JP2023053810A - Power conversion device - Google Patents

Abstract

A power conversion device capable of suppressing an increase in size of the power conversion device when power conversion units are connected in series on the output side of an inverter section is provided. A power conversion device (100) includes an inverter section (30) that converts a DC voltage into an AC voltage by switching a plurality of semiconductor switching elements (31a to 31d). A plurality of stacks 40 (power conversion units) are provided to configure a unit series connection section 41 by being connected. Further, in the power conversion device 100, by grounding the bus bar 80 (inter-unit connection wiring) that is wiring that connects the stacks 40 that are connected in series with each other, the positive side potential and the negative side potential of the unit series connection portion 41 and an intermediate grounding portion 50 for setting the intermediate potential between the and the ground potential. [Selection drawing] Fig. 1

Description

TECHNICAL FIELD The present invention relates to a power conversion device, and more particularly to a power conversion device including a plurality of power conversion units each including an inverter section.

2. Description of the Related Art Conventionally, a power conversion device including a plurality of power conversion units each including an inverter section has been disclosed (see Patent Document 1, for example).

The above Patent Document 1 discloses a power conversion device provided with a plurality of stacks (power conversion units) each including a smoothing capacitor and an inverter section having a plurality of semiconductor switch elements. In the above power converter, the stacks are connected in series with each other on the output side of the inverter section, so that the voltage supplied from the power converter to the load can be higher than the peak voltage of each stack. Therefore, power transmission loss to the load can be suppressed as compared with the case where the same number of power converters are connected in parallel.

JP 2020-171153 A

In a power conversion device such as that disclosed in Patent Document 1, the housing is grounded to prevent electric shock to the user, and the housing is set to ground potential. In the above Patent Document 1, since a voltage higher than the peak voltage of each stack (for example, twice the peak voltage) is applied to the inverter section, the insulation distance from the housing (ground potential) in the inverter section is should be larger than when connected to For this reason, it is conceivable that the size of the power converter is increased. Therefore, when stacks (power conversion units) are connected in series on the output side of the inverter section, it is desired to suppress the increase in size of the power converter.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and one object of the present invention is to provide a power conversion apparatus in which power conversion units are connected in series to each other on the output side of an inverter section. An object of the present invention is to provide a power converter capable of suppressing an increase in size.

In order to achieve the above object, a power converter according to one aspect of the present invention includes inverter sections that output AC voltages by switching a plurality of semiconductor switching elements, and the output sides of the inverter sections are connected in series with each other. By grounding a plurality of power conversion units constituting the unit series connection section and inter-unit connection wiring that connects the power conversion units connected in series with each other, the positive side of the unit series connection section is grounded. and an intermediate grounding portion for setting an intermediate potential between the potential and the negative potential to the ground potential.

As described above, the power converter according to one aspect of the present invention is provided with the intermediate grounding portion that sets the intermediate potential between the positive side potential and the negative side potential of the unit series connection portion to the ground potential. This makes it possible to reduce the potential difference between the negative potential of the serially connected unit and the ground potential, compared to the case where the positive potential of the serially connected unit is set to the ground potential, for example. The same is true when the negative potential of the unit series connection portion is set to the ground potential. As a result, compared to the case where the positive or negative potential of the unit series connection is set to the ground potential, the insulation distance from the ground can be reduced in the inverter section, so the size of the power converter increases accordingly. can be suppressed. Therefore, when the power conversion units are connected in series on the output side of the inverter section, it is possible to suppress an increase in the size of the power converter.

In the power conversion device according to the above aspect, the intermediate grounding section is preferably provided so as to ground the inter-unit connection wiring via the resistive element. With this configuration, the resistance element can reduce the ground fault current that flows when a ground fault occurs in the power converter. As a result, it is possible to suppress the flow of a large ground fault current, thereby suppressing the occurrence of an abnormality in the power converter.

In the power conversion device according to the above aspect, preferably, the inter-unit connection wiring grounded by the intermediate grounding section is provided to connect the inverter sections of the power conversion units connected in series with each other. . With this configuration, the intermediate potential between the inverter sections of the power conversion units connected in series can be set to the ground potential by the intermediate ground section through the inter-unit connection wiring.

In this case, preferably, the inter-unit connection wiring grounded by the intermediate grounding section is provided so as to connect the plurality of power conversion units in series by connecting the output terminals of the inverter section. With this configuration, the wiring used to connect the power conversion units in series can be used as the inter-unit connection wiring used for grounding. number) can be reduced.

In the power conversion device in which the inter-unit connection wiring connects the output terminals of the inverter section, the plurality of power conversion units preferably includes a first power conversion unit and a second power conversion unit connected in series with each other. , the inverter section of each of the first power conversion unit and the second power conversion unit is connected in series with a first series circuit composed of a first semiconductor switching element and a second semiconductor switching element connected in series with each other. A second series circuit composed of a third semiconductor switching element and a fourth semiconductor switching element are connected in parallel to each other. It is provided to connect the output end of the second series circuit in the full bridge circuit of one power conversion unit and the output end of the first series circuit in the full bridge circuit of the second power conversion unit. With this configuration, the intermediate potential between the output terminal of the second series circuit of the first power conversion unit and the output terminal of the first series circuit of the second power conversion unit is transferred via the inter-unit connection wiring. It can be grounded by an intermediate grounding portion.

In the power converter in which the inter-unit connection wiring connects the inverter sections, the inter-unit connection wiring is preferably provided so as to connect the input ends of the inverter sections. With this configuration, the potential between the input terminals of the inverter section can be set to the ground potential by the intermediate ground section through the inter-unit connection wiring.

In this case, preferably, the plurality of power conversion units includes a first power conversion unit and a second power conversion unit that are connected in series with each other, and the inter-unit connection wiring is connected to the positive side of the inverter section in the first power conversion unit. the positive side wiring of the first power conversion unit connected to the side input terminal; the positive side wiring of the second power conversion unit connected to the positive side input terminal of the inverter section in the second power conversion unit; The negative wire of the first power conversion unit connected to the negative input terminal of the inverter section in the conversion unit, and the negative pole of the second power conversion unit connected to the negative input terminal of the inverter section of the second power conversion unit. It is provided so as to connect with the side wiring. With this configuration, the positive electrode side wiring of each of the first power conversion unit and the second power conversion unit and the negative electrode side wiring of each of the first power conversion unit and the second power conversion unit are connected by the inter-unit connection wiring. Since they are connected, the intermediate potential between the positive side potential and the negative side potential of the power conversion device can be easily set to the ground potential by the intermediate ground portion through the inter-unit connection wiring.

In the power conversion device in which the inter-unit connection wiring connects the positive electrode side wiring and the negative electrode side wiring, preferably, the inter-unit connection wiring has an anode connected to the positive electrode side wiring of the first power conversion unit. a pair of positive diode units including a first diode and a second diode having an anode connected to the positive electrode wiring of the second power conversion unit and having a cathode connected to the cathode of the first diode; a third diode having a cathode connected to the negative wiring of the power conversion unit; and a fourth diode having a cathode connected to the negative wiring of the second power conversion unit and having an anode connected to the anode of the third diode. and a pair of negative diode sections including a diode, and the intermediate ground section is provided to ground the inter-diode wiring that connects the pair of positive side diode sections and the pair of negative side diode sections. ing. With this configuration, the pair of positive diode sections prevents the positive wiring of the first power conversion unit and the positive wiring of the second power conversion unit from being electrically connected, and the pair of negative diode sections prevents the positive side wiring of the first power conversion unit from being electrically connected to the positive side wiring of the second power conversion unit. While preventing the negative electrode side wiring of the first power conversion unit and the negative electrode side wire of the second power conversion unit from being electrically connected by can be done.

In this case, preferably, a pair of capacitors are provided on the inter-diode wiring, and the intermediate ground portion is provided so as to ground a portion of the inter-diode wiring between the pair of capacitors. With this configuration, the current flowing through the intermediate grounding portion charges the pair of capacitors, so that it is possible to prevent the current flowing through the intermediate grounding portion from continuing to flow to the ground and consuming power.

ADVANTAGE OF THE INVENTION According to this invention, as mentioned above, when connecting a power inverter unit mutually in series in the output side of an inverter part, it can suppress that a power converter device becomes large.

1 is a circuit diagram of a power conversion device according to a first embodiment; FIG. It is a figure which changes in the voltage of each wiring of the power converter device by 1st Embodiment. 1 is a perspective view of a power converter according to a first embodiment; FIG. 1 is a side view of a power conversion device according to a first embodiment; FIG. It is a circuit diagram of a power conversion device according to a second embodiment.

Embodiments embodying the present invention will be described below with reference to the drawings.

[First embodiment]
The configuration of a power converter 100 according to the first embodiment will be described with reference to FIGS. 1 and 2. FIG. The power conversion device 100 is a device for an induction heating device 200 used in a melting furnace that melts metal by induction heating. The power conversion device 100 is supplied with AC power from an AC power supply 300 .

(Circuit configuration of power converter)
First, the circuit configuration of the power converter 100 will be described with reference to FIG.

As shown in FIG. 1, the power converter 100 includes a plurality of rectifier circuits 10 (rectifier circuits 10a and 10b). The power conversion device 100 also includes a plurality of stacks 40 (stacks 40a, 40b) including a plurality of smoothing capacitors 20 (smoothing capacitors 20a, 20b) and a plurality of inverter units 30 (inverter units 30a, 30b). . Stack 40a includes rectifier circuit 10a, smoothing capacitor 20a, and inverter section 30a. The stack 40b also includes a rectifier circuit 10b, a smoothing capacitor 20b, and an inverter section 30b. Note that the stack 40, the stack 40a, and the stack 40b are examples of the "power conversion unit" in the claims. Also, the stack 40a and the stack 40b are examples of the "first power conversion unit" and the "second power conversion unit" in the claims, respectively.

Rectifier circuit 10 converts an AC voltage input from AC power supply 300 into a DC voltage. The rectifier circuits 10 are provided in the same number as the plurality of stacks 40 . That is, a rectifier circuit 10a and a rectifier circuit 10b are provided for an AC power supply 300 (transformer 301). The DC voltage converted by the rectifier circuit 10a is supplied to the stack 40a. The DC voltage converted by the rectifier circuit 10b is supplied to the stack 40b.

The smoothing capacitor 20 is connected to the output side of the rectifier circuit 10 that rectifies the AC voltage. A smoothing capacitor 20 is provided for each rectifier circuit 10 . That is, smoothing capacitors 20a and 20b are connected to the output sides of rectifier circuits 10a and 10b, respectively.

Inverter section 30 (30a, 30b) includes a plurality of semiconductor switching elements 31a-31d. The inverter section 30 converts the DC voltage smoothed by the rectifier circuit 10 (10a, 10b) into an AC voltage by switching the plurality of semiconductor switching elements 31a to 31d. The AC voltage converted by the semiconductor switching element 31 is output from the inverter section 30 to the induction heating coil 210 of the induction heating device 200 . Also, the inverter unit 30 is provided for each rectifier circuit 10 . That is, inverter units 30a and 30b are provided for rectifier circuits 10a and 10b, respectively. The semiconductor switching element 31a and the semiconductor switching element 31b are examples of the "first semiconductor switching element" and the "second semiconductor switching element" in the claims, respectively. The semiconductor switching element 31c and the semiconductor switching element 31d are examples of the "third semiconductor switching element" and the "fourth semiconductor switching element" in the claims, respectively.

Each of semiconductor switching elements 31a to 31d is an IGBT (Insulated Gate Bipolar Transistor) element. Each of semiconductor switching elements 31a-31d may be, for example, a MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor).

Each of inverter section 30a and inverter section 30b includes a semiconductor module 32a and a semiconductor module 32b. The semiconductor module 32a accommodates a semiconductor switching element 31a and a semiconductor switching element 31b. Semiconductor switching element 31c and semiconductor switching element 31d are housed in semiconductor module 32b.

Although not shown in FIG. 1, each of the semiconductor modules 32a and 32b has a plurality of semiconductor modules connected in parallel. For example, each of the semiconductor modules 32a and the semiconductor modules 32b is provided for 6 parallels.

Each of the inverter units 30 of the stacks 40a and 40b includes a series circuit 33a including a semiconductor switching element 31a and a semiconductor switching element 31b connected in series, a semiconductor switching element 31c connected in series and a semiconductor switching element 31b. A series circuit 33b consisting of a switching element 31d and a full bridge circuit are connected in parallel with each other. That is, the series circuit 33a and the series circuit 33b are housed in the semiconductor module 32a and the semiconductor module 32b, respectively. The series circuit 33a and the series circuit 33b are examples of the "first series circuit" and the "second series circuit" in the claims, respectively.

A plurality of stacks 40 ( 40 a, 40 b ) are connected in series with each other on the output side of the inverter section 30 to form a unit series connection section 41 . The power conversion device 100 is also provided with a bus bar 80 that is a wiring that connects the stacks 40a and 40b that are connected in series with each other. The bus bar 80 is an example of "inter-unit connection wiring" in the scope of claims.

An output terminal A provided at a connection point between the semiconductor switching elements 31a and 31b of the inverter section 30a is electrically connected to one end of the induction heating coil 210 via a capacitor 211. . An output terminal B provided at a connection point between the semiconductor switching element 31c and the semiconductor switching element 31d of the inverter section 30b is electrically connected to the other end of the induction heating coil 210 via a capacitor 212. .

Here, in the first embodiment, the power conversion device 100 grounds the bus bar 80, thereby setting the intermediate potential between the positive side potential and the negative side potential of the unit series connection portion 41 to the ground potential. 50. Specifically, the intermediate potential of the unit series connection portion 41 becomes the ground potential (that is, 0=ground potential in FIG. 2) by setting the potential of the bus bar 80 to the ground potential by the intermediate ground portion 50 . As a result, the absolute value of the maximum potential and the absolute value of the minimum potential at the unit series connection portion 41 become equal to the ground potential. That is, assuming that the potential difference between the maximum potential and the minimum potential at the unit series connection portion 41 is 2Vp, the maximum potential and the minimum potential are Vp and -Vp, respectively. Therefore, the ground potential at the unit series connection portion 41 (power converter 100) is Vp. Note that the ground potential Vp (intermediate potential) in the unit series connection portion 41 (power conversion device 100) is not necessarily the positive potential (Vp) and the negative potential (Vp) due to variations in impedance for each of the plurality of stacks 40 (40a, 40b). It does not become the middle potential with the potential (−Vp), and can fluctuate within a certain range. If this variation is large, the insulation distance between the power conversion device 100 and a case 60 described later may be insufficient, and the power conversion device 100 may be grounded. Therefore, it is necessary to minimize the deviation from the central potential. In the present embodiment, the structures of the plurality of stacks 40 (40a, 40b) are made common to each other, and the parts used for each stack 40 (40a, 40b) are made common to each other, whereby the plurality of stacks 40 (40a, 40b) 40b), it is possible to suppress variations in impedance for each. As a result, it is possible to minimize the deviation from the central potential.

In the power conversion device 100, no current flows to the ground (earth 53, which will be described later). Since the power converter 100 is grounded only at one point of the ground 53, unlike the case where two or more points are grounded, the current path passing through the ground points (the current path via the ground 53 ) is not formed. Moreover, when the wiring length of the input wiring of the power conversion device 100 is long, the neutral point of the input wiring may be grounded due to the stray capacitance of the input wiring. That is, two points, that is, the ground point (earth 53) of the power converter 100 and the neutral point of the input wiring are grounded. Even in this case, since the potential of the ground point (earth 53) of the power converter 100 is substantially the same potential as the neutral point, a current does not flow and no current path through ground 53 is formed.

Also, the intermediate ground portion 50 includes a resistive element 51 and a ground wiring 52 . The resistance element 51 is provided on the ground wiring 52 . Moreover, the resistance value of the resistance element 51 is about 50Ω. Also, the ground wiring 52 is a cable wiring (bundled wire). When a current sensor (not shown) detects that the current flowing through the resistance element 51 is equal to or greater than a predetermined value, a controller (not shown) determines that a ground fault has occurred.

Further, in the first embodiment, the intermediate grounding portion 50 is provided so as to ground the bus bar 80 via the resistance element 51 . Ground wiring 52 includes a first wiring 52 a connecting bus bar 80 and resistance element 51 and a second wiring 52 b connecting resistance element 51 and ground 53 . The first wiring 52a and the bus bar 80 are connected at a connection point E. As shown in FIG.

Further, in this embodiment, the bus bar 80 grounded by the intermediate grounding portion 50 is provided so as to connect the inverter portions 30 of the stacks 40 connected in series with each other.

Specifically, the bus bar 80 grounded by the intermediate grounding section 50 is provided so as to connect the plurality of stacks 40 in series by connecting the output terminal C and the output terminal D of the inverter section 30 . there is That is, the bus bar 80 has both functions (roles) of being grounded by the intermediate grounding portion 50 and connecting the stacks 40 in series.

Specifically, the bus bar 80 grounded by the intermediate grounding portion 50 connects the output terminal C of the series circuit 33b in the full bridge circuit of the stack 40a and the output terminal D of the series circuit 33a in the full bridge circuit of the stack 40b. provided for connection. Thus, when the semiconductor switching element 31a and the semiconductor switching element 31d are turned on and the semiconductor switching element 31b and the semiconductor switching element 31c are turned off, the bus bar 80 connects the negative electrode side wiring 42b of the stack 40a and the stack 40b. It is electrically connected to the positive electrode side wiring 42c. As a result, the negative voltage of the stack 40a (hereinafter referred to as voltage N1) and the positive voltage of the stack 40b (hereinafter referred to as voltage P2) are brought to the same potential. When the semiconductor switching elements 31a and 31d are turned off and the semiconductor switching elements 31b and 31c are turned on, the bus bar 80 connects the positive electrode wiring 42a of the stack 40a and the negative electrode of the stack 40b. 42 d of side wirings are electrically connected. As a result, the positive voltage of the stack 40a (hereinafter referred to as voltage P1) and the negative voltage of the stack 40b (hereinafter referred to as voltage N2) are brought to the same potential. Each of the positive electrode wiring 42a, the negative electrode wiring 42b, the positive electrode wiring 42c, and the negative electrode wiring 42d is configured by a bus bar.

Specifically, as shown in FIG. 2, when semiconductor switching element 31a and semiconductor switching element 31d are turned on and semiconductor switching element 31b and semiconductor switching element 31c are turned off, voltage P1 and voltage N2 are , respectively become Vp and -Vp, and each of voltage N1 and voltage P2 becomes 0 V, which is an intermediate potential between Vp and -Vp. In this case, voltage Vu across capacitor 211 and voltage Vv across capacitor 212 are Vp and -Vp, respectively.

When semiconductor switching element 31a and semiconductor switching element 31d are turned off and semiconductor switching element 31b and semiconductor switching element 31c are turned on, voltage N1 and voltage P2 become -Vp and Vp, respectively. Each of P1 and voltage N2 becomes 0 V, which is an intermediate potential between Vp and -Vp. In this case, voltage Vu of capacitor 211 and voltage Vv of capacitor 212 are -Vp and Vp, respectively.

As shown in FIG. 1, the positive electrode wiring 42a of the stack 40a is connected to the positive input terminal 34a of the inverter section 30a of the stack 40a. The positive input terminal 34a of the inverter section 30a means the positive terminals (collector terminals) of the semiconductor switching elements 31a and 31c of the inverter section 30a. Also, the negative-side wiring 42b of the stack 40a is connected to the negative-side input end 34b of the inverter section 30a in the stack 40a. The negative input terminal 34b of the inverter section 30a means the negative terminals (emitter terminals) of the semiconductor switching elements 31b and 31d of the inverter section 30a. The positive input terminal 34a and the negative input terminal 34b are examples of "input terminal" in the scope of claims.

Also, the positive-side wiring 42c of the stack 40b is connected to the positive-side input end 34c of the inverter section 30b in the stack 40b. The positive input terminal 34c of the inverter section 30b means the positive terminals (collector terminals) of the semiconductor switching elements 31a and 31c of the inverter section 30b. Also, the negative-side wiring 42d of the stack 40b is connected to the negative-side input terminal 34d of the inverter section 30b in the stack 40b. The negative input terminal 34d of the inverter section 30b means the negative terminals (emitter terminals) of the semiconductor switching elements 31b and 31d of the inverter section 30b. The positive input terminal 34c and the negative input terminal 34d are examples of "input terminal" in the claims.

(Overview of structure of power converter)
Next, the outline of the structure of the power converter 100 will be described with reference to FIGS. 3 and 4. FIG.

As shown in FIG. 3 , in power converter 100 , two stacks 40 (stack 40 a and stack 40 b ) are arranged side by side in the vertical direction (Z direction) in one housing 60 . The stacks 40a and 40b are arranged on the lower side (Z2 side) and the upper side (Z1 side) of the housing 60, respectively.

In the following description, the up-down direction, left-right direction, and front-rear direction of the housing 60 are defined as the Z direction, the X direction, and the Y direction, respectively. Moreover, the upward direction (upper side), downward direction (lower side), left side, right side, front side and rear side are defined as Z1 direction (Z1 side), Z2 direction (Z2 side), X1 side, X2 side, Y1 side and Y1 side, respectively. Y2 side.

Further, as shown in FIG. 4, the positive electrode wiring 42a and the negative electrode wiring 42b of the stack 40a and the positive electrode wiring 42c and the negative electrode wiring 42d of the stack 40b are orthogonal to the Z direction. 40b is configured to be substantially symmetrical with respect to a center plane 90 in the middle. That is, in the power conversion device 100, the structures within the plurality of stacks 40 (stacks 40a and 40b) (the shapes of the members within the stack 40 and the relative arrangement between the members within the stack 40) are substantially equal to each other. is configured to be

In addition, the busbar 80 has a shape along the Z direction and substantially symmetrical with respect to a center line 91 of the busbar 80 in the Y direction. The bus bar 80 is provided so as to connect the first portion 81 provided on the stack 40a side, the second portion 82 provided on the stack 40b side, and the first portion 81 and the second portion 82. a third portion 83;

As shown in FIG. 3, the resistive element 51 is provided to extend along the X direction below the stack 40a (Z2 side). As shown in FIG. 4, the first wiring 52a of the grounding wiring 52 connecting the bus bar 80 and the resistance element 51 connects the first portion 81 of the bus bar 80 and the terminal 51a of the resistance element 51 on the X1 side. . The first wiring 52a is wired along the housing 60 from the first portion 81 to the terminal 51a. By providing the connection point E between the first wiring 52a and the bus bar 80 in the center of the third portion 83 in the Z direction, the wiring distance between the stack 40a and the resistance element 51 and the distance between the stack 40b and the resistance element 51 may be configured to be uniform.

As shown in FIG. 3 , the second wiring 52 b of the wiring for grounding 52 connects the terminal 51 b on the X2 side of the resistance element 51 and the ground 53 . A ground 53 is provided on the Y1 side of the stack 40a. The second wiring 52b is wired from the terminal 51b of the resistance element 51 to the ground 53 along the housing 60 .

(Effect of the first embodiment)
The following effects can be obtained in the first embodiment.

In the first embodiment, as described above, by grounding the bus bar 80 that is the wiring that connects the stacks 40 that are connected in series with each other, the potential intermediate between the positive potential and the negative potential of the unit series connection portion 41 is obtained. The power conversion device 100 is configured to include an intermediate grounding section 50 that grounds the intermediate potential of . As a result, the potential difference between the negative potential of unit series connection portion 41 and the ground potential can be reduced compared to, for example, the case where the positive potential of unit series connection portion 41 is set to the ground potential. The same applies when the negative potential of the unit series connection portion 41 is set to the ground potential. As a result, compared to the case where the positive potential or the negative potential of the unit series connection portion 41 is set to the ground potential, the insulation distance from the ground in the inverter portion 30 can be reduced. Here, in the power conversion device 100, the housing 60 is grounded to prevent electric shock to the user, and the housing 60 is grounded. Therefore, by reducing the insulation distance from the housing 60 (ground potential) in the inverter unit 30, it is possible to suppress the power conversion device 100 from increasing in size. Therefore, when the stacks 40 are connected in series on the output side of the inverter section 30, it is possible to suppress the power conversion device 100 from increasing in size.

Further, in the first embodiment, the power converter 100 is configured such that the intermediate grounding portion 50 grounds the bus bar 80 via the resistance element 51 as described above. Thus, the resistance element 51 can reduce the ground fault current that flows when a ground fault occurs in the power converter 100 . As a result, it is possible to suppress the flow of a large ground fault current, thereby suppressing the occurrence of abnormality in the power converter 100 .

Further, in the first embodiment, as described above, the power conversion device 100 is configured such that the bus bar 80 grounded by the intermediate grounding portion 50 connects the inverter portions 30 of the stacks 40 connected in series with each other. configure. As a result, the intermediate potential between the inverter units 30 of the stacks 40 connected in series with each other can be grounded by the intermediate grounding unit 50 via the bus bar 80 .

In the first embodiment, as described above, the bus bar 80 grounded by the intermediate grounding section 50 connects the output terminals (C, D) of the inverter section 30 to each other, thereby connecting the plurality of stacks 40 to each other. The power electronics device 100 is configured to be connected in series. As a result, the wiring used to connect the stacks 40 in series can be used as the bus bar 80 used for grounding, so that the number of parts (the number of wirings) of the power conversion device 100 can be reduced. can.

In the first embodiment, as described above, the bus bar 80 grounded by the intermediate grounding portion 50 is connected to the output terminal C of the series circuit 33b in the full bridge circuit of the stack 40a and the series circuit in the full bridge circuit of the stack 40b. The power converter 100 is configured to connect the output end D of the circuit 33a. As a result, the intermediate potential between the output terminal C of the series circuit 33b of the stack 40a and the output terminal D of the series circuit 33a of the stack 40b can be grounded by the intermediate grounding section 50 via the bus bar 80. .

[Second embodiment]
A second embodiment will be described with reference to FIG. In this second embodiment, unlike the first embodiment, a plurality of stacks 40 are connected in series on the input side of the inverter section 30 . In the figure, the same reference numerals are given to the same configurations as those of the first embodiment, and the description thereof will be omitted.

(Circuit configuration of power converter)
A circuit configuration of the power conversion device 400 will be described with reference to FIG.

As shown in FIG. 5, the power conversion device 400 includes an inter-unit connection wiring 180 that is wiring that connects the stacks 40a and 40b that are connected in series with each other. Inter-unit connection wiring 180 includes wiring 181 , wiring 182 , wiring 183 , wiring 184 , and wiring 185 . Also, the inter-unit connection wiring 180 (181 to 185) is a cable wiring (bundle). The wiring 185 is an example of "inter-diode wiring" in the claims.

Here, in the second embodiment, the inter-unit connection wiring 180 is provided so as to connect the input terminals (34a to 34d) of the inverter section 30 to each other. Specifically, the inter-unit connection wiring 180 is connected to the input terminal ( 34a, 34b) and the input terminals (34c, 34d) of the inverter section 30b.

Specifically, the inter-unit connection wiring 180 is provided to connect the positive wiring 42a of the stack 40a and the positive wiring 42c of the stack 40b to the negative wiring 42b of the stack 40a and the negative wiring 42d of the stack 40b. It is As a result, the positive side input terminals (34a, 34c) of the inverter section 30 and the negative side input terminals (34b, 34d) of the inverter section 30 are connected to the positive side wiring 42a, the negative side wiring 42b, the positive side wiring 42c, the negative side wiring 42c, and the negative side wiring 42c. They are connected by the side wiring 42 d and the inter-unit connection wiring 180 .

The power conversion device 400 also includes an intermediate grounding section 150 that grounds the intermediate potential of the unit series connection section 41 by grounding the inter-unit connection wiring 180 . The intermediate ground portion 150 includes a resistive element 151 and a ground wire 152 connected to the ground. The resistance element 151 is provided on the ground wiring 152 . The resistance value of the resistance element 151 is about 50Ω. Also, the ground wiring 152 is a cable wiring (bundled wire). When a current sensor (not shown) detects that the current flowing through the resistance element 151 is equal to or higher than a predetermined value, the controller (not shown) determines that a ground fault has occurred.

In addition, even if the positive wiring 42a, the negative wiring 42b, the positive wiring 42c, or the negative wiring 42d is short-circuited while the inverter section 30 is stopped, the inter-unit connection wiring 180 is connected to the input terminal (34a to 34d), a current flows through the resistance element 151 via the inter-unit connection wiring 180, so a ground fault can be detected based on the value of the current flowing through the resistance element 151. FIG.

A pair of positive diode sections 153 are provided in the intermediate ground section 150 . The pair of positive diode portions 153 has a diode 153a having an anode connected to the positive electrode wiring 42a of the stack 40a, and an anode connected to the positive electrode wiring 42c of the stack 40b and connected to the cathode of the diode 153a. and a diode 153b having a cathode. A wiring 181 connects the positive electrode wiring 42a and the diode 153a. A wiring 182 connects the positive wiring 42c and the diode 153b. That is, the pair of positive diode portions 153 are provided on the inter-unit connection wiring 180 . The diode 153a and the diode 153b are examples of the "first diode" and the "second diode" in the claims, respectively.

A pair of negative diode sections 154 are provided in the intermediate ground section 150 . The pair of negative diode sections 154 has a diode 154a having a cathode connected to the negative wiring 42b of the stack 40a, and a cathode connected to the negative wiring 42d of the stack 40b and connected to the anode of the diode 154a. and a diode 154b having an anode. A wiring 183 connects the negative wiring 42b and the diode 154a. A wiring 184 connects the negative wiring 42d and the diode 154b. That is, the pair of negative diode sections 154 are provided on the inter-unit connection wiring 180 . The diode 154a and the diode 154b are examples of the "third diode" and the "fourth diode" in the claims, respectively.

Here, in the second embodiment, the intermediate grounding portion 150 is provided so as to ground the wiring 185 that connects the pair of positive side diode portions 153 and the pair of negative side diode portions 154 . Specifically, the wiring 185 and the ground wiring 152 are connected at the connection point F. As shown in FIG.

Intermediate ground portion 150 also includes a pair of capacitors 155 . A pair of capacitors 155 includes a capacitor 155a and a capacitor 155b. A pair of capacitors 155 are provided on the wiring 185 . The capacitance of each of capacitor 155a and capacitor 155b is approximately 1 μF.

Here, in the second embodiment, the intermediate grounding portion 150 is provided so as to ground a portion 185a of the wiring 185 between the pair of capacitors 155 (between the capacitors 155a and 155b). That is, the connection point F between the wiring 185 and the grounding wiring 152 is provided on the portion 185a of the wiring 185. As shown in FIG.

Other configurations of the second embodiment are the same as those of the first embodiment.

(Effect of Second Embodiment)
The following effects can be obtained in the second embodiment.

In the second embodiment, as described above, the power converter 400 is configured such that the inter-unit connection wiring 180 connects the input terminals (34a to 34d) of the inverter section 30 to each other. As a result, the potential between the input terminals (34a to 34d) of the inverter section 30 can be set to the ground potential by the intermediate ground section 150 through the inter-unit connection wiring 180. FIG.

In the second embodiment, as described above, the inter-unit connection wiring 180 includes the positive wiring 42a of the stack 40a and the positive wiring 42c of the stack 40b, the negative wiring 42b of the stack 40a and the negative wiring 42b of the stack 40b. The power conversion device 400 is configured to connect with the wiring 42d. As a result, the positive wiring (42a, 42c) of each of the stacks 40a and 40b and the negative wiring (42b, 42d) of each of the stacks 40a and 40b are connected by the inter-unit connection wiring 180. The intermediate potential between the positive side potential and the negative side potential of the power conversion device 400 can be easily grounded by the intermediate ground portion 150 via the inter-unit connection wiring 180 .

In addition, in the second embodiment, as described above, the power conversion device 400 is configured such that the intermediate grounding section 150 grounds the wiring 185 connecting the pair of positive side diode sections 153 and the pair of negative side diode sections 154 to the ground. configure. Thus, the pair of positive diode portions 153 prevents the positive electrode wiring 42a of the stack 40a and the positive electrode wiring 42c of the stack 40b from being electrically connected, and the pair of negative diode portions 154 prevents the negative electrode side of the stack 40a from being electrically connected. The intermediate potential, which is the potential of the wire 185, can be grounded by the intermediate ground portion 150 while preventing the wire 42b and the negative wire 42d of the stack 40b from being electrically connected.

Further, in the second embodiment, as described above, the power conversion device 400 is configured such that the intermediate grounding section 150 grounds the portion 185a of the wiring 185 between the pair of capacitors 155 . As a result, the pair of capacitors 155 are charged by the current flowing through the intermediate grounding portion 150, so that the current flowing through the intermediate grounding portion 150 can be prevented from continuing to flow to the ground and causing power consumption.

Other effects of the second embodiment are the same as those of the first embodiment.

[Modification]
The embodiments disclosed this time should be considered illustrative and not restrictive in all respects. The scope of the present invention is indicated by the scope of the claims rather than the description of the above-described embodiments, and includes all modifications (modifications) within the scope and meaning equivalent to the scope of the claims.

For example, in the above-described first and second embodiments, the intermediate grounding portion 50 (150) is grounded via the resistance element 51 (151), but the present invention is not limited to this. The resistance element 51 (151) may not be provided in the intermediate grounding portion 50 (150).

In addition, in the above-described first and second embodiments, an example in which only the stack 40a (first power conversion unit) and the stack 40b (second power conversion unit) are provided in the power conversion device 100 (400) was shown. The present invention is not limited to this. The power converter 100 (400) may be provided with one or more pairs of stacks connected in series with each other in addition to the stacks 40a and 40b.

Further, in the above-described first and second embodiments, an example in which the ground wiring 52 (152) is cable wiring (bundled wiring) has been described, but the present invention is not limited to this. The ground wiring 52 (152) may be a bus bar.

Further, in the second embodiment, an example in which a pair of capacitors 155 are provided in the intermediate grounding portion 150 was shown, but the present invention is not limited to this. The pair of capacitors 155 may not be provided in the intermediate ground portion 150 .

Also, the resistance value of the resistance element 51 (151), the capacitance of the capacitor 155, and the like shown in the first and second embodiments are only examples, and can be changed as appropriate.

30 (30a, 30b) inverter section 31a semiconductor switching element (first semiconductor switching element)
31b semiconductor switching element (second semiconductor switching element)
31c semiconductor switching element (third semiconductor switching element)
31d semiconductor switching element (fourth semiconductor switching element)
33a series circuit (first series circuit)
33b series circuit (second series circuit)
34a, 34c positive input end (input end)
34b, 34d Negative side input terminal (input terminal)
40 stack (power conversion unit)
40a stack (first power conversion unit)
40b stack (second power conversion unit)
41 unit series connection part 42a, 42c positive electrode side wiring 42b, 42d negative electrode side wiring 50, 150 intermediate grounding part 51, 151 resistance element 80 bus bar (connection wiring between units)
100, 400 power conversion device 153 pair of positive side diode units 153a diode (first diode)
153b diode (second diode)
154 pair of negative diodes 154a diode (third diode)
154b diode (fourth diode)
155, 155a, 155b Capacitor 180 Connection wiring between units 185 Wiring (wiring between diodes)
185a part (part between a pair of capacitors)
C, D output terminal

Claims (9)

a plurality of power conversion units each including an inverter section for outputting an AC voltage by switching a plurality of semiconductor switching elements, and configured to form a unit series connection section by being connected in series with each other on the output side of the inverter section;
By grounding the inter-unit connection wiring, which is the wiring that connects the power conversion units connected in series with each other, the intermediate potential between the positive side potential and the negative side potential of the unit series connection portion is set to the ground potential. and an intermediate ground. 2. The power converter according to claim 1, wherein said intermediate grounding portion is provided so as to ground said inter-unit connection wiring through a resistive element. 3. The unit connection wiring according to claim 1, wherein said inter-unit connection wiring grounded by said intermediate grounding portion is provided so as to connect said inverter portions of said power conversion units connected in series with each other. Power converter. The inter-unit connection wiring grounded by the intermediate grounding portion is provided so as to connect the plurality of power conversion units in series by connecting the output terminals of the inverter portion to each other. 4. The power converter according to 3. The plurality of power conversion units includes a first power conversion unit and a second power conversion unit connected in series with each other,
The inverter section of each of the first power conversion unit and the second power conversion unit includes a first series circuit including a first semiconductor switching element and a second semiconductor switching element that are connected in series with each other, and a full bridge circuit in which a second series circuit composed of a third semiconductor switching element and a fourth semiconductor switching element are connected in parallel;
The inter-unit connection wiring grounded by the intermediate grounding portion is connected to the output end of the second series circuit in the full bridge circuit of the first power conversion unit and the full bridge circuit of the second power conversion unit. 5. The power conversion device according to claim 4, provided so as to connect said output terminal of said first series circuit in said. 4. The power converter according to claim 3, wherein said inter-unit connection wiring is provided so as to connect input ends of said inverter section. The plurality of power conversion units includes a first power conversion unit and a second power conversion unit connected in series with each other,
The inter-unit connection wiring includes a positive-side wiring of the first power conversion unit connected to a positive-side input terminal of the inverter section of the first power conversion unit, and a positive-side wiring of the inverter section of the second power conversion unit. positive side wiring of the second power conversion unit connected to a positive side input terminal, negative side wiring of the first power conversion unit connected to a negative side input terminal of the inverter section in the first power conversion unit, and a negative-side wiring of the second power conversion unit connected to a negative-side input terminal of the inverter section in the second power conversion unit, the electric power according to claim 6 . conversion device. On the inter-unit connection wiring,
A first diode having an anode connected to the positive electrode wiring of the first power conversion unit, and an anode connected to the positive electrode wiring of the second power conversion unit and connected to the cathode of the first diode. a pair of positive diode sections including a second diode having a cathode that is connected to the
a third diode having a cathode connected to the negative wiring of the first power conversion unit; and a cathode connected to the negative wiring of the second power conversion unit and connected to the anode of the third diode. a pair of negative diode sections including a fourth diode having an anode that is connected to the
8. The power converter according to claim 7, wherein said intermediate grounding section is provided so as to ground an inter-diode wiring connecting said pair of positive side diode sections and said pair of negative side diode sections. A pair of capacitors are provided on the wiring between the diodes,
9. The power converter according to claim 8, wherein said intermediate grounding portion is provided so as to ground a portion of said inter-diode wiring between said pair of capacitors.

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