Device and method for angle stabilization of a virtual synchronous machine

Abstract

Provided is a control circuit of a converter, in particular a power converter of a wind power installation, configured to control the converter in such a way that the converter emulates a behavior of a synchronous machine. The control circuit includes a power module for calculating a power change depending on a detected power and a correction module for setting a power set point, in particular for the converter, depending on the calculated power change.

Claims

1. A control circuit of a converter, wherein the control circuit is configured to control the converter to cause the converter to emulate a synchronous machine, and wherein the control circuit comprises: a power circuit configured to determine a power change depending on a detected power; a power angle circuit configured to determine a power angle change depending on at least one detected frequency; a multiplier configured to multiply the power change and the power angle change to form a coefficient; and a correction circuit configured to set a power set point for the converter depending on the power change, the power angle change and the coefficient.

2. The control circuit as claimed in claim 1, wherein the converter is a power converter of a wind power installation.

3. The control circuit as claimed in claim 1, wherein the power angle circuit includes: a subtractor configured to determine a frequency difference based on comparing at least one first electrical frequency with a second electrical frequency.

4. The control circuit as claimed in claim 3, wherein the power angle circuit includes: at least one limiter configured to limit the frequency difference to a positive value.

5. The control circuit as claimed in claim 1, wherein the correction circuit is configured to only set the power set point if the coefficient exceeds a predetermined threshold value.

6. The control circuit as claimed in claim 1, wherein the power circuit includes: at least one discrete processor configured to determine, discretely, numerically or digitally, a derivative of the detected power.

7. The control circuit as claimed in claim 6, wherein the power circuit includes: at least one discrete filter, coupled to an output of the discrete processor, configured to determine the power change.

8. The control circuit as claimed in claim 1, wherein the power circuit includes: at least one observer configured to determine the power change.

9. The control circuit as claimed in claim 8, wherein: the observer is a proportional-integral (PI) controller, and the observer is configured to determine the power change based on a difference between the detected power and an estimated power that is estimated by the observer.

10. A controller of the converter, comprising: the control circuit as claimed in claim 1.

11. The controller as claimed in claim 10, wherein the controller controls the converter.

12. The converter as claimed in claim 11, wherein the controller is for a virtual synchronous machine.

13. A wind power installation, comprising: the converter as claimed in claim 11.

14. A method for controlling a power converter of a wind power installation to emulate a synchronous machine, comprising: detecting a power at an output of the power converter; calculating a power change depending on the detected power; determining a power angle change depending on at least one detected frequency; multiplying the power change and the power angle change to produce a coefficient; and setting a power set point for the power converter depending on the power change, the power angle change and the coefficient.

15. The method for controlling the power converter as claimed in claim 14, wherein the coefficient has the same sign as a synchronizing power coefficient.

16. The method for controlling the power converter as claimed in claim 14, comprising: determining the power angle change at least by comparing a mechanical frequency and an electrical frequency.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) The present invention is explained in greater detail hereinafter in an exemplary manner using exemplary embodiments with reference to the accompanying figures, wherein the same reference numbers are used for the same or similar components.

(2) FIG. 1A shows a schematic view of a wind power installation according to an embodiment.

(3) FIG. 1B schematically shows the control unit of a virtual synchronous machine.

(4) FIG. 2 shows a control module of a converter in an embodiment.

(5) FIG. 3 shows a control module of a converter in a preferred embodiment.

(6) FIG. 4 shows a control module of a converter in a particularly preferred embodiment.

(7) FIG. 5 shows a power module of a control module in a preferred embodiment.

(8) FIG. 6 shows a power module of a control module of a further, preferred embodiment.

DETAILED DESCRIPTION

(9) FIG. 1A shows a schematic view of a wind power installation 100 according to an embodiment.

(10) The wind power installation 100 comprises a tower 102 and a nacelle 104. An aerodynamic rotor 106 with three rotor blades 108 and a spinner 110 is arranged on the nacelle 104. The rotor 106 is transferred into a rotational movement by the wind during operation and thus drives a generator in the nacelle 104.

(11) The generator is connected to an electrical network, for example a wind park network or an electrical supply network, by means of a converter, in order to feed in a three-phase alternating current.

(12) For this purpose, the wind power installation comprises a control module (circuit) described previously or hereinafter and/or a control unit described previously or hereinafter and/or a converter described previously or hereinafter and/or a control unit of a converter which is set up to carry out a method described previously or hereinafter.

(13) FIG. 1B schematically shows the control unit 300 of a virtual synchronous machine.

(14) By means of this control unit 300, the converter 200 of the wind power installation 100, as shown in FIG. 1A, for example, can be controlled in such a way that the converter 200 emulates the behavior of a synchronous machine.

(15) For this purpose, the control unit 300 comprises an active power control 310, a reactive power control 320, a processing unit (processor) 330, a current control 340 and a set point setting 350.

(16) The active power control 310 is set up to calculate an angular velocity ω and an internal reference angle Θ from this from an active power set point P_set, in particular for the converter, which is specified by a wind power installation control, for example.

(17) For this purpose, the active power set point P_set is firstly offset against an actual generator torque T_e and an angular velocity ω is determined from this with the aid of a frequency droop mechanism fdm.

(18) The internal reference angle Θ is then determined for the virtual synchronous machine from the angular velocity ω using an amplification k.

(19) The internal reference angle Θ then serves as an input variable for the processing unit 330.

(20) The reactive power control 320 is set up to calculate a virtual excitation voltage v_vir_e from a reactive power set point Q_set, in particular for the converter, which is specified by a wind power installation control, for example, and a detected reactive power Q_mea, which virtual excitation voltage serves as an input variable for the processing unit 330.

(21) In addition, a voltage control vdc is provided inside the reactive power control, which voltage control compares a voltage V_PCC_mea detected at the converter output with a voltage target specification V_PCC and can be connected by means of the switch S1.

(22) The processing unit 330 is further set up to calculate a virtual pole wheel voltage e* from a or the virtual excitation voltage v_vir_e, in particular of the reactive power control 320, a or the angular velocity ω and a or the internal reference angle Θ.

(23) Current set points S* are then calculated for the converter from this virtual pole wheel voltage e* by means of the current control 340, for example for a tolerance band method by means of which the converter 200 is controlled.

(24) In further embodiments, further set point settings Set_1, Set_2 can additionally be provided in order to further optimize operation of the virtual synchronous machine.

(25) FIG. 2 shows a control module (circuit) 1000 of a converter in an embodiment.

(26) In particular, the control module 1000 is set up to control a converter in such a way that the converter emulates the behavior of a synchronous machine.

(27) The control module comprises a power module (circuit) 1100 and a correction module (circuit) 1200 for this purpose.

(28) The power module 1100 has a detected power, in particular detected at the converter output, as an input variable, in particular an active power P_mea.

(29) As described previously or hereinafter, the power module calculates a power change dP/dt therefrom, in particular depending on the detected power P_mea.

(30) The power change dP/dt calculated in this way is supplied to the correction module 1200.

(31) The correction module 1200 calculates a power set point P_set_corr or directly the power set point P_set for the converter from the power change dP/dt, for example, if the power change dP/dt exceeds a predetermined threshold value, for example.

(32) The control module 1000 therefore preferably only intervenes in the control of the converter, as in FIG. 1B, for example, if a predetermined threshold value is exceeded, which indicates a loss of angular stability.

(33) In such cases, it is then proposed to control a smaller power set point P_set or in particular to set the correction value for the power set point P_set_corr by means of the correction module.

(34) In particular, it is therefore also proposed to reduce the power output of the converter in the event of a loss of angular stability.

(35) FIG. 3 shows a control module 1000 of a converter, in particular as shown in FIG. 2, in a preferred embodiment.

(36) The control module 1000 additionally has a power angle module (circuit) 1300.

(37) The power angle module 1300 is set up to calculate a power angle change dδ/dt depending on the detected frequencies, in particular the electrical frequency ω_g of the electrical supply network and the electrical frequency ω_m of the virtual synchronous machine.

(38) The power angle change dδ/dt calculated in this way is then multiplied by the power change dP/dt by means of the multiplication, in particular in order to obtain a coefficient PSC which has the same sign as a power synchronizing coefficient. This coefficient can also be described as a change in the power according to the angle, i.e., dP/dδ.

(39) FIG. 4 shows a control module 1000 of a converter, in particular as shown in FIG. 3, in a particularly preferred embodiment.

(40) In this case, the power angle module 1300 has at least one summation (adder/subtractor) 1310 which is set up to compare at least one first electrical frequency ω_g with a second electrical frequency ω_m, in particular in order to calculate a frequency difference (w).

(41) In this case, the first electrical frequency is preferably the electrical frequency of the electrical supply network ω_g and the second electrical frequency the electrical frequency of the virtual synchronous machine ω_m.

(42) In addition, the power angle module 1300 has at least one limiter 1320 which is set up to limit the frequency difference ω to positive values. The limiter therefore preferably operates between 0 and infinity.

(43) In particular, it is therefore also proposed to only consider positive values with regard to the power angle change dδ/dt.

(44) For this purpose, the power angle change dδ/dt is led via a saturation block 1320 or limited to exclusively positive values.

(45) If negative values are therefore present, a zero is output by the limiter or saturation block which results in the product of the power angle change dδ/dt and power change dP/dt also being zero, whereby the threshold value of the correction module is not exceeded and the set points P_set thus do not change, in particular because there is a stable operation.

(46) In particular, it is therefore also proposed that only the situations in which the angle δ accelerates and the power P decreases are identified as a critical state.

(47) FIG. 5 shows a power module 1100 of a control module 1000, as shown in FIGS. 2 to 4, for example, in a preferred embodiment.

(48) The power module 1100 comprises at least one discrete implementation (discrete processor) 1110 and a discrete filtering 1120.

(49) The power module 1110 is thus set up to calculate a derivative of the power with respect to time from the detected active power P_mea, in particular a power change dP/dt, which is filtered by means of the discrete filtering 1120.

(50) In particular, this means that the power module 1110 is set up to determine the power change dP/dt with respect to time, in particular as a differential.

(51) In particular, a discrete implementation 1110 of the derivative of the measured power P_mea is proposed for determining this power change dP/dt, which implementation cooperates with an additional cascaded discrete filtering 1120.

(52) FIG. 6 shows a power module 1100 of a control module 1000, as shown in FIGS. 2 to 4, for example, in a further preferred embodiment.

(53) The power module 1100 comprises at least one observer 1130.

(54) The observer can be run by a PI controller, for example, which acts on a difference between the measured power P_mea and an estimated power P_est and calculates a state variable dP.sub.dt as a result.

(55) The control module makes it possible to avoid angular instability in the virtual synchronous machine. This can arise, for example, if an error occurs in a line and the equivalent impedance between the converter and the network suddenly increases as a result of switching off the affected line. The result of this is that the set point power can no longer be transmitted due to the physical limits of the system. This, in turn, causes the synchronization with the network to be lost in a virtual synchronous machine (as indeed in a synchronous machine). The control module implements an additional controller which identifies this critical state using available measured values and allows appropriate measures to be taken, such as adjusting the power set point, for example.

LIST OF REFERENCE NUMBERS

(56) 100 wind power installation

(57) 200 converter, in particular a power converter of a wind power installation

(58) 300 control unit of a virtual synchronous machine

(59) 310 active power control, in particular for the converter

(60) 320 reactive power control, in particular for the converter

(61) 330 processing unit, in particular of the virtual synchronous machine

(62) 340 current control, in particular for the converter

(63) 350 set point setting, in particular for the converter

(64) 1000 control module

(65) 1100 power module

(66) 1110 discrete implementation, in particular of the power module

(67) 1120 discrete filtering, in particular of the power module

(68) 1130 observer, in particular of the power module

(69) 1200 correction module

(70) 1300 power angle module

(71) 1310 summation

(72) 1320 limiter

(73) 1400 multiplication (multiplier)

(74) e* virtual pole wheel voltage

(75) fdm frequency droop mechanism

(76) k amplification

(77) k_tresh predetermined threshold value

(78) P_est estimated active power

(79) P_mea detected active power

(80) P_set power set point, in particular for the wind power installation

(81) P_set_corr correction value for the power set point, in particular for the wind power installation

(82) P_set active power set point setting, in particular for the converter

(83) PSC coefficient or product

(84) Q_set reactive power set point setting, in particular for the converter

(85) Q_mea detected reactive power

(86) S1 switch

(87) S* current set points, in particular for the converter

(88) Set_1 first further set point setting

(89) Set_2 second further set point setting

(90) T_e actual generator torque

(91) V_PCC voltage target specification, in particular for the converter, at the converter output

(92) V_PCC_mea voltage detected at the converter output

(93) v_vir_e virtual excitation voltage, in particular virtual excitation voltage

(94) vdc voltage control, in particular voltage droop control

(95) ω_g electrical frequency of the electrical supply network

(96) ω_m electrical frequency of the virtual synchronous machine

(97) dP/dt power change, in particular power change with respect to time

(98) dδ/dt power angle change, in particular power angle change with respect to time

(99) The various embodiments described above can be combined to provide further embodiments. These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.