JPH0583928A - Snubber-power regenerative circuit - Google Patents

Abstract

PURPOSE:To reduce cost by simplifying the configurations of a power regenerative circuit regenerating snubber power and a snubber circuit. CONSTITUTION:In an AC direct conversion circuit with an AC power 1, bi- directional switches 4-7, single-phase AC buses 500, 501 and a transformer 8, each series node of snubber diodes and snubber capacitors in snubber circuits 171-174 is connected to the primary winding of the transformer 8 through switches 201-204 for regeneration and reactors 205, 206 respectively. When either of the bi-directional switches is turned ON and voltage is applied to a primary winding, the switch for regeneration connected to the snubber capacitor having voltage having the same polarity as the voltage is turned ON only for a voltage applying period to the primary winding, and the power of the snubber capacitor is regenerated in the transformer 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a snubber power regeneration circuit, and more particularly to a snubber power regeneration circuit that regenerates the power absorbed by a snubber capacitor in the snubber circuit.

[0002]

2. Description of the Related Art FIG. 6 shows a main circuit of a so-called SMR (Switch Mode Rectifier) converter (see the Technical Report of the Institute of Electrical Engineers of Japan, October 1990, p. 16) which is a kind of AC direct conversion circuit. The snubber circuit used for this is shown. In FIG. 6, one terminal of the bidirectional switch 4 capable of passing a current in both forward and reverse directions and one terminal of the bidirectional switch 5 are connected to each other to form a so-called arm pair. A similar pair of arms is constructed for the bidirectional switches 6 and 7,
The other terminals of the bidirectional switches 4 and 6 are single-phase AC buses 50.
0 is connected to one input terminal U of the transformer 8 and the other terminals of the bidirectional switches 5 and 7 are connected to the other input terminal V of the transformer 8 via the single-phase AC bus 501, respectively. ..

The series connection points R and S of the two bidirectional switches in each arm pair are connected to the AC power supply 1 via the reactors 2 and 3. Output terminals u and v of the transformer 8
Is connected to an AC input terminal of a full-wave rectifier circuit 134 composed of diodes 9, 10, 11, and 12, and a capacitor 13 is connected between its DC output terminals. Each terminal of the capacitor 13 is connected to the DC output terminals P and N, and DC power is supplied to a load (not shown) connected to these DC output terminals P and N.

On the other hand, at both terminals of the bidirectional switch 4, a snubber circuit 181 composed of a full-wave rectifying circuit composed of diodes 101, 102, 103 and 104 and a snubber capacitor 120 connected between its DC output terminals. Of the snubber circuit 181 are connected to the two input terminals of the power regeneration circuit 130, respectively. Similarly, for the bidirectional switches 5, 6 and 7, the diodes 106 to 109 are similarly provided.
And a snubber capacitor 121 and a snubber circuit 182, diodes 110 to 113 and a snubber capacitor 122, a snubber circuit 183, and diodes 114 to 117 and a snubber capacitor 123. The power regeneration circuits 131 to 133 are connected to the snubber circuits 182 to 184, respectively. And all the power regeneration circuits 130
Each of the two output terminals (1 to 133) is connected to the two terminals of the capacitor 13, respectively.

In such a circuit configuration, the bidirectional switches 4 to 7 carry out an on / off operation as shown in FIG. 2, which will be described later. Now, the bidirectional switches 4 to 7 are all turned on and then the bidirectional switch 5 is turned on. , 6 will be in the off state. When the bidirectional switches 4 to 7 are turned on, the AC power supply 1, the reactor 2, the bidirectional switch 4,
A current I _AC flows through the path of the bidirectional switch 6 and the reactor 3 and the path of the AC power supply 1, the reactor 2, the bidirectional switch 5, the bidirectional switch 7 and the reactor 3. Here, when the bidirectional switches 5 and 6 are turned off, the current I
_AC is reactor 2, bidirectional switch 4, single-phase AC bus 5
00, the transformer 8, the single-phase AC bus 501, the bidirectional switch 7, and the reactor 3 try to flow.

By the way, the wiring of the single-phase AC buses 500 and 501 connecting between the bidirectional switches 4 to 7 and the transformer 8 contains the inductance component 100, and the transformer 8 contains the leakage inductance 800. Has been. Therefore, when the bidirectional switches 5 and 6 are turned off, the current I _AC rapidly flows, so that a large electromotive voltage is generated in the inductance 10.
0,800, and the sum of this voltage and the input voltage of the transformer 8 causes the bidirectional switch 5, which has turned off.
6 is applied across each terminal.

Snubber circuits 181 to 184 are connected for the purpose of suppressing this voltage below the allowable voltage of the bidirectional switch. For example, in the bidirectional switch 5, when the switch is turned off, one terminal D2 to the other terminal D2.
The current flowing through 1 is the terminal D2, the diode 107,
It flows through the capacitor 121, the diode 108, and the terminal D1, and suppresses the inter-terminal voltage of the bidirectional switch 5 to the voltage value of the capacitor 121. At the same time, this voltage is also applied to the inductances 100 and 800, which promotes an increase in the current value flowing through the inductances 100 and 800 to become equal to I _AC . The same operation is performed for the bidirectional switch 6.

A current flows in the snubber capacitors 121 and 122 when the bidirectional switches 5 and 6 are turned off, that is, the capacitors 121 and 122 absorb electric power. Therefore, the terminal voltage of the capacitors 121 and 122 increases in proportion to the amount of power absorbed. For the purpose of suppressing this voltage rise and maintaining a prescribed voltage value, the power regeneration circuits 131, 1
32 (similarly for the other 130 and 133) is required. The power regeneration circuits 131 and 132 are the snubber circuit 18
The electric power absorbed by the capacitors 121 and 122 is insulation-converted into the voltage of the capacitor 13 and discharged so that the voltage values of the capacitors 121 and 122 of Nos. 2 and 183 become predetermined values, thereby regenerating the electric power. ..

[0009]

According to the above-mentioned conventional structure, the snubber circuits 181-184 have a full-wave rectification circuit, which makes the structure complicated. In addition, the power regeneration circuit 130-1
Since the 33 needs to have a voltage control function of insulating the input side and the output side thereof and holding the voltage of the snubber capacitors 120 to 123 at a predetermined value, the DC circuit 33 has a complicated circuit configuration and is expensive. There is a problem that the / DC conversion circuit must be used. The present invention has been made to solve the above problems, and an object of the present invention is to provide a snubber power regeneration circuit that can efficiently regenerate snubber power with a simple and inexpensive circuit configuration. ..

[0010]

In order to achieve the above object, the first aspect of the present invention is directed to at least one arm pair in which two bidirectional switches are connected in series, and a single end to which both ends of the arm pair are connected. AC via a phase AC bus, a transformer whose primary winding is connected to this single-phase AC bus, and whose secondary winding is connected to the load circuit, through the series connection point of the bidirectional switch and the primary winding An AC direct conversion circuit that includes an AC power supply that supplies electric power, converts the AC power to single-phase AC power by turning on / off a bidirectional switch, and performs an insulation conversion by a transformer to supply power to a load circuit. A first series circuit including a snubber diode and a snubber capacitor,
A snubber circuit in which a second series circuit composed of a snubber diode and a snubber capacitor in the opposite direction to the snubber diode are connected in parallel is connected between both terminals of each bidirectional switch, and each series of the snubber diode and the snubber capacitor is connected. When connecting a connection point to the primary winding through a regeneration switch and a reactor, respectively, and applying a voltage to the primary winding by turning on any of the bidirectional switches, a voltage having the same polarity as that voltage. The regenerative switch connected to the snubber capacitor having the above is turned on only during the voltage application period to the primary winding.

A second invention is, in the above AC direct conversion circuit, a first series circuit comprising a snubber diode and a snubber capacitor, and a second invention comprising a snubber diode and a snubber capacitor in a reverse direction to the snubber diode.
A series circuit of a snubber circuit connected in parallel between the two terminals of each bidirectional switch, each series connection point of the snubber diode and the snubber capacitor through the regeneration switch and the reactor of the transformer first A regenerative switch connected to a snubber capacitor having a voltage of the same polarity as the voltage when the bidirectional switch is turned on and a voltage is applied to the primary winding while the bidirectional switch is turned on. It is turned on only during the voltage application period to the primary winding.

A third aspect of the present invention is, in the above AC direct conversion circuit, a first series circuit including a snubber diode and a snubber capacitor, and a second series circuit including a snubber diode and a snubber capacitor in a reverse direction to the snubber diode.
And a serial circuit connected in parallel to each other between two terminals of each bidirectional switch, and each series connection point of the snubber diode and the snubber capacitor is connected to a second transformer via a regeneration switch and a reactor. A secondary winding of the second transformer connected in parallel to the secondary winding of the first transformer in the AC direct conversion circuit, and any one of the bidirectional switches. When a voltage is applied to the primary winding of the first transformer by turning on the switch, a regeneration switch connected to a snubber capacitor having a voltage of the same polarity as the voltage is applied to the primary winding of the first transformer. It is turned on only during the voltage application period.

[0013]

According to the first aspect of the present invention, when all the bidirectional switches are turned on from the state where all the bidirectional switches are turned on, the main circuit current flowing before that is in the on state. It begins to flow through the bidirectional switch, the single-phase AC bus and the primary winding of the transformer. Along with this, the sum of the electromotive voltage generated in the wiring inductance of the single-phase AC bus and the leakage inductance of the transformer and the input voltage of the transformer is applied to both ends of the bidirectional switch that has been turned off.
The voltage applied to both ends of the bidirectional switch has both positive and negative polarities, but the snubber capacitor can be applied to both polarities by the first and second series circuits of the snubber capacitor and the snubber diode in the snubber circuit. Can be absorbed by. As a result, the inter-terminal voltage of the bidirectional switch can be suppressed to the inter-terminal voltage of the snubber capacitor, and a bidirectional overvoltage suppressing effect can be obtained.

When the energy is absorbed by the snubber capacitor in this way, the voltage of the snubber capacitor rises above the input voltage of the transformer. Here, since the two snubber capacitors forming the first and second series circuits are both connected in parallel to the bidirectional switch, their terminal voltages are also the same. When a voltage is applied to the primary winding of a transformer due to the ON operation of a bidirectional switch, and the regenerative switch connected to a snubber capacitor with a voltage of the same polarity as this voltage is turned on, the capacitor voltage The difference voltage between the input voltage of the transformer and the input voltage of the transformer is added to the reactor, and the discharge current flows from the capacitor to the transformer side. Therefore, the terminal voltage of the capacitor is reduced to a value close to the input voltage of the transformer. That is, the energy of the snubber circuit absorbed by the capacitor is regenerated to the single-phase AC bus (transformer). On the other hand, when the voltage applied to the input winding of the transformer disappeared due to the conduction of the bidirectional switch, when the regenerative switch was turned off, the magnetic energy stored in the reactor was connected to the same single-phase AC bus. It will be regenerated to the other snubber capacitor.

According to the second invention, since the other end of the reactor connected to the regenerative switch is connected to the third winding of the transformer, the electric power absorbed by the snubber capacitor is absorbed by the regenerative switch and the reactor. And is regenerated into a single-phase AC bus (transformer) via the third winding. Therefore, the voltage generated in the primary winding due to the main circuit current flowing in the primary winding of the transformer does not affect the discharge voltage of the capacitor.

According to the third aspect of the invention, since the other end of the reactor connected to the regenerative switch is connected to the primary winding of the second transformer, the electric power absorbed by the snubber capacitor is absorbed by the regenerative switch and the regenerative switch. It is regenerated by the second transformer via the reactor. Therefore, the voltage generated in the primary winding by the main circuit current flowing in the primary winding of the first transformer does not affect the discharge voltage of the capacitor.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an embodiment of the first invention together with a main circuit of an AC direct conversion circuit. The same components as those in FIG. 6 are designated by the same reference numerals. In FIG. 1, one terminal D2 of the bidirectional switch 4 and one terminal D1 of the bidirectional switch 5 are connected to form an arm pair, and the other terminal D1 of the bidirectional switch 4 is connected to the single-phase AC bus 500. The other terminal D2 of the bidirectional switch 5 is connected to the single-phase AC bus 501, respectively.

The bidirectional switches 6 and 7 are similarly connected, and the reactor 2 is connected between the connection point R of the bidirectional switches 4 and 5 and the connection point S of the bidirectional switches 6 and 7.
The AC power supply 1 and the reactor 3 are connected. One input terminal U of the primary winding 81 of the transformer 8 is connected to the single-phase AC bus line 500, and the other input terminal V is connected to the single-phase AC bus line 5.
01, and the output terminals u and v of the secondary winding 82 of the transformer 8 are connected to the DC output terminals P and N via the full-wave rectifier circuit 134 including the diodes 9 to 12 and the capacitor 13 as described above. It is connected.

On the other hand, 171 to 174 are bidirectional switches 4
It is a snubber circuit corresponding to 7 respectively. this house,
The configuration of the snubber circuit 171 corresponding to the bidirectional switch 4 will be described. One end of the snubber capacitor 41 is connected to the terminal D1 of the bidirectional switch 4, the other end is connected to the cathode of the snubber diode 43, and the snubber diode 43 is connected. The anode of 43 is connected to the terminal D2 of the bidirectional switch 4. One end of the snubber capacitor 42 is connected to the terminal D1, the other end is connected to the anode of the snubber diode 44, and the cathode of the snubber diode 43 is connected to the terminal D2.

That is, the snubber circuit 171 includes a first series circuit composed of a snubber diode 43 and a snubber capacitor 41, and a second series circuit composed of a snubber diode 44 and a snubber capacitor 42 in the opposite direction to the snubber diode 43. Are connected in parallel, and the snubber circuit 171 is connected between both terminals of the bidirectional switch 4. Similarly, the snubber circuit 172 is configured by the diodes 53, 54 and the capacitors 51, 52, the snubber circuit 173 is configured by the diodes 63, 64 and the capacitors 61, 62, and the snubber circuit 174 is configured by the diodes 73, 74 and the capacitors 71, 72, respectively. To be done.

In addition, the cathodes of the diodes 43 and 63 are MOSFETs (hereinafter simply referred to as FE) as regeneration switches.
T) connected to the drain of 204, diode 4
The anodes of 4, 64 are also F as a regeneration switch.
The source of the FET 204 and the drain of the FET 203 are connected to the source of the ET 203, and are connected to the input terminal V of the transformer 8 via the reactor 205. Further, the diodes 53, 54, 73, 74 are similarly connected to the FETs 201, 202 as regeneration switches, and the source of the FET 201 and the drain of the FET 202 are connected to the input terminal U of the transformer 8 via the reactor 206. It is connected.

Next, the operation of this embodiment will be described with reference to the operation waveforms of FIG. As shown in FIG. 2, a control circuit (not shown) generates an ON / OFF signal for the bidirectional switches 4 to 7 from the voltage waveform V _AC ′ substantially equal to the voltage waveform of the AC power supply 1 and the triangular wave modulation signal. As a result, when the bidirectional switches 4 to 7 are operated, the voltage V _RS is generated between the AC terminals _RS of FIG. This voltage V _RS
By this, the input current I _AC of the AC direct conversion circuit is controlled, and the AC voltage V _UV is generated between the input terminals U-V of the transformer 8. At this time, the terminals D1 and D of the bidirectional switches 4 to 7
The waveforms of the voltages V ₄ , V ₅ , V ₆ , and V ₇ between the two are as shown in FIG.

Consider now the operation between times t _{1 and} t ₂ shown in the waveform diagram of the voltages V ₅ and V ₆ in FIG. At time t ₁ , all of the bidirectional switches 4 to 7 are turned on,
The bidirectional switches 5 and 6 are turned off. When all the bidirectional switches 4 to 7 are in the ON state, the paths of the AC power supply 1, the reactor 2, the bidirectional switches 4, 6, and the reactor 3, and the AC power supply 1, the reactor 2, the bidirectional switches 5, 7, and the reactor 3 The current I _AC is flowing through the path.

Here, when the bidirectional switches 5 and 6 are turned off, the current I _AC is the reactor 2, the bidirectional switch 4, the single-phase AC bus 500, the transformer 8, and the single-phase AC bus 5.
01, the bidirectional switch 7, and the reactor 3 are about to flow. However, since the single-phase AC buses 500 and 501 have the wiring inductance 100, and the transformer 8 has the leakage inductance 800, the current I _AC rapidly flows in these inductances 100 and 501.
An electromotive voltage is generated in 800, and a sum voltage of the electromotive voltage and the input voltage of the transformer 8 is generated between both terminals of the bidirectional switches 5 and 6.

As a result, the voltage between the terminals of the bidirectional switches 5 and 6 rises.
When the voltage of 5 is reached, the diodes 53 and 64 become conductive, and current flows through the terminal D1 of the bidirectional switch 5, the diode 53 and the path of the capacitor 51, and the terminal D1 of the bidirectional switch 6, the capacitor 62 and the path of the diode 64. It absorbs the magnetic energy of the inductances 100 and 800.
Therefore, the voltages of the capacitors 51 and 62 rise, and the inter-terminal voltages V ₅ and V ₆ of the bidirectional switches 5 and ₆ have a difference voltage ΔV _DD in the applied voltage V _SS to the transformer 8 as shown in FIG. It becomes the added value. Normally, the capacitance of the snubber capacitor is selected so that this voltage (V _SS + ΔV _DD ) is less than the withstand voltage of the bidirectional switch.

Further, in synchronization with the period when the bidirectional switches 5 and 6 are off, as shown in FIG.
203 is turned on. For example, when the FET 201 is turned on during the period from time t ₁ to t ₂ , the reactor 20
6, a voltage difference ΔV _DD between the voltage of the snubber capacitor 51 and the input voltage of the transformer 8 is added, a current I ₂₀₆ flows through the reactor 206, and the voltage of the snubber capacitor 51 decreases, and its power is a single-phase AC bus. It is regenerated to the load side via the transformers 8 and 500 or 501 side. This action is F
The same applies to the ET 203, the capacitor 62, and the reactor 205.

Next, at time t ₂ , when the FET 201 is turned off, the current I _{206 of the} reactor 206 flows through the transformer 8, the capacitor 72, and the FET 202,
The magnetic energy stored in the reactor 206 is regenerated in the capacitor 72. Further, even when the FET 203 is turned off, the magnetic energy of the reactor 205 is regenerated in the capacitor 61. In addition, FET202,2
When 04 is turned on, the current I ₂₀₆ and the currents I ₂₀₂ and I ₂₀₄ having opposite polarities shown in FIG. 2 flow by the same operation. Needless to say, the above operation is the same for the other bidirectional switches 4 and 7.

As described above, the FETs 201 to 204 and the reactor 20 absorb the power absorbed by the snubber circuits 171 to 174 with respect to the off operation of all the bidirectional switches.
Since the regeneration can be performed only by 5,206, the configuration of the power regeneration circuit can be simplified. Also, the snubber circuits 171 to 174 themselves can be realized by a simple configuration with only two diodes and two capacitors for each bidirectional switch 4 to 7.

Next, FIG. 3 shows another embodiment of the first and second inventions. That is, in this embodiment, the main circuit configuration of the AC direct conversion circuit is different from that of FIG. 1, and the bidirectional switches 6 and 7 and the snubber circuits 173 and 174 in FIG.
In addition, the so-called center tap system in which the other end of the reactor 3 is connected to the intermediate tap M is used as the transformer 8'in the primary winding 81 'as a transformer 8'. It is a difference.

The difference in operation of the main circuit from that of FIG. 1 in this embodiment is that when the bidirectional switches 4 and 5 are both in the ON state, the main circuit currents are the AC power supply 1, the reactor 2 and the bidirectional switch. 4, the terminal U of the transformer 8 ', the intermediate tap M,
The path of the reactor 3, the AC power supply 1, the reactor 2, the bidirectional switch 5, the terminal V of the transformer 8 ', the intermediate tap M,
It will be two of the paths of Reactor 3. Regardless of such a difference in the operation of the main circuit, the FETs 201 to 20
4, it is easily understood that the voltage and the current between the terminals 205 and 206 of the reactors 205 and 206 and the terminals 8 and V of the transformer 8'are the same as in the case of FIG. 1, and according to the present invention, in the center tap type SMR converter. Also, the configurations of the power regeneration circuit and the snubber circuit can be simplified.

Next, FIG. 4 shows an embodiment of the second invention, in which the reactors 205 and 206 are the third transformer 8A.
1 is different from that shown in FIGS. 1 and 3 in the circuit configuration. In this embodiment, the operations of the bidirectional switches 4 to 7 and the snubber circuits 171 to 174 are similar to those of the embodiment of FIG. 1, but the capacitors of the snubber circuits 171 to 174 are discharged when the switches 201 to 204 are turned on and off. 1 differs from FIG. 1 in that a current flowing through the third winding 83 of the transformer 8A flows.

Thus, the winding 83 through which the discharge current of the snubber circuits 171 to 174 flows and the winding 8 through which the main circuit current flows.
By separating 1, the winding 8 depends on the main circuit current.
It is possible to prevent the voltage generated in the leakage inductance 800 of No. 1 from affecting the discharge voltage of the snubber circuits 171 to 174. As a result, the snubber circuits 171-1
The discharge voltage of 74 is uniformly determined by the transformation ratio between the third winding 83 and the secondary winding 82 and the DC output voltage of the main circuit, which has the advantage of stabilizing the voltage of the snubber capacitor. Be done.

FIG. 5 shows an embodiment of the third invention. Instead of the third winding 83 in the embodiment of FIG.
A second transformer 8B is added in addition to the first transformer 8 and one ends of the reactors 205 and 206 are connected to both ends of a primary winding 83 of the transformer 8B, respectively, and a secondary winding of the transformer 8B is provided. The difference in circuit configuration is that 84 is connected in parallel to the secondary winding 82 of the first transformer 8.

In this embodiment, snubber circuits 171 to 17 are provided.
By separating the second transformer 8B in which the discharge current of No. 4 flows and the first transformer 8 in which the main circuit current flows, the voltage generated in the winding having the common magnetic circuit depending on the main circuit current. Does not affect the discharge current of the snubber circuit.
Further, the discharge voltage of the snubber circuits 171 to 174 is the transformer 8
It is uniformly determined by the transformer ratio of B and the DC output voltage of the converter, and the advantage that the voltage of the snubber capacitor is stable is obtained.

The first to fourth inventions described above are
The AC power supply 1 is connected to the terminals R and S without the reactors 2 and 3, and the DC output terminals P and N of the full-wave rectifier circuit 134 including the diodes 9 to 12 and the capacitor 13 are connected to a reactor (not shown). The present invention is also applicable to a so-called voltage type SMR circuit connected via the rectifier circuit and a case where the rectifier circuit section is different (for example, a center tap type rectifier circuit system). Further, the AC direct conversion circuit to which the present invention is applied is not limited to the single-phase circuit as in each of the embodiments, but may be a three-phase circuit including a three-phase power supply and a three-phase bridge including a bidirectional switch. Furthermore, in addition to FETs as regenerative switches, bipolar power transistors with self-extinguishing capability,
It may be a GTO thyristor, an SI thyristor or the like.

[0036]

As described above, according to the first aspect of the present invention, the electric power absorbed by the snubber circuit due to the off operation of all the bidirectional switches can be regenerated only by the regenerative switch and the reactor. The configuration can be greatly simplified compared to the conventional one. In particular, since the power regeneration circuit does not need to have the function of controlling the voltage of the snubber capacitor to a predetermined value and the expensive and complicated DC / DC conversion function as in the past, further simplification and cost reduction of the configuration. Can be planned. At the same time, the snubber circuit itself has a simple structure, which is economical and reliable.

According to the second or third aspect of the invention, in addition to the effects described above, the reactor of the power regenerative circuit is electrically separated from the primary winding of the transformer of the main circuit, so that it is accompanied by the main circuit current. It is possible to eliminate the influence of the voltage generated in the primary winding on the discharge voltage of the snubber capacitor, and as a result, the discharge voltage of the snubber circuit can be held at a predetermined voltage and the voltage of the snubber capacitor can be stabilized. ..

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment of a first invention.

FIG. 2 is an operation waveform diagram of the embodiment of FIG.

FIG. 3 is a circuit diagram showing another embodiment of the first invention.

FIG. 4 is a circuit diagram showing an embodiment of the second invention.

FIG. 5 is a circuit diagram showing an embodiment of the third invention.

FIG. 6 is a circuit diagram showing a conventional technique.

[Explanation of symbols]

1 AC power source 2,3 reactor 4,5,6,7 bidirectional switch 8,8 ', 8A, 8B transformer 81,81', 83 primary winding 82,84 secondary winding 83 third winding 41 , 42, 51, 52, 61, 62, 71, 72 Snubber capacitors 43, 44, 53, 54, 63, 64, 73, 74 Snubber diodes 171, 172, 173, 174 Snubber circuits 201, 202, 203, 204 Regeneration 205,206 Reactor 500,501 as switch for single-phase AC bus

Claims (3)

[Claims] 1. An at least one pair of arms in which two bidirectional switches are connected in series, a single-phase AC bus to which both ends of the arm pair are connected, and a primary winding connected to the single-phase AC bus. And a transformer having a secondary winding connected to the load circuit, an AC power supply that supplies AC power through the series connection point of the bidirectional switch and the primary winding, and the bidirectional switch is turned on / off. In the AC direct conversion circuit for converting the AC power into single-phase AC power by means of a transformer, and performing insulation conversion by a transformer to supply power to a load circuit, a first series circuit including a snubber diode and a snubber capacitor, and the snubber diode. A second series circuit composed of a snubber diode and a snubber capacitor in the opposite direction is connected in parallel between both terminals of each bidirectional switch. When each series connection point of a diode and a snubber capacitor is connected to the primary winding via a regenerative switch and a reactor, and one of the bidirectional switches is turned on to apply a voltage to the primary winding. A snubber power regeneration circuit, wherein a regeneration switch connected to a snubber capacitor having a voltage of the same polarity as that voltage is turned on only during a voltage application period to the primary winding. 2. At least one arm pair in which two bidirectional switches are connected in series, a single-phase AC bus to which both ends of the arm pair are connected, and a primary winding is connected to the single-phase AC bus. And a transformer having a secondary winding connected to the load circuit, an AC power supply that supplies AC power through the series connection point of the bidirectional switch and the primary winding, and the bidirectional switch is turned on / off. In the AC direct conversion circuit for converting the AC power into single-phase AC power by means of a transformer, and performing insulation conversion by a transformer to supply power to a load circuit, a first series circuit including a snubber diode and a snubber capacitor, and the snubber diode. A second series circuit composed of a snubber diode and a snubber capacitor in the opposite direction is connected in parallel between both terminals of each bidirectional switch. Each series connection point of the diode and the snubber capacitor is connected to the third winding of the transformer through the regenerative switch and the reactor, and one of the bidirectional switches is turned on to turn on the voltage to the primary winding. The snubber power regeneration circuit is characterized in that, when the voltage is applied, a regeneration switch connected to a snubber capacitor having a voltage having the same polarity as that voltage is turned on only during a voltage application period to the primary winding. 3. At least one arm pair in which two bidirectional switches are connected in series, a single-phase AC bus bar to which both ends of the arm pair are connected, and a primary winding is connected to the single-phase AC bus bar. And a secondary winding connected to the load circuit
And a series connection point of a bidirectional switch and an AC power supply that supplies AC power via the primary winding, and the AC power is converted to single-phase AC power by turning the bidirectional switch on and off. Also, in an AC direct conversion circuit that performs insulation conversion by a first transformer and supplies power to a load circuit, a first series circuit including a snubber diode and a snubber capacitor, and a snubber diode and a snubber diode in a reverse direction to the snubber diode. A snubber circuit in which a second series circuit including a capacitor is connected in parallel is connected between both terminals of each bidirectional switch, and each series connection point of the snubber diode and the snubber capacitor is connected via a regeneration switch and a reactor. Connect to the primary winding of the second transformer and connect the secondary winding of the second transformer in parallel to the secondary winding of the first transformer In addition, when a voltage is applied to the primary winding of the first transformer by turning on any of the bidirectional switches, the regenerative switch connected to the snubber capacitor having a voltage of the same polarity as that voltage A snubber power regeneration circuit, which is turned on only during a voltage application period to the primary winding of the transformer of No. 1.