JP2521345B2 - Constant voltage / constant frequency power supply - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a constant voltage / constant frequency power supply device used for speed control of a small-sized single-phase induction motor, a computer, and the like, and more particularly to a constant voltage power supply device used as an uninterruptible power supply device. The present invention relates to a voltage / constant frequency power supply device.

[Prior Art] An example of a conventional power supply device will be described with reference to FIG.

The figure is proposed by the present applicant in Japanese Patent Application No. 62-148666. In this figure, (A) is a converter circuit, which is formed by connecting diodes (1) in series.

(B) is a smoothing circuit connected in parallel to the converter circuit (A), and is formed by two capacitors connected in series.

(C) is an inverter circuit connected to the smoothing circuit (B), and is composed of two switching elements (3) connected in series.

This switching element (3) is a transistor (3t)
And a flywheel diode (3d) connecting between its collector and emitter.

One of the single-phase AC voltage power input units (5)
It is connected to the middle part of the two diodes (1) of the converter circuit (A).

Further, one of the power output parts (6) is connected to the intermediate part of the two switching elements (3) of the inverter circuit (C).

The other of the power input unit (5) and the power output unit (6)
Are connected by one connection line. This connection line is grounded and through a switch (4),
It is connected to an intermediate portion between two capacitors (2) of the smoothing circuit (B).

 Next, the operation will be described.

The single-phase AC voltage is input from the power input section (5),
One side of the power input section (5) is connected to one side of the power fishing section (6) by one connecting wire. Since this connecting wire is grounded, it is held at a predetermined potential.

The other side of the power input section (5) is connected by a connecting line to the middle section of the two diodes (1) of the converter circuit (A).

Since the diodes (1) are connected in series in the same direction, current flows only upward in the figure and is rectified. The DC voltage including the large ripple component obtained in this manner is supplied to the smoothing circuit (B).
Is smoothed. This gives a few percent ripple
The following DC voltage is obtained.

This DC voltage is converted into AC power of a predetermined voltage and frequency by the inverter circuit (C). Switching in the inverter circuit (C) is performed by, for example, the following PWM control. This PWM control obtains AC power of a predetermined voltage and frequency by modulating and controlling the width of a pulse applied to the base of the transistor (3t).

The upper shaded portion in FIG. 6 shows the conduction state of the upper switching element (3) in FIG. 5, and the lower shaded portion in FIG. 6 is the lower switching element in FIG. The conduction state of (3) is shown. By such switching control, the output power having the waveform as shown by the curve (7) in FIG. 6 is obtained.

Here, the DC voltage V _PN output from the smoothing circuit (B)
Is 2 Ed from Ed to −Ed. Then, when the switch (4) is turned on, the potential at the intermediate point of the smoothing circuit (B) becomes 0 V, which is just between Ed and -Ed. The switch (4) is turned off when the power input section (5) is directly connected to the power source and the power output section (6) is directly connected to a load such as a motor.

[Problems to be Solved by the Invention] Since the conventional constant-voltage / constant-frequency power supply device is configured as described above, for example, when the voltage waveform (A) shown in FIG. Flows as shown in FIG. 7 (b). Also, the voltage waveform (B) shown in FIG. 7 (a)
In the range of, the current flows as shown in FIG. 7 (c). When used as an uninterruptible power supply, it is used by switching to a commercial AC power supply, so it is desirable that the output voltage be approximately the same as the AC input voltage when switching, but as shown in Fig. 5, the input voltage is AC100V. Between PN DC voltage will be applied. Therefore, the PN voltage between PN is
It becomes 282.8V. When the DC voltage 282.8V is converted into AC by PWM inverter control, the output voltage becomes 87.8V, for example. As mentioned above, in order to obtain the output voltage of 100V, 28
DC voltage between PN of 2.8 × 100 / 87.8 = 322.1V or more is required.

If you want to obtain output voltage (6) of 200V or more, PN voltage is 640V
This is necessary. When it is desired to obtain the output voltage (6) of about 100V, there is no particular problem, but when it is desired to obtain 200V or more, the element to be used needs to have a withstand voltage twice or more that of the 100V class. For this reason, the element used is a component for high withstand voltage of, for example, 1000 V or more, which is expensive. Further, since the circuit configuration has a high voltage, it is necessary to consider the insulation distance between the parts, which causes a problem that the entire circuit configuration becomes large and the device itself becomes large.

The present invention has been made in order to solve the above problems. A first object of the present invention is to provide a constant voltage / voltage regulator that does not require the use of special parts for high breakdown voltage even if the output voltage is 200V class. A constant frequency power supply device is obtained. A second object is to obtain a constant voltage / constant frequency power supply device capable of obtaining an output voltage equal to or higher than the input voltage.

[Means for Solving the Problems] In the constant-voltage / constant-frequency power supply device according to the present invention, an even number of rectifying elements that form a converter circuit are connected in series to one connecting portion of a pair of AC power input portions. Connected to the intermediate point, one of the pair of AC power output section is connected to the intermediate point where an even number of switching circuits forming the first phase of the inverter circuit section are connected in series, and a pair of AC power is connected. The other connecting part of the input part and the other connecting part of the pair of AC power output parts are connected by a common line, and the common line is connected in series with an even number of switching circuits forming the second phase of the inverter circuit part. It is connected to the middle point.

Further, in the constant voltage / constant frequency power supply according to the present invention, one connecting part of a pair of AC power input parts is connected via a reactor to an intermediate point where an even number of switching circuits forming a converter circuit are connected in series. Then, one connecting portion of the pair of alternating-current power output portions is connected to an intermediate point where an even number of switching circuits constituting the first phase of the inverter circuit portion are connected in series, and the other connecting portion of the pair of alternating-current power input portions is connected. Is connected to the other connecting portion of the pair of AC power output portions by a common line, and the common line is connected in series with an even number of switching circuits forming the second phase of the inverter circuit portion. It is connected to a point.

[Operation] In the constant voltage / constant frequency power supply device according to the present invention, the arm of the bridge of the second phase of the inverter circuit unit is turned on / off at each zero point of the input voltage of the AC power input to the converter circuit. , The voltage of the same phase as the predetermined input voltage by the first phase arm of the inverter circuit unit,
Since the switching control for converting into the AC power of the frequency is performed, the switching element of the second phase of the inverter circuit unit can use the switching element of the commercial frequency instead of the high speed switching element.

Also, in the constant voltage / constant frequency power supply device according to the present invention, the arm of the bridge of the second phase of the inverter circuit unit is turned on / off at each zero point of the input voltage of the AC power input to the converter circuit, Since the switching element of the converter circuit is controlled to be turned on / off at a frequency higher than the frequency of the AC power, the DC voltage can be boosted.

[Embodiment of the Invention] A constant voltage / constant frequency power supply device according to a first embodiment of the present invention will be described with reference to FIG.

In the figure, (A) is a converter circuit, which is formed by connecting rectifying elements such as a diode (1) in series.

(B) is a smoothing circuit connected in parallel to the converter circuit (A). The smoothing circuit (B) is formed by one smoothing capacitor (2). (C) is an inverter circuit, which is connected to the smoothing circuit (B) and serves as a first phase bridge of the inverter circuit section, and is composed of two switching circuits (3) connected in series.

The switching circuit (3) is composed of, for example, a switching element (3t) such as a transistor or an FET and a rectifying element (3d) such as a flywheel diode connecting the collector and the emitter.

(D) is a changeover switch unit as a bridge of the second phase of the inverter circuit unit connected to the smoothing circuit (B), and is a switching device including a switching element (4) such as a transistor and a rectifying element (5) such as a diode. Circuit (6)
Are connected in series.

And, one side of the power input section (7) of the single-phase AC voltage is
It is connected to the two diodes (1) and the intermediate part of the converter circuit (A).

Further, one of the power output parts (8) is connected to the intermediate part of the two switching circuits (3) of the inverter circuit (C).

And the other of the power input section (7) and the power output section (8)
The other of is connected by a single connecting wire (9).
The connection line (9) serving as the common line is grounded and connected to the intermediate portion of the switching circuit (6) of the changeover switch unit (D).

 Next, the operation of the first embodiment will be described.

The single-phase AC voltage is input from the power input section (7),
One side of this power input section (7) is connected to one side of the voltage output section (8) by a connecting wire (9). And
Since this connecting wire (9) is grounded, it is held at a predetermined potential.

The other side of the power input (7) is connected by a connecting line to the middle of the two diodes (1) of the converter circuit (A).

Since the diodes (1) are connected in series in the same direction, current flows only upward in the figure and is rectified. The DC voltage including the large ripple component obtained in this manner is supplied to the smoothing circuit (B).
Is smoothed. This gives a few percent ripple
The following DC voltage is obtained.

The input voltage e ₀ shown in FIG. 2 is an AC input voltage applied to the input 7 in FIG. When the input voltage e ₀ is positive, the switching element 4b on the lower arm of the switching circuit (6) of the changeover switch unit (D) is turned on, and the inverter circuit (3) is turned to PW.
The positive half cycle of the output voltage (10) is controlled by switching by M control.

When the input voltage e ₀ is negative, the switching element 4a of the upper arm of the switching circuit (6) of the changeover switch section (D) is
Turning on, the switching circuit (3) of the inverter circuit (C)
Is controlled by PWM control to control the negative half cycle of the output pressure (10). Therefore, the changeover switch unit (D) alternately turns on and off the switching element 4a of the upper arm and the switching element 4b of the lower arm of the switching circuit (6) at the timing of the zero cross of the input voltage e ₀ . The switching circuit (3) of the inverter circuit (C) is controlled in synchronization with the AC input voltage of the converter circuit (A).

The DC voltage is converted into AC power having a predetermined voltage and frequency by the inverter circuit (C). Switching in the inverter circuit (C) is performed by, for example, the following PWM control. In this PWM control, AC power of a predetermined voltage and frequency is obtained by modulating and controlling the width of the pulse applied to the base of the switching element (3t) of the inverter (C).

In the range of the voltage waveform (A) shown in FIG. 3 (a), the current flows as shown in FIG. 3 (b). Further, in the range of the voltage waveform (B) shown in FIG. 3 (a), the current flows as shown in FIG. 3 (d). Therefore, if the input voltage is
When AC200V, between PN shown in Fig. 1 DC voltage will be applied. This DC voltage In the range of the voltage waveform (A) shown in FIG. 3 (a), the voltage waveforms shown in FIG. 3 (c) and FIG. 3 (a) In the range of B), the current flow is as shown in FIG. 3 (e). And the output voltage is almost 175V.

However, as a condition, the waveforms of the input voltage e ₀ and the output voltage v (10) may be different, but they are in phase (the zero points of the voltage are the same).
Must.

The shaded portion on the positive side in FIG. 2 indicates that the switching element (4b) of the changeover switch section (D) in FIG.
a) shows a switching state, and the shaded portion on the negative side in FIG. 2 indicates that the switching element (4a) of the changeover switch section (D) in FIG. The switching element (3b) is switching. By such switching control, an output voltage having a waveform as shown by the curve (10) in FIG. 2 is obtained by passing through a filter circuit (not shown).

With the above configuration, the DC voltage V _PN output from the smoothing circuit (B) becomes Ed.

In this circuit, one of the input unit and the output unit is connected by one connection line. Therefore, there is no voltage change here, and it is possible to prevent the output from being affected by noise. Further, since this connection line is grounded, a step-like change in the potential between the input and output does not appear, and the generation of noise is reliably prevented.

In addition, by the PWM control as described above, as shown in FIG.
Then, the same sinusoidal voltage fundamental wave can be generated, and a sinusoidal constant voltage / constant frequency output voltage can be obtained through a filter (not shown). Further, the output voltage can be changed according to the control command value.

Next, a constant voltage / constant frequency power supply device according to a second embodiment of the present invention will be described with reference to FIG.

In this embodiment, a converter circuit (F) is used instead of the converter circuit (A) shown in FIG.

This converter circuit (F) is, for example, a transistor,
Alternatively, a switching circuit (11) consisting of a switching element (3t) such as FET and a rectifying element (3c) such as diode.
Are connected in series.

And, one side of the power input section (7) of the single-phase AC voltage is
Two switching circuits of converter circuit (F) (11)
Is connected to the middle part of the via a reactor (14).

The configuration other than the above is the same as that of the above-described first embodiment of the invention.

The second embodiment of the present invention is configured as described above, and therefore the circuit in this example has the same configuration when viewed from both the input side and the output side. Also, since the switching element is bidirectional with respect to the current, it can be both an inverter and a converter. Therefore, when the power source (12) is connected to the input side and the load (13) side is connected to the output side, it is possible to regenerate electric power by sending power from the load (13) side to the power source (12) side.

The reactor (14), the switching circuit (11) of the converter circuit (F), and the capacitor (B) convert an AC input voltage into a DC voltage, and the switching circuit (11) is PWM-controlled to generate a capacitor ( The voltage at both ends of B) can be boosted to the peak value of the AC input voltage or more, and the same output voltage as the input voltage could not be obtained in the embodiment of the first invention, but the required DC voltage was obtained. By boosting the voltage, an output voltage equal to or higher than the voltage can be obtained.

The converter circuit (F) turns on and off the switching circuit (11) at a switching frequency about 10 times the fundamental frequency of the AC input voltage.

When the AC input voltage is positive, the switching element (4b) of the lower arm of the changeover switch unit (D) is ON, the switching element (4a) of the upper arm is OFF, and the switching circuit (11) of the converter circuit (F) is Looking at one ON / OFF,
Switching element of the lower arm of the switching circuit (11)
When 3t is ON (At this time, the switching element 3t of the upper arm is
OFF), reactor 14 → converter circuit (F) switching circuit (11) lower arm switching element 3t → changeover switch section (D) lower arm diode 5 → AC input power supply circuit Time energy is accumulated in the reactor 14.

Next, when the switching element 3t of the lower arm of the switching circuit (11) is OFF (at this time, the switching element 3t of the upper arm is ON), the reactor 14 → the upper arm of the switching circuit (11) of the converter circuit (F). Diode 3c → capacitor 2 →
The energy stored in the reactor 14 moves to the capacitor 2 and is charged in the path of the diode 5 of the lower arm of the changeover switch unit (D) → the AC input power source.

When the AC input voltage is negative, the changeover switch (D)
The upper arm (4a) is ON, the lower arm (4b) is OFF, and the switching circuit (11) of the converter circuit (F) is turned ON once.
Looking at N and OFF, when the switching element 3t in the upper arm is ON (at this time, the switching element 3t in the lower arm is OFF), AC input power → diode 5 in the upper arm of the changeover switch (D) → converter circuit (F) switching circuit (11) upper arm switching element 3t → reactor 14
A short-circuit current flows through the path of, and at this time, energy is stored in the reactor 14.

Next, when the switching element 3T of the upper arm of the switching circuit (11) is OFF (at this time, the switching element 3t of the lower arm is ON), the AC input power supply → the diode 5 of the upper arm of the changeover switch unit (D) → The energy stored in the reactor 14 along the path of the capacitor 2 → the lower arm diode 3c of the switching circuit (11) of the converter circuit (F) → the reactor 14 moves to the capacitor 2 and is charged.

As described above, by turning ON / OFF the switching element 3t of the switching circuit (11) of the converter circuit (F), the AC input voltage is boosted, and the voltage across the capacitor 2 is fed back to the control circuit (not shown). , The voltage across the capacitor 2 can be kept constant.

According to the first and second embodiments described above, the DC voltage can be doubled with the voltage value of the conventional circuit (in the case of the single-phase half bridge only). That is, the element withstand voltage of one element is equivalent to that of the conventional circuit, and a double output voltage can be obtained.

Also, a converter circuit (F) and an inverter circuit (C)
Shut off all switching elements, and turn ON / O the switching elements of the changeover switch (D) according to the positive or negative of the input voltage.
By setting it to FF, the input section can be directly connected to the output section. That is, the input power can be output as it is without conversion.

In the above embodiments, the bipolar type transistor is shown as the transistor with the flywheel diode, but it may be a MOSFET type transistor, or may be an element which can be operated in the same manner in place of these.

In the above embodiment, the inverter circuit (C)
Although the PWM (pulse width modulation) control is shown as the switching control for converting into the AC power of a predetermined voltage and frequency in the above, the same effect can be obtained by the PAM (pulse amplitude modulation) control.

Furthermore, since the switching element of the changeover switch unit (D) may be a commercial frequency switching element, it is not necessary to use a high-speed switching element.

[Effects of the Invention] As described above, according to the present invention, the arm of the bridge of the second phase of the inverter circuit unit is turned on and off for each zero point of the input voltage of the AC power input to the converter circuit, and Since the first phase arm of the inverter circuit unit performs the switching control for converting the predetermined input voltage into the in-phase voltage and frequency AC power,
The second phase switching element of the inverter circuit section can use a commercial frequency switching element instead of a high speed switching element, and must use a high breakdown voltage element while maintaining the feature of the half bridge circuit that suppresses switching loss. For example, an output voltage of 200V class can be obtained with a 100V class element, and a high withstand voltage insulation distance is not required, so that the device itself is compact.

Further, the arm of the bridge of the second phase of the inverter circuit unit is turned on / off for each zero point of the input voltage of the AC power input to the converter circuit, and the switching element of the converter circuit is operated at a frequency higher than the frequency of the AC power. Since the ON / OFF control is performed, the DC voltage can be boosted and an output voltage equal to or higher than the input voltage can be obtained.

Therefore, the device itself can be made compact and inexpensive, and a highly reliable constant voltage / constant frequency power supply device having excellent safety can be obtained.

[Brief description of drawings]

1 is a circuit diagram showing a basic circuit of a constant voltage / constant frequency power supply device according to an embodiment of the present invention, FIG. 2 is a waveform diagram showing an output waveform of an embodiment of the present invention, and FIG. FIG. 1 is a state explanatory view showing the states of voltage and current, FIG. 4 is a basic circuit diagram showing another embodiment of the present invention, and FIG. 5 is a conventional constant voltage
FIG. 6 is a circuit diagram showing a basic circuit of a constant frequency power supply device, FIG. 6 is a waveform diagram showing an output waveform of a conventional device, and FIG. 7 is a state explanatory diagram showing the voltage and current states of FIG. In the figure, (A) and (F) are converter circuits, (B) is a smoothing circuit, (C) is an inverter circuit, (D) is a changeover switch section (1) is a diode (rectifying element), and (2) is a smoothing capacitor. (3) (11) is a switching circuit, (3t)
(4) is a switching element, (3d) is a rectifying element, (5)
Is a switching element, (6) is a switching circuit,
(7) is a power input unit, (8) is a power output unit, (9) is a connection line (common line), and (14) is a reactor. The same reference numerals in the drawings indicate the same or corresponding parts.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazuhiko Tanaka 5-1-14 Yada Minami, Higashi-ku, Nagoya, Aichi Mitsubishi Electric Corporation Nagoya Works (72) Inventor Akinori Nishihiro 5 Yata-Minami, Higashi-ku, Nagoya, Aichi 1-14 No. Mitsubishi Electric Co., Ltd. Nagoya Works (56) References JP 63-314176 (JP, A) JP 62-233069 (JP, A)

Claims (2)

(57) [Claims] 1. A converter circuit configured by connecting an even number of rectifying elements in series to convert input AC power to DC power, a smoothing capacitor for smoothing this DC power, and a rectifying element reverse to a switching element. A constant voltage / constant frequency having an inverter circuit section that has two-phase bridges that connect even number of switching circuits connected in parallel in series and that converts the DC power smoothed by the smoothing capacitor into a predetermined AC power. In the power supply device, one connecting portion of the pair of alternating current power input portions is connected to an intermediate point where an even number of rectifying elements forming the converter circuit are connected in series, and one connecting portion of the pair of alternating current power output portions is connected. Is connected to an intermediate point where an even number of switching circuits forming the first phase of the inverter circuit section are connected in series, and the pair of AC power input sections is connected. And the other connecting portion of the pair of alternating-current power output portions is connected by a common line, and the common line is connected in series with an even number of switching circuits forming the second phase of the inverter circuit portion. Connected to an intermediate point of the inverter circuit section, the arm of the bridge of the second phase of the inverter circuit section is turned on and off for each zero point of the input voltage of the AC power input to the converter circuit, and A constant-voltage / constant-frequency power supply device characterized by performing switching control for converting a predetermined input voltage into a voltage having the same phase and AC power having a frequency by the arm of the first phase. 2. A converter circuit configured by connecting an even number of switching circuits in which rectifying elements are connected in anti-parallel to switching elements in series and converting input AC power into DC power, and this DC power. It has a smoothing capacitor that smoothes and a bridge that connects an even number of switching circuits in which rectifying elements are connected in anti-parallel to switching elements in series, and converts the DC power smoothed by the smoothing capacitor into a predetermined AC power. In the constant voltage / constant frequency power supply device having an inverter circuit section, a connecting portion of one of the pair of AC power input sections is connected to an intermediate point where an even number of switching circuits forming the converter circuit are connected in series. And connecting one of the pair of AC power output units to form a first phase of the inverter circuit unit. The switching circuits are connected to an intermediate point where they are connected in series, and the other connecting portion of the pair of alternating-current power input portions and the other connecting portion of the pair of alternating-current power output portions are connected by a common line and the common connection. The line is connected to an intermediate point where an even number of switching circuits forming the second phase of the inverter circuit section are connected in series, and the arm of the bridge of the second phase of the inverter circuit section is input to the converter circuit. A constant voltage / constant frequency power supply device characterized by performing ON / OFF control for each zero point of the input voltage of the AC power to be controlled, and ON / OFF control of the switching element of the converter circuit at a frequency higher than the frequency of the AC power. .