PREMAGNETIZING OF MMC CONNECTED TRANSFORMER

Abstract

The present invention is concerned with pre-magnetizing a Modular Multilevel power Converters connected transformer in order to moderate inrush currents upon connecting the transformer to an electric grid. The invention takes advantage of the high amount of stored energy in MMC converters as compared to other converter types. This stored energy is used to pre-magnetize the converter-connected transformer, therefore no additional or dedicated pre-magnetizing hardware is required in addition to the charging hardware provided to charge the converter capacitors. As the transformer pre-magnetizing takes place subsequent to the converter charging, the converter charging circuit is not used to, and therefore does not need to be designed to, directly magnetize the transformer.

Claims

1. A method of pre-magnetizing a main transformer connectable to a Modular Multilevel power Converter MMC with a plurality of converter cells each including a cell capacitor and power semiconductor switches, comprising in order disconnecting the main transformer from the MMC, charging the cell capacitors of the MMC, and pre-magnetizing the main transformer from energy stored in the cell capacitors of the MMC.

2. The method of claim 1, comprising connecting a charging unit including an auxiliary power source to the MMC for charging the cell capacitors of the MMC, and disconnecting the charging unit prior to pre-magnetizing the main transformer.

3. The method of claim 1, wherein the main transformer is connectable to an AC grid, the step of pre-magnetizing the transformer comprising measuring a network voltage V.sub.N of the AC grid, and determining, based on the network voltage V.sub.N, a converter voltage reference V.sub.ref for the MMC.

4. The method of claim 3, comprising correcting the converter voltage reference V.sub.ref to avoid saturation of a transformer core of the main transformer.

5. The method of claim 4, comprising estimating a transformer flux in the transformer from the converter voltage reference V.sub.ref, and comparing a transformer flux magnitude of the transformer flux to a limit.

6. The method of claim 1, wherein the MMC is a Statcom for static power-factor correction.

7. An MMC controller for controlling operation of a Modular Multilevel power Converter MMC with a plurality of converter cells each including, a cell capacitor and power semiconductor switches, wherein the MMC is connectable to a main transformer and wherein the MMC controller is configured to control, upon charging of the cell capacitors and following connection of the main transformer to the MMC, by actively operating the power semiconductor switches, a pre-magnetization of the main transformer from energy stored in the cell capacitors of the MMC.

8. The MMC controller of claim 7, wherein it is configured to determine, based on a network voltage V.sub.N of an AC grid to which the main transformer is connectable, a converter voltage reference V.sub.ref for the MMC.

9. The MMC controller of claim 8, wherein it is configured to correct the converter voltage reference V.sub.ref to avoid saturation of a transformer core of the main transformer.

10. The MMC controller of claim 9, wherein it is configured to estimate a transformer flux in the transformer from the converter voltage reference V.sub.ref, and to compare a transformer flux magnitude of the transformer flux to a limit.

11. The MMC controller of claim 7, wherein the MMC is a Statcom for static power factor correction.

12. The method of claim 2, wherein the main transformer is connectable to an AC grid, the step of pre-magnetizing the transformer comprising: measuring a network voltage V.sub.N of the AC grid; and determining, based on the network voltage V.sub.N, a converter voltage reference V.sub.ref for the MMC.

13. The method of claim 12, comprising correcting the converter voltage reference V.sub.ref to avoid saturation of a transformer core of the main transformer.

14. The method of claim 13, comprising: estimating a transformer flux in the transformer from the converter voltage reference V.sub.ref, and comparing a transformer flux magnitude of the transformer flux to a limit.

15. The method of claim 2, wherein the MMC is a Statcom for static power-factor correction.

16. The method of claim 3, wherein the MMC is a Statcom for static power-factor correction.

17. The method of claim 4, wherein the MMC is a Statcom for static power factor correction.

18. The method of claim 12, wherein the MMC is a Statcom for static power-factor correction.

19. The MMC controller of claim 8, wherein the MMC is a Statcom for static power-factor correction.

20. The MMC controller of claim 9, wherein the MMC is a Statcom for static power-factor correction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] The subject matter of the invention will be explained in more detail in the following text with reference to preferred exemplary embodiments which are illustrated in the attached drawings, in which:

[0016] FIG. 1 schematically shows an exemplary initialization set-up for a single MMC;

[0017] FIG. 2 schematically shows an exemplary initialization set-up for two MMCs;

[0018] FIG. 3 illustrates a transformer magnetization and saturation prevention algorithm,

[0019] FIG. 4 shows components of reference voltage and estimated transformer flux vectors, and

[0020] FIG. 5 depicts the two components of the transformer flux vector of FIG. 4 in 2D.

[0021] In principle, identical parts are provided with the same reference symbols in the figures.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0022] The invention is equally advantageous for all kinds of transformer-connected Modular Multilevel power Converter (MMC) applications. By way of example, the MMC may be used in electric power transmission systems as Static VAR Compensator (Statcom) for static power-factor correction. AC-only Statcoms provide reactive power support to an electric power grid by producing or absorbing reactive power. The MMC may likewise be used as MMC converter/inverter adapted for converting dc current into ac current and/or vice versa, for converting a single or multi-phase current into another single or multi-phase current, or for connecting a load or power source with a power grid. Specifically, the MMC converter/inverter may be an indirect AC-DC or AC-AC converter, with top and bottom branches forming two parallel wye circuits, and with a neutral point of each wye circuit being connected to a respective DC or two-phase AC terminal.

[0023] FIG. 1 depicts an exemplary MMC initialization set-up. A three phase AC power grid 1 is connectable via a main circuit breaker, or converter feeder breaker, 2 to a primary side of a main, or power, transformer 3. A secondary side of the main transformer is connectable, via converter disconnetor 4, to ac terminals of an MMC 5. A charging unit including an auxiliary power source 6 and a dedicated auxiliary or charging transformer 7 to which the source 6 is connectable, is connectable to the ac terminals of the MMC via a charging switch, or disconnector, 8. Converter disconnector 4 is provided in the supply line between the main transformer 3 and a connection point of the charging unit in order to allow disconnecting the main transformer 3 during charging.

[0024] FIG. 2 depicts the MMC setup for two parallel-connected MMC converters 5, 5′ coupled, via respective converter disconnectors 4, 4′, to a respective secondary winding of the main transformer 3. The two converters have dedicated charging units including auxiliary power source 6, 6′, auxiliary transformer 7, 7′, and a charging switch 8, 8′. Alternatively, two parallel main transformers may be provided to feed the two MMCs, wherein a single MMC 5 may be sufficient to align the flux of both transformers.

[0025] The proposed transformer pre-magnetization approach includes the following stages:

[0026] 1. The converter capacitors are charged from the auxiliary power source while the converter is disconnected from the transformer. Common-mode charging is also possible in this configuration.

[0027] 2. When the converter is completely charged, or at least sufficiently charged for the subsequent transformer magnetization process to reproduce a grid voltage on the primary side, the charging unit or charging circuit is disconnected by opening the charging switch, and the converter is connected to the transformer by closing the converter disconnector.

[0028] 3. Transformer magnetization algorithms are executed as described below. In exceptional circumstances, another converter charging process including stages 1 and 2 above may be required to compensate for depleted converter capacitors prior to normal application operation.

[0029] 4. After the main transformer is magnetized, the transformer is connected to the grid by closing the main circuit breaker. The converter may now begin its normal grid-connected operation.

[0030] The transformer magnetization and saturation prevention algorithm of stage 3 above results in a time-dependent converter voltage reference V.sub.ref to be provided to an MMC controller of the MMC converter. The MMC controller in turn determines the switching modulation of the semiconductor switches of the MMC based on V.sub.ref, which ultimately generate the transformer magnetizing current I.sub.mag.

[0031] FIG. 3 exemplifies the algorithm of stage 3. Amplitude and phase angle of the network voltage V.sub.N of the three phase AC power grid to which the grid-side, or primary side, of the main transformer needs to be synchronized is being measured. A target converter voltage reference V.sub.ref′ is determined based on V.sub.N and a transformer ratio of the main transformer. The target voltage reference V.sub.ref′ increases from zero to a steady state value corresponding to the network voltage V.sub.N in a manner that causes perfect transformer flux alignment to the network voltage.

[0032] In a feed-forward transformer flux estimation and reference voltage synchronizer 9 the target converter voltage reference V.sub.ref′ is corrected in view of a magnetic flux limit of the transformer core of the main transformer. To that purpose, in a flux estimator 91, a rotating transformer flux vector is estimated based on first principles including a time-integral of an actual converter reference voltage V.sub.ref, assuming that the flux starts from zero, or an otherwise known value. In a flux magnitude extractor 92, a transformer flux magnitude is determined from the vector components of the transformer flux vector. A transformer flux magnitude limit is defined based on either a specified or nominal rated flux value for the main transformer, where a nominal flux vector magnitude typically corresponds with the nominal or peak operating voltage. In a flux magnitude comparator 93, the transformer flux magnitude is compared to the specified flux magnitude limit, and in case the former exceeds the latter, a scalar correction or conversion factor based on the excess flux magnitude and a gain K is provided to a multiplier 94. In the multiplier, the correction factor is multiplied with the estimated transformer flux to provide a correction term, which in turn is subtracted from the target converter voltage reference V.sub.ref′ to produce the actual, or corrected, converter voltage reference V.sub.ref.

[0033] FIG. 4 shows, in the top graph or plot, two components of a rotating vector of the 3-phase target converter reference voltage V.sub.ref′ in a stationary reference frame. In the second graph, the actual reference voltage V.sub.ref is depicted, while the bottom graph depicts both the two components and the magnitude of the estimated transformer flux vector for a correctly operating feed-forward mechanism. At time t=0.267 s the transformer magnetization process sets in, starting from zero converter voltage and zero transformer flux. Both the target reference voltage and the actual reference voltage increase rapidly, as does the transformer flux vector magnitude. At about time t=0.269 s, the flux vector magnitude exceeds the limit (a value of one per unit), and a correction term is applied to each phase of the 3-phase target converter reference voltage which leads to the actual voltage reference V.sub.ref in the middle graph departing noticeably from the target voltage reference V.sub.ref′. As time proceeds further, the transformer flux magnitude excess slowly decreases, yet with a residual correction to the voltage reference resulting in the actual voltage reference having a slightly (below 5%) lower amplitude compared to the target reference voltage.

[0034] The transformer magnetizing process may be defined as completed after one cycle, or even half a cycle, if the actual transformer does not saturate, or after three cycles if the transformer saturates and a feedback controller engages as described below. In practice, the magnetization may be made to take one or two cycles to prevent any ringing or overshoot due to the converter response. With the magnetization being completed that quickly, the depletion of the MMC capacitors is very small, and the time it takes for the mechanical main circuit breaker to connect the magnetized transformer to the grid typically takes longer than the magnetization process. Combining the magnetization process and connection to the grid, the MMC capacitors may typically only lose less than 5% voltage.

[0035] FIG. 5 depicts the two components of transformer flux vector of FIG. 4 plotted in two dimensions. The transformer flux vector starts at zero and increases out towards a one-per-unit-radius circle. The saturation point can be thought of as a perfect circle around zero with a magnitude one. When this limit is exceeded the effect of the reference voltage correction is to align the flux to rotate around the zero-centred circle with a one per-unit radius. The feed-forward approach implies that not ramping is needed, or in other words, that the voltage can be increased almost instantly, with the correction term providing for alignment of the flux vector trajectory.

[0036] Returning to FIG. 3 and the case where the feed-forward controller is based on the reasonable but unverified assumption that transformer magnetization has previously decayed to zero. As this assumption may not be true in all circumstances the initial estimate of the transformer flux may be wrong. In other words, if the transformer has remanent magnetization, or if the selected flux limit is too large, the transformer may still saturate resulting in excessive current. Therefore a subsequent feedback controller 10 may be necessary for limiting the transformer magnetizing current I.sub.mag circulating through the secondary windings of the main transformer in the event that the transformer should exhibit saturating effects. To that purpose, the transformer magnetizing current is measured and evaluated in the feedback controller that implements fast current limits if the transformer saturates. The feedback controller also has a droop characteristic that limits the current during the period that the transformer is connected to the grid, and if multiple parallel converters magnetize multiple parallel-connected or multiple-secondary transformers at the same time.

[0037] While the invention has been described in detail in the drawings and foregoing description, such description is to be considered illustrative or exemplary and not restrictive. Variations to the disclosed embodiments can be understood and effected by those skilled in the art and practising the claimed invention, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain elements or steps are recited in distinct claims does not indicate that a combination of these elements or steps cannot be used to advantage, specifically, in addition to the actual claim dependency, any further meaningful claim combination shall be considered disclosed.