This paper presents a sensorless control scheme for the stand-alone brushless doubly fed induction generator (BDFIG) feeding nonlinear loads. The fundamental and harmonic components of the distorted power winding (PW) voltage caused by the nonlinear loads are extracted and controlled separately. A rotor speed observer is employed to estimate the speed based on the PW voltage and control winding (CW) current without the need of any other machine parameters except for the number of pole pairs. Since the d- and q-axis references of the CW current from the PW voltage control loop contain both dc and ac components, which cannot be tracked easily by conventional PI controllers, a CW predictive current controller is designed to regulate the CW current. Finally, the performance of the proposed control scheme is verified by comprehensive experiments on a 35-kVA prototype BDFIG.
1. Introduction
The brushless doubly fed induction generator (BDFIG) contains two stator windings with different pole pairs, one of which is called power winding (PW) and the other one called control winding (CW) [1]. A specially designed rotor allows an indirect coupling between the two stator windings [2]. A stand-alone BDFIG can generate voltage with constant amplitude and frequency by employing a fractionally rated power converter while the rotor speed and load are changing, which are suitable for variable speed constant frequency (VSCF) power generation systems [3]. As shown in Figure 1, the stand-alone BDFIG control system includes both the CW side converter (CSC) supplying the CW with frequency-variable exciting current and the load side converter (LSC) connected between the dc bus and the loads for regulating the dc bus voltage and achieving bidirectional energy flow. Generally, the electrical loads include both linear loads (such as air conditioners and lighting equipment) and nonlinear loads (typically the front rectifier of converters driving fans, pumps, winders, and so on).
Configuration of the BDFIG-based stand-alone power generation system.
However, a nonlinear load would result in a distorted PW three-phase current, which could produce harmonic voltage drops across the three-phase impedances of the PW, resulting in a distorted PW voltage. In order to make the BDFIG power generation system to generate a voltage, which has constant amplitude and frequency with as few harmonics as possible under the nonlinear load condition, it is necessary to propose an effective and enhanced control strategy. In addition, the control of the CSC needs the information of the rotor position and speed. However, the conventional control strategies obtain the rotor position and speed by employing the corresponding sensors, which would increase the cost and decrease the reliability of the system. So, it is necessary to eliminate the rotor position and speed sensors.
The vector control schemes of BDFIGs for grid-connected wind power generation have been developed under balanced operation [4], unbalanced operation [5, 6], and low-voltage ride through [7]. However, all control schemes proposed in [4–7] employ the rotor position/speed sensor to acquire the rotor position/speed. Some other papers, such as [8, 9], have discussed the rotor speed observers for the grid-connected brushless doubly fed reluctance generator (BDFRG) similar to the grid-connected BDFIG. It is noted that these rotor speed observers proposed in [8, 9] both need specific parameters of the PW inductance and resistance to estimate the flux. However, in the stand-alone BDFIG system, nonlinear loads are frequently connected to the system, leading to distorted PW voltage and current. Therefore, it is difficult to accurately estimate the PW flux, and consequently the observed rotor speed is inaccurate. Moreover, the dependence on the machine parameters can also reduce the robustness of the observer.
Generally, a grid-connected wind power generation system needs to control the active and reactive power, whereas in a stand-alone power generation system, the amplitude and frequency of the output voltage should be stabilized when the rotor speed or load varies. Therefore, the control scheme of a stand-alone BDFIG is different from that of a grid-connected BDFIG. For the stand-alone BDFIG, a control scheme based on the CW current orientation has been designed without considering nonlinear load conditions [10]. Besides, a direct voltage control scheme has been developed under linear load conditions [11]. The transient control of reactive current for the LSC in the stand-alone BDFIG power generation system has been proposed in [12] to improve the quality of the output voltage. Some studies have investigated the control scheme of the stand-alone doubly fed induction generator (DFIG) under nonlinear load conditions [13–15]; there are few related studies on BDFIG. A harmonic voltage and current elimination method for stand-alone BDFIG with nonlinear loads has been proposed in [16]. However, this method is achieved by using a speed sensor.
This paper presents an enhanced sensorless control scheme of the stand-alone BDFIG under nonlinear load conditions. The fundamental and harmonic components of the PW voltage are extracted and then regulated separately. A new rotor speed observer is designed to observe the rotor position and speed based on the PW voltage and CW current. Since the d- and q-axis references of the CW current from the PW voltage control loop contain both dc and ac components, the predictive control method is introduced to regulate the CW current. Comprehensive experimental results on a 35-kVA prototype BDFIG are presented to validate the effectiveness of the proposed control scheme.
The following sections of this paper is organized as follows: firstly, the operational principle and dynamic model of BDFIG are introduced in Section 2; the system analysis and modeling under nonlinear loads is presented in Section 3; the control scheme is proposed in Section 4; experimental results are illustrated in Section 5; and finally the conclusions are drawn in Section 6.
2. Operational Principle and Dynamic Model of BDFIG2.1. Basic Operational Principle of BDFIG
The BDFIG rotor mechanical angular frequency can be determined by the PW and CW angular frequencies as follows:(1)ωr=ωp+ωcpp+pc,where pp and pc are the numbers of pole pairs of PW and CW, ω is the angular frequency, and the subscripts p, c, and r indicate the PW, CW, and rotor, respectively.
In order to keep ωp constant, ωc should be changed with the variation of the rotor speed according to the following expression derived from (1):(2)ωc=ωrpp+pc−ωp.
2.2. Dynamic Vector Model of BDFIG
The unified reference frame vector model proposed in [17] is employed in this paper. In the fundamental reference frame (dq+1) rotating at the speed of ωp, this model can be expressed as(3)updq+1=Rpipdq+1+sψpdq+1+jωpψpdq+1,ψpdq+1=Lpipdq+1+Lprirdq+1,ucdq+1=Rcicdq+1+sψcdq+1+jωp−pp+pcωrψcdq+1,ψcdq+1=Lcicdq+1+Lcrirdq+1,urdq+1=Rrirdq+1+sψrdq+1+jωp−ppωrψrdq+1,ψrdq+1=Lrirdq+1+Lpripdq+1+Lcricdq+1,where udq, idq, and ψdq represent the voltage, current, and flux vectors, Rp, Rc, and Rr the resistances of PW, CW, and rotor, Lp, Lc, and Lr the self-inductances of PW, CW, and rotor, Lcr and Lcr the coupling inductances between the stator and rotor windings, respectively, s the differential operator d/dt, and superscripts +1 the fundamental reference frame.
3. System Analysis and Modelling3.1. System Analysis
Nonlinear loads make the PW current distorted, which in turn causes abundant harmonic current in the CW due to the indirect coupling between the two stator windings through the rotor. And then, the PW harmonic current results in harmonic-voltage drop on the three-phase internal impedances of the PW.
Therefore, under nonlinear load conditions, the PW terminal voltage of the stand-alone BDFIG would contain significant harmonic components and consequently degrade the performance of other linear loads connected to the system. Among these harmonic components, the fifth and seventh harmonic components are the most significant ones. Figure 2 presents the impact of the nonlinear loads on the stand-alone BDFIG system.
Impact of the nonlinear loads on the stand-alone BDFIG.
3.2. Mathematical Modelling
In order to derive the dynamic vector model of the stand-alone BDFIG under nonlinear loads, the other two reference frames need to be defined as shown in Figure 3. The negative fifth harmonic reference frame (dq−5) rotates at the angular speed of -5ωp, and the positive seventh harmonic reference frame (dq+7) at the angular speed of 7ωp.
The fundamental and harmonic reference frames in the dynamic vector model of the stand-alone BDFIG under nonlinear loads.
The relationship among the expressions of an arbitrary vector Fdq in different reference frames can be presented as(4)Fdq+1=Fdq−5e−j6ωpt,(5)Fdq+1=Fdq+7ej6ωpt,where the superscripts +1, −5, and +7 represent the fundamental, the negative fifth harmonic, and the positive seventh harmonic reference frames, respectively.
Under nonlinear loads, the general electrical vector Fdq+1 of a BDFIG in the reference frame dq+1 can be expressed as(6)Fdq+1=Fdq1+1+Fdq5+1+Fdq7+1,where the subscripts 1, 5, and 7 indicate the fundamental, the fifth harmonic, and the seventh harmonic components, respectively.
Substituting (4) and (5) into (6), the following can be obtained:(7)Fdq+1=Fdq1+1+Fdq5−5e−j6ωpt+Fdq7+7ej6ωpt.
From (7), the voltage, current, and flux vectors of the PW in the fundamental reference frame can be expressed as(8)updq+1=updq1+1+updq5−5e−j6ωpt+updq7+7ej6ωpt,(9)ipdq+1=ipdq1+1+ipdq5−5e−j6ωpt+ipdq7+7ej6ωpt,(10)ψpdq+1=ψpdq1+1+ψpdq5−5e−j6ωpt+ψpdq7+7ej6ωpt,
By substituting (8)–(10) into the first part of (3), the PW fundamental- and harmonic-voltage equations in the corresponding reference frames can be derived as(11)updq1+1=Rpipdq1+1+sψpdq1+1+jωpψpdq1+1,(12)updq5−5=Rpipdq5−5+sψpdq5−5+j−5ωpψpdq5−5,(13)updq7+7=Rpipdq7+7+sψpdq7+7+j7ωpψpdq7+7,
Similarly, the PW fundamental- and harmonic-flux equations can be obtained by(14)ψpdq1+1=Lpipdq1+1+Lprirdq1+1,(15)ψpdq5−5=Lpipdq5−5+Lprirdq5−5,(16)ψpdq7+7=Lpipdq7+7+Lprirdq7+7.
A similar method can also be employed to derive the fundamental- and harmonic-voltage and flux equations of the CW and rotor. And then, by ignoring those harmonics with the order more than seventh, the dynamic vector model of the BDFIG under nonlinear loads can be decomposed into three sets of equations as follows:(17)updq1+1=Rpipdq1+1+sψpdq1+1+jωpψpdq1+1,ψpdq1+1=Lpipdq1+1+Lprirdq1+1,ucdq1+1=Rcicdq1+1+sψcdq1+1+jωp−pp+pcωrψcdq1+1,ψcdq1+1=Lcicdq1+1+Lcrirdq1+1,urdq1+1=Rrirdq1+1+sψrdq1+1+jωp−ppωrψrdq1+1,ψrdq1+1=Lrirdq1+1+Lpripdq1+1+Lcricdq1+1,(18)updq5−5=Rpipdq5−5+sψpdq5−5+j−5ωpψpdq5−5,ψpdq5−5=Lpipdq5−5+Lprirdq5−5,ucdq5−5=Rcicdq5−5+sψcdq5−5+j−5ωp−pp+pcωrψcdq5−5,ψcdq5−5=Lcicdq5−5+Lcrirdq5−5,urdq5−5=Rrirdq5−5+sψrdq5−5+j−5ωp−ppωrψrdq5−5,ψrdq5−5=Lrirdq5−5+Lpripdq5−5+Lcricdq5−5,(19)updq7+7=Rpipdq7+7+sψpdq7+7+j7ωpψpdq7+7,ψpdq7+7=Lpipdq7+7+Lprirdq7+7,ucdq7+7=Rcicdq7+7+sψcdq7+7+j7ωp−pp+pcωrψcdq7+7,ψcdq7+7=Lcicdq7+7+Lcrirdq7+7,urdq7+7=Rrirdq7+7+sψrdq7+7+j7ωp−ppωrψrdq7+7,ψrdq7+7=Lrirdq7+7+Lpripdq7+7+Lcricdq7+7,where (17)–(19) are the fundamental, fifth harmonic, and seventh harmonic equations, respectively.
4. Design of Control Scheme
The overall control scheme for the enhanced sensorless control of the stand-alone BDFIG with nonlinear loads is shown in Figure 4. The PW fundamental-voltage controller, based on the PW fundamental-voltage vector orientation, is employed to regulate the amplitude and frequency of the PW fundamental voltage. The PW harmonic-voltage controller can eliminate the fifth and seventh harmonic components of the PW voltage. Then, it summarizes the outputs of both PW fundamental- and harmonic-voltage controllers in order to get the references of the CW d- and q-component currents. By theoretical analysis, it is known that the references of CW d- and q-component currents contain both dc and ac parts, which cannot be tracked easily by conventional PI controllers. Therefore, a predictive current controller is employed to regulate the CW current. In addition, the multiple second-order generalized integrator-based PLL (MSOGI-PLL) [18] is used to extract the α- and β-components of the fundamental, fifth, and seventh harmonics of the PW voltage. The improved rotor speed observer can estimate the rotor position and speed of the BDFIG based on the PW voltage and CW current.
The overall control scheme for the enhanced sensorless control of the stand-alone BDFIG with nonlinear loads.
4.1. Control of PW Fundamental Voltage
The PW fundamental-voltage controller is based on the PW fundamental voltage vector orientation and can be derived from (17). By splitting the first part of (17) into d- and q-components, the PW fundamental voltage in the reference frame dq+1, upd1+1 and upq1+1, can be obtained by(20)upd1+1=Rpipd1+1+sψpd1+1−ωpψpq1+1,(21)upq1+1=Rpipq1+1+sψpq1+1+ωpψpd1+1.
Generally, the sampling period of the power converters for BDFIG is smaller than 1 ms, which results in the PW flux being regarded as a constant during one sampling period. Hence, the differential terms of the flux linkages in (20) and (21) are approximately equal to 0, and equations (20) and (21) can be simplified as(22)upd1+1=Rpipd1+1−ωpψpq1+1,(23)upq1+1=Rpipq1+1+ωpψpd1+1.
Besides, the PW resistance Rp is usually very small, resulting in the first term on the right side of (22) and (23) being much smaller than the second term. Hence, the first term on the right side of (22) and (23) can be neglected. Consequently, equations (22) and (23) can be simplified as(24)upd1+1≈−ωpψpq1+1,(25)upq1+1≈ωpψpd1+1.
Converting the second part of (17) into the form of d- and q-components, the following can be obtained:(26)ψpd1+1=Lpipd1+1+Lprird1+1,(27)ψpq1+1=Lpipq1+1+Lprirq1+1.
From the fifth and sixth parts of (17), with the rotor voltage equivalent to zero, the d- and q-components of the rotor current can be derived as(28)ird1+1=−α1+1icd1+1+α2+1icq1+1+α3+1ipd1+1+α4+1ipq1+1,(29)irq1+1=−β1+1icq1+1+β2+1icd1+1+β3+1ipq1+1+β4+1ipd1+1.
The detailed expressions for α1+1 ∼α4+1, and β1+1∼β4+1 can be seen in Appendix.
Substituting (28) into (26) and substituting (29) into (27), the PW fundamental flux can be derived as(30)ψpd1+1=−Lprα1+1icd1+1+Lprα2+1icq1+1+Lp+Lprα3+1ipd1+1+Lprα4+1ipq1+1,(31)ψpq1+1=−Lprβ1+1icq1+1+Lprβ2+1icd1+1+Lp+Lprβ3+1ipq1+1+Lprβ4+1ipd1+1.
By substituting (30) into (24) and substituting (31) into (25), the relationship between the PW voltage and the CW current can be obtained by(32)−icd1+1=1ωpLprα1+1upq1+1+Dpd1+1,(33)icq1+1=1ωpLprβ1+1upd1+1+Dpq1+1.
The detailed expressions for Dpd1+1 and Dpq1+1 can be found in Appendix. 1/ωpLprα1+1 is the transfer function from upq1+1 to −icd1+1, and 1/ωpLprβ1+1 the transfer function from upd1+1 to icq1+1. It is noted that 1/ωpLprα1+1 is equal to 1/ωpLprβ1+1 according to (A.1). From (32) and (33), upd1+1 and upq1+1 can be controlled by icq1+1 and icd1+1, respectively. Dpd1+1 and Dpq1+1 are the disturbance terms, including the cross-coupling disturbance between d- and q-components of the CW current and the coupling disturbance between the PW and CW, and can be used as the feedforward compensation to improve the dynamic ability of the control loop.
Since the PW fundamental-voltage controller is based on the PW fundamental voltage vector orientation, the d-axis of the reference frame dq+1 is forced to align with the PW fundamental-voltage vector, and the references of the d- and q-components of the PW fundamental voltage, upd1+1∗ and upq1+1∗, should be set to(34)upd1+1∗=Up1∗,upq1+1∗=0,where Up1∗ is the reference of the PW fundamental voltage amplitude. According to (32)–(34), the PW fundamental-voltage controller can be obtained as shown in Figure 4.
4.2. Control of PW Harmonic Voltage
From (18), by using the derivation method similar to that in the control of PW fundamental voltage, the relationship between the PW voltage and the CW current in the fifth harmonic reference frame (dq−5) can be derived as(35)icd5−5=15ωpLprα1−5upq5−5+Dpd5−5,(36)−icq5−5=15ωpLprβ1−5upd5−5+Dpq5−5.
The detailed expressions for α1−5–α4−5, β1−5–β4−5, Dpd5−5, and Dpq5−5 have been given in Appendix. In (35) and (36), 1/5ωpLprα1−5 is the transfer function from upq5−5 to icd5−5, 1/5ωpLprβ1−5 the transfer function from upd5−5 to −icq5−5, and Dpd5−5 and Dpq5−5 the disturbance terms. Therefore, the d- and q-components of the PW fifth harmonic voltage, upd5−5 and upq5−5, can be controlled by icq5−5 and icd5−5, respectively.
Similarly, the relationship between the PW voltage and the CW current in the seventh harmonic reference frame (dq+7) can be obtained from (19) as follows:(37)−icd7+7=17ωpLprα1+7upq7+7+Dpd7+7,(38)icq7+7=17ωpLprβ1+7upd7+7+Dpq7+7.
The detailed expressions for α1+7–α4+7, β1+7–β4+7, Dpd7+7, and Dpd7+7 have been given in Appendix. Similarly, the d- and q-components of the PW seventh harmonic voltage, upd7+7 and upq7+7, can be controlled by icq7+7 and icd7+7, respectively.
In order to eliminate the fifth and seventh harmonic components in the PW voltage, these references of the d- and q-components of the PW harmonic voltage, upd5−5∗, upq5−5∗, upd7+7∗, and upq7+7∗, should be set to(39)upd5−5∗=upq5−5∗=upd7+7∗=upq7+7∗=0.
According to (35)–(38), the PW harmonic-voltage controller can be designed as shown in Figure 4. Since the harmonic component of the PW voltage is much smaller than the fundamental one, the dynamic performance requirements of the harmonic-voltage controller can be lower than that of the fundamental-voltage controller. Therefore, the disturbance terms Dpd5−5, Dpq5−5, upd7+7, and upq7+7 are not used as the feedforward compensation of the control loop due to their dependence on the machine parameters. Although the dynamic performance would be compromised, the stability could be guaranteed. Besides, it is noteworthy that the CW current references obtained by the PW harmonic-voltage controller should be transformed to the fundamental reference frame (dq+1) according to (4) and (5), so as that the CW current controller can be designed in the reference frame dq+1.
4.3. Design of CW Predictive Current Controller
Since the CW current references contain both the dc and ac components, the conventional PI controller is not suitable in this case. An improved predictive current control strategy for unbalanced stand-alone doubly fed induction generator (DFIG) has been proposed to track the ac references of the rotor current in [19]. However, such method has not been used in the BDFIG. In this paper, a CW predictive current controller is designed. The proposed current controller is derived in the reference frame dq+1.
From the fifth and sixth parts of (3), according to [10], the d- and q-components of the rotor current in the reference frame dq+1 can be simplified as(40)ird+1=−Lpripd+1+Lcricd+1Lr−RrLpripq+1+Lcricq+1Lr2ωc−pcωr,(41)irq+1=−Lpripq+1+Lcricq+1Lr.
By substituting (40) and (41) into the third part of (3), the d- and q-components of the CW voltage in the reference frame dq+1, ucd+1 and ucq+1, can be obtained by(42)ucd+1=Rcicd+1+σcLcsicd+1+Dcd+1,(43)ucq+1=Rc+RrLcr2ωcLr2ωc−pcωricq+1+σcLcsicq+1+Dcq+1,where σc=1−Lcr2/LcLr is the leakage constant of the CW and Dcd+1 and Dcq+1 are the disturbance terms indicating the cross coupling between d- and q-components of the CW current and the indirect coupling between the PW and CW. The detailed expressions for Dcd+1 and Dcq+1 can be seen in Appendix. The CW frequency ωc is obtained by using (2).
Discretizing (42) and (43), the CW voltage at the kth sampling period can be expressed as(44)ucd+1k=Rcicd+1k+σcLcΔicd+1kTs+Dcd+1k,(45)ucq+1k=Rc+RrLcr2ωcLr2ωc−pcωricq+1k+σcLcΔicq+1kTs+Dcq+1k,where Δicd+1 and Δicq+1 are the differences of the CW d- and q-component currents between two adjacent sampling periods and Ts is the sampling interval. Δicd+1k and Δicq+1k are defined as(46)Δicd+1k=icd+1k+1−icd+1k,Δicq+1k=icq+1k+1−icq+1k.
It is difficult to predict accurately the actual CW currents icd+1k+1 and icq+1k+1. However, the target of the CW predictive current controller is to minimize the CW current errors at the (k+1)th sampling period; therefore, the reference CW currents icd+1∗k+1 and icq+1∗k+1 at the (k+1)th sampling period could be used to replace the actual ones in (46). The reference CW currents at the (k+1)th sampling period can be obtained by the linear extrapolation method as follows:(47)icd+1∗k+1=2icd+1∗k−icd+1∗k−1,icq+1∗k+1=2icq+1∗k−icq+1∗k−1.
Hence, the differences of the CW currents between the (k+1)th and the kth sampling periods can be expressed as(48)Δicd+1k=2icd+1∗k−icd+1∗k−1−icd+1k,Δicq+1k=2icq+1∗k−icq+1∗k−1−icq+1k.
By substituting (48) to (44) and (45), the d- and q-component references of the CW voltage, ucd+1∗k and ucq+1∗k, can be obtained. The three-phase CW voltage references can be calculated according to the coordinate transformation method proposed in [17], which requires the estimated rotor position θ^r and the reference of the PW voltage phase θp∗.
4.4. Extraction of PW Harmonic Voltage
According to the analysis in Section 3, under nonlinear load conditions, the PW voltage contains significant harmonic components, especially the fifth and the seventh harmonics. In order to suppress these harmonics in the PW voltage, these harmonics need to be extracted accurately and then input to the PW harmonic-voltage controller. In the previous studies for control of the stand-alone DFIG under nonlinear load conditions [13, 14], a band-pass filter is employed to extract the harmonic components, but the dynamic response is highly degraded because the frequencies of the fundamental, fifth, and seventh harmonics are relatively close.
In this paper, a MSOGI [18] and a stationary-frame phase-locked loop (PLL) [20] are employed to estimate these harmonic components. Hence, the scheme for the PW harmonic voltage extraction is called the MSOGI-PLL, as shown in Figure 5. The MSOGI consists of three dual second-order generalized integrators (DSOGIs), which are used to extract the fundamental, fifth harmonic, and seventh harmonic components of the PW voltage, respectively. The stationary-frame PLL is employed to estimate the fundamental frequency and phase angle based on the α- and β-components of the fundamental PW voltage. The resonance frequencies of the three DSOGIs are 1, 5, and 7 times the fundamental frequency, respectively. The variable k is the damping factor of the first DSOGI, and the damping factors of the second and the third DSOGIs are set to k/5 and k/7, respectively, in order to guarantee the same bandwidth for all the DSOGIs.
The MSOGI-PLL for the extraction of PW harmonic voltage.
4.5. Rotor Speed Observer
This paper employs an improved rotor speed observer to estimate the rotor speed [21]. By making integration of (1), it can get the relationship among the rotor position θr, the PW voltage vector angle θp, and the CW current vector angle θc, as expressed by(49)pp+pcθr=θp+θc.
From (49), the difference Δθr between the actual and estimated rotor position in the vicinity of the equilibrium point can be derived as(50)pp+pcΔθr=pp+pcθr−θ^r=θp+θc−pp+pcθ^r≈sinθp+θc−pp+pcθ^r.
According to (50), a stationary-frame PLL can be employed to obtain the estimated rotor position θ^r and rotor speed ω^r. The basic rotor speed observer is proposed, as shown in Figure 6, which is based on the three-phase PW voltage and the three-phase CW current.
Structure of the basic rotor speed observer.
According to the analysis in Section 3, a nonlinear load can result in distorted PW voltage and CW current, which would cause inaccurate rotor position and speed estimation by using the basic rotor speed observer. In order to overcome this problem, the PW voltage and CW current need to be prefiltered before their input to the basic rotor speed observer. Fortunately, as it can be seen from Figure 5, the α- and β-components of the PW fundamental voltage, upα1 and upβ1, have been extracted by the MSOGI-PLL. In addition, the two low-pass filters are employed to adaptively filter the CW current, in order to obtain the α- and β-components, icα1 and icβ1, of the CW fundamental current. The resonance frequency of the two SOGIs is derived from (2). Finally, the quantities upα1, upβ1, icα1, and icβ1 are input to the basic rotor speed observer to obtain the accurate rotor position and speed. The improved rotor speed observer is presented in Figure 7.
The improved rotor speed observer for the stand-alone BDFIG under nonlinear load conditions.
5. Experimental Results5.1. Experimental Setup
The experimental setup is shown in Figure 8. The experiments are performed on a 35-kVA prototype BDFIG, whose detailed parameters are listed in Table 1. A 50-kW three-phase induction motor is used as a prime mover. The reference RMS and frequency of the PW line voltage are set to 380 V and 50 Hz, respectively. The nonlinear load is a three-phase diode rectifier supplying a resistive load of 25 Ω.
Photograph of the experimental setup.
Main parameters of the prototype BDFIG.
Parameter
Value
Capacity
35 kVA
Speed range
600–1200 rpm
PW and CW pole pairs
1, 3
PW-rated voltage and current
380 V, 53 A
CW voltage and current range
0–350 V, 0–50 A
PW, CW, and rotor resistances
0.5102 Ω, 0.3350 Ω, 0.4129 Ω
PW, CW, and rotor self-inductances
0.4865 H, 0.0312 H, 0.2034 H
Mutual inductance between PW and rotor
0.4128 H
Mutual inductance between CW and rotor
0.0314 H
5.2. Performance Test of the Rotor Speed Observer
The performance test of the rotor speed observer is carried out without the activation of the PW harmonic-voltage controller, which is regarded as the most demanding operation condition for the observer due to the severely distorted PW voltage and CW current. The test results are shown in Figure 9.
Test results of the rotor speed observer without the PW harmonic-voltage controller being activated. (a) PW voltage (1 p.u. = 500 V) and CW current (1 p.u. = 60 A). (b) Detailed view of (a). (c) Rotor speeds observed by the basic and improved observers. (d) Rotor speed errors of the basic and improved observers.
At the beginning, the stand-alone BDFIG runs under no-load condition at the rotor speed of 600 rpm. At 0.44 s, the connection of the nonlinear load leads to significant distortion of the PW voltage and CW current. Due to a sudden connected nonlinear load at 0.44 s, the amplitude of PW voltage drops from 537 to 98 V, which results in the amplitude of CW current being increased from 30 to 96 A under the control of the system. And, a severe transient drop of the rotor speed occurs due to a sudden increased load on the prime mover. Between 2.4 and 10 s, the rotor speed rises from 600 to 930 rpm and then drops to 890 rpm. During the whole process, the basic and improved rotor speed observers give a similar response speed. Therefore, in the improved observer, the prefiltering of the PW voltage and the CW current does not result in the dynamic performance degradation. Besides, the rotor speed estimated by the basic observer is always with a fluctuation of about 24 rpm peak-to-peak value, whereas the fluctuation of the improved observer is significantly reduced to about 4 rpm. Hence, the improved observer can provide satisfactory performance for the stand-alone BDFIG with nonlinear loads.
5.3. Experimental Results under Constant Rotor Speed
Figure 10 presents the experimental results with and without the activation of the PW harmonic-voltage controller at the rotor speed of 600 rpm. It can be seen that, without the activation of the PW harmonic-voltage controller, the amplitude of the fifth harmonic voltage reaches about 30 V and that of the seventh harmonic voltage to 25 V. After the activation of the PW harmonic-voltage controller, some harmonics are injected into the CW current to compensate the distortion of the PW voltage, and consequently the amplitudes of the fifth and seventh harmonic voltages are reduced to nearly zero within 50 ms. With the activation of the PW harmonic-voltage controller, the total harmonic distortion (THD) of the PW voltage is significantly reduced from 8.1% to 2.6%. And, it can be noted that, without the activation of the PW harmonic-voltage controller, the amplitudes of the seventh and nineteenth harmonic voltages are almost the same. Actually, the nineteenth harmonic component in PW voltage is mainly caused by the PWM modulation of LSC. Since this paper focuses on eliminating the harmonics produced by nonlinear loads rather than those caused by the modulation of power converters, the compensation for the nineteenth harmonic component of PW voltage is not considered in the design of the control scheme. Besides, after the activation of the PW harmonic-voltage controller, the reference of the q-component of the CW current is composed of ac and dc parts and can be well tracked by the proposed CW predictive current controller. Due to the limited number of analog output channels in the control system, the quantities about the CW current d-component are not acquired and shown.
Experimental results with and without the activation of the PW harmonic-voltage controller at the rotor speed of 600 rpm. (a) PW line voltage (1 p u= 500 V) and CW phase current (1 p u = 60 A). (b) Amplitude of PW harmonic voltage. (c) Reference, feedback, and error of the q-component of the CW current. (d) Harmonic spectrum of PW voltage before activation of the PW harmonic-voltage controller. (e) Harmonic spectrum of PW voltage after activation of the PW harmonic-voltage controller.
5.4. Experimental Results under Variable Rotor Speed
In order to validate the dynamic performance of the control system under the variable rotor speed, the experiments have been carried out in the typical rotor speed range (from the supersynchronous speed 900 rpm to the subsynchronous speed 600 rpm). The experimental results are presented in Figure 11. Through the whole process, the amplitude and frequency of the PW voltage are almost constant. The rotor speed can be estimated very well by using the improved rotor speed observer. The THD of the PW voltage at the rotor speed of 900 rpm is about 2.1% and that at 600 rpm has been presented in Figure 10(e).
Experimental results with the activation of the PW harmonic-voltage controller during the rotor speed dropping from 900 rpm (supersynchronous speed) to 600 rpm (subsynchronous speed). (a) PW line voltage. (b) Enlarged view of the PW line voltage between 2.4 s and 2.6 s (c) CW phase current. (d) Measured and observed rotor speed. (e) Harmonic spectrum of the PW voltage at the rotor speed of 900 rpm.
6. Conclusion
This paper presents an enhanced sensorless control scheme for the stand-alone BDFIG with nonlinear loads. The PW fundamental-voltage controller, based on the PW fundamental-voltage vector orientation, is used to control the amplitude and frequency of the PW fundamental voltage. The PW harmonic-voltage controller is employed to eliminate the harmonics of the PW voltage, especially the fifth and seventh ones. A rotor speed observer is proposed to estimate the rotor position and speed from the PW voltage and CW current. The predictive control method is introduced to this system to regulate the CW current. Comprehensive experiments demonstrate that the proposed scheme can significantly improve the performance of the stand-alone BDFIG under nonlinear loads.
In (A.1)–(A.4), the parameter n corresponds to +1, −5, or +7 for fundamental, fifth, and seventh components.
Data Availability
The data used to support the findings of this study are included within the article.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
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