JPH11262240A - Power conversion apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To control a load on the power switch and moreover reduce snubber loss, even when a heavier current is cut off. SOLUTION: In a power conversion apparatus for converting a DC power into an AC power by respectively forming a positive arm and a negative arm through connecting in parallel a snubber circuit which consists of at least subber capacitors 6A, 6B and snubber diodes 7A, 7B, connected in series to the power switches 3A, 3B which are connected to the DC power supply 1, a change-over means 20 for connecting in parallel the discharge switches 9A, 9B connecting in series the snubber resistors 8a, 8B to the snubber diodes 7A, 7B and then changing over the discharge switches 9A, 9B to the conductive condition or non-conductive condition is also provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power converter for converting a DC power into an AC power, in which a power switch is provided with a snubber circuit, a positive arm and a negative arm are respectively formed, and more particularly to a snubber circuit. The present invention relates to a power conversion device capable of switching between the power converters.

[0002]

2. Description of the Related Art Conventionally, power converters for converting DC power into AC power have been widely used, for example, in uninterruptible power supplies, industrial drive devices, and the like. When the power switch in the power converter performs switching, a surge voltage or the like is generated by the energy of the stray inductance of the circuit. This surge voltage increases the load on the power switch.

For this reason, usually, a snubber circuit for processing the energy of the stray inductance is provided around the power switch, and the positive side arm and the negative side arm are often configured.

FIG. 10 is a circuit diagram showing a configuration example of a main part of a conventional power conversion device (inverter device) using a charge / discharge type snubber circuit. In FIG. 10, a DC power supply 1 includes a flywheel diode (hereinafter, referred to as FWD) 4.
A, 4B power switches 3A, 3B connected in parallel
Are connected in series via the anode reactors 5A and 5B, and the DC power from the DC power supply 1 is converted into AC power and supplied to the load 2 such as an electric motor.

For the power switches 3A and 3B, snubber capacitors 6A and 6B and snubber resistors 8A and
A positive-side arm and a negative-side arm are respectively formed by connecting in parallel a charge / discharge-type snubber circuit formed by connecting in series snubber diodes 7A and 7B with 8B connected in parallel.

In FIG. 10, power switches 3A,
Although 3B is expressed by using the symbol of IGBT, the same applies to a case where this is replaced with another power switch such as GTO, GCT, IEGT, or FET.

[0007] Such a power converter operates as follows. That is, when the power switch 3A is turned off in a state where a current is flowing from the DC power supply 1 to the load 2 via the anode reactor 5A and the power switch 3A, the energy of the anode reactor 5A is changed to the snubber capacitor 6A. Is absorbed by

At this time, the voltage between the terminals of the power switch 3A is suppressed by the voltage between the terminals of the snubber capacitor 6A.
Stand up soft. The energy stored in the snubber capacitor 6A is discharged to 0 via the snubber resistor 8A when the power switch 3A is conducting.

The anode reactors 5A and 5B are not required in the mode in which the current is flowing through the power switch 3A and are turned off, but the power switch 3B is turned on while the current is flowing through the FWD 4A. Sometimes needed.

In other words, when the anode reactors 5A and 5B are not present, the FWD 4A is conducting (at this time, the voltage between the terminals of the snubber capacitor 6A is discharged to 0).
When the power switch 3B is turned on, the DC power supply 1, the power switch 3B, the snubber diode 7A,
An extremely large short-circuit current flows in the closed circuit of the snubber capacitor 6A. In this case, if the anode reactors 5A and 5B are present, the short-circuit current does not flow.

FIG. 11 is a circuit diagram showing a configuration example of a main part of a conventional power conversion device (inverter device) using a clamp type snubber circuit. The same elements as those in FIG. Are omitted, and only different portions will be described here.

In FIG. 11, power switches 3A, 3
B, snubber capacitors 6A and 6B, snubber diodes 7A and 7B, and snubber resistors 8A and 8B are connected as shown in the figure to form a clamp-type snubber circuit for power switches 3A and 3B.

[0013] Such a power converter operates as follows. That is, when the power switch 3A is turned off in a state where a current is flowing from the DC power supply 1 to the load 2 via the anode reactor 5A and the power switch 3A, the energy of the anode reactor 5A is used by the energy of the anode reactor 5A. The voltage between the terminals of the switch 3A increases.

When the voltage between the terminals of the power switch 3A exceeds the voltage between the terminals of the snubber capacitor 6A, the snubber diode 7A becomes conductive, and the energy of the anode reactor 5A is absorbed by the snubber capacitor 6A. You.

At this time, the voltage between terminals of power switch 3 # is suppressed by the voltage between terminals of snubber capacitor 6A.
The energy stored in the snubber capacitor 6A is discharged to the inter-terminal voltage of the DC power supply 1 via the snubber resistor 8A.

The load of the power switch is greater in the clamp type snubber circuit than in the charge / discharge type snubber. On the other hand, unlike the charge / discharge type snubber circuit, there is no mode in which the short-circuit current flows even if the anode reactors 5A and 5B are omitted. Therefore, the anode reactor 5A,
5B can be omitted or the capacity can be set very small. Further, snubber capacitors 6A, 6A
Since B is not discharged to 0, energy consumed by the snubber circuit is small.

[0017]

As described above, the charge / discharge type snubber circuit has the advantage that the load on the power switches 3A and 3B can be reduced, but has the problem that the snubber loss is large. .

Further, in order to prevent a short circuit current, the anode reactors 5A and 5B having a large capacity are required, and there is a problem that the apparatus becomes large and expensive. On the other hand, the clamp-type snubber circuit can reduce the snubber loss, and the anode reactors 5A, 5B
Can be omitted, but there is a problem that the load on the power switches 3A and 3B is heavy.

An object of the present invention is to provide a power conversion device provided with a snubber circuit capable of suppressing a load on a power switch even when a large current is interrupted and reducing a snubber loss. .

Another object of the present invention is to provide a snubber circuit capable of reducing the load on the power switch even when a large current is interrupted and reducing the capacity, size and cost of the device. To provide a power conversion device.

[0021]

In order to achieve the above object, according to the present invention, at least a snubber capacitor and a snubber diode are connected in series to a power switch connected to a DC power supply. The snubber circuit is connected in parallel, the positive side arm and the negative side arm are respectively configured, and in a power converter that converts DC power to AC power, a snubber resistor is connected in series to a snubber diode. Discharge switches are connected in parallel, and switching means is provided for switching the discharge switches to a conducting state or a blocking state based on predetermined switching conditions.

Therefore, in the power converter according to the first aspect of the present invention, the charge / discharge type snubber circuit is switched by switching the discharge switch to the conductive state or the blocking state based on the predetermined switching condition. And a clamp type snubber circuit.

That is, even during the operation of the power conversion device, it is possible to switch between a charge / discharge type snubber circuit with a small load on the power switch and a clamp type snubber circuit with a small snubber loss, thereby reducing the discharge voltage of the snubber capacitor. It can be adjusted.

Thus, the load on the power switch can be reduced even when a large current is interrupted, and the snubber loss can be reduced. In the invention according to claim 2, a snubber circuit formed by connecting at least a snubber capacitor and a snubber diode in series is connected in parallel to the power switch connected to the DC power supply, so that the positive side arm and the negative side are connected. Side arms are each configured and at least 3
In a power converter that outputs a potential equal to or higher than a level, a discharge switch in which a snubber resistor is connected in series is connected in parallel to a snubber diode, and based on predetermined switching conditions, the discharge switch is turned on or off. And switching means for switching to.

Therefore, in the power converter according to the second aspect of the present invention, the state of the discharge switch is switched in the multi-level power converter by switching the discharge switch to the conducting state or the blocking state based on a predetermined switching condition. Accordingly, it is possible to switch between the charge / discharge type snubber circuit and the clamp type snubber circuit, and it becomes possible to adjust the discharge voltage of the snubber capacitor.

On the other hand, in the third aspect of the present invention,
Alternatively, in the power converter according to the second aspect of the present invention, based on the output current detected by the current detector and the output current detected by the current detector, the output current is positive if the output current is positive. When the output current is negative, the discharge switch of the positive arm is turned off and the discharge switch of the negative arm is turned off. A switching condition determining means for providing a switching condition for setting the conductive state as a switching condition of the switching means is added.

Therefore, in the power converter according to the third aspect of the present invention, when the output current of the power converter main body is positive, the discharge switch of the positive arm is made conductive and the discharge switch of the negative arm is turned on. In the blocking state, and when the output current is negative, the discharging switch of the positive arm is set to the blocking state and the discharging switch of the negative arm is set to the conducting state. When the other power switch is turned on from the FWD conduction to the mold snubber circuit, it can be switched to the clamp type snubber circuit.

As a result, it is possible to omit the anode reactor or set the capacity to be small. According to a fourth aspect of the present invention, in the power conversion device according to the first or second aspect of the invention, a current detecting means for detecting an output current of the power conversion device main body, and an output current detected by the current detection means. When the absolute value of the output current is larger than the reference current value and positive, the discharge switch of the positive arm is turned on, and when the absolute value of the output current is larger than the reference current value and negative. A switching condition for setting the discharge switch of the negative arm to a conducting state, and otherwise setting the discharge switch of the positive arm and the negative arm to a blocking state as a switching condition of the switching means. Judgment means is added.

Therefore, in the power conversion device according to the fourth aspect of the invention, when the absolute value of the output current of the power conversion device main body is larger than the reference current value and is positive, the discharge switch of the positive arm is turned on. When the absolute value of the output current is larger than the reference current value and is negative, the discharge switch of the negative arm is turned on.
By setting the discharge switches of the positive arm and the negative arm to the blocking state, when the power switch turns off the reference current or more, it becomes a charge / discharge type snubber circuit, otherwise it can be switched to a clamp type snubber circuit. .

Thus, the load on the power switch can be reduced, and the period of the charge / discharge type snubber circuit is shorter than in the case of the third aspect of the present invention, so that the snubber loss can be further reduced. it can.

On the other hand, in the invention according to claim 5, a snubber circuit comprising at least a snubber capacitor and a thyristor having a snubber resistor connected in parallel is connected in series to the power switch connected to the DC power supply. Connect in parallel,
A power conversion device that includes a positive arm and a negative arm and that converts DC power into AC power includes a switching unit that switches a thyristor to a conductive state or a blocking state based on a predetermined switching condition.

Therefore, in the power converter according to the fifth aspect of the present invention, the thyristor is switched to the conducting state or the blocking state based on a predetermined switching condition, so that the charge / discharge type snubber circuit and the RC are controlled by the conducting state of the thyristor. It can be switched to a snubber circuit.

That is, even during the operation of the power converter, it is possible to switch between a charge / discharge type snubber circuit with a small load on the power switch and an RC snubber circuit without a short-circuit mode at turn-on. It is possible to adjust the discharge voltage.

Thus, the load on the power switch can be reduced even when the large current is interrupted, and the short-circuit mode does not occur even when the power is turned on. Therefore, the anode reactor can be omitted or the capacity can be reduced. In addition, the capacity, size, and cost of the device can be reduced.

According to the sixth aspect of the present invention, the fifth aspect of the present invention is provided.
In the power conversion device according to the invention, a current detection means for detecting an output current of the power conversion device main body, and a thyristor of a positive arm based on the output current detected by the current detection means when the output current is positive. Switching conditions such that the thyristor of the negative arm is turned off and the thyristor of the negative arm is turned off, and when the output current is negative, the thyristor of the positive arm is turned off and the thyristor of the negative arm is turned on. And a switching condition determining means for providing the switching condition as a switching condition of the switching means.

Therefore, in the power converter according to the sixth aspect of the present invention, when the output current of the power converter main body is positive, the thyristor of the positive arm is turned on and the thyristor of the negative arm is turned off. When the output current is negative, the thyristor of the positive arm is set to the blocking state and the thyristor of the negative arm is set to the conductive state, so that when the power switch is turned off, the charge / discharge type snubber circuit is used. When the other power switch is turned on after the FWD is turned on, it can be switched to the RC snubber circuit.

As a result, it is possible to reduce the capacity, size and cost of the apparatus by omitting the anode reactor or setting the capacity to be small. According to a seventh aspect of the present invention, in the power conversion device according to the fifth aspect of the present invention, the power conversion device includes: a current detection unit configured to detect an output current of the power conversion device main unit; When the absolute value of the output current is larger than the reference current value and is positive, the thyristor of the positive arm is made conductive, and when the absolute value of the output current is larger than the reference current value and negative, the negative arm And a switching condition determining means for providing a switching condition for setting the thyristors of the positive arm and the negative arm to a blocking state in other cases as a switching condition of the switching means.

Therefore, in the power converter of the present invention, when the absolute value of the output current of the power converter main body is larger than the reference current value and is positive, the thyristor of the positive arm is made conductive. When the absolute value of the output current is larger than the reference current value and is negative, the thyristor of the negative arm is made conductive, otherwise, the thyristors of the positive arm and the negative arm are blocked. When the power switch turns off the reference current or more, it becomes a charge / discharge type snubber circuit.
It can be switched to a C-type snubber circuit.

Thus, the load on the power switch can be reduced, and the period during which the charge / discharge type snubber circuit is used is shorter than in the case of the sixth aspect of the present invention, so that the snubber loss can be further reduced. it can.

[0040]

Embodiments of the present invention will be described below in detail with reference to the drawings. (First Embodiment) FIG. 1 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment. The same elements as those in FIG. Here, only the different parts will be described.

That is, in the power converter of the present embodiment, as shown in FIG. 1, discharge switches 9A and 9B in which snubber resistors 8A and 8B are connected in series are connected in parallel to snubber diodes 7A and 7B. They are connected to form snubber circuits of the power switches 3A and 3B, respectively.

The diodes 10A and 10B are connected to the snubber circuit as shown in the figure. Further, there is provided switching means including a switch 20 and AND circuits 21A and 21B.

The switch 20 outputs a switching condition signal based on a predetermined switching condition. AND circuits 21A, 21
B takes an AND condition between a switching condition signal from the switch 20 and a synchronization signal from a gate circuit (not shown) of the power switches 3A and 3B, and when this AND condition is satisfied,
A signal for turning on the discharge switches 9A and 9B is output.

Thus, the switching means is provided by the discharge switch 9
A and 9B are switched between a conducting state (ON) and a blocking state (OFF). Next, the operation of the power converter of the present embodiment configured as described above will be described.

When the switch 20 outputs a switching condition signal of "1" to the AND circuit 21A based on a predetermined switching condition, the AND condition with the synchronization signal from the gate circuit of the power switch 3A is satisfied. And the AND circuit 21
A outputs a signal to turn on (turn on) the discharge switch 9A of the positive arm.

Thus, the discharge switch 9 of the positive arm
When A is turned on, the snubber capacitor 4A discharges to 0 when the power switch 3A is turned on. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

When a switching condition signal of "0" is output from the switch 20 to the AND circuit 21A based on a predetermined switching condition, the AND condition with the synchronization signal from the gate circuit of the power switch 3A is output. Is not established, and a signal for turning off the discharge switch 9A of the positive arm from the AND circuit 21A is output.

Thus, the discharge switch 9 of the positive arm
When A is in the blocking state, snubber capacitor 4A discharges to the terminal voltage of DC power supply 1. That is, FIG.
The operation is similar to that of the clamp type snubber circuit shown in FIG.

As described above, depending on the conduction state of the discharge switch 9A, the snubber circuit of the power switch 3A of the positive arm can be switched between a charge / discharge type snubber circuit and a clamp type snubber circuit.

On the other hand, when a switching condition signal of "1" is output from the switch 20 to the AND circuit 21B based on a predetermined switching condition, the AND condition with the synchronizing signal from the gate circuit of the power switch 3B is output. Is established, a signal for turning on the discharge switch 9B of the positive side arm is output from the AND circuit 21B.

Thus, the discharge switch 9 of the negative arm
When B becomes conductive, the snubber capacitor 4B discharges to 0 when the power switch 3B is conductive. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

When a switching condition signal of "0" is output from the switch 20 to the AND circuit 21B based on a predetermined switching condition, the AND condition with the synchronization signal from the gate circuit of the power switch 3B is output. Is not established, and a signal is output from the AND circuit 21B to turn off the discharge switch 9B of the negative arm (OFF).

Thus, the discharge switch 9 of the negative arm
When B enters the blocking state, snubber capacitor 4B discharges to the terminal voltage of DC power supply 1. That is, FIG.
The operation is similar to that of the clamp type snubber circuit shown in FIG.

As described above, depending on the conduction state of the discharge switch 9B, the snubber circuit of the power switch 3B of the negative arm can be switched between the charge / discharge type snubber circuit and the clamp type snubber circuit.

As described above, in the power converter according to the present embodiment, the discharge switch 9 is controlled based on the predetermined switching condition.
Since A and 9B are switched between the conducting state and the blocking state, it is possible to switch between the charge / discharge type snubber circuit and the clamp type snubber circuit by the conducting state of the discharge switches 9A and 9B.

That is, even during the operation of the power converter, it is possible to switch between the charging / discharging type snubber circuit with a small load on the power switches 3A and 3B and the clamp type snubber circuit with a small snubber loss.
It becomes possible to adjust the discharge voltages of A and 6B.

As a result, a load on the power switches 3A and 3B can be reduced even when a large current is interrupted, and a power converter that can reduce snubber loss can be obtained.

(Modification of First Embodiment) FIG. 2 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment. The same elements as those in FIG. The description thereof will be omitted, and only different portions will be described here.

That is, as shown in FIG. 2, the power converter according to the present embodiment includes a snubber resistor 11 and a charging / discharging type snubber circuit shown in FIG.
A and 11B are different from each other in that they are separately provided.

The switching means for the discharge switches 9A and 9B are the same as those shown in FIG.
Here, illustration and description thereof are omitted. The operation of the power converter according to the present embodiment configured as described above is the same as that in the case of FIG.

However, unlike the case of FIG. 1, the snubber resistors 11A and 11A are used in the charge / discharge type snubber circuit and the clamp type snubber circuit.
Providing 11B separately allows the snubber resistance value to be changed between the charge / discharge type snubber circuit and the clamp type snubber circuit.

As described above, the same effect as in the case of FIG. 1 can be obtained with the power converter of the present embodiment. (Second Embodiment) FIG. 3 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment. The same elements as those in FIG. Here, only the different parts will be described.

That is, as shown in FIG. 3, the power converter of the present embodiment is basically configured by combining a plurality of stages (two stages in the figure) of the circuit shown in FIG. And a power converter that outputs at least three levels of potential.

Note that 3C and 3D are power switches,
C and 4D are FWD, 6C and 6D are snubber capacitors, 7
C and 7D are snubber diodes, 8C and 8D are snubber resistors, 9C and 9D are discharge switches, 10C and 10D are diodes, and 12 is a diode, and are connected as shown.

The discharge switches 9A, 9B, 9C, 9
Since the switching means of D is the same as that shown in FIG. 1, illustration and description thereof are omitted here.
The operation of the power converter according to the present embodiment configured as described above is the same as that in the case of FIG.

That is, the snubber circuits of the power switches 3A to 3D can be switched to a charge / discharge type snubber circuit or a clamp type snubber circuit depending on the conduction state of the discharge switches 9A to 9D, respectively.

As described above, the same effect as in the case of FIG. 1 can be obtained with the power converter of the present embodiment. (Third Embodiment) FIG. 4 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment. The same elements as those in FIG. Here, only the different parts will be described.

That is, the power converter of the present embodiment is different from the power converter of FIG. 4 in that a current detector 22 and a switching condition determiner 23 are newly provided in FIG. .

The current detector 22 detects the output current IL of the power conversion device main body. The switching condition determiner 23 is based on the output current IL detected by the current detector 22.
When the output current IL is positive (IL> 0), the discharge switch 9A of the positive arm is turned on and the discharge switch 9B of the negative arm is turned off.
When L is negative (IL <0), the switching condition for setting the discharge switch 9A of the positive arm to the blocking state and setting the discharge switch 9B of the negative arm to the conductive state is the switching condition of the switch 20. Give as.

Next, the operation of the power converter of the present embodiment configured as described above will be described with reference to the waveform diagram shown in FIG. The current detector 22 detects the output current IL of the power conversion device main body.

In the switching condition judging device 23, the current detector 22
Is used to determine the polarity of the detected output current IL. That is, when the output current IL is positive (IL> 0), the switching condition is such that the discharge switch 9A of the positive arm is turned on and the discharge switch 9B of the negative arm is turned off. It is given as a navel switching condition.

Then, the switching unit 20 outputs a switching condition signal of “1” to the AND circuit 21A based on the switching condition from the switching condition determination unit 23, and outputs a synchronization signal from the gate circuit of the power switch 3A. When the AND condition with the signal is satisfied, the AND circuit 21A outputs a signal to make the discharge switch 9A of the positive arm conductive (ON).

Thus, the discharge switch 9 of the positive arm
When A is turned on, the snubber capacitor 4A discharges to 0 when the power switch 3A is turned on. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

As described above, the snubber circuit of the power switch 3A of the positive arm can be switched between the charge / discharge type snubber circuit and the clamp type snubber circuit depending on the conduction state of the discharge switch 9A.

The switching unit 20 includes a switching condition determination unit 2
When the switching condition signal of "0" is output to the AND circuit 21B based on the switching condition from the switching circuit 3, the AND condition with the synchronization signal from the gate circuit of the power switch 3B is not satisfied, and the AND circuit 21B A signal for turning off the discharge switch 9B of the negative arm is output.

Thus, the discharge switch 9 of the negative arm
When B enters the blocking state, snubber capacitor 4B discharges to the terminal voltage of DC power supply 1. That is, FIG.
The operation is similar to that of the clamp type snubber circuit shown in FIG.

As described above, the output current IL is positive (IL>
In the case of 0), the power switch 3A is a charge / discharge type snubber circuit, and the power switch 3B is a clamp type snubber circuit. On the other hand, when the output current IL is negative (IL <0),
A switching condition for turning off the discharge switch 9A of the positive arm and turning on the discharge switch 9B of the negative arm is given to the switch 20 as the switching condition.

Then, the switching unit 20 outputs a switching condition signal of “0” to the AND circuit 21A based on the switching condition from the switching condition determination unit 23, and outputs a synchronization signal from the gate circuit of the power switch 3A. The AND condition with the signal is not satisfied, and the AND circuit 21A outputs a signal for turning off the discharge switch 9A of the positive side arm (OFF).

Thus, the discharge switch 9 of the positive arm
When A is in the blocking state, snubber capacitor 4A discharges to the terminal voltage of DC power supply 1. That is, FIG.
The operation is similar to that of the clamp type snubber circuit shown in FIG.

In the switching unit 20, the switching condition determining unit 2
When a switching condition signal of "1" is output to the AND circuit 21B based on the switching condition from the switching circuit 3, the AND condition with the synchronization signal from the gate circuit of the power switch 3B is satisfied. A signal for turning on (discharging) the discharge switch 9B of the side arm is output.

Thus, the discharge switch 9 of the negative arm
When B becomes conductive, the snubber capacitor 4B discharges to 0 when the power switch 3B is conductive. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

As described above, the output current IL becomes negative (IL <
In the case of 0), the power switch 3A is a clamp type snubber circuit, and the power switch 3B is a charge / discharge type snubber circuit. In this way, depending on the conduction state of the discharge switches 9A and 9B, the power switch 3 of the positive side arm and the negative side arm
The snubber circuits A and 3B can be switched between a charge / discharge type snubber circuit and a clamp type snubber circuit.

In this state, even if the anode reactor is omitted, the short-circuit mode, which is in the conventional charge / discharge type snubber circuit described above, does not occur. Thereby, the anode reactor can be omitted or the capacity can be set small.

As described above, also in the power converter of the present embodiment, the same effect as in the case of FIG. 1 can be obtained, and in addition, the anode reactor can be omitted,
Alternatively, the capacity can be set small.

(Fourth Embodiment) FIG. 5 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment. The same elements as those in FIG. Are omitted, and only different portions will be described here.

That is, as shown in FIG. 5, the power converter according to the present embodiment uses the switching condition determination unit 2 shown in FIG.
3 is omitted, and a switching condition determining unit 24 is newly provided instead.

The switching condition judging unit 24 determines, based on the output current IL detected by the current detector 22, that the absolute value of the output current IL is larger than the reference current value _Iref and positive (IL> _Iref > 0). ) in the case of the discharge switch 9A of the positive-side arm to the conductive state, also greater than the absolute value of the reference current value -I _ref of the output current IL and negative (IL <-I
_ref <0), the switching condition is such that the discharge switch 9B of the negative arm is turned on, and the discharge switches 9A and 9B of the positive arm and the negative arm are turned off in other cases. This is given as a switching condition of the switch 20.

Next, the operation of the power converter of the present embodiment configured as described above will be described with reference to the waveform diagram shown in FIG. The current detector 22 detects the output current IL of the power conversion device main body.

In the switching condition judging unit 24, the current detector 22
Is used to determine the magnitude and polarity of the output current IL detected. That is, when the absolute value of the output current IL is larger than the reference current value I _ref and is positive (IL> I _ref > 0), a switching condition for making the discharge switch 9A of the positive arm conductive is: The switching condition is given to the switch 20.

Then, the switching unit 20 outputs a switching condition signal of “1” to the AND circuit 21A based on the switching condition from the switching condition determination unit 24, and outputs a synchronization signal from the gate circuit of the power switch 3A. When the AND condition with the signal is satisfied, the AND circuit 21A outputs a signal to make the discharge switch 9A of the positive arm conductive (ON).

Thus, the discharge switch 9 of the positive arm
When A is turned on, the snubber capacitor 4A discharges to 0 when the power switch 3A is turned on. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

[0092] In the case of the absolute value of the reference current value -I _ref larger and more negative than the output current _{IL (IL <-I ref <0} ) is to the discharge switch 9B negative-side arm to the conductive state Various switching conditions are given to the switch 20 as the switching conditions.

Then, the switching unit 20 outputs a switching condition signal of “1” to the AND circuit 21B based on the switching condition from the switching condition determining unit 24, and outputs a synchronization signal from the gate circuit of the power switch 3B. When the AND condition with the signal is satisfied, the AND circuit 21B outputs a signal for turning on the discharge switch 9B of the positive arm.

Thus, the discharge switch 9 of the negative arm
When B becomes conductive, the snubber capacitor 4B discharges to 0 when the power switch 3B is conductive. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

Further, the absolute value of the output current IL is larger than the reference current value _Iref and is not positive (IL> _Iref > 0), and the absolute value of the output current IL is equal to the reference current value- _Iref.
Greater than and negative (IL <-I _ref <0) if neither the discharge switch 9 of the positive side arm and the negative-side arm
A switching condition that sets A and 9B to the blocking state is given to the switch 20 as the switching condition.

When the discharge switches 9A and 9B of the positive arm and the negative arm are in the blocking state, snubber capacitors 4A and 4B discharge to the terminal voltage of DC power supply 1. That is, the operation is the same as that of the clamp type snubber circuit shown in FIG.

As described above, when the absolute value of the output current IL exceeds the reference current value, the discharge switches 9A and 9B are turned on, and otherwise, the discharge switches 9A and 9B are turned off.

That is, the snubber circuit of the power switches 3A and 3B of the positive arm and the negative arm becomes a charge / discharge type snubber circuit only when the cutoff current exceeds a certain reference value.
At other times, it becomes a clamp type snubber circuit.

Thus, the burden on the power switches 3A and 3B is reduced. Further, since the period of the charge / discharge type snubber circuit is shorter than in the case of the third embodiment, the snubber loss is further reduced.

As described above, also in the power converter of the present embodiment, the same effects as in the case of FIG. 1 can be obtained, and the power switches 3A and 3B turn off the reference current or more. Sometimes it becomes a charge / discharge type snubber circuit,
Otherwise, it is possible to switch to the clamp type snubber circuit, so that the load on the power switches 3A and 3B can be reduced, and the period during which the charge / discharge type snubber circuit is used is shorter than in the case of the third embodiment. Since the length is short, the snubber loss can be further reduced.

(Fifth Embodiment) FIG. 8 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment. The same elements as those in FIGS. 1 and 10 are denoted by the same reference numerals. The description thereof will be omitted, and only different portions will be described here.

That is, as shown in FIG. 1, the power converter of this embodiment omits the snubber diodes 7A and 7B in FIG. 1, and newly replaces the thyristor 1
The difference is that 2A and 12B are provided.

Further, a switch 25 and an AND circuit 26
A and 26B. Switch 2
5 outputs a switching condition signal based on a predetermined switching condition.

The AND circuits 26A and 26B are
And a synchronization condition signal from a gate circuit (not shown) of the power switches 3A and 3B, and when the AND condition is satisfied, the thyristor 12
Gate signals for turning A and 12B on (on) are output.

As a result, the switching means is connected to the thyristor 12
A, 12B are conducting (on) or blocking (off)
To switch to. Next, the operation of the power converter of the present embodiment configured as described above will be described.

When a switching condition signal of "1" is output from the switch 25 to the AND circuit 26A based on a predetermined switching condition, the AND condition with the synchronization signal from the gate circuit of the power switch 3A is satisfied. And the AND circuit 26
A outputs a gate signal for turning on (turning on) the thyristor 12A of the positive arm.

As a result, the thyristor 12 of the positive arm
When A is turned on, the snubber capacitor 4A discharges to 0 when the power switch 3A is turned on. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

When a switching condition signal of "0" is output from the switch 25 to the AND circuit 21A based on a predetermined switching condition, the AND condition with the synchronizing signal from the gate circuit of the power switch 3A is output. Is not established, and the AND circuit 21A outputs a signal for setting the thyristor 21A of the positive arm to the blocking state (off).

As a result, the thyristor 12 of the positive arm
When A is in the blocking state, snubber capacitor 4A discharges to the terminal voltage of DC power supply 1. That is, the operation is the same as that of the RC snubber circuit.

As described above, depending on the conduction state of the thyristor 12A, the snubber circuit of the power switch 3A of the positive arm can be switched between the charge / discharge type snubber circuit and the RC snubber circuit.

On the other hand, when a switching condition signal of "1" is output from the switch 20 to the AND circuit 21B based on a predetermined switching condition, the AND condition with the synchronizing signal from the gate circuit of the power switch 3B is output. Is established, the AND circuit 21B outputs a signal for turning on (turning on) the thyristor 12B of the positive arm.

As a result, the thyristor 12 of the negative arm
When B becomes conductive, the snubber capacitor 4B discharges to 0 when the power switch 3B is conductive. That is, the operation is the same as that of the charge / discharge type snubber circuit shown in FIG.

When a switching condition signal of "0" is output from the switch 20 to the AND circuit 21B based on a predetermined switching condition, the AND condition with the synchronizing signal from the gate circuit of the power switch 3B is output. Is not established, and a signal for turning off the thyristor 12B of the negative side arm (OFF) is output from the AND circuit 21B.

As a result, the thyristor 12 of the negative arm
When B enters the blocking state, snubber capacitor 4B discharges to the terminal voltage of DC power supply 1. That is, the operation is the same as that of the RC snubber circuit.

As described above, depending on the conduction state of the thyristor 12B, the snubber circuit of the power switch 3B of the negative arm can be switched between the charge / discharge type snubber circuit and the RC snubber circuit.

As described above, in the power converter according to the present embodiment, the thyristor 12
Since A and 12B are switched between the conducting state and the blocking state, it is possible to switch between the charge / discharge type snubber circuit and the RC snubber circuit depending on the conducting state of the thyristors 12A and 12B.

That is, even during the operation of the power conversion device, it is possible to switch between the charge / discharge type snubber circuit with a small load on the power switch and the RC snubber circuit without the short-circuit mode at the time of turn-on. ,
6B can be adjusted.

As a result, the load on the power switches 3A and 3B can be reduced even when the large current is interrupted, and the short-circuit mode does not occur even when the power is turned on. Therefore, the anode reactor can be omitted or the capacity can be reduced. By setting, the capacity, size and cost of the device can be reduced.

(Modification of Fifth Embodiment) FIG. 9 is a circuit diagram showing a configuration example of a main part of a power converter according to the present embodiment, and the same elements as those of FIG. The description thereof will be omitted, and only different portions will be described here.

That is, as shown in FIG. 9, the power converter according to the present embodiment is composed of the charge / discharge type snubber circuit and the RC type snubber circuit shown in FIG.
Is provided in common.

Since the switching means for the thyristors 12A and 12B is the same as that shown in FIG. 8, its illustration and description are omitted here. The operation of the power converter of the present embodiment configured as described above is the same as that in the case of FIG.

As described above, the same effect as in the case of FIG. 8 can be obtained with the power converter of the present embodiment. (Other Embodiments) (a) Also in the fifth embodiment and its modifications, similarly to the third embodiment or the fourth embodiment, the current detector 22 , Switching condition determiner 2
Needless to say, the switching condition judging device 23 or the switching condition judging device 24 or the switching condition judging device 24 may be added as the switching condition of the switching device 20.

In this case, it is also possible to obtain the same operation and effect as in the case described above. (B) In each of the above embodiments, a case has been described in which the switching device 20 that outputs a switching condition signal based on a predetermined switching condition is provided. However, the present invention is not limited to this, and the predetermined switching condition as described above is satisfied. Thus, the switching of the conduction state (ON) or the blocking state (OFF) of the discharge switch or the thyristor may be manually performed.

[0124]

As described above, according to the first to fourth aspects of the present invention, the load on the power switch can be reduced even when a large current is interrupted, and the snubber loss can be reduced. A power conversion device provided with a simple snubber circuit can be provided.

According to the fifth to seventh aspects of the present invention, the load on the power switch can be reduced even when a large current is interrupted, and the capacity, size and cost of the device can be reduced. A power conversion device provided with a snubber circuit capable of performing the above can be provided.

That is, since there is no short-circuit mode as in the conventional charge / discharge type snubber circuit, the anode reactor is omitted or the capacity of the anode reactor is reduced as compared with the charge / discharge type snubber circuit. Can be changed to capacity.

Further, when the cutoff current of the power switch is large, the load on the power switch can be reduced by using a charge / discharge type snubber circuit so as to reduce the load.

[Brief description of the drawings]

FIG. 1 is a circuit configuration diagram showing a first embodiment of a power converter according to the present invention.

FIG. 2 is a circuit diagram showing a modified example of the first embodiment of the power converter according to the present invention.

FIG. 3 is a circuit diagram showing a second embodiment of the power converter according to the present invention.

FIG. 4 is a circuit diagram showing a third embodiment of the power converter according to the present invention.

FIG. 5 is a circuit configuration diagram showing a fourth embodiment of the power converter according to the present invention.

FIG. 6 is a waveform chart for explaining the operation of the power converter according to the third embodiment.

FIG. 7 is a waveform chart for explaining the operation of the power converter according to the fourth embodiment.

FIG. 8 is a circuit diagram showing a fifth embodiment of the power converter according to the present invention.

FIG. 9 is a circuit diagram showing a modification of the fifth embodiment of the power converter according to the present invention.

FIG. 10 is a circuit diagram showing a configuration example of a main part of a power conversion device using a conventional charge / discharge type snubber circuit.

FIG. 11 is a circuit diagram showing a configuration example of a main part of a power conversion device using a conventional clamp-type snubber circuit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... DC power supply, 2 ... Load, 3A-3D ... Power switch, 4A-4D ... FWD, 5A-5D ... Anodized reactor, 6A-6C ... Snubber capacitor, 7A-7D ... Snubber diode, 8A-8D ... Snubber resistance, 9A-9D: discharge switch, 10A-10D: diode, 11A-11D: snubber resistance, 12: diode, 20: switch, 21A, 21B: AND circuit, 22: current detector, 23, 24: switch Condition determiner, 25: switcher, 26A, 26B: AND circuit.

Claims (7)

[Claims] A power switch connected to a DC power supply is connected in parallel with a snubber circuit formed by connecting at least a snubber capacitor and a snubber diode in series, and a positive side arm and a negative side arm are connected to each other. Composed,
In a power converter for converting DC power to AC power, a discharge switch having a snubber resistor connected in series is connected in parallel to the snubber diode, and the discharge switch is turned on based on a predetermined switching condition. Alternatively, a power conversion device comprising switching means for switching to a blocking state. 2. A power switch connected to a DC power supply, a snubber circuit having at least a snubber capacitor and a snubber diode connected in series is connected in parallel, and a positive side arm and a negative side arm are respectively connected. Composed,
In a power converter that outputs at least three levels of potential, a discharge switch in which a snubber resistor is connected in series is connected in parallel to the snubber diode, and the discharge switch is turned on based on a predetermined switching condition. A power converter comprising switching means for switching between a state and a blocking state. 3. The power conversion device according to claim 1, wherein a current detection unit that detects an output current of the power conversion device main body, and an output current that is detected by the current detection unit. When the output current is positive, the discharge switch of the positive arm is turned on and the discharge switch of the negative arm is turned off, and when the output current is negative, the discharge switch of the positive arm is turned off. And a switching condition determining means for providing, as a switching condition of the switching means, a switching condition for setting the discharging switch to a blocking state and setting the discharging switch of the negative arm to a conducting state. Power converter. 4. The power conversion device according to claim 1, wherein a current detection means for detecting an output current of the power conversion device main body, and a power supply based on the output current detected by the current detection means. When the absolute value of the output current is larger than the reference current value and is positive, the discharge switch of the positive arm is made conductive, and when the absolute value of the output current is larger than the reference current value and negative, The switching condition of the switching means is set such that the discharge switch of the negative arm is turned on and the discharge switches of the positive arm and the negative arm are turned off in other cases. A power conditioner comprising: a switching condition determining unit; 5. A power switch connected to a DC power supply, wherein a snubber circuit formed by connecting at least a snubber capacitor and a thyristor having a snubber resistor connected in parallel is connected in parallel. A power conversion device configured to each of the side arm and the negative side arm and converting DC power into AC power, comprising: switching means for switching the thyristor to a conductive state or a blocking state based on a predetermined switching condition. Characteristic power converter. 6. The power conversion device according to claim 5, wherein current detection means for detecting an output current of the power conversion device main body; and the output current based on the output current detected by the current detection means. Is positive, the thyristor of the positive arm is turned on and the thyristor of the negative arm is turned off, and if the output current is negative, the thyristor of the positive arm is turned off. And a switching condition determining means for providing a switching condition for causing the thyristor of the negative arm to be in a conductive state as a switching condition of the switching means. 7. The power converter according to claim 5, wherein current detection means for detecting an output current of the power conversion device main body, and the output current based on the output current detected by the current detection means. When the absolute value of the output current is larger than the reference current value and is positive, the thyristor of the positive arm is made conductive, and when the absolute value of the output current is larger than the reference current value and negative, the negative arm A switching condition determining means for providing, as the switching condition of the switching means, a switching condition for making the thyristor of the thyristor conductive and otherwise setting the thyristors of the positive arm and the negative arm to the blocking state. A power converter characterized by comprising: