it is necessary to configure the STATCOM for the DWF especially in an unbalanced grid or a fault condition.
Recently, the cascaded H-bridges (CHB) STATCOM has been used in DWF because of its large-capacity, high-voltage and few harmonic currents. For the CHB-STATCOM, the dc capacitor voltages of three-phase clusters become unbalanced when it is required to inject the negative-sequence current because the negative-sequence current can lead to unequal distribution of active power among three-phase clusters. Such phenomenon will result in over-modulation problem and make the system unstable. To address this problem, the zero-sequence voltage injecting and the third harmonic voltage injecting methods were studied. All of the mentioned methods can redistribute the active power of three-phase clusters; thus, the dc capacitor of three-phase clusters can be balanced effectively.
Many literatures focus on using the compensation capability of renewable energy to suppress the unbalanced grid voltage because the remaining capacity of inverter can be utilized. However, the coordinated control of different inverters for suppressing unbalanced grid voltage is not considered in these literatures. It is necessary to consider the unbalanced compensation effort sharing for different inverters because the spare capacity of inverters is different if they operate at different conditions. For example, the inverters should inject more negative-sequence currents when they have more remaining capacity, while they should inject less negative-sequence currents when they have less remaining capacity.
To fully utilize the negative-sequence current injection capability of STATCOM, this invention provides a coordinated control strategy of PMSGs and STATCOM based virtual NSOA. Noting that STATCOM will inject negative-sequence currents immediately if there is exists unbalanced voltage at the PCC, a zero-sequence voltage injecting method is used to keep the dc capacitor voltage balance among three-phase clusters of STATCOM. If the unbalanced grid voltage cannot be fully suppressed by STATCOM, the PMSGs will share the remaining unbalanced voltage until the power quality of PCC to meet the grid code.
The present invention provides an unbalanced voltage compensation method for dispersed wind farm (DWF) by cooperating permanent magnetic synchronous generator (PMSG) with a star-connected cascaded H-bridge STATCOM. The topology of a typical DWF is given and the mathematical models of STATCOM and PMSGs are established to show that the unbalanced grid voltage can be suppressed by controlling the NSOA of PMSG and STATCOM. As mentioned above, if there is exists unbalanced voltage at the PCC, the STATCOM will inject negative-sequence currents immediately. In order to make the STATCOM work stable even if it injects a mount of negative-sequence currents, the over-modulation and over-current limitations are introduced to quantitatively analyze the negative-sequence current injection ability of the STATCOM.
If the unbalanced grid voltage cannot be fully suppressed by STATCOM even if it injects the maximum negative-sequence current, the PMSGs will share the remaining unbalanced voltage according to their NSOA. The participation factors of PSMGs based on a secondary control strategy are designed, thus their NSOA can be changed by controlling the participation factor. Furthermore, the participation factor calculation method is also proposed in consideration of both remaining capacity and voltage unbalanced factor (VUF) for different PMSGs.
In the following description, the control method of STATCOM and PMSGs thereof and the likes are set forth as preferred examples. It will be apparent to those skilled in the art that modifications, including additions and/or substitutions may be made without departing from the scope and spirit of the invention. Specific details may be omitted so as not to obscure the invention; however, the disclosure is written to enable one skilled in the art to practice the teachings herein without under undue experimentation.
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Modeling of PMSG's Grid-Side Inverter in Negative-Sequence Synchronous reference frame (NS-SRF)
where ωg is angular frequency of the grid; Rf, Lf, Rg, Lg and C constitute of LCL filter; ifdqn, igdqn are the negative-sequence components of the grid current and the inverter output current, respectively; vgdqn, vinvdqn, vcdqn, are the negative-sequence components of grid voltage, inverter output voltage and capacitor voltage, respectively; In the steady state, the dxldt=0, where x=ifdqn, igdqn, vcdqn. Therefore, the (1), (2) and (3) can be rewritten as,
v
cdqn=(Rf−jωgLf)ifdqn+vinvdqn (4)
−(Rg−jωgLg)igdqn+vcdqn+vgdqn=0 (5)
i
fdqn
=i
gdqn
−jω
g
Cv
cdqn (6)
Substituting (4) and (6) into (5), the negative-sequence current of PMSG can be expressed with negative-sequence output voltage of inverter and negative-sequence grid voltage as,
Mi
gdqn
=−v
invdqn
+Nv
gdqn (7)
where,
M=−(Rg−jωgLg)−(Rf−jωgLf)+(Rg−jωgLg)(Rf−jωgLf)jωgC (8)
N=1−(Rf−jωgLf)jωgC (9)
Thus, the NSOA of the PMSG can be obtained as
Therefore, we can see from (10) that the NSOA of PMSG can be controlled by changing the negative-sequence components of the grid-side inverter's output voltage.
where Rst and Lst are the resistance and inductance of the filter. istdqn is the negative-sequence current, vstinvdqn is the negative-sequence component output voltage, vg1dqn is the voltage of the terminal connected with the CHB-STATCOM.
In the steady state, the left side of (11) is equal to 0. So, the NSOA of CHB-STATCOM can be obtained as
Similarly, we can see from (12) that the NSOA of the CHB-STATCOM can be controlled by changing its output voltage.
The negative-sequence model of overall wind power integration is established to analyze the coordinated mechanism for compensating unbalanced voltage of PCC, as shown in
According to
The negative-sequence admittance of transformer can be obtained after by commissioning tests, in other word, Lt1n, Yt2n, Yt3n cannot be changed. Therefore, from (13) and (14), we can see that as long as the NSOA of PMSGs or CHB-STATCOM is large enough, the NSOA see from the PCC (see
The operating principle of CHB-STATCOM under unbalanced grid condition can be found in [8], [12].
In this invention, CHB-STATCOM provides negative-sequence currents to suppress the unbalanced voltage, which inevitably result in uneven active powers among three clusters. Thus, the balanced phenomenon of dc voltage of three clusters of CHB-STATCOM will be broken. Here, cluster voltage balancing control is used to generate a suitable zero-sequence command (M0) to redistribute the active power of three clusters, and make the dc voltage of three-cluster balanced. The M0 can be calculated as [12],
Vstd0 and Vstq0 can be calculated as [12],
where Vstdp, Vstqp, Vstdn, Vstqn, Istdp, Istqp, Istdn, Istqn are the d-q components of positive-sequence and negative-sequence output voltage and current of CHB-STATCOM; Pa_fb, and Pb_fb can be obtained by a proportional integral (PI) controller to derive dc voltage of phase-A and phase-B clusters, respectively. Here, the voltage drop of inductance is neglected.
The maximum amplitude of output phase voltage of CHB-STATCOM can be calculated as,
V
st max=max√{square root over ((Vstmp2+Vstmn2+Vst02))},m=a,b,c (17)
where Vstmp, Vstmn are the amplitude of the positive-sequence and negative-sequence in three-phase, respectively; V0 is the amplitude of the zero-sequence voltage. Vstmp, Vstmn and V0 can be calculated by the dq transformation. To prevent the over-modulation, Vstmax must be lower than the maximum permit output voltage, that is,
V
st max
≤N·M
dc
·V
dc (18)
where Mdc is the modulation index; N is the numbers of cells per phase. In this paper, the PSC-PWM scheme is used, hence, Mdc=1. Except for the limitation of the maximum amplitude of output voltage, the limitation of the peak current should be considered. The instantaneous current of the CHB-STATCOM can be expressed as,
where m=a, b, c, and d=0, 1, −1; φi is the angle difference between the positive-sequence and negative-sequence current. Istp, Istn can be calculated as,
I
stp=√{square root over ((Istdp)2+(Istqp)2)} (20)
I
stn=√{square root over ((Istdn)2+(Istqn)2)} (21)
From (19), we can know that the instantaneous peak current can reach the maximum value when the trigonometric is equal to 1, thus, the peak value of phase current is expressed by,
i
st max
=I
stp
+I
stn (22)
It can be found in IEEE Std1517 that the fault current is usually limited to be less than 1.25 times the rated value. Here, the maximum allowable value of phase current is set as 1.25 p.u., therefore, the limitation of phase current can be expressed as,
I
st max≤1.25 (23)
The negative-sequence current injected by CHB-STATCOM is depend on (18) and (23), according to these two limitations, the negative-sequence current injection region of a 10 kV, ±5 MVar CHB-STATCOM can be obtained at the different reactive output power, as shown in
I
dnref1
=d
1
×I
dnc
,I
qnref1
=d
1
×I
qnc (24)
I
dnref
=d
2
×I
dnref1
,I
qnref
=d
2
×I
qnref1, (25)
where Idnc, Iqnc can be obtained from
The desired negative-sequence current should satisfy (23), otherwise, d1 uses 0.95 as a step to reduce the negative-sequence reference until (23) is satisfied, we remark the negative-sequence references from the first iteration method are Idnref1 and Iqnref1. The Vstd0 and Vstq0 can be calculated by using the Idnref1 and Iqnref1 to replace Istdn and Istqn in (16), then the maximum amplitude of output phase voltage of CHB-STATCOM can be calculated by using (17), which can be used to judge the (18) is satisfied or not. If the limitation of (18) is satisfied, the tdnref1 and Iqnref1 will be transmitted to the negative-sequence current controller of CHB-STATCOM, otherwise, d2 also uses 0.95 as a step to reduce the negative-sequence references until (18) is satisfied. In this way, the desired negative-sequence current can be limited within the safe operation area, in other word, the over-modulation and over-current phenomenon cannot occur, which can make sure the CHB-STATCOM operates stably.
To address the over-modulation problem that the conventional virtual admittance method may bring, a virtual NSOA method based on a negative-sequence current reference for CHB-STATCOM and PMSGs is proposed. The participation factors of them based on a secondary control strategy are designed, thus their NSOA can be changed by controlling the participation factor. Besides, a coordinated control strategy of CHB-STATCOM and PMSGs for suppressing unbalanced voltage is discussed.
I
dqrefxn=(Idqxn+VgdqnYbn)kx (26)
where Ybn is a known constant, here Ybn=8. kx is the participation factor of the PMSGs (e.g., x=1, 2, m) or the CHB-STATCOM (e.g., x=st). Idqxn and Ldqrefxn are the measured and the reference negative-sequence current, respectively; Vgdqn is the d-q components of negative-sequence voltage at the PCC.
Assuming that the PI parameters are perfectly designed, the negative-sequence control loop can track negative-sequence current reference well, as follows,
I
dqrefxn=(Idqxn+VgdqnYbn)kx (27)
Substituting (27) into (26), the NOSA of PMSGs or CHB-STATCOM can be expressed as,
Equation (28) clearly show that the NSOA of PMSGs or CHB-STATCOM is equal to 0 if kx=0, while it can reach infinity if kx=1. Therefore, kx should be limited to be within 0-1, to control the NSOA of PMSGs or CHB-STATCOM from 0 to infinity.
As mentioned above, the final participation factor kx should be limited to within 0-1, thus, a 0-1 limiter should be used. In order to ensure that the controller does not work when the VUF is lower than 2%, a selector with dead-band is added in the participation factor calculation block. Specifically, if ΔVUF>e1, the final participation factor kx will be equal to kcx, otherwise, the kx=0. Here, the e1 is the threshold of the dead-band, which can be predefined. In this paper, e1 is set to 0.05. It is worth noting that if the e1 is too small (e.g., almost 0), the kx will switch from 0 to kcx too frequently, which makes the system unstable, while the bigger e1 makes the compensation accuracy decrease.
A typical 50 MW DWF with 25 PMSGs and a ±5 Mvar CHB-STATCOM, as shown in
To test the negative-sequence current injection capability of CHB-STATCOM, the following circumstances are considered in this case: before t=0.9 s, the CHB-STATCOM injects the rated positive-sequence reactive current; at t=0.9 s, it is required to inject the negative-sequence current to track the VUF reference as much as possible; at t=1.78 s, t=2.2 s, t=3.2 s, the reactive power references are changed to 0.8 p.u., 0.5 p.u., and 1.0 p.u., respectively.
In this case, the simulation considers the following circumstance: at t=0.9 s, the CHB-STATCOM and PMSGs starts to inject negative-sequence according to the algorithm; at t=8.1 s, the active power of G1 is changed from 11.2 MW to 12.8 MW. At the beginning, we assume that the voltage of Phase-B drops from 1.0 p.u. to 0.85 p.u, which excites the voltage unbalance phenomenon occur. According to the calculation result, the VUF at PCC is 6.8%. Meanwhile, the CHB-STATCOM will inject the maximum negative-sequence to decrease the value VUF as much as possible. Here, the reactive power reference is set to 0.8 p.u..
Based on the simulation results, it is demonstrated that the CHB-STATCOM will inject negative-sequence current to decrease the VUF at the PCC, it the CHB-STATCOM injects the maximum negative-sequence currents and the VUF cannot be decrease to 2%, the PMSGs will participate in sharing the unbalanced grid voltage according to their participate factor. The coordinate control strategy can suppress the unbalanced grid voltage for a dispersed wind farm without any additional cost but changing the corresponding controller for CHB-STATCOM and PMSGs.
The foregoing description of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications and variations will be apparent to the practitioner skilled in the art.
The embodiments were chosen and described in order to best explain the principles of the invention and its practical application, thereby enabling others skilled in the art to understand the invention for various embodiments and with various modifications that are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalence.
The present application is a Continuation Application of PCT Application No. PCT/CN2020/096967 filed on Jun. 19, 2020, the contents of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/CN2020/096967 | Jun 2020 | US |
Child | 16931437 | US |