JP2020178503A - Power conversion device - Google Patents

Abstract

To provide a power conversion device that can prevent a resonance current with a simple configuration without reducing the conversion efficiency of the power conversion device.SOLUTION: A power conversion device according to an embodiment comprises: a plurality of converters that may be applied with a DC voltage via a circuit breaker and are connected in parallel; and a first capacitor that is applied with the DC voltage at both ends. Each of the plurality of converters includes a pair of DC terminals that are applied with the DC voltage, an AC terminal that outputs and then receives an AC voltage, a conversion circuit that is connected between the pair of DC terminals and the AC terminal, a second capacitor that is connected between the pair of DC terminals and the conversion circuit, a diode that is connected such that a current flows from the AC terminal toward the DC terminal on a high potential side of the pair of DC terminals, and a resistor that is connected between any one of the pair of DC terminals and the second capacitor.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to a power converter.

There is a parallel multiplex type power converter in which a plurality of converters are connected in parallel. Each converter has a switching element, and by switching the switching element, a DC voltage or an AC voltage is converted into a DC voltage, or vice versa. A capacitor is provided at the DC end of each converter, and a plurality of LC resonance loops are formed by the capacitor and the wiring inductance. Resonant current flows in these loops as the switching elements are switched.

In such a parallel multiplexing type power conversion device, various methods for suppressing the resonance current have been proposed (for example, Patent Document 1 and the like).

However, if complicated control and circuit elements are required to suppress the resonance current, or if circuit constants such as switching speed are adjusted, the performance of the entire power converter will deteriorate and it will be difficult to design the device. There is a risk of becoming.

Japanese Unexamined Patent Publication No. 2003-70263

The embodiment provides a power conversion device having a simple configuration and capable of suppressing a resonance current without lowering the conversion efficiency of the power conversion device.

The power converter according to the embodiment includes a plurality of converters connected in parallel to which a DC voltage can be applied via a circuit breaker, and a first capacitor to which the DC voltage is applied to both ends. Each of the plurality of converters is connected between a pair of DC terminals to which the DC voltage is applied, an AC terminal that outputs and inputs an AC voltage, and the pair of DC terminals and the AC terminal. The conversion circuit, the second capacitor connected between the pair of DC terminals and the conversion circuit, and the current flow from the AC terminal to the DC terminal on the high potential side of the pair of DC terminals. It includes a connected diode and a resistor connected between the DC terminal of any one of the pair of DC terminals and the second capacitor.

In the present embodiment, a power conversion device capable of suppressing the resonance current without lowering the conversion efficiency of the power conversion device is realized with a simple configuration.

It is a block diagram which illustrates the power conversion apparatus which concerns on 1st Embodiment. It is a block diagram which illustrates the power conversion apparatus of the comparative example. It is a block diagram which illustrates the power conversion apparatus which concerns on 2nd Embodiment. It is a block diagram which illustrates the power conversion apparatus of the comparative example.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the ratio of the sizes between the parts, and the like are not necessarily the same as the actual ones. Further, even when the same parts are represented, the dimensions and ratios may be different from each other depending on the drawings.
In addition, in the present specification and each figure, the same elements as those described above with respect to the above-mentioned figures are designated by the same reference numerals, and detailed description thereof will be omitted as appropriate.

(First Embodiment)
FIG. 1 is a block diagram illustrating an electric power conversion device according to the present embodiment.
As shown in FIG. 1, the power conversion device 10 of the embodiment is connected to the DC circuit 1 via terminals 11a and 11b. The DC circuit 1 is connected to the power conversion device 10 via the cutoff device 50. The DC circuit 1 includes, for example, a DC power supply. The DC power supply may be one that is converted into a DC voltage by rectifying an AC voltage or the like, or another DC power supply, for example, a power storage device including a power source or a battery generated by a solar power generation panel or the like. It may be.

The term "terminal" is not limited to the connection point when connecting using a terminal block, etc., but is also used when screwing to a wiring member such as a bus bar, fastening with bolts and nuts, direct soldering, welding, etc. It shall include the connection point.

The power conversion device 10 is connected to the DC circuit 2 via the terminals 11c and 11d. The DC circuit 2 includes a smoothing capacitor (not shown). The DC circuit 2 includes, for example, a DC power supply. The DC power source is a storage battery, in which case the storage battery may also serve as a smoothing capacitor. The terminals 11c and 11d are connected.

The power converter 10 is a DC-DC converter that converts a DC voltage V1 input from the DC circuit 1 into a DC voltage V2 and outputs the DC voltage V1 to the DC circuit 2. In this example, the magnitude of the DC voltage V1 is larger than the magnitude of the DC voltage V2, and the power converter 10 operates as a step-down DC-DC converter.

The power conversion device 10 can also input the DC voltage V2 input from the DC circuit 2, convert it to the DC voltage V1, and output it to the DC circuit 1. In this case, the power converter 10 operates as a step-up DC-DC converter.

Whether the power converter 10 operates as a step-down DC-DC converter or a step-up DC-DC converter is appropriately controlled by a control device (not shown).

The cutoff device 50 is connected to the DC circuit 1 via terminals 51a and 51b. The cutoff device 50 is connected to the power conversion device 10 via the terminals 51c and 51d. In this example, the circuit breaker 50 has a circuit breaker 52 connected in series between the terminals 51a and 51c. The circuit breaker 52 is, for example, a DC high-speed vacuum circuit breaker. The circuit breaker 52 opens the circuit and cuts off the current when the current exceeding the set current value continues for a predetermined period. For example, when the DC power supply side is short-circuited, that is, when the terminals 51a and 51b are short-circuited and a current exceeding the current value set in the circuit breaker 52 flows, the circuit breaker 52 opens the circuit and causes the circuit breaker 52. Along with the flowing current, the current flowing through the power converter 10 is cut off.

The power converter 10 includes converters 21 to 23. The three converters 21 to 23 are connected in parallel by a pair of terminals (a pair of DC terminals) 21a to 23a and 21b to 23b. Specifically, the terminals (DC terminals) 21a to 23a connected to the DC circuit 1 of the converters 21 to 23 are connected to each other, and the terminals (DC terminals) 21b to 23b are also connected to each other. The terminals 21c to 23c connected to the DC circuit 2 of the converters 21 to 23 are connected to each other.

The converters 21 to 23 are connected to the terminals 11a of the power converter 10 via the terminals 21a to 23a, and are connected to the terminals 11b of the power converter 10 via the terminals 21b to 23b.

An inductor 12 is connected in series between the terminals 11a and the terminals 21a to 23a. A capacitor (first capacitor) 13 is connected in parallel between the terminals 21a to 23a and the terminals 21b to 23b. The inductor 12 and the capacitor 13 form an L-shaped filter. The filter including the inductor 12 and the capacitor 13 removes unnecessary noise from the DC voltage between the terminals 11a and 11b. Of these, the inductor 12 also has a role of limiting the short-circuit current when a short-circuit accident occurs on the DC circuit 1 side, which will be described later.

In the power converter 10, inductors 41 to 43 are connected in series between the outputs of the converters 21 to 23 and the terminals 11c and 11d, respectively. One ends of the inductors 41 to 43 are connected to terminals 21c to 23c of the converters 21 to 23, respectively. The other ends of the inductors 41 to 43 are connected to each other and connected to the terminal 11c. The inductors 41 to 43 pass a current according to the voltage between the terminals 21c and 11c.

A circuit breaker 44 is connected in series between the connection ends of the inductors 41 to 43 and the terminal 11c. The circuit breaker 44 opens a circuit to cut off an excessive current when the current flowing through the terminals 11c and 11d of the power conversion device 10 exceeds a predetermined value.

The converter 21 includes a resistor 210, switching elements 211 and 212, diodes 213 and 214, and a capacitor 215. The converter 22 includes a resistor 220, switching elements 221 and 222, diodes 223 and 224, and a capacitor 225. The converter 23 includes a resistor 230, switching elements 231 and 232, diodes 233 and 234, and a capacitor 235. The converters 21 to 23 have different codes, but all the components are the same. When explaining the configurations of the converters 21 to 23, one of them, the converter 21, will be described, and the description of the configurations of the other converters 22 and 23 will be omitted as appropriate. The same applies to other embodiments and comparative examples described later.

The switching elements 211 and 212 of the converter 21 are connected in series. The diodes 213 and 214 are connected to the switching elements 211 and 212 in antiparallel, respectively. The capacitor (second capacitor) 215 is connected in parallel to the series circuit (conversion circuit) of the switching elements 211 and 212. The parallel circuit of the switching elements 211 and 212 and the capacitor 215 is connected between the terminals 21a and the terminals 21b. Terminals 21c are connected to the connection nodes of the switching elements 211 and 212.

The resistor 210 is connected in series between the terminal 21a and the terminal 21c, and more specifically, is connected between the terminal 21a and the parallel circuit of the switching elements 211 and 212 and the capacitor 215. ..

When the power converter 10 operates as a step-down DC-DC converter, the switching element 211 is turned on and the switching element 212 is turned off to supply a current from the DC circuit 1 and the switching element 211 to the DC circuit 2 via the inductor 41. To do. Following the switching element turning off, the switching element 212 turns on and supplies a current to the DC circuit 2 so as to release the energy stored in the inductor 41.

When the power converter 10 operates as a step-up DC-DC converter, the switching element 212 is turned on and the switching element 211 is turned off, and energy is stored in the inductor 41 from the DC circuit 2. Following the switching element 212 turning off, the switching element 211 turns on and supplies a current to the DC circuit 1 so as to release the energy stored in the inductor 41.

Here, the diode 213 connected in antiparallel to the switching element 211 is provided to supply a current from the inductor 41 to the DC circuit 1 during the boosting operation. The diode 214 connected in antiparallel to the switching element 212 is provided to supply a current from the inductor 41 to the DC circuit 2 during the step-down operation.

In this way, the converter 21 converts the DC voltage V1 supplied from the DC circuit 1 into the DC voltage V2 and supplies it to the DC circuit 2. Further, the converter 21 converts the DC voltage V2 supplied from the DC circuit 2 into the DC voltage V1 and supplies it to the DC circuit 1.

The converters 21 to 23 control the DC voltage according to a gate signal from a control device (not shown), for example, by PWM control. The phases of the gate signals of the converters 21 to 23 are, for example, 120 ° out of phase and are multiplexed.

The operation of the power conversion device 10 of the present embodiment will be described.
First, the formation of the resonance loop will be described.
As described above, the converters 21 to 23 are connected in parallel, and the DC circuit 1 side and the DC circuit 2 side are connected to each other by a bus bar, wiring, or the like. Depending on the arrangement of the converters 21 to 23, the wiring length for connection differs for each converter.

The terminal 21a of the converter 21, the terminal 22a of the converter 22, and the terminal 23a of the converter 23 are connected to, for example, one terminal of the capacitor 13 by wirings 31a, 32a, 33a, respectively. The terminal 21b of the converter 21, the terminal 22b of the converter 22, and the terminal 23b of the converter 23 are connected to, for example, the other terminal of the capacitor 13 by wirings 31b, 32b, 33b, respectively. These wirings 31a to 33b each have a different length and therefore have different parasitic inductances.

The circuit composed of the parasitic inductance of the wirings 31a and 31b and the capacitors 215 and 13 forms a resonance loop, and a resonance current based on the inductance value and the capacitance value can flow. The circuit composed of the parasitic inductance of the wirings 32a and 32b and the capacitors 225 and 13 forms another resonance loop, and a resonance current based on the inductance value and the capacitance value can flow. Another resonance loop may be formed in the circuit including the wirings 33a and 33b and the capacitors 235 and 13, and the resonance current may flow based on the inductance value and the capacitance value. Not only are all these resonance loops electrically connected via the capacitor 13, but they are also magnetically coupled depending on the arrangement of the wiring, so that they may exhibit complicated behavior. When an excessive resonance current flows through these resonance loops, it may adversely affect the external circuit, the control circuit of the power conversion device 10, and the like. Further, an excessive resonance current may cause overheating of various circuit elements and wiring existing on the resonance loop.

The resistors 210 to 230 are each inserted in series in the above-mentioned resonance loop. Therefore, the resistors 210 to 230 function as a damping resistor when a resonance current flows through the resonance loop, so that the influence of the resonance current can be suppressed.

Next, the operation when a short-circuit accident occurs on the side of the DC circuit 1 will be described.
Specifically, the short-circuit accident on the side of the DC circuit 1 is assumed to be a case where the terminals 51a and 51b of the breaking device 50 are short-circuited. When the output of the DC circuit 1 is short-circuited, that is, when the terminals 51a and 51b of the breaking device 50 are short-circuited and the DC power supply of the DC voltage V2 is connected between the terminals 11c and 11d of the power conversion device 10. , The following current path is formed. However, it is assumed that the power conversion device 10 is stopped and all the switching elements are in the off state.

Regarding the converter 21, the terminal 11c, the circuit breaker 44, the inductor 41, the terminal 21c, the diode 213, the resistor 210, the terminal 21a, the terminal 11a, the terminal 51c, the circuit breaker 52, the terminal 51a, the terminal 51b, the terminal 51d, and the terminal 11b. , And a short-circuit current flows along the path of the terminal 11d.

Regarding the converter 22, the terminal 11c, the circuit breaker 44, the inductor 42, the terminal 22c, the diode 223, the resistor 220, the terminal 22a, the terminal 11a, the terminal 51c, the circuit breaker 52, the terminal 51a, the terminal 51b, the terminal 51d, and the terminal 11b. , And a short-circuit current flows along the path of the terminal 11d.

Regarding the converter 23, the terminal 11c, the circuit breaker 44, the inductor 43, the terminal 23c, the diode 233, the resistor 230, the terminal 23a, the terminal 11a, the terminal 51c, the circuit breaker 52, the terminal 51a, the terminal 51b, the terminal 51d, the terminal 11b. , And a short-circuit current flows along the path of the terminal 11d.

That is, the short-circuit current is diverted to the converters 21 to 23 and flows. The short-circuit current that flows separately from the converters 21 to 23 flows through the diodes 213, 223, and 233, then flows to the DC circuit 1 side via the resistors 210 to 230, and flows to the DC circuit 2 side.

The resistance value of the resistors 210 to 230 is determined according to the current in which the short-circuit current is divided and flows. More specifically, it is set to a value that limits the current that flows through the converters 21 to 23 before the circuit breaker 52 or the circuit breaker 44 starts operating and cuts off the short-circuit current. That is, by assuming that the currents diverted to each of the converters 21 to 23 are substantially equal, a resistor having a resistance value three times the resistance value required for limiting the short-circuit current, that is, a resistance value several times in parallel is provided.

In this way, the resistors 210 to 230 are connected in series to the resonance loops formed for each of the converters 21 to 23 connected in parallel, and function as a damping resistor. At the same time, the resistors 210 to 230 also function as a short-circuit current limiting resistor in the event of a short-circuit accident.

The effect of the power conversion device 10 of the present embodiment will be described with reference to a comparative example.
A power conversion device of a comparative example will be described.
FIG. 2 is a block diagram illustrating a power conversion device of a comparative example.
As shown in FIG. 2, the power conversion device 110 of the comparative example is connected to the breaking device 150 via the terminals 111a and 111b, and the breaking device 150 is connected to the DC circuit 1. The circuit breaker 150 includes a circuit breaker 52 and a resistor 500. The circuit breaker 52 and the resistor 500 are connected in series. The circuit breaker 52 and the resistor 500 connected in series are connected in series between the terminal 150a connected to the DC circuit 1 and the terminal 150c connected to the power conversion device 110.

The power converter 110 of the comparative example has converters 121 to 123. The converters 121 to 123 are connected to each other at terminals 121a to 123a and 121b to 123b, and are connected to each other at terminals 121c to 123c. The converters 121 to 123 are different from the above-described embodiment in that they do not include resistors 210 to 230, and have the same circuit configuration as the above-described embodiment in other respects.

In the case of this comparative example, since the resistor 500 has the resistor 500 in which the resistor 500 is inserted in series with the power converter 110, the short-circuit current at the time of short-circuiting of the DC circuit 1 can be limited. On the other hand, the resonance current can be damped by further inserting a resistor between the terminals 121a and 121c of the converter 121, between the terminals 122a and 122c of the converter 122, and between the terminals 123a and 123c of the converter 123, respectively. However, since the loss is generated by all the resistors including the resistor 500, the conversion efficiency of the whole including the power converter 110 and the breaking device 150 is lowered.

On the other hand, in the power converter 10 of the present embodiment, the converters 21 to 23 function as a damping resistor in the resonance loop, and the resistors 210 to 230 also function as a current limiting resistor in the event of a short circuit accident.

Therefore, in the power conversion device 10 of the present embodiment, the resonance current can be suppressed and the short-circuit current at the time of a short-circuit accident can be limited without lowering the overall conversion efficiency including the breaking device 50. ..

(Second Embodiment)
In the case of the above-described embodiment, the resistor is inserted on the high potential side, but the same effect can be obtained by inserting the resistor on the low potential side.
FIG. 3 is a block diagram illustrating an electric power conversion device according to the present embodiment.
As shown in FIG. 3, the power conversion device 310 of the present embodiment is connected to the cutoff device 50 via the terminals 311a and 311b, and is connected to the DC circuit 2 via the terminals 311c and 311d. The power converter 310 includes converters 321 to 323. In the present embodiment, the configurations of the converters 321 to 323 are different from those of the other embodiments described above, and are otherwise the same as those of the other embodiments described above. The same components are designated by the same reference numerals, and detailed description thereof will be omitted as appropriate.

The converter 321 includes a resistor 210, switching elements 211 and 212, diodes 213 and 214, and a capacitor 215. In the case of this embodiment, the resistor 210 is connected to the low potential side. The resistor 210 is connected between the terminals 321b and 321d. Further, the terminals 321d, 322d, and 323d are connected to each other and are connected to the terminal 311d.

Also in this embodiment, the resistors 210-230 function as damping resistors in the resonant loop of the transducers 321-23, the capacitors 13, and the wiring connecting them. Then, even when the DC circuit 1 is short-circuited and the DC circuit 2 supplies the DC voltage V2, the resistors 210 to 230 can limit the current obtained by dividing the short-circuit current.

FIG. 4 is a block diagram illustrating a power conversion device of a comparative example.
As shown in FIG. 4, in the power converter 410 of this comparative example, the configurations of the converters 121 to 123 are the same as those of FIG. 2 described above. In this power conversion device 410, the connection of the terminal 411d is different from that of FIG. The terminal 411d is connected to the terminals 121d, 122d, 123d of the converters 121, 122, 123.

The power conversion device 410 is connected to the breaking device 450 via terminals 411a and 411b, and is connected to the DC circuit 2 via terminals 411c and 411d.

The circuit breaker 450 has a circuit breaker 52 and a resistor 500. The circuit breaker 52 is connected between the terminals 451a and 451c. The resistor 500 is connected between the terminals 451b and 451d.

When the DC circuit 1 is short-circuited and the DC voltage V2 is supplied from the DC circuit 2, the short-circuit current is diverted to each of the converters 121 to 123, passes through the respective converters 121 to 123, and then the terminals 121a to It merges with the wiring connected to 123a, 121b to 123b and flows into the breaking device 450. The resistor 500 limits the short circuit current until the circuit breaker 52 or circuit breaker 44 of the circuit breaker 450 opens the circuit.

As described above, in the power conversion device 410 of the comparative example, the short-circuit current can be limited by the resistor 500 as in the case of the comparative example described above. However, it is difficult to reduce the resonance current because a resonance loop is formed by the capacitors 215, 225, 235, the wiring, and the capacitor 13 of the converters 121 to 123. By inserting a resistor in each resonance loop, it is possible to dampen the resonance current, but the overall conversion efficiency including the breaking device 450 will decrease.

On the other hand, in the power conversion device 310 of the present embodiment, the resistors 210 to 230 are inserted in the resonance loops of the converters 321 to 323. The resistors 210 to 230 function as a damping resistance against the resonance current, and even when the DC circuit 1 is short-circuited, the short-circuit current is diverted to the converter to limit the short-circuit current.

In the above description, an example in which three converters are connected in parallel has been described, but the number of converters in parallel is not limited to three, and may be two or four or more. Further, preferably, the output capacities of the converters connected in parallel are equal, but the output capacities are not necessarily limited to the same output capacities.

Further, in the above description, an example in the case of a bidirectional DC-DC converter has been described, but another side in which one side of the power conversion device causes a short circuit accident and a short circuit current flows due to the voltage applied to the other side. It also applies to the configuration. For example, the present invention is not limited to a bidirectional DC-DC converter, and may be a unidirectional DC-DC converter, an AC-DC converter, or an inverter.

The circuit configuration of the converter may also be another configuration in which a current path is formed from one terminal to the other terminal. For example, it may have a full bridge configuration, a neutral point clamp method, a flying capacitor method, or the like.

The diode 213 forming the current path from one terminal to the other terminal is not limited to the case where it is connected to the switching element 211 which is an IGBT, and may be a parasitic diode or the like of a MOSFET when the switching element is a MOSFET. Good.

Further, in the above description, the circuit breaker 52 is provided outside the power conversion devices 10 and 310, but may be provided inside the power conversion device.

According to the embodiment described above, it is possible to realize a power conversion device capable of suppressing the resonance current without lowering the conversion efficiency of the power conversion device.

Although some embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention and its equivalents described in the claims. In addition, the above-described embodiments can be implemented in combination with each other.

1,2 DC circuit, 10 Power converter, 12 Inductor, 13 Capacitor, 21-23, 321-23 23 Converter, 21a-23a, 21b-23b, 21c-23c, 21d-23d, 321a-323a, 321b-323b , 321c to 323c, 321d to 323d terminals, 31a to 33a, 31b to 33b wiring, 41 to 43 inductors, 44 circuit breakers, 50 circuit breakers, 52 circuit breakers, 210, 220, 230 resistors, 211,212,221 222,231,232 switching elements, 213,214,223,224,233,234 diodes

Claims (5)

Multiple converters connected in parallel, to which a DC voltage can be applied through a circuit breaker,
The first capacitor to which the DC voltage is applied to both ends and
With
Each of the plurality of converters
The pair of DC terminals to which the DC voltage is applied and
With an AC terminal that outputs and inputs AC voltage,
A conversion circuit connected between the pair of DC terminals and the AC terminal,
A second capacitor connected between the pair of DC terminals and the conversion circuit,
A diode connected so that a current flows from the AC terminal to the DC terminal on the high potential side of the pair of DC terminals.
A resistor connected between the DC terminal of any one of the pair of DC terminals and the second capacitor, and
Power converter including. The power conversion device according to claim 1, wherein the resistor is connected between the DC terminal on the high potential side of the pair of DC terminals and the second capacitor. The power conversion device according to claim 1, wherein the resistor is connected between the DC terminal on the low potential side of the pair of DC terminals and the second capacitor. The first terminal to which the high potential side of the DC voltage can be applied via the circuit breaker,
A second terminal to which the low potential side of the DC voltage can be applied, and
The third terminal to which the first AC voltage is output or input, and
A first diode connected between the first terminal and the third terminal so that a current flows from the third terminal toward the first terminal.
A first resistor connected between the first terminal and the first diode,
A first capacitor connected between the first terminal and the second terminal,
1st converter including
The fifth terminal connected to the first terminal via the first wiring and
With the sixth terminal connected to the second terminal via the second wiring,
A seventh terminal to which a second AC voltage having a phase different from that of the first AC voltage is output or input, and
The eighth terminal connected to the fourth terminal and
A second diode connected between the fifth terminal and the seventh terminal so that a current flows from the seventh terminal toward the fifth terminal.
A second resistor connected between the seventh terminal and the second diode,
A second capacitor connected between the fifth terminal and the sixth terminal,
2nd converter including
A third capacitor connected between the first wiring and the second wiring,
Power converter equipped with. The first terminal to which the high potential side of the DC voltage can be applied via the circuit breaker,
A second terminal to which the low potential side of the DC voltage can be applied, and
The third terminal to which the first AC voltage is output or input, and
With the 4th terminal
A first diode connected between the first terminal and the third terminal so that a current flows from the third terminal toward the first terminal.
A first resistor connected between the second terminal and the fourth terminal,
A first capacitor connected between the first terminal and the second terminal,
1st converter including
The fifth terminal connected to the first terminal via the first wiring and
With the sixth terminal connected to the second terminal via the second wiring,
A seventh terminal to which a second AC voltage having a phase different from that of the first AC voltage is output or input, and
The eighth terminal connected to the fourth terminal and
A second diode connected between the fifth terminal and the seventh terminal so that a current flows from the seventh terminal toward the fifth terminal.
A second resistor connected between the 7th terminal and the 8th terminal,
A second capacitor connected between the fifth terminal and the sixth terminal,
2nd converter including
A third capacitor connected between the first wiring and the second wiring,
Power converter equipped with.

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