WO2005078278A1 - Method for operating a wind power plant and correspondingly designed wind power plant - Google Patents

Abstract

The invention provides a method for operating a wind power plant during which a generator is driven via a transmission, and the electrical power generated by the generator is fed into a mains supply via a converter. The invention ensures that, in the event of predetermined operating conditions such as a failure of the mains supply, the power generated by the generator is diverted in a controlled manner. The invention also provides a safety module in a wind power plant equipped with a transmission, a generator and a converter, as well as with a connection for connecting the wind power plant to a mains supply. This safety module has an energy accumulator or electrical consumer and an electronic circuit. In the event of a failure of the supply mains, said electronic circuit controls the diversion of power generated by the generator into the energy accumulator or to the electrical consumer.

Description

"Method for operating a wind power plant, and correspondingly designed wind power plant"

The invention relates to a method according to the preamble of claim 1 and a wind power plant according to the preamble of claim 8

It is known from practice to use a double-fed asynchronous generator in younger wind turbines to generate the electrical energy, which is operated with a converter specially developed for this purpose. Such a converter has a self-protection mechanism which is intended to avoid damage to the converter in certain operating states, in particular if the power supply fails. In this context, self-protection “mechanism” is also to be understood as an electronic circuit which provides the desired protection against electrical and / or mechanical overloading of the converter.

In the case of wind turbines, the gear unit may wear prematurely, with mechanical influences being primarily responsible for this premature wear, for example sudden gusts of wind, which an adjustment of the angle of attack of the rotors cannot correspond to quickly enough.

The invention is based on the object of improving a generic method and of specifying a corresponding wind power plant such that the longest possible service life of the wind power plant can be achieved with the least possible effort.

This object is achieved by a method with the method steps of claim 1 and by a wind turbine with the features of claim 8.

In other words, the invention proposes to switch off the generator in a controlled manner in certain operating states, such as the aforementioned power failure. The invention is based on the surprising consideration that damage to the gearbox is not caused solely by the mechanical action of the rotor exposed to the wind, but also by the other side of the gear

Wind turbine can occur, namely from the electrical side: In the event of a power failure, the rotor shaft of the generator is short-circuited to protect the converter. As a result of this short circuit, the generator has a considerably increased rotational resistance in the shortest possible time, so that mechanical impacts are accordingly introduced into the transmission. The self-protection mechanism provided to protect the converter therefore effectively protects the converter, but ultimately endangers the gearbox of the wind turbine.

The present proposal can be compared, for example, with the use of an uninterruptible power supply in wind turbines to protect the transmission, generator, converter and / or other components from mechanical or electrical overload. For example, it can be provided that the Generate generated electrical energy that cannot be dissipated into the power grid in a controlled manner in any other way, instead of short-circuiting the generator rotor shaft. Such consumption can take place, for example, by means of heating resistors, for example so-called “dump loads” known to the person skilled in the art. These can be designed as heating elements which are arranged, for example, in the ground to protect against overheating and for reasons of heat dissipation. Alternatively, it is conceivable that in the generator - generated and, in the event of a power failure, cannot feed electrical energy into an energy store from which it can later be used.

This controlled derivation of the energy generated in the generator by the continuing rotary movement of the rotor prevents the self-protection mechanism of the converter from responding, so that inverters without such a self-protection mechanism can be used cost-effectively if the proposed safety module is used.

On the one hand, the safety module leads to the dissipation of the electrical energy still generated after a power failure, so that power failures with a duration in the range of fractions of a second can be bridged without risk.

On the other hand, the safety module, similar to the aforementioned uninterruptible power supply, enables the generator to be "shut down" from its operating state that generates electrical energy to an idle state last for a long time, for example in regions with a particularly unstable power supply, and in which cases the introduction of electrical energy generated by the generator into the intended consumers could lead to the destruction of the consumers, for example to heating of the heating elements, or in which cases sufficiently large energy stores would be uneconomical to absorb the corresponding amounts of energy.

The mentioned "shutdown" of the generator into an idle state can take place until the rotor of the wind power plant comes to a standstill so that the generator no longer generates electricity. However, minimal operation of the generator can also be provided as an idle state Amount of energy is generated, which can be easily dissipated firstly and secondly allows electrical monitoring or control circuits to be maintained. In addition, in a "minimal operation" of this type, the rotor is rotated at a "minimal speed", so that the rotor then starts up and is started up again the wind turbine is facilitated since the rotor does not have to be rotated from a standstill while overcoming corresponding breakaway torques.

In a manner known per se, the angle of attack of the rotor blades can be changed in order to throttle the energy generation by the generator or to bring it down to zero. The proposed safety module can therefore have a circuit that not only triggers the dissipation of the energy that is not to be dissipated into the power grid, but also triggers this rotor blade adjustment and, if necessary, initiates further measures to protect the converter and the transmission in particular.

An exemplary embodiment of the invention is explained in more detail below on the basis of the purely schematic representation of a wind power plant.

1 designates a wind turbine as a whole, which has a rotor 2, with a hub 3 and rotor blades 4. The rotor blades 4 have servomotors with which the

Can influence the angle of attack of the respective rotor blade. Around in the event of impermissible wind speeds or in the event of a power failure, to enable the wind turbine 1 to be switched off, these servomotors are supplied with electrical energy in a manner known per se by an energy store, such as by an accumulator.

In a nacelle indicated by 5, a gear 6 is arranged as well as a generator 7 which, in a manner known per se, is driven indirectly by the rotor 2 and, at a speed which is different from the rotor speed, directly by the gear 6 and generates electrical current.

Furthermore, the wind turbine 1 has a converter 8. This converter 8 can be designed without a self-protection mechanism known per se, or there can be such a self-protection mechanism which is, however, switched off.

The wind turbine 1 is connected to a power network by a connection 9, such as a public one

Power grid - connected. In the event of a power failure, damage to the wind power plant 1 is prevented by a safety module 10, which is arranged between the converter 8 and the connection 9 in terms of circuitry in that the safety module 10 protects both the converter 8 and components of the wind power plant 1 upstream in the converter 8 , including the generator 7 and the transmission 6.

The safety module 10 firstly ensures that the electrical energy still generated after the failure of the network by the generator 7 is discharged in a controlled manner without, for example, the generator 7 having to be short-circuited, and furthermore the security module 10 ensures that the power supply continues for a prolonged period Generator 7 is shut down in a controlled state, ie in its Power is throttled or reduced to zero, for example by appropriate adjustment of the rotor blades 4.

According to the proposal, and not only limited to the exemplary embodiment shown, it is provided that if the

A sufficient amount of energy is made available by the security module 10 in the power network, even in the millisecond range, or is used by the security module, which amount of energy enables the wind turbine 1 to be shut down and shut down in a coordinated manner.

Claims

claims:

1. A method for operating a wind power plant, wherein a generator is driven via a transmission, and wherein the electrical energy generated by the generator is fed into a power grid via a converter, characterized. that the energy generated by the generator (7) is discharged in a controlled manner in predetermined operating states, such as in the event of a power grid failure.

2. The method according to claim 1, characterized in that when the predetermined operating state occurs, the generator (7) is brought into an idle state in which it generates minimal or no electrical energy - as by adjusting the angle of attack of rotor blades (4).

3. The method according to claim 1 or 2, characterized in that the measures provided for the predetermined operating states are initiated by means of an electronic circuit within fractions of a second.

4. The method according to any one of claims 1 to 3, characterized in that the energy generated by the generator (7) is fed into an energy store.

5. The method according to claim 4, characterized in that before the occurrence of the predetermined operating state, the energy store is filled up only to a part of its capacity, this partial capacity being dimensioned such that the energy stored in the energy store is sufficient for shutting down the wind turbine (1) -as for ab- switch the generator (7).

6. The method according to any one of claims 1 to 3, characterized in that the energy generated by the generator (7) is supplied to a consumer.

7. The method according to claim 6, characterized in that the energy is converted into heat.

8. Wind power plant, with a gearbox, a generator, and a converter, and with a connection for connecting the wind power plant to a power grid, characterized by a security module (10), which has an energy store or electrical consumer and an electronic circuit, the electronic Circuit in the event of a power grid failure regulates the dissipation of energy generated by the generator (7) into the energy store or to the electrical consumer.

9. Wind power plant according to claim 8, characterized in that the safety module (10) regulates the coordinated transition of the wind power plant (1) into an idle state, such that the generator (7) generates minimal or no electrical energy in the idle state.

10. Wind power plant according to claim 8 or 9, characterized in that the safety module (10) is arranged in terms of circuitry between the converter (8) and the connection (9) to the power grid, such that the safety module (10) both the converter (8) as well as the transmission (6) protects.

11. Wind power plant according to claim 10, characterized in that the converter (8) without an out finally, the converter (8) protecting its own protection mechanism - like a so-called scraw bar - is designed.