CONTROL METHOD AND APPARATUS

Abstract

A method and a controller for controlling a wind power generation system is disclosed. The system is connected to a grid at a point of connection, and is devised to feed reactive power to the grid in order to improve grid stability. A Q-V characteristic is determined for the grid at the point of connection as well as a nose point for the Q-V characteristic. A minimum reactive current, IQmin, which is safe from the nose point, is determined, and the feeding of reactive power is controlled such that the reactive current is kept higher than the minimum reactive current. This ensures that the reactive current does not make the Q-V characteristic reverse, and thereby the stability of the system is improved.

Description

TECHNICAL FIELD

The present disclosure relates to a method for controlling a wind power generation system connected to a grid at a point of connection, wherein the system is devised to feed reactive power to the grid in transient conditions in order to improve grid stability. The disclosure is further related to a corresponding controller.

BACKGROUND

Such a method is shown e.g. in EP1855367. By being able to cope with voltage fluctuations in the grid and supplying reactive power to the grid, the power generation system can improve the overall stability of the grid. One problem associated with such control method is how to avoid situations where the voltage collapses such that the generation system must be disconnected.

SUMMARY

One embodiment in accordance with aspects of the invention is therefore to provide a control method of the initially mentioned kind with improved stability. Such an embodiment achieves improved stability by means of a method as defined in claim 1. More specifically the method involves determining a Q-V characteristic for the grid at the point of connection, and controlling the feeding of reactive power based on the Q-V characteristic. In this way it can be avoided that the controller drives the reactive current to a point where the voltage collapses as a result thereof. This improves the stability of the system.

The method may further involve determining a nose point for the Q-V characteristic and determining a minimum reactive current, I_Qmin, which is safe from the nose point. The controlling of the feeding of reactive power may then include keeping the reactive current higher than the minimum reactive current. This provides improved reliability, and the minimum reactive currents percentage of the nose point current may be set by a user.

The Q-V characteristic may be determined by injecting a disturbance at the point of connection. This means that the Q-V characteristic can be determined at regular intervals, as there is no need to await a disturbance in the grid.

The feeding of reactive power to the grid may be controlled by controlling rotor currents of a double fed induction generator, DFIG, or, alternatively by controlling switches of an AC/DC/AC converter configuration connecting a generator with the grid. A controller carrying out the method may be readily integrated in the control loops of any such system, since means for controlling the reactive power is already provided for therein.

The method may be used both in transient and steady state conditions, in order to improve grid stability. A controller comprising functional blocks capable of carrying out the actions of the method implies corresponding advantages and may be varied correspondingly.

Such a controller may be included in a wind power generation system.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a wind power generating system connected to a grid;

FIG. 2 illustrates a Q-V characteristic;

FIG. 3 illustrates a flow chart for a control method;

FIG. 4 shows a configuration of a wind power generation system with a doubly fed induction generator;

FIG. 5 shows a configuration of a wind power generation system with a full converter; and

FIG. 6 schematically illustrates a wind power generation system controller.

DETAILED DESCRIPTION

FIG. 1 illustrates a wind power generating facility 1 connected to a grid 3. Generally, the facility comprises a turbine 5, including a plurality of blades and being mounted on a tower 7 and connected, often via a gearbox, to a generator in the tower. The generator in turn is connected to the grid 3 with a three phase connection (zero connection not shown) at a point of connection 9, often via a switched converter (not shown), and usually via one or more transformers (not shown).

In the illustrated case, the wind power generating facility 1 has only one turbine 5. However, a wind power generating facility 1 in the context of this disclosure may comprise a plurality of turbines, which may each be mounted on a tower. The wind power generating facility 1 may thus be a wind farm. In addition to the illustrated type of wind turbine, vertical axis turbines are also conceivable.

Grid codes established by authorities and grid operators require that wind power generating facilities are capable of staying connected to the grid during a fault in the grid, which capability is known as low voltage ride through, LVRT. Moreover, the power generating facilities should be able to supply reactive power to or absorb reactive power from the grid during a transient condition. For instance, if a voltage dip occurs due to a fault on one or more grid phases, the power generating facility should be able to supply reactive current to the grid in order to improve stability. Reactive power regulating means 11 is therefore connected to the grid 3 at the point of connection. The reactive power regulating means 11 may be integrated with the energy conversion link in the system or may be provided as a separate auxiliary unit. Various ways of regulating reactive power in accordance with aspects of the present disclosure will be described later, in connection with FIGS. 4 and 5.

In this disclosure, a transient condition refers not only to voltage dips in the grid, but to any sudden change in grid parameters that can be affected by injecting or absorbing reactive power to or from the grid at the point of connection. Thus, for instance a voltage surge is also included.

FIG. 2 illustrates a Q-V characteristic 13 for a typical connection point of a grid. In this disclosure Q relates to the amount of reactive power (VAr) injected to or absorbed from the grid by adding or subtracting reactive current at the point of connection to the grid. V relates to the grid voltage at the point of connection. The Q-V characteristic shows the relation between the two parameters. The characteristic is, for higher added reactive currents, relatively linear. See the Q-V characteristics to the right of the voltage V relating to the point Q_min. For these relatively higher currents in the illustrated charcteristics the voltage increases with increasing added reactive current. However, the Q-V curve as a whole has a parabolic nature. Consequently, at a point 15 of the Q-V characteristic dV/dQ is zero. This point is called a nose point 15, and the present charcteristics of the grid determines where the nose point 15 is situated. Below this point, an increase in added reactive current will decrease the voltage instead of increasing it, and such an increase in added reactive current would consequently worsen the state of the grid.

Therefore, embodiments in accordance with aspects of the invention provide a control method where the provision of reactive power is controlled so as to be kept at a safe part of the Q-V characteristics, where a certain margin to the nose point is provided. This means that the risk of the wind power generation system worsening the state of the grid is more or less eliminated. FIG. 3 illustrates a flow chart for an exemplary control method.

Firstly, the Q-V characteristic for the grid at the point of connection is determined 21. For any given active power level, the Q-V-curve in the desired operating range resembles a parabolic function with the form:

aQ=V ² +bV+c

By injecting a disturbance, typically by increasing the injected reactive current, the parameters a, b, and c can be determined. It is however also possible to utilize other disturbances in the system, e.g. a voltage drop to determine the characteristic.

The nose point for the Q-V characteristic is determined 23. This can be done simply by finding the point on the characteristic where dQ/dV is zero which is a very simple operation.

Then, thirdly, a minimum reactive current, I_Qmin, is determined 25. This current should be safe from the nose point, i.e., in some distance from and above the nose point, typically meaning that I_Qmin is 110% of the current that corresponds to the nose point. However, this percentage is only an example and may be varied in accordance with grid stability requirements or operator settings. Hereby, the operation is kept at points of the Q-V characteristic at reactive currents I_Q greater than the minimum reactive current I_Qmin so that the voltage V is kept higher than the voltage corresponding to the nose point. Hereby, it is ensured that an increase in added reactive current will increase the voltage.

Then the controller is set 27 to provide I_Qmin as a minimum reactive current, such that the added reactive current is kept higher than the level providing the minimum reactive current even during a LVRT condition.

A reactive power regulating means 11 (cf. FIG. 1) should comprise functional blocks for carrying out these actions. FIG. 6 illustrates a regulator comprising such blocks, namely a Q-V characteristics detector 51, a nose point detector 53, an I_Qmin determination unit 55, and a current controller 57. Such blocks may typically be software implemented as routines executed on a digital signal processor even though various hardware configurations, e.g. utilizing applications specific integrated circuits, ASICs, would in principle also be conceivable.

FIG. 4 shows a power conversion configuration with a doubly fed induction generator 31, connected to a wind turbine (not shown). A slip ring may be used to feed currents 33 to windings in the rotor. The rotor currents 33 may be provided by means of an AC/DC/AC converter 35 connected to the generator 31 output. Such doubly fed induction generators allow the rotor of the generator to rotate with a varying rotation speed, out of synchronism with the grid frequency. Optionally, a transformer (not shown) may be placed between the grid 3 and the generator 31. Additionally, as is well known per se, the amount of active and reactive power that is fed to the grid may be controlled by controlling the currents fed to the rotor windings of the generator. In such a context, the regulator 11 may then have the converter 35 as an integrated part, generating the rotor currents that provide the desired amount of added reactive power.

FIG. 5 shows a power conversion configuration for a synchronous generator 41, connected to a wind turbine (not shown). Then, a permanent magnet synchronous generator PMSG 41 is used together with an AC/DC/AC converter configuration 43, 45, 47. The converter configuration comprises an AC/DC converter 43, connected to the stator windings of the generator 41. The AC/DC converter 43 feeds DC power to a filter capacitor 45. A DC/AC converter 47 feeds power from the filter capacitor 45 to the grid 3. The amount of active and reactive power supplied to the grid may be controlled by controlling the switches of the DC/AC converter in the configuration, which forms part of the reactive power regulator 11.

As a further alternative, the reactive power regulator 11 may include a static VAR capacitor bank which may be used to control the reactive power produced. In principle, a rotating compensator could also be used in the same way.

The present disclosure is not limited to the described embodiments, it may be altered and varied in different ways within the scope of the appended claims.

Claims

1. A method for controlling a wind power generation system connected to a grid at a point of connection, wherein the system is devised to feed reactive power to the grid, comprising: determining a Q-V characteristic for the grid at the point of connection by injecting a disturbance at the point of connection; andcontrolling the feeding of reactive power based on the Q-V characteristic.

2. A method according to claim 1, wherein the method further comprises: determining a nose point for the Q-V characteristic; anddetermining a minimum reactive current, IQmin, which is safe from the nose point; and whereinthe controlling of the feeding of reactive power includes keeping the reactive current higher than the minimum reactive current, IQmin.

3. A method according to claim 1, wherein the feeding of reactive power to the grid is controlled by controlling rotor currents of a double fed induction generator, DFIG.

4. A method according to claim 1, wherein the feeding of reactive power to the grid is controlled by controlling switches of an AC/DC/AC converter configuration connecting a generator with the grid.

5. A method according to claim 1, wherein the method is used in transient conditions.

6. A method according to claim 1, wherein the method is used in steady state conditions.

7. A controller for controlling a wind power generation system connected to a grid at a point of connection, wherein the system is devised to feed reactive power to the grid, comprising: a power regulator for injecting a disturbance at the point of connection,a Q-V characteristic detector for determining the Q-V characteristic for the grid at the point of connection; anda controller controlling the feeding of reactive power based on the Q-V characteristic.

8. A controller according to claim 7, wherein the controller further comprises: a nose point detector for detecting the nose point of the Q-V characteristic; anda determination unit determining a minimum reactive current, IQmin, which is safe from the nose point; and whereinthe controller is devised to keep the reactive current higher than the minimum reactive current, IQmin.

9. A wind power generating system comprising a controller according to claim 7.