JP2647182B2 - High voltage power supply - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a large-capacity high-voltage power supply device suitable for variable frequency operation from 0 (Hz) to a required frequency.

(Prior Art) FIG. 10 shows an example of the prior art, wherein 1 is a power source, 2 is a power source,
Is a transformer, 3 is a reactor, 4 is a three-phase voltage source self-excited converter, 5 is a single-phase bridge voltage source self-excited converter, 6 is a step-up transformer, and 7 is a load. Although only one set of the three-phase voltage-type self-excited converter 4 and the single-phase bridge voltage-type self-excited converter is shown here, they are collectively referred to as an AC power supply unit 10. In the configuration shown in FIG. 10, after the power supply 1 is transformed by the transformer 2, it is connected to the first AC terminals 4U, 4V, 4W of the three-phase voltage source self-excited converter 4 via the reactor 3, and the first The DC terminals 4P, 4N are connected to the second DC terminals 5P, 5N of the single-phase bridge voltage type self-excited converter 5. The second AC terminals 5U and 5V of the single-phase bridge voltage type self-excited converter are connected to the primary side of the transformer 6 and the load 7 is connected to the secondary side.

One example of specific circuits of the three-phase voltage source self-excited converter 4 and the single-phase voltage source self-excited converter 5 is shown in FIGS. 11 and 12, respectively.
This circuit is conventionally known as an inverter that converts direct current to alternating current. However, since conversion from alternating current to direct current is also possible, the name of a voltage-type self-excited converter is used here.

11 and 12, 101 is a GTO thyristor, 102 is a diode, 103 is a fuse, and 104 is a capacitor.
This circuit requires a snubber circuit, a gate circuit, and the like for practical use. The operation of this circuit is well known,
For example, "Semiconductor Power Conversion Circuit" published by IEEJ (March 1987)
It is described in detail in Chapters 6 and 9 of (Mon), and thus the description is omitted. This circuit configuration can operate the single-phase bridge voltage-type self-excited converter 5 as a rectifier and the three-phase voltage-type self-excited converter 4 as an inverter.

Returning to FIG. 10, considering the application where it is necessary to apply a sine wave alternating current of any frequency from 0 Hz to 25 Hz to the load 7 at a high voltage of up to 11 kV, the transformer 7 is provided. There is a basic problem that DC cannot be transmitted to the load side. If transformers are not available, voltage source self-excited converters 4 and 5 will have to choose a DC voltage of about 18 kV in order to be able to output 11 kV AC directly. However, since the components constituting the conversion circuit, for example, semiconductor elements, are not durable, it is necessary to use ten or more units connected in series.

Although serial connection of semiconductor elements such as GTO has already been performed, an anode reactor and a snubber capacitor are required to improve voltage sharing. However, each time the semiconductor element is turned on, the electric charge of the snubber capacitor is discharged, which causes a loss. On the other hand, each time the semiconductor element is turned off, the stored energy of the anode reactor is lost. Studies have been conducted to reduce these losses, but no effective means has been found for a series connection. Therefore, since the switching frequency must be reduced as much as possible, it becomes difficult to supply a sine wave alternating current.

FIG. 13 shows an example of a conventional circuit improved so that DC can be transmitted to a load. The difference from FIG. 10 lies in that a plurality of single-phase bridge voltage type self-excited converters 5 are provided, and one of the outputs is connected to a load without passing through a transformer. Conventional problems have been solved, such as being able to supply direct current, and being able to output sinusoidal alternating current through PWM (pulse width modulation) control.

(Problems to be Solved by the Invention) The circuit configuration shown in FIG. 13 solves the conventional problems as described above, but the transformer occupies an input side and an output side. Wide, especially the output side is low frequency, so the outer shape of the transformer is almost twice the size of the transformer for commercial frequency, special control to prevent the transformer from being magnetized by direct current However, there still remain problems such as the necessity of the design, the design with redundancy for improving the reliability, and the design of the function of the partial operation.

The present invention has been made to solve the above problems,
An object of the present invention is to provide an excellent large-capacity high-voltage power supply device capable of generating a sine wave alternating current from a direct current to a desired frequency, reducing transformers, and having a partial operation function for improving reliability.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a first multi-phase or single-phase bridge voltage source having a first AC terminal and a first DC terminal. Connecting a self-excited converter, a second single-phase bridge voltage-type self-excited converter having a second DC terminal and a second AC terminal, or connecting the first DC terminal and the second DC terminal,
N sets of AC power supply units (where n is an integer of 2 or more) having a function of generating another AC from the AC supplied from the first AC terminal to the second AC terminal via the DC circuit. The n sets of first AC terminals are connected to a common AC power supply via n sets of reactors and insulating transformers, respectively, and the n sets of second AC terminals are connected in series to form a DC connection terminal. A switching device that is normally open-circuited between the second AC terminals of each of the n sets, and a faulty power supply unit is operated when any of the AC power supply units fails. Is stopped and the switchgear provided in the failed power supply unit is closed so that the operation can be partially continued.

Also, a first AC terminal having a first AC terminal and a first DC terminal is provided.
And a second single-phase bridge voltage-type self-excited converter having a second DC terminal and a second AC terminal comprises the first DC terminal and the An AC power supply unit having a function of generating a different AC from the AC supplied from the first AC terminal at the second AC terminal by connecting the DC power to the second DC terminal and connecting the DC power to the second AC terminal. 1) a set (where m: an integer of 2 or more), a converter similar to the first polyphase or single-phase bridge voltage type self-excited converter, and a third having a positive terminal, a negative terminal, and an intermediate potential terminal. DC terminal and third
A third half-bridge voltage source self-excited converter having an AC terminal connects the first DC terminal to the positive terminal and the negative terminal of the third DC terminal, and the third DC terminal connects to the third DC terminal via the DC circuit. One set of an AC power supply unit having a DC neutral point having a function of generating another AC from the AC supplied from one AC terminal between the third AC terminal and the positive terminal and the negative terminal is provided, and m sets of The first AC terminals are connected to a common AC power supply via m sets of reactors and insulating transformers, respectively.
A second AC terminal of the (m-1) sets of AC power supply units, a third AC terminal of the AC power supply unit with a DC neutral point, and an intermediate potential terminal are connected in series, and a load is connected between the series connection terminals. And a switching device that is normally open between each of the (m-1) sets of the second AC terminals and between the set of the third AC terminals and the intermediate potential terminal is provided. When any one of the power supply units fails, the operation of the failed power supply unit is stopped, and the switching device provided in the failed power supply unit is closed so that the operation can be partially continued.

(Operation) With the configuration described above, a high voltage can be obtained because the output voltage of each AC power supply unit is added in series to the load and applied.

Also, since there is no transformer on the output side of the AC power supply unit, the device can be downsized, and if any of the AC power supply units fails, the operation of the failed AC power supply unit is stopped. By closing the switchgear provided in the failed AC power supply unit, the operation can be continued with the remaining healthy AC power supply unit, so that the reliability can be improved.

(Embodiment) FIG. 1 shows an embodiment of the present invention. The description of the same components as those used in the description of the conventional drawings is omitted. However, the suffix is added for distinction when there are a plurality of identical sets. The 10 AC power supply units are the same as those in FIG. 10 except that there are three sets and the input side has three reactors 3 ₁ , 3
_They are connected to the transformer 2 via ₂ , 3 ₃ respectively. The output side is connected in series to the load 7. A switching device 11 is provided between the second AC terminals 5U and 5V of the voltage source self-excited converter 5.

The operation of FIG. 1 will be described. AC power supply units 10 ₁ , 10 ₂ ,
Each of 10 ₃ obtains a desired alternating current from one alternating current through direct current by operating the three-phase voltage source self-excited converter 4 as a rectifier and the single-phase bridge voltage source self-excited converter 5 as an inverter. Can be done. The respective generated voltages are added in series to become a high voltage and supplied to the load 7. Conversely, by operating the single-phase bridge voltage-type self-excited converter 5 as a rectifier and the three-phase voltage-type self-excited converter 4 as an inverter, the energy of the load 7 can be regenerated to the power supply. Switchgear 11 _1, 11 _2, 11 but ₃ are open at all times, for example when the AC power source unit 10 ₁ has failed, as well as shut down only the AC power supply unit, by closing the opening and closing device _111, the remaining power can be supplied to the load 7 with the AC power source unit 10 ₂ and 10 _3. In this example, the voltage drops to 2/3 because there are only three AC power supply units, but when the number of AC power supply units is large, or by adding redundancy in advance, the operation is almost unaffected by failure. Can be continued. Even if a component inside the AC power supply unit 10 becomes defective, the fuse in the internal circuit is blown so that the operation of other sound AC power supply units is not hindered. A separate switchgear may be provided for each AC power supply unit 10 as necessary, instead of a fuse.

The effects obtained by the present invention are listed as follows.

(1) Since there is no transformer between the AC power supply unit and the load, DC can be supplied to the load.

(2) Since there is no switching restriction due to the series connection, the single-phase bridge voltage-type self-excited converter 5 can apply a sine wave AC with little waveform distortion to the load by performing PWM control.

(3) Since the transformer is provided only on the power supply side, it is expected that the installation area and cost will be reduced.

(4) When a part of the AC power supply unit fails, the operation of the part can be stopped and the remaining AC power supply unit can be partially operated. In the case where it is used, no unnecessary confusion is given.

(5) Compared to FIG. 10, the number of AC power supply units seems to be uneconomical, but assuming a case where the capacity of the target load is very large, in the case of FIG. While one set of AC power supply units is used in parallel, in the case of FIG. 1, since the number of units is increased to increase the capacity, the number of semiconductor elements is the same or rather small.

FIG. 2 shows another embodiment. The difference from FIG. 1 is that the voltage-type self-excited converter 4 has a single phase. The voltage-type self-excited converter 4 may be exactly the same as the single-phase bridge voltage-type self-excited converter 5. The only operation is the difference between three-phase and single-phase.

FIG. 3 shows another embodiment of the present invention. FIG. 3 is different from FIG. 1 in that one of the three single-phase bridge voltage type self-excited converters 5 is replaced with a single-phase half-bridge voltage type self-excited converter. This is an alternative to the vessel 8. Reference numerals 10 ₁ and 10 ₂ denote AC power supply units similar to those shown in FIG. Reference numeral 20 denotes a single-phase AC power supply unit with a neutral point having a neutral point in the DC circuit, and includes a three-phase voltage-type self-excited converter 4 and a single-phase half-bridge voltage-type self-excited converter 8. The single-phase half-bridge voltage source self-excited converter 8 refers to a circuit as shown in FIG. 4, and there is no difference in operation except that the output voltage is half that of the circuit of FIG. The AC side has a third AC terminal. For DC, besides the positive electrode 8P and the negative electrode 8N, a neutral point 8C
There is a third DC terminal having An advantage of the configuration of FIG. 3 is that it is suitable for a multi-phase configuration. FIG. 5 shows a configuration of a power supply device for obtaining two-phase outputs A and B as an example. The subscripts A and B are A phase and B, respectively.
Used when needed to distinguish phases. In addition to connecting the two neutral points, a two-phase output is obtained by shifting the phases of the AC output voltages by 90 ° with respect to each other by a controller not shown. FIG. 6 shows a power supply for obtaining a two-phase output as in FIG. 5, but the transformer 2 is common to each phase and a part of the AC power supply unit with a neutral point is common. It is. Reference numeral 30 denotes an AC power supply unit with a neutral point having a different number of output terminals from that of 20, and 9 denotes a two-phase half-bridge voltage-type self-excited converter with a neutral point. The first DC terminal of the voltage-type self-excited converter is connected to the third DC terminal of the two-phase half-bridge voltage-type self-excited converter 9 with a neutral point. FIG. 7 is a detailed view of the two-phase half-bridge voltage source self-excited converter 9 with a neutral point. This circuit can be considered as having two sets of the DC and neutral points in FIG. 4 in common.

5 and 6, when one of the AC power supply units in the set breaks down, the operation of the corresponding AC power supply unit is stopped, and the switching device 11 provided at the output thereof is stopped.
Is partially closed, but at the same time, the operation of some other AC power supply units is stopped and the switchgear provided at its output is also partially closed, resulting in voltage imbalance. Desirable for not.

In the power supply device of the present invention represented by FIG. 1, the reactor 3 and the transformer 2 are separate, but if a stray reactance of the transformer is used as the reactor, a circuit configuration having no apparent reactor is also established. It is clear that. The switching device 11 is not limited to a mechanical device, but is a general term for devices having a function of short-circuiting between the second AC terminals or between the third AC terminal and the neutral point.

The power supply devices described so far basically can transfer energy from the power supply to the load and from the load to the power supply. However, depending on the type of the load, only the reversible function is not always required. FIG. 8 is an example of a non-reciprocal power supply device. 40 is an AC power supply unit, 41 is a separately excited rectifier, and 42 is an L-type LC filter. The specific circuit 41 is a circuit well known as a three-phase bridge rectifier as shown in FIG. The secondary of the transformer 2 is connected to the fourth AC terminals 41U, 41V, 41W of the separately-excited rectifier 41, and the input AC is converted to DC and then smoothed by an L-type LC filter. The output is obtained from the fourth DC terminals 42P and 42N. The fourth DC terminal is connected to the second DC terminal of the single-phase bridge voltage type self-excited converter 5, and the alternating current reconverted by the single-phase bridge voltage type self-excited converter is obtained from the second AC terminal. Other operations are the same as those in FIG. 1 except that they are irreversible and that the separately excited rectifier has no power factor control function.

[Effects of the Invention] The present invention described in detail above can reduce the occupied area of equipment and ensure high operational reliability by eliminating the need for a transformer on the output side as compared with the conventional one. Therefore, DC
It is most suitable as a large-capacity and high-voltage power supply that requires a sine wave alternating current from 0 Hz to a relatively low frequency, for example, a power supply for driving a linear synchronous motor of transportation.

[Brief description of the drawings]

FIG. 1, FIG. 2, FIG. 3, FIG. 5, FIG. 6, FIG. 8, and FIG.
The figure shows the configuration of the conventional device, and FIGS. 4, 7, 11, 12
FIG. 13 is a diagram for explanation. DESCRIPTION OF SYMBOLS 1 ... Power supply, 2 and 6 ... Transformer, 3 ... Reactor, 4 ... Voltage-type self-excited converter, 5 ... Single-phase bridge voltage-type self-excited converter, 7 ... Load, 8 ... Medium Single-phase half-bridge voltage-type self-excited converter with neutral point, 9 ... 2-phase half-bridge voltage-type self-excited converter with neutral point, 10 ... AC power supply unit, 11 ... load, 20 ... neutral point With single-phase AC power supply unit, 30 ... two-phase AC power supply unit with neutral point, 40 ... non-reciprocal AC power supply unit, 41 ... separately-excited rectifier, 42 ... L-type
LC filter, 101 GTO thyristor, 102 diode, 103 fuse, 104 capacitor, 105 thyristor.

Claims (9)

(57) [Claims] 1. A first multi-phase or single-phase bridge voltage-type self-excited converter having a first AC terminal and a first DC terminal, and a second having a second DC terminal and a second AC terminal. A single-phase bridge voltage source self-excited converter connects the first DC terminal and the second DC terminal, and separates another AC from the AC supplied from the first AC terminal via the DC circuit. N sets of AC power supply units having a function of generating an alternating current at the second AC terminal (where n is an integer of 2 or more) are provided, and the n sets of first AC terminals are respectively provided with n sets of reactors and insulation transformers. Connected to a common AC power supply via a switch, the n sets of second AC terminals are connected in series, a load is connected between the series connected terminals, and each of the n sets of second AC terminals is connected. A switching device that is normally open is provided between the AC power supply units. High-voltage power supply apparatus when the is characterized in that as the failed power supply unit can continue to stop by the failure partially operated by closing said opening and closing device provided in the power unit operation. 2. The high-voltage power supply according to claim 1,
A high-voltage power supply unit characterized in that the n sets of reactors are replaced by stray reactance functions of an insulating transformer. 3. The high-voltage power supply according to claim 1,
Instead of the first multi-phase or single-phase bridge voltage-type self-excited converter, a multi-phase or single-phase bridge separately-excited rectifier having a fourth AC terminal and a fourth DC terminal and an L-type LC filter. A high-voltage power supply device characterized by the above-mentioned. 4. A first multi-phase or single-phase bridge voltage-type self-excited converter having a first AC terminal and a first DC terminal, and a second having a second DC terminal and a second AC terminal. A single-phase bridge voltage-type self-excited converter connects the first DC terminal and the second DC terminal to form a DC link, and converts another AC from the AC supplied from the first AC terminal. An AC power supply unit having a function of generating at the second AC terminal is (m-
1) a set (however, m: an integer of 2 or more), an exchange similar to the first multi-phase or single-phase bridge voltage-type self-excited converter, and a third switch having a positive terminal, a negative terminal, and an intermediate potential terminal. A third herb bridge voltage-type self-excited converter having a DC terminal and a third AC terminal connects the first DC terminal to the positive terminal and the negative terminal of the third DC terminal, An AC power supply unit with a DC neutral point having a function of generating another AC from the AC supplied from the first AC terminal through a circuit between the third AC terminal, the positive terminal, and the negative terminal. The m sets of first AC terminals are connected to a common AC power supply via m sets of reactors and insulating transformers, respectively, and the second AC terminals of the (m-1) sets of AC power supply units and the Third AC terminal and intermediate potential of AC power supply unit with DC neutral point And a load is connected between the series connection terminals, and between each of the (m-1) sets of the second AC terminals and between the one set of the third AC terminals and the intermediate potential terminal. A switching device that is normally open is provided, and when any of the AC power supply units fails, the failed power supply unit stops operating and closes the switching device provided in the failed power supply unit. A high-voltage power supply unit characterized in that the operation can be partially continued. 5. The high-voltage power supply according to claim 4,
A plurality of sets of high-voltage power supplies are provided, each neutral point is connected, and each high-voltage power supply is operated with a phase difference to generate an AC output having a different phase. Phase high voltage power supply. 6. The high-voltage power supply according to claim 5,
The first multi-phase or single-phase bridge voltage-type self-excited converter of the AC power supply unit with a neutral point and the reactor and the insulation transformer winding connected thereto are provided commonly to a plurality of sets of high-voltage power supply units. Multi-phase high voltage power supply. 7. The high-voltage power supply according to claim 5,
A multi-phase high-voltage power supply device characterized in that when a one-phase high-voltage power supply device performs a partial operation due to a failure of some of the AC power supply units, the other phase high-voltage power supply device performs the same partial operation. 8. The high-voltage power supply according to claim 6, wherein
A multi-phase high-voltage power supply, wherein when a partial operation is performed due to a failure of one-phase high-voltage power supply, another high-voltage power supply performs the same partial operation. 9. A high-voltage power supply according to claim 4, wherein the m sets of reactors are replaced by stray reactance functions of the insulating transformer. apparatus.