DE102008009276A1 - Electric circuit operating method for e.g. gas turbine energy generation system, involves disconnecting coupling between stator of asynchronous generator and energy supply network during occurrence of failure in energy supply network - Google Patents

Abstract

The method involves coupling a double-fed asynchronous generator (G) with an energy supply network at a stator side and at a rotor side by a rotor side converter (Mpr), an intermediate circuit (Cd) and a network side converter (Npr). The coupling between a stator of the asynchronous generator and the energy supply network is disconnected during an occurrence of failure in the energy supply network by locking a stator switch (Es) that includes a power semiconductor component. The magnetic flow of the asynchronous generator is synchronized with a defective energy supply network. An independent claim is also included for an electric circuit comprising an asynchronous generator.

Description

The The invention relates to an electrical circuit, in particular for a double-fed asynchronous generator with grid-connected stator.

It is known, the stator of an asynchronous generator directly with a to connect electrical power grid during the Rotor of the asynchronous generator via a rotor-side converter, a DC link and a line-side converter is coupled to the power grid. The two inverters become dependent of streams and voltages measured within the described circuit be controlled so that the voltage induced in the stator adapted to the power grid and fed there becomes.

at This electrical circuit is still known between to arrange a switch for the stator and the power supply network, which disconnects the stator from the power grid can. But these switches are common only suitable for switching over in the no-load state.

One Errors in the power supply network can result in that Asynchronous generator, a short-circuit current is generated, which leads to a Charging the DC link leads. This can be a hazard lead the components of the two converters. As a countermeasure is it is known to provide a rotor-side short-circuiting device with which the rotor of the asynchronous generator via a semiconductor switch and a resistor are short-circuited can. From a certain voltage in the DC link, the semiconductor switch turned on, so that the resistance is effective. exceeds the voltage in the DC link predetermined maximum values, then must The operation of the two converters will be terminated to destroy the components to avoid the inverter. In this case, then the DC link back to legal Tension values returned and the semiconductor switch of the short circuiter locked again to the Operation of the inverter to start again.

at explained Have to take action in particular the components of the two converters at least in one certain extent for increased voltages be designed in the DC link. Also, the short-circuiter provides one increased Component cost.

task The invention is an electrical circuit of the aforementioned Kind of creating with which a fault of the power supply network can be processed with less component cost.

The Invention solves this object by a method according to claim 1 and by an electrical circuit according to claim 5.

at the method according to the invention is an asynchronous generator stator side with a power grid coupled. Rotor side is the asynchronous generator via a Rotor-side converter, a DC link and a line-side converter connected to the power grid. In case of an error in the Power supply network is the coupling between the stator of the asynchronous generator and the power grid by blocking a power semiconductor device interrupted stator switch interrupted.

It So it's not a short circuiter or the like required. This represents a significant reduction Furthermore, there is no oversizing of the components the two inverters required. Also with this is a diminished Effort reached.

One Another essential advantage of the method according to the invention is that immediately after the occurrence of the network error of the network side Inverter fed a reactive current in the power grid can be. additionally can immediately after the Sperrend switching of the stator the excitation of the asynchronous generator to the faulty power grid be adjusted. After re-conducting the stator switch can then all the needed Reactive current can be supplied by the asynchronous generator. This can be done by the operator of the power grid specified requirements for the Feeding energy in case of failure on particularly simple, but nevertheless fast way be fulfilled.

Further Features, applications and advantages of the invention will become apparent from the following description of exemplary embodiments of the invention, which are shown in the drawing. Make up all features described or illustrated alone or in any combination the subject of the invention, regardless of its summary in the claims or their relationship as well as independent of their formulation or presentation in the description or in the drawing.

The single figure of the drawing shows a schematic diagram of a embodiment an electrical according to the invention Circuit.

A three-phase power supply network is connected to a transformer T, to which a stator switch Es is still connected nerseits is connected to the stator of an asynchronous generator G. The switch may be any type of controllable electrical or electronic switch capable of breaking the current or voltage between the transformer T and the stator. In particular, the switch Es may be an electrical or electronic power semiconductor component, for example a thyristor or an insulated gate bipolar transistor (IGBT) or the like.

to Measuring the mains voltage Un is on the mains side of the stator switch It provided a voltage sensor. For measuring the stator voltage Us is on the stator side of the stator switch It another voltage sensor intended. On this stator side is further a current sensor present the over the stator switch It is flowing Stator current Is measures.

At the connection point of the transformer T and the stator switch It is connected to a mains inverter Npr, which has one DC link Cd is connected to a motor inverter Mpr. Of the Motor inverter Mpr is still with the rotor of the asynchronous generator G connected. The power converter Npr and the motor inverter Mpr can be arbitrary be constructed, in particular, these may be circuits, having a plurality of semiconductor devices, for example Diodes or transistors or the like. The intermediate circuit Cd is intended for storing a DC voltage and has in particular one or more capacitors.

to Measurement of over the mains inverter Npr flowing Current Inp is a current sensor on the grid side of the grid inverter Npr intended. To measure the over the motor inverter Mpr flowing Rotor current Ir is on the machine side of the motor inverter Mpr another current sensor is available. Between the motor inverter Mpr and the intermediate circuit Cd, a voltage sensor is provided, with which the intermediate circuit voltage Ud can be measured.

The Measuring signals of the mains voltage Un, the stator voltage Us, the intermediate circuit voltage Ud, about the power converter Npr flowing Current Inp, the stator current Is and the rotor current Ir are one Control ST supplied as input signals. This control generates ST a plurality of output signals ZES, ZNpr, ZMpr, with which the stator switch Es, the grid inverter Npr and the motor inverter Mpr are controlled can.

at the circuit described is a so-called double-fed asynchronous generator with grid-connected stator. These Circuit is used in particular in power generation plants, For example, in wind power or hydropower or gas turbine power generation plants.

in the Normal operation of this circuit is the stator switch It conductive connected. If the rotor by an external force, for example by wind or water, in a rotary motion, so is in the Stator induced a voltage across the stator switch Es in the power grid is fed. The adaptation, in particular the synchronization of the induced voltage in the stator to the Mains voltage Un of the power supply network is provided by the controller ST by a corresponding control of the power converter Npr and the motor inverter Mpr achieved.

kick in the power grid an error and this error detected by the controller ST, the stator switch Es from switched off the control ST blocking. The stator switch It is able to do so even under load and especially in one Fault in the power supply network, a switch from its manager to to perform the locked state. Switching to the locked state is achieved when it is reached a predetermined intermediate circuit voltage Ud or upon reaching a given stator current Is or upon reaching another threshold, for example, the falling below the mains voltage Un below a predetermined limit, triggered by the controller ST.

This has the consequence that the stator of the asynchronous generator G of the Transformer T and thus separated from the power grid is. It flows so that no stator current Is more. A further charge of the DC bus Cd over the Stator and the rotor is no longer possible. The components of the both converters Mpr, Npr are not endangered and it is not necessary to stop the operation of the two inverters Mpr, Npr.

With the detection of a fault in the power grid is the mains-side converter Npr controlled by the control ST, that it feeds a reactive current into the power grid. Furthermore, the two inverters Mpr, Npr are so controlled by the controller ST driven that a desirable Active current is generated, which is used to maintain the DC link voltage Ud is required.

After the interruption of the stator current Is by the stator switch, the rotor-side converter Mpr is controlled by the controller ST in such a way that the magnetic flux to the faulty power supply system is as fast as possible is synchronized. The controller monitors the mains voltage Un and the stator voltage Us. If the difference between these two voltages becomes zero, which is equivalent to the voltage applied to the stator switch Es becoming zero, then the stator switch Es is again turned on by the control ST. Thereafter, the stator current Is controlled by the controller ST by means of the rotor-side inverter Mpr such that predetermined by the operator of the power grid requirements for the supply of energy in case of failure are met.

is the error in the power grid eliminated again, it works described method in a corresponding manner again. The stator switch So it is switched off, then the magnetic flux to synchronize with the now intact power grid. As soon as then the voltage applied to the stator switch Es becomes zero, the stator switch It is turned on again so that energy from the asynchronous generator G back into the power grid can be fed.

Claims (6)

Method for operating an electrical circuit, in which an asynchronous generator (G) is coupled to a power supply network on the stator side, and in which the asynchronous generator (G) is connected to the rotor via a rotor-side converter (Mpr), an intermediate circuit (Cd) and a network-side converter (Npr) is connected to the power grid, characterized in that in case of a fault in the power grid, the coupling between the stator of the asynchronous generator and the power grid by blocking a power semiconductor device having a stator (Es) is interrupted. The method of claim 1, wherein after locking of the stator switch (Es) the magnetic flux of the asynchronous generator (G) is synchronized with the faulty power grid. The method of claim 2, wherein the stator switch (It) is turned on, as soon as the difference between the Mains voltage (Un) of the power supply network and the stator voltage (Us) becomes zero. Method according to one of claims 1 to 3, wherein according to the Fixed the fault in the power grid the coupling between the stator of the asynchronous generator (G) and the power grid is interrupted, the magnetic flux of the asynchronous generator is synchronized with the intact power grid, and the Stator of the asynchronous generator again with the power supply network is coupled as soon as the difference between the mains voltage of Power supply network and the stator voltage is zero. Electrical circuit with an asynchronous generator (G) whose stator is coupled to a power supply network, and its rotor over a rotor-side converter (Mpr), a DC link (Cd) and a network-side converter (Npr) to the power grid is connected, characterized in that between the stator and the power grid is a power semiconductor device connected stator switch (Es) is provided for this purpose is, in the case of a fault in the power supply network, a switch from to conduct his conducting to his locked state. An electrical circuit according to claim 5, wherein the Stator switch (Es) at least one thyristor or IGBT (insulated gate bipolar transistor) per phase.