JPH02307366A - Variable voltage/variable frequency power-supply device - Google Patents

Abstract

PURPOSE:To improve an output waveform by interposing a reactor between the switching circuits of a converter circuit. CONSTITUTION:A variable voltage/variable frequency power-supply device is composed of a converter circuit D with switching circuits 3 connected in series, a smoothing circuit B, and an inverter circuit E with switching circuits 3 connected in series. Then, the power input section 5 of single phase AC volt age, and the intermediate section of the two switching circuits 3 of the converter circuit D are connected to each other via a reactor 17. As a result, the terminal voltage of direct current can be boosted with the roactor 17.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a variable voltage/variable frequency power supply device used for speed control of a small single-phase induction motor, a computer, etc., and particularly to improvement of the input current waveform and output power waveform. It's about.

[Conventional technology]

Fig. 2 is a circuit diagram showing a conventional power supply device as shown in Japanese Patent Application Laid-Open No. 68-814176.
) are connected in series.

This switching circuit (3) is, for example, a transistor,
Alternatively, it is constituted by a switching element (3t) such as F'ET and a rectifying element (8d) such as a flywheel diode that connects the collector and emitter of the switching element (3t).

(B) is a smoothing circuit connected in parallel to the converter circuit (D). The smoothing circuit (B) consists of two smoothing capacitors (
2) are connected in series to form a field.

(2) is an inverter circuit connected to the smoothing circuit (in the smoothing circuit), which is formed from two series-connected nine switching circuits (3).

This switching circuit (3) includes, for example, a transistor,
The loop is composed of a switching element (8t) such as F'ET, and a rectifying element (8d) such as a flywheel diode connected between the collector and emitter.

One of the single-phase AC voltage power input sections (5) is connected to the intermediate section of the two switching circuits (3) of the converter circuit (D).

19. One of the power output parts (6) is connected to the middle part of the two switching circuits (3) of the inverter circuit.

Then, the other of the power input section (5) and the power output section (6)
The other side is connected by a single connection line.

This connection line is grounded and connected via a switch (4) to the intermediate portion of the two capacitors (2) in the smoothing circuit.

Next, the operation will be explained.

A single-phase AC voltage is inputted from a power input section (5), and one of the power input sections (5) is V-connected to one of the power output sections (6) by a single connection line. This connection line is grounded and held at a predetermined potential.

The other end of the power input section (5) is connected to the middle section of the two switching circuits (3) of the converter circuit (converter circuit) through a connecting line.

Then, the switching element (
8t)? By switching, the current is rectified and flows in one direction. Then, the DC voltage obtained in this way, including nine large ripples, is in the smoothing circuit)
smoothed by This will reduce ripple by a few percent
The following DC voltage is obtained.

This DC voltage is converted into AC power at a predetermined voltage and two frequencies by an inverter circuit (2). For example, the switching in this inverter circuit
Performed by tiIJQ. This PWM control obtains alternating current power of a predetermined voltage and one frequency by modulating and controlling the width of the pulse applied to the base of the switching element (8t).

[Problem to be solved by the invention]

The conventional variable voltage/variable frequency power supply device ili cannot apply the reduced input voltage configured as described above to an external voltage, and therefore cannot obtain an output voltage equivalent to the input voltage, and lacks applicability. I had a lot of problems with Guru.

The present invention aims to solve all of the above problems, and aims to provide a variable voltage/variable frequency power supply device that can obtain an output voltage equivalent to the input voltage.

[Friendly means of solving problems]

In the variable voltage/variable frequency power supply device according to the present invention, input AC power is exchanged into DC power by a full converter circuit, smoothed by a full smoothing circuit, and converted into predetermined AC power by a full inverter circuit. A power supply device, in which the converter circuit is configured by connecting at least two switching circuits consisting of a rectifying element and a switching element in series, the inverter circuit is configured by connecting at least two smoothing circuit capacitors in series, and the inverter circuit is configured by connecting at least two switching circuits consisting of a rectifying element and a switching element in series. It is constructed by connecting at least two switching circuits consisting of elements and switching elements in series, and one of the pair of AC power input sections is connected to the entire converter circuit t through a reactor Iv between the switching circuits that constitute the converter circuit t. One side of the AC power output section is connected between the switching circuits that constitute the inverter circuit, the other side of the AC power input section and the other side of the AC power output section are connected through a common line, and one side is connected to the capacitor of the above smoothing circuit. and the other is connected to the common line.

[For production]

In the variable voltage/variable frequency power supply device according to the present invention, one of the pair of AC power input sections is connected between two switching circuits of the converter circuit.

Thereby, the input AC power is rectified and converted into DC voltage.

This DC voltage is smoothed by a smoothing circuit.

Then, this smoothed -gfl DC voltage is applied to the inverter l
It is converted into a predetermined alternating current voltage by the 1al path.

This conversion is performed by switching control of a switching circuit constituting the inverter circuit W&.

Here, one of the power input portions and one of the power output portions are ILC-connected.

This reduction and the first conversion are performed on this input/output common side, and the circuit has a half-bridge configuration.

Further, one of the pair of AC power input parts is connected to the intermediate part connecting the two switching circuits t-m of the converter circuit via a reactor (react)A/'@, thereby applying a DC terminal voltage to an external voltage.

[Example of invention]

FIG. 1 is a circuit diagram showing one embodiment of the present invention, and FIG.
In ζ, (D) is formed by connecting a converter circuit and a switching circuit '(3) in series.

This switching circuit (3) includes, for example, a transistor,
Switching element (8t) such as 4FET
It is constituted by a rectifying element (8d) such as a FF/I/p diode which is T-connected between the collector and emitter.

(The average is 6 with a smoothing circuit connected in parallel to the converter circuit 0. The smoothing circuit (B) is formed by connecting two smoothing capacitors (2) in series.

(The average is the inverter circuit connected to the smoothing port # & (B), and the two series-connected nine switching circuits'#!? (3)
Vomit formed from vomiting.

This switching circuit (3) is, for example, a transistor,
Alternatively, it is structured by a switching element (8t) such as F' ET and a rectifying element (8d) such as a flywheel diode that connects the collector and emitter.

One of the single-phase AC voltage power inputs 5 (5) is connected to two switching circuits of the converter circuit (Di) if! (
It is connected to the middle part of 3) via reactor/L' (b).

17t, one of the power output parts (6) is an inverter circuit (
It is connected to the middle part of the two switching circuits (3).

And power input f! 6(5) and the power output section (
6) is connected by a single connection line.

This connection line is grounded and connected via a switch (4) to the intermediate portion of the two capacitors (2) of the smoothing circuit (B).

Next, the operation will be explained.

A single-phase alternating current voltage is input from the power input section (5), and one of the electric power sources 11s (5) is connected to one of the electric power outputs 5 (6) by a single connection line. This connecting wire is grounded and held at a predetermined potential.

The other end of the power input section (5) is connected to an intermediate section between the two switching circuits (3) of the converter circuit 0 via a reactor ραη by a connecting line.

Then, the switching element (
8t) By performing t-switching, the current flows in one direction while being rectified. Then, the DC voltage including the large rip μ obtained in this way is processed by the smoothing circuit (
B). As a result, a DC voltage with a rip μ of several percent or less can be obtained.

This DC power EE is converted into AC power at a predetermined voltage and 9 frequencies by an inverter circuit (2). The switching in this inverter circuit (■) is performed using, for example, the following PWM
This is done by lljll. This PWM system a obtains alternating current power at a predetermined voltage and two frequencies by modulating and controlling the width of a pulse applied to the base of a switching element (3).

The circuit described above has an identical configuration both from the input side and from the output side. 1 box, switching elements (8
Since t) has a bidirectional effect on current, it can be applied to both inverters and converters. Therefore, the power supply (8) is connected to the input side.
When the negative IF (9) side is connected to the output side with a t-connection, power regeneration that sends power from the load (9) side to the power source (8) side becomes possible.

Also, by using the reactor ραη and the switching circuit (3) of the converter circuit (D), the DC terminal voltage can be converted to an external voltage using the principle of an external pressure chipper, which is a known technique, and by boosting the DC voltage to the required DC voltage, the input voltage can be increased. It is possible to obtain an output voltage equal to or higher than the voltage.

Furthermore, the switch (4) on the circuit configuration marked is ON when converting DC voltage to AC voltage in the normal converter circuit Φ) and inverter circuit (E, and as a special case, the switch (4) in the converter circuit ρ) ), inverter circuit (
E) When the t-control is not performed or when the switching element (8t) of the switching circuit (3) is broken, the switch (4) is turned t-OFF.

In the above embodiment, a Paibov type transistor is used as a transistor with a flywheel diode, but a MO8FET type transistor may be used, or an element capable of the same operation may be used instead of these transistors.

〔Effect of the invention〕

As described above, according to the variable voltage/variable frequency power supply device of the present invention, since the switching circuits constituting the converter circuit are connected via the reactor, the external voltage can be made to be the same as the input voltage by the reactor. Not only can an output voltage be obtained, but also an output voltage that is equal to or higher than the input voltage can be obtained by applying an external voltage to a necessary DC voltage.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing a variable voltage/variable frequency power supply device according to an embodiment of the present invention, and FIG. 2 is a circuit diagram showing a conventional variable voltage/variable frequency power supply device.
FIG. 2 is a circuit diagram showing a variable frequency power supply device mt. In the figure, (2) is a capacitor, (3) is a switching circuit, (3t) is a switching element, (3d) is a rectifier, αη beam axle, φ) is a smoothing circuit, (D) is a converter circuit, and ■ is an inverter. It is a circuit. In addition, the same reference numerals in the figures indicate the same parts, and the boxes indicate corresponding parts.

Claims (1)

[Scope of Claims] A power supply device that receives AC power and has a converter circuit that converts it into DC power, a smoothing circuit that smoothes this DC power, and an inverter circuit that converts this DC power into predetermined AC power. In the above, the converter circuit is configured by connecting at least two switching circuits including a rectifying element and a switching element in series, the smoothing circuit is configured by connecting at least two capacitors in series, and the inverter circuit is configured by connecting at least two capacitors in series. , configured by connecting at least two switching circuits consisting of a rectifying element and a switching element in series, one of the AC power input sections is connected via a reactor between the switching circuits forming the converter circuit, One of the output parts is connected between the switching circuits forming the inverter circuit, the other of the AC power input part and the other of the AC power output part are connected by a common line, and one of the parts is connected between the capacitors of the smoothing circuit. A variable voltage/variable frequency power supply device characterized in that the other side is connected to the common line.