DE102008026621A1 - Single or multi-phase electrical circuit for switching current produced via alternating current or three-phase power controller, has controller with valves designed as disconnectable valves, where device is connected parallel to valves - Google Patents

Abstract

The circuit has an alternating current (AC) or three-phase power controller with a valve per phase, where the valves are designed as disconnectable valves. A parallel switched protection device is connected parallel to the valves via diodes. The device has a parallel connection of a resistor (R) and a capacitor (C) or a serial connection of the resistor and the capacitor or a varistor. The capacitor or the varistor is dimensioned with respect to a possible failure i.e. overload current. Switching-thyristors (T1, T2) e.g. gate-turn-off-thyristors (GTO), are provided as the disconnectable valve. An independent claim is also included for a method for switching current produced by a valve of alternating current or a three-phase power controller.

Description

The The invention relates to a single- or multi-phase electrical circuit to turn off one over an AC or three-phase controller guided current. The invention also relates to a method for turning off one via Valve of an AC or three-phase controller led current.

For example for coupling two electrical networks or for coupling a network and a motor or generator load it is known the currents over the valves an AC or three-phase controller. Occurs in such a If there is an error in the electrical circuit, then the currents can pass through the circuit Valves increase to a multiple of their rated current. To avoid of damage is it for example for Thyristors known, the same by blocking the ignition pulses switch off in the current zero crossing. For the resulting overload the thyristors are often oversized or protected by the installation of fuses.

task The invention is a circuit and a method of the initially to provide a simple way of damaging the said species Valves is avoided in the event of a fault.

The Invention solves this object by the circuit according to claim 1 and by the method according to claim 12.

The electrical according to the invention Circuit is provided with an AC or three-phase controller, having at least one valve per phase. This valve is designed as a turn-off valve. The switchable valve is a protective device connected in parallel. According to the inventive method the valve is shut off, for example, in case of failure and the Electricity is then over a protective device connected in parallel with the switch-off valve guided.

by virtue of its shutdown, the valve, especially in case of failure be switched off. The current passed through the valve can over afterwards decay the protective device connected in parallel. The current in this way, the total becomes zero. The invention allows it so that the switch-off valve immediately shuts off in the event of a fault can be without endangering the shut-off valve to lead would. An oversizing the turn-off valve is also not necessary.

at an advantageous embodiment of the invention, the protection device from a parallel connection of a resistor and a capacitor or from a series connection of a resistor and a capacitor or from a varistor or a combination thereof. In this way let yourself realize the protective device easily and inexpensively.

Especially It is advantageous if the capacitor or the varistor with respect to to a possible accident dimensioned, in particular with regard to one possibly occurring overload current. Thus, such an overcurrent over the Decrease protective device.

at an advantageous embodiment of the invention is as turn-off Valve a turn-off thyristor, in particular a gate turn-off thyristor (GTO), or a turn-off transistor, in particular an insulated gate Bipolar transistor (IGBT), provided. Such electronic components are in itself for the realization of an AC or three-phase controller not required and usually also not intended. By the inventive use of these components is achieved that the AC or three-phase controller in the case a fault at the same time to turn off one of the AC or Three-phase actuator guided Electricity can be used.

Especially It is advantageous if the circuit according to the invention for coupling a electrical energy supply network and a generator in particular a wind power plant is used.

Further Features, applications and advantages of the invention will become apparent from the following description of exemplary embodiments of the invention, which are illustrated in the figures of the drawing. All described or illustrated features form for themselves or in any combination, the subject matter of the invention, regardless of their summary in the claims or their dependency as well as independently from their formulation or presentation in the description or in the drawing.

The 1a to 7b each show a schematic circuit diagram of an embodiment of an electrical circuit according to the invention and 8th shows a schematic circuit diagram of an embodiment of an electrical circuit with a double-fed asynchronous generator with grid-connected stator.

In the 1a is a single-phase circuit shown in which two electrical networks are coupled together via an AC power controller.

The two networks are represented by the mains voltages Un and Uq, with both A network inductance Ln and Lq is assigned to networks. One of the two networks can also be a passive motor or generator load. The alternating current controller is represented by the two shutdown thyristors T1 and T2 connected in parallel and in opposite directions.

The Turn-off thyristors T1 and T2 are hereinafter considered as switches, the conducting in the forward direction by a positive current pulse can be switched and then live are, and the off again by a negative current pulse can be and then block in the forward direction. For example, gate turn-off Thyristors, so-called GTOs, be used as turn-off thyristors T1, T2.

The first network with the mains voltage Un, the associated network inductance Ln, the two parallel turn-off thyristors T1, T2 connected to the second network associated line inductance Lq and the second mains with the mains voltage Uq form a series connection.

The two shutdown thyristors T1, T2 is assigned a protective device, consisting of a parallel connection of a resistor R and a capacitor C exists. Alternatively, a series connection of a resistor and a capacitor may be provided as a protective device. The protective device is the two turn-off thyristors T1, T2 connected in parallel.

A Control ST is present, the output signals ZT1, ZT2 for driving the turn-off thyristors T1, T2 generated. From a current sensor W1 becomes a load current flowing between the two networks Un and Uq measured and passed a corresponding signal to the controller ST. Furthermore, the controller ST is over bidirectional lines coupled with other control or regulation systems.

It is now assumed that the turn-off thyristor T2 conducts and thus leads the load current. Furthermore, it is assumed that the capacitor C is substantially discharged. Furthermore, it is assumed that, in particular, the capacitor C is dimensioned with regard to a possible fault, ie with regard to a possibly occurring overload current. By an appropriate choice of the resistance R occur in the normal operation of the circuit of 1a essentially no losses.

In In this operating state, a fault occurs that leads to an overload current Ik leads, which can be a multiple of the load current. This over the Shutdown thyristor T2 flowing overload current Ik is measured by the current sensor W1. Exceeds the overload current Ik a predetermined threshold, this leads to the fact that the turn-off thyristor T2 is turned off by the controller ST. Those in the network inductances Ln, Lq stored energy, however, has the consequence that the overload current Ik continues, over the described protective device time. This has the consequence that the capacitor C of the protective device is charged. The energy stored in the grid inductances Ln, Lq now goes into the capacitor C over. The overload current Ik becomes smaller and sounds to zero.

It is thus now reached a state in which the turn-off thyristor T2 is turned off, and in which the overload current Ik is equal to zero is. Unlike the initial state, however, is the capacitor C charged. As soon as the other turn-off thyristor T1 the next time conducts and thus leads the load current, the capacitor C is discharged again.

In the 1b is shown a single-phase circuit that partially matches the circuit of the 1a having. It will therefore only those components and functions of the circuit below the 1b which is different from the circuit of the 1a differ. With regard to matching components and functions of the circuit of 1b will be on the description of the circuit of 1a directed.

In the 1b there are four diodes D1, D2, D3, D4, via which either the turn-off thyristor T1 or the turn-off thyristor T2 is coupled to the protection device. If the turn-off thyristor T2 is switched off in the event of a fault, the overload current Ik flows from the line inductance Ln via the diode D2 to the protection device and from there via the diode D3 to the line inductance Lq.

Due to the existing diodes D1, D2, D3, D4, it is possible to use the circuit of 1b not only to operate with a full-level control, so ultimately as an on / off switch, but also with only partial modulation.

In the 1c is shown a single-phase circuit that partially matches the circuit of the 1a having. It will therefore only those components and functions of the circuit below the 1c which is different from the circuit of the 1a differ. With regard to matching components and functions of the circuit of 1c will be on the description of the circuit of 1a directed.

In contrast to 1a shows the circuit of 1c as protective device a varistor V on, so a voltage-dependent resistor. During normal operation of the circuit, the resistance is high and there are essentially no losses. Furthermore, it is assumed that, in particular, the varistor V is dimensioned with regard to a possible fault, ie with regard to a possibly occurring overload current. In the case of a fault, the resistance of the varistor V becomes small, so that the overload current Ik driven further by the network inductances Ln, Lq can decay via the varistor V.

It is understood that a corresponding varistor V also in the circuit of 1b can be used as a protective device. It is also understood that the described parallel and series circuits of a resistor R and a capacitor C can also be combined with the described varistor V and then used as a protective device.

In the 2a is shown a polyphase circuit that partially matches the circuit of the 1b having. It will therefore only those components and functions of the circuit below the 2a which is different from the circuit of the 1b differ. With regard to matching components and functions of the circuit of 2a will be on the description of the circuit of 1b directed.

In the 2a There are three phases, are connected to the input and output voltage systems whose star points are connected to each other via a common neutral. In each of the three phases, an alternating current controller is contained, which is represented by two parallel and oppositely connected turn-off thyristors T11, T21, T12, T22, T13, T23. All three phases are assigned a common protective device consisting of a resistor R and a capacitor C.

This protection device is compatible with each of the three AC drives 2a connected in the same way as this in the 1b for a single AC controller is the case. For this purpose, a total of twelve diodes D11, D12, D13, D14, D21, D22, D23, D24, D31, D32, D33, D34 are required, wherein four diodes are always associated with a phase. The operation of the circuit of 2a thus basically corresponds to the operation of the circuit of 1b ,

In the 2 B is shown a polyphase circuit that partially matches the circuit of the 2a having. It will therefore only those components and functions of the circuit below the 2 B which is different from the circuit of the 2a differ. With regard to matching components and functions of the circuit of 2 B will be on the description of the circuit of 2a directed.

Like in the 2a so are also in the 2 B three phases present, are connected to the input and output voltage systems whose star points are connected to each other via a common neutral. In contrast to 2a is however at the 2 B for each of the two possible current directions via the AC power controller each have a separate protection device available. The turn-off thyristors T11, T12, T13 of the one current direction, a first parallel circuit of a resistor R1 and a capacitor C1 is connected in parallel, and the turn-off thyristors T21, T22, T23 of the opposite current direction is a second parallel connection of a resistor R2 and a Capacitor C2 connected in parallel. The explained parallel connection of the two protective devices takes place via a total of twelve diodes, as in a corresponding manner in the circuit of 2a the case is.

In the 3a is shown a polyphase circuit that partially matches the circuit of the 2a having. It will therefore only those components and functions of the circuit below the 3a which is different from the circuit of the 2a differ. With regard to matching components and functions of the circuit of 3a will be on the description of the circuit of 2a directed.

In contrast to 2a shows the circuit of 3a as a protective device on a varistor V, so a voltage-dependent resistor. During normal operation of the circuit, the resistance is high and there are essentially no losses. In the case of a fault, however, the resistance of the varistor V becomes small, so that the overload current Ik1, Ik2, Ik3 driven further by the grid inductances Ln1, Lq1, Ln2, Lq2, Ln3, Lq3 can decay via the varistor V.

It is understood that corresponding varistors V also in the circuit of 2 B can be used as protective devices. It is also understood that the described parallel and series circuits of a resistor R and a capacitor C can also be combined with the described varistor V and then used as a protective device.

In the 3b is shown a polyphase circuit that partially matches with the circuit of 3a having. It will therefore only those components and functions of the circuit below the 3b which is different from the circuit of the 3a differ. With regard to matching components and functions of the circuit of 3b will be on the description of the circuit of 3a directed.

In the 3b Each of the three phases is assigned a separate varistor V. The at the 3a existing diodes are in the circuit of 3b not available anymore. In that sense, each of the three phases corresponds to the 3b in itself the circuit of the 1c , In normal operation, the varistors V each have a high resistance, so that essentially no losses occur. In case of failure, the load current leading shutdown thyristor is turned off. The current driven further by the network inductances then flows via the associated varistor V, which has a low resistance in this operating state. The current thus drops to zero.

In the 4 is shown a polyphase circuit that partially matches the circuit of the 2a having. It will therefore only those components and functions of the circuit below the 4 which is different from the circuit of the 2a differ. With regard to matching components and functions of the circuit of 4 will be on the description of the circuit of 2a directed.

In the 4 There are three phases to which the input and output voltage systems are connected, but their star points are different from the 2a are not connected to each other via a neutral. So there is no common neutral.

Unlike the 2a are in the circuit of 4 Furthermore, not two parallel and oppositely connected turn-off thyristors in each phase present, but in each case only one turn-off thyristor T1, T2, T3 and an opposite direction connected diode D1, D2, D3.

Due to the missing neutral, the sum of all phase currents in the circuit of 4 always equal to zero. Thus, the currents in two phases always flow in one direction and the current in the third phase in the opposite direction. A shutdown of all phases can thus always be achieved, for example, that the turn-off thyristors of the two phases are switched off with rectified current flow. The current in the phase with the counter-current current then inevitably becomes zero.

The three turn-off thyristors T1, T2, T3 of the circuit of 4 a common protective device is connected in parallel. The protective device is connected via a total of 6 diodes D11, D14, D21, D24, D31, D34, which are connected to the corresponding diodes of the Diodes 2a correspond. The protective device consists in the 4 from a parallel connection of a resistor R and a capacitor C.

in the Error case, the turn-off thyristors of those two phases switched off, over the load current flows in the same direction. The load current then gives way over the associated Diodes off and flows over the Protective device. The load current then decays to the value zero. This is also the power over the third phase to zero.

In the 5a is shown a polyphase circuit that partially matches the circuit of the 4 having. It will therefore only those components and functions of the circuit below the 5a which is different from the circuit of the 4 differ. With regard to matching components and functions of the circuit of 5a will be on the description of the circuit of 4 directed.

In contrast to 4 shows the circuit of 5a as a protective device on a varistor V, so a voltage-dependent resistor. During normal operation of the circuit, the resistance is high and there are essentially no losses. In the case of a fault, however, the resistance of the varistor V becomes small, so that the overload current Ik1, Ik2, Ik3 driven further by the grid inductances Ln1, Lq1, Ln2, Lq2, Ln3, Lq3 can decay via the varistor V.

In the 5b is shown a polyphase circuit that partially matches the circuit of the 5a having. It will therefore only those components and functions of the circuit below the 5b which is different from the circuit of the 5a differ. With regard to matching components and functions of the circuit of 5b will be on the description of the circuit of 5a directed.

In the 5b Each of the three phases is assigned a separate varistor V. The at the 5a existing diodes are in the circuit of 5b not available anymore.

In normal operation, the three varistors V have a high resistance. In the event of a fault, the turn-off thyristors of those two phases are switched off, via which the load current in the same Rich flows. The load current then flows through the two associated varistors V, whose resistance in this operating state is small. The load current is thus attenuated by these two varistors V and sounds to zero. Thus, the current over the third phase to zero.

In the 6 . 7a . 7b multiphase circuits are shown that partially match the circuits of the 4 . 5a . 5b exhibit. Therefore, only those components and functions of the circuits of the 6 . 7a . 7b explained, different from the circuits of the 4 . 5a . 5b differ. With regard to matching components and functions of the circuits of 6 . 7a . 7b is based on the description of the circuits 4 . 5a . 5b directed.

Unlike the 4 . 5a . 5b , where as turn-off thyristors T1, T2, T3, for example, GTO's can be used, are in the circuits of the 6 . 7a . 7b turn-off transistors T1, T2, T3 available. These may be, for example, insulated-gate bipolar transistors, so-called IGBTs. Otherwise agree the structure and operation of the circuits of 4 . 5a . 5b with the circuits of 6 . 7a . 7b match.

In the 8th an electrical circuit is shown with a double-fed asynchronous generator with grid-connected stator. This circuit is used in particular in power generation plants, for example in wind power or hydropower or gas turbine power generation plants.

A three-phase power supply network is connected to a transformer T, to which a stator switch Es is further connected, which in turn is connected to the stator of an asynchronous generator G. The stator switch It can be controlled by means of one or more of the circuits of 1a to 7b be realized. The stator switch So it has at least one of the turn-off thyristors or one of the turn-off transistors of 1a to 7b on.

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.

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.

If an error occurs in the power supply network and if this fault is detected by the controller ST, then the stator switch Es is switched off as quickly as possible by the controller ST. The through one of the circuits of the 1a to 7b realized stator switch It is able to perform a changeover from its conductive to the locked state, even under load and especially in the case of a fault in the energy supply network. The switchover to the locked state is achieved upon reaching a predetermined intermediate circuit voltage Ud or Er range of a given stator current Is or triggered by the control ST when another predetermined threshold value is reached.

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.

To the interruption of the stator current Is through the stator switch Es the rotor-side converter Mpr is so from the controller ST controlled that the magnetic flux synchronized to the faulty power grid becomes. Watched the controller is the mains voltage Un and the stator voltage Us. Becomes the difference of these two voltages to zero, which is synonymous with that, the voltage applied to the stator switch Es becomes zero, the stator switch Es from the controller ST switched back on. Thereafter, the stator current Is from the controller ST are controlled by means of the rotor-side converter Mpr such that predetermined by the operator of the power grid Requirements for the supply of energy in case of failure are met.

Claims (13)

Single-phase or multi-phase electrical circuit for switching off a guided via an AC or three-phase controller current, wherein the AC or three-phase controller has at least one valve per phase, characterized in that the valve is designed as a shut-off valve, and that the shut-off valve, a protection device is connected in parallel. Single or multi-phase circuit according to claim 1, wherein the protective device consists of a parallel connection of a resistor (R) and a capacitor (C) or from a series circuit of a resistor and a capacitor or from a varistor (V) or from a Combination of it exists. Single or multi-phase circuit according to claim 2, wherein the capacitor (C) or the varistor (V) with regard to a possible accident dimensioned, in particular with regard to one possibly occurring overload current. Single or multi-phase circuit according to one of the preceding Claims, as shut-off valve, a shutdown thyristor, in particular a gate turn-off thyristor (GTO), or a turn-off transistor, in particular an insulated gate bipolar transistor (IGBT) is provided. Single or multi-phase circuit according to one of the preceding Claims, the protective device over Diodes the shut-off valve is connected in parallel. Polyphase circuit according to one of claims 1 to 5, wherein the phases are connected to each other via a neutral conductor, wherein in each phase two switchable valves are present, and wherein all turn-off valves associated with a common protective device ( 2a . 3a ). Polyphase circuit according to one of claims 1 to 5, wherein the phases are connected to one another via a neutral conductor, wherein in each phase two switchable valves are present, and wherein the shut-off valves associated with a matching current direction are each assigned a separate protective device ( 2 B . 3b ). Polyphase circuit according to one of claims 1 to 5, wherein the phases are not connected to each other via a neutral conductor, wherein in each phase a diode (D1, D2, D3) and a turn-off valve are present, and wherein all turn-off valves associated with a common protective device is ( 4 . 5a and 6 . 7a ). Polyphase circuit according to one of claims 1 to 5, wherein the phases are not connected to each other via a neutral conductor, wherein in each phase a diode (D1, D2, D3) and a turn-off valve are present, and wherein each disconnectable valve associated with a separate protection device is ( 5b and 7b ). Single or multi-phase circuit according to one of the preceding Claims, wherein the AC or three-phase controller between two electrical Networks (Un, Uq) or between an electrical network and a load is switched. Single or multi-phase circuit according to claim 10, wherein as an electrical network, an energy supply network and as a load, a generator, in particular a wind power plant is provided. Method for switching off a valve via an AC or three-phase controller led Strom, characterized in that the valve as disconnectable Valve is designed that the valve is turned off, and that the current over a protective device connected in parallel with the switch-off valve guided becomes. The method of claim 12, wherein an asynchronous generator on the stator side the switch-off valve is coupled to a power supply network, wherein the asynchronous generator on the rotor side via a rotor-side converter, a Zwischenkries and a network-side inverter to the power grid is coupled, and wherein at a fault in the power grid the coupling between the stator of the asynchronous generator and the Power supply network as possible is interrupted.