JPH09219975A - Inverter device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the power supply unit of an upper arm drive circuit in a bridge-connected inverter device. SOLUTION: This device is provided with a d.c. power supply 61, power capacitors 62, 63 for supplying power to upper arm drive circuits 41, 43 respectively, and diodes 64, 65. While the switching circuit of a lower arm in an inverter main circuit 2 is ON, charging current is passed through the power capacitors 62, 63 via the diode 64 or 65 from the d.c. power supply 61.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bridge-connected inverter device, and more particularly to a power supply for upper and lower arm drive circuits of an inverter main circuit of the inverter device.

[0002]

2. Description of the Related Art FIG. 4 is a circuit configuration diagram of an inverter device showing a conventional example of this type, and shows a case of a single-phase bridge connection. In FIG. 4, 1 is an inverter main circuit 2
Main circuit DC power supply for supplying electric power to 21 to 24 is an insulated gate bipolar transistor (hereinafter simply referred to as IGBT) as a self-extinguishing type semiconductor element, 31 to 34 are diodes, 41 and 43 are IGBTs 21 and 23 Upper arm drive circuit, 42 and 44 are IGBTs 22 and 2
4, a lower arm drive circuit for driving 4, a DC power source for the upper arm drive circuit 41, a DC power source for the lower arm drive circuit 42 and a lower arm drive circuit 44, 5
Reference numeral 3 is a DC power supply for the upper arm drive circuit 43.

The DC power supplies 51 to 53 shown in FIG. 4 are insulated from each other by converting the main circuit DC power supply 1 into a desired voltage by a DC-DC converter (not shown).
In addition, the upper arm drive circuits 41 and 43 shown in FIG.
And the lower arm drive circuits 42 and 44 have a known circuit configuration, and generally, the respective circuits have the same circuit configuration.

[0004]

According to the circuit configuration of the above-mentioned conventional inverter device, the power supplies of the upper and lower arm drive circuits require at least three sets of insulated DC power supplies, and further, three-phase bridge connection is required. In the inverter main circuit, at least four sets of DC power supplies of this type are required, and as a result, the circuit configuration of the inverter device is complicated and expensive.

An object of the present invention is to provide an inverter device which solves the above problems.

[0006]

SUMMARY OF THE INVENTION The first invention is an inverter main circuit in which a plurality of sets of switching circuits each having a structure in which a self-arc-extinguishing type semiconductor element and a diode are connected in antiparallel are bridge-connected, and the inverter main circuit. A main circuit DC power supply connected in parallel to the main circuit for supplying electric power, an upper arm drive circuit for driving each self-extinguishing type semiconductor element of the switching circuit of the upper arm of the inverter main circuit, and a lower arm of the inverter main circuit. A lower arm drive circuit for driving each self-extinguishing type semiconductor element of the switching circuit, a first DC power supply used as a power source for the upper arm drive circuit, and a switching circuit for the lower arm of the inverter main circuit are provided. During the on period, the first
A power supply capacitor that is charged from a DC power supply and supplies power to each of the upper arm drive circuits, a cathode terminal is connected to the positive electrode of each of the power supply capacitors, and respective anode terminals are connected in parallel. A charging diode having a point connected to the first DC power supply, and a second DC power supply supplying power to each of the lower arm drive circuits.

A second aspect of the present invention is an inverter main circuit in which a plurality of sets of switching circuits each having a structure in which a self-arc-extinguishing type semiconductor element and a diode are connected in anti-parallel are bridge-connected, and power is connected in parallel to the inverter main circuit. A main circuit DC power supply for supplying, an upper arm drive circuit for driving each self-extinguishing type semiconductor element of the switching circuit of the upper arm of the inverter main circuit, and a self of each of the switching circuits of the lower arm of the inverter main circuit. While the lower arm drive circuit for driving the arc-extinguishing semiconductor device, the first DC power supply used as a power source for the respective upper arm drive circuits, and the switching circuit of the lower arm of the inverter main circuit are on, A power supply controller that is charged from the first DC power supply and supplies power to each of the upper arm drive circuits. And capacitors, the connecting the cathode to the cathode terminal of each of the power supply capacitor, the charge diode connected in parallel to respective anode terminals, the first
A PNP transistor connected between the positive side terminal of the DC power source and the parallel connection point of the charging diodes, and a PNP transistor connected between the base terminal of the PNP transistor and the negative side terminal of the first DC power source. And a second DC power supply for supplying power to the respective lower arm drive circuits.

A third aspect of the invention is an inverter main circuit in which a plurality of sets of switching circuits each having a structure in which a self-arc-extinguishing type semiconductor element and a diode are connected in anti-parallel are bridge-connected, and power is connected in parallel to the inverter main circuit. A main circuit DC power supply for supplying, an upper arm drive circuit for driving each self-extinguishing type semiconductor element of the switching circuit of the upper arm of the inverter main circuit, and a self of each of the switching circuits of the lower arm of the inverter main circuit. While the lower arm drive circuit for driving the arc-extinguishing semiconductor device, the first DC power supply used as a power source for the respective upper arm drive circuits, and the switching circuit of the lower arm of the inverter main circuit are on, A power supply controller that is charged from the first DC power supply and supplies power to each of the upper arm drive circuits. And capacitors, the connecting the cathode to the cathode terminal of each of the power supply capacitor, the charge diode connected in parallel to respective anode terminals, the first
A PNP transistor connected between the positive side terminal of the DC power source and the parallel connection point of the charging diodes, and a PNP transistor connected between the base terminal of the PNP transistor and the negative side terminal of the first DC power source. Resistance and the PNP
A first capacitor connected between a base terminal and an emitter terminal of the transistor, and a second DC power supply for supplying power to the respective lower arm drive circuits are provided.

Further, in a fourth aspect based on the first to third aspects, the switching circuit of the lower arm of the inverter main circuit is turned on for a predetermined period at the time of initial charging of the power source capacitors. According to the first aspect of the invention, the charging voltage of the power supply capacitor charged from the set of DC power supplies via the respective diodes during the ON period of the lower arm switching circuit is used as the power supply of the respective upper arm drive circuits. It can be configured.

According to the second aspect of the invention, the charging voltage of the power supply capacitor charged from the set of DC power supplies via the PNP transistor and the respective diodes during the ON period of the switching circuit of the lower arm is increased. The arm drive circuit can be configured to use as a power source, and the charging current of the power source capacitor can be kept constant by the resistor connected to the base of the PNP transistor.

In addition to the operation of the second invention, the third invention suppresses the charging current while the DC power supply is rising by the first capacitor between the base and emitter terminals of the PNP transistor. DC power supply can be started up smoothly. Further, in a fourth aspect of the present invention, in the first to third aspects, a simple circuit that turns on the switching circuit of the lower arm for a predetermined time at the time of initial charging of each power source capacitor can be configured.

[0012]

FIG. 1 is a circuit configuration diagram of an inverter device showing a first embodiment of the present invention. Components having the same functions as those of the conventional example shown in FIG. And its description is omitted. That is, in FIG. 1, a DC power source 61 used as a power source for the upper arm drive circuits 41 and 43, power source capacitors 62 and 63 for supplying power to the upper arm drive circuits 41 and 43, and a power source capacitor 62, 63 A charging diode 64, 6 in which a cathode terminal is connected to each positive electrode, and respective anode terminals are connected in parallel and connected to the positive terminal of the DC power supply 61.
5 is provided.

The power supply capacitors 62 and 63 are charged by the DC power supply 61 while the switching circuit of the lower arm of the inverter main circuit 2 is on. Further, the charging completion voltage of each of the power supply capacitors 62 and 63 is determined by the diode 32 of the switching circuit of the lower arm of the inverter main circuit 2.
Alternatively, in relation to the conduction mode of the diode 34, the voltage value becomes higher than the voltage value of the DC power supply 61 by the voltage of the layers of these diodes. Therefore, by making the voltage value of the DC power supply 61 smaller than the voltage value of the DC power supply 52 by the arm layer voltage, the driving conditions of all the IGBTs 21 to 24 can be made the same.

FIG. 2 is a circuit configuration diagram of an inverter device showing a second embodiment of the present invention, and those having the same functions as those of the first embodiment of the present invention shown in FIG. The description is omitted. That is, in FIG. 2, between the positive side terminal of the DC power supply 61 and the parallel connection point of the charging diodes 64 and 65 in the circuit of FIG.
P transistor 66 is connected to connect PNP transistor 66
A resistor 6 is placed between the base terminal of the DC power supply and the negative terminal of the DC power supply 61.
7 is connected.

The power supply capacitors 62 and 63 are charged from the DC power supply 61 through the PNP transistor 66 and the charging diode 64 or the charging diode 65 while the lower arm switching circuit of the inverter main circuit 2 is on. The charging current at this time is the PNP transistor 6
DC power supply 6 with the resistance value of resistor 67 which is the bias resistor of 6
It is determined by a value obtained by multiplying the bias current value obtained by dividing the voltage of 1 by the DC current amplification factor (h _FE ) of the PNP transistor 66.

In this way, the PNP transistor 6 is provided in the charging path from the DC power supply 61 to the power supply capacitors 62 and 63.
The charging current suppressing circuit including the resistor 67 and the resistor 67 keeps the charging current of the power supply capacitors 62 and 63 constant. FIG. 3 is a circuit configuration diagram of an inverter device showing a third embodiment of the present invention, and those having the same functions as those of the second embodiment of the present invention shown in FIG. The description is omitted.

That is, in FIG. 3, P of the circuit of FIG.
A capacitor 71 is connected between the base and emitter terminals of the NP transistor 66, and when the voltage of the DC power supply 61 rises, the capacitor 71 causes the PNP transistor 6 to operate.
Since the bias current of 6 is bypassed, the power supply capacitors 62 and 63 are not charged by the transient voltage at the time of rising of the voltage of the DC power supply 61.

[0018]

According to the present invention, the charging voltage of the power supply capacitor charged from the set of DC power supplies via the respective diodes during the ON period of the lower arm switching circuit is set to the upper arm drive circuit. Since the power source is used, the circuit configuration of the inverter device is simple and inexpensive as a result.

[Brief description of drawings]

FIG. 1 is a circuit configuration diagram of an inverter device showing a first embodiment of the present invention.

FIG. 2 is a circuit configuration diagram of an inverter device showing a second embodiment of the present invention.

FIG. 3 is a circuit configuration diagram of an inverter device showing a third embodiment of the present invention.

FIG. 4 is a circuit configuration diagram of an inverter device showing a conventional example.

[Explanation of symbols]

1 ... Main circuit DC power supply, 2 ... Inverter main circuit, 21-2
4 ... IGBT, 31-34 ... Diode, 41, 43 ...
Upper arm drive circuit, 42, 44 ... Lower arm drive circuit, 51-54, 61 ... DC power supply, 62, 63 ... Power supply capacitor, 64, 65 ... Charging diode, 66 ...
PNP transistor, 67 ... Resistor, 71 ... Capacitor.

Claims (4)

[Claims] 1. An inverter main circuit in which a plurality of sets of switching circuits each having a configuration in which a self-extinguishing type semiconductor element and a diode are connected in antiparallel are connected in a bridge, and a main circuit DC connected in parallel to the inverter main circuit and supplying electric power. A power supply, an upper arm drive circuit for driving each self-extinguishing semiconductor element of the switching circuit of the upper arm of the inverter main circuit, and a self-extinguishing semiconductor element of each of the switching circuits of the lower arm of the inverter main circuit A lower arm drive circuit for driving a first DC power supply used as a power source for each of the upper arm drive circuits, and a first DC power supply during a period in which a lower arm switching circuit of the inverter main circuit is on. A capacitor for power supply, which is further charged and supplies power to each of the upper arm drive circuits, A cathode terminal is connected to the positive electrode of each power supply capacitor, respective anode terminals are connected in parallel, and a charging diode in which the parallel connection point is connected to the first DC power supply, and the respective lower arm drives An inverter device comprising: a second DC power supply for supplying electric power to a circuit. 2. An inverter main circuit in which a plurality of sets of switching circuits each having a configuration in which a self-arc-extinguishing type semiconductor element and a diode are connected in anti-parallel are bridge-connected, and a main circuit DC connected in parallel to the inverter main circuit and supplying electric power. A power supply, an upper arm drive circuit for driving each self-extinguishing semiconductor element of the switching circuit of the upper arm of the inverter main circuit, and a self-extinguishing semiconductor element of each of the switching circuits of the lower arm of the inverter main circuit A lower arm drive circuit for driving a first DC power supply used as a power source for each of the upper arm drive circuits, and a first DC power supply during a period in which a lower arm switching circuit of the inverter main circuit is on. A capacitor for power supply, which is further charged and supplies power to each of the upper arm drive circuits, A charging diode in which a cathode terminal is connected to the positive electrode of each power source capacitor, and respective anode terminals are connected in parallel, and a positive side terminal of the first DC power source and a parallel connection point of the respective charging diodes. A PNP transistor connected between the PNP transistor, a resistor connected between the base terminal of the PNP transistor and the negative terminal of the first DC power supply, and a second power supply for supplying power to the respective lower arm drive circuits. An inverter device comprising a DC power supply. 3. An inverter main circuit in which a plurality of sets of switching circuits each having a structure in which a self-extinguishing type semiconductor element and a diode are connected in anti-parallel are connected in a bridge, and a main circuit DC connected in parallel to the inverter main circuit and supplying electric power. A power supply, an upper arm drive circuit for driving each self-extinguishing semiconductor element of the switching circuit of the upper arm of the inverter main circuit, and a self-extinguishing semiconductor element of each of the switching circuits of the lower arm of the inverter main circuit A lower arm drive circuit for driving a first DC power supply used as a power source for each of the upper arm drive circuits, and a first DC power supply during a period in which a lower arm switching circuit of the inverter main circuit is on. A capacitor for power supply, which is further charged and supplies power to each of the upper arm drive circuits, A charging diode in which a cathode terminal is connected to the positive electrode of each power source capacitor, and respective anode terminals are connected in parallel, and a positive side terminal of the first DC power source and a parallel connection point of the respective charging diodes. A PNP transistor connected between the PNP transistor, a resistor connected between the base terminal of the PNP transistor and the negative terminal of the first DC power supply, and a resistor connected between the base terminal and the emitter terminal of the PNP transistor. And a second DC power supply for supplying power to the respective lower arm drive circuits. 4. The inverter device according to claim 1, wherein a switching circuit of a lower arm of the inverter main circuit is turned on for a predetermined period during initial charging of each of the power supply capacitors. Inverter device characterized by.