JP6910498B1 - Busbar module and power converter using it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a bus bar module capable of miniaturization while suppressing a temperature rise of a sheet metal bus bar provided in the bus bar module, and a power conversion device using the same. A bus bar module includes a sheet metal bus bar having a plurality of plate-shaped connecting ends connected to components constituting an electric circuit, and a plate-shaped conductor portion connecting between the plurality of connecting ends, and a conductor. A sheet metal member having a plate-shaped portion having a portion and one surface facing each other, and a resin member surrounding each of the sheet metal bus bar and the sheet metal member are provided, and the other surface of the plate-shaped portion is exposed to the outside from the resin member. , The sheet metal bus bar and the sheet metal member are integrated with a resin member. [Selection diagram] FIG. 9

Description

The present application relates to a bus bar module and a power conversion device using the bus bar module.

An electric vehicle such as an electric vehicle or a hybrid vehicle in which a motor is used as a drive source is equipped with a plurality of electric power conversion devices. The power converter includes a charger that converts a commercial AC power supply to a DC power supply and charges the high-voltage battery, and a DC / DC converter that converts the DC power supply of the high-pressure battery into the voltage of the battery for auxiliary equipment (for example, 12V). Examples thereof include an inverter that converts DC power from a battery into AC power to a motor. The power conversion device mounted on an electric vehicle or a hybrid vehicle is required to be downsized and lightened for the purpose of improving fuel efficiency, expanding the space inside the vehicle, reducing the cost, and the like. Therefore, it is important to reduce the size and weight of each component constituting the power conversion device.

As a method for miniaturizing electromagnetic induction devices such as transformers and reactors that make up a power conversion device, it is effective to increase the drive frequency of these components. By increasing the drive frequency, the number of turns of the coils constituting the transformer and the reactor can be reduced. Further, by increasing the drive frequency, the cross-sectional area of the core, which is a magnetic material, can be reduced. However, in the pattern of the wiring board connecting the coil and each component, the influence of the skin effect becomes remarkable by increasing the drive frequency, the high frequency resistance increases, and the amount of heat generated increases. Therefore, there is a problem that the temperature of the coil and the pattern rises remarkably due to the increase in the drive frequency.

Further, in recent years, there is an increasing tendency to increase the capacity of batteries mounted on electric vehicles in particular for the purpose of increasing the cruising range. Therefore, there is an increasing demand for increasing the output power of an in-vehicle charger that plays a role of converting and transforming a commercial AC power source into DC and supplying it to a battery. When increasing the output of an in-vehicle charger, it is necessary to increase the amount of current from the commercial AC power supply on the input side. Therefore, the amount of current flowing through the transformer and reactor coils constituting the vehicle-mounted charger and the pattern of the wiring board increases, and the amount of heat generated also increases. In addition to the miniaturization, there is also a problem that the temperature of the coil and the pattern rises remarkably due to the increase in the output of the in-vehicle charger. To solve these problems, in order to suppress the temperature rise of the coil and pattern by reducing the wiring inductance, which is the resistance component of the wiring, bus bars of a plurality of plate-shaped conductors are laminated in the thickness direction of the bus bar and molded. (See, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-56972

In Patent Document 1, since the bus bars of a plurality of plate-shaped conductors are laminated in the thickness direction of the bus bars, the wiring inductance, which is a resistance component of the wiring, is reduced, and the temperature rise of the coil and the pattern is suppressed. be able to. However, since a plurality of bus bars are stacked, it is difficult to cool the stacked surfaces of the plurality of bus bars with a cooler, and there is a problem that the power conversion device becomes large due to the stacking. Even when cooling the side surfaces of the stacked busbars, the laminated surfaces of the busbars are orthogonal to the cooler, so that the laminated surfaces of the busbars face the cooler in the same manner as when the laminated surfaces of the busbars face the cooler. There is a problem that the power conversion device becomes large.

Therefore, an object of the present application is to obtain a bus bar module capable of miniaturization while suppressing a temperature rise of a sheet metal bus bar provided in the bus bar module and a power conversion device using the bus bar module.

The busbar module disclosed in the present application includes a sheet metal busbar having a plurality of plate-shaped connecting ends connected to components constituting an electric circuit, and a plate-shaped conductor portion connecting between the plurality of connecting ends. A sheet metal member having a plate-shaped portion having a conductor portion and one surface facing each other and a resin member surrounding each of the sheet metal bus bar and the sheet metal member are provided, and the other surface of the plate-shaped portion is exposed to the outside from the resin member. , The sheet metal bus bar and the sheet metal member are integrated with a resin member.

The power conversion device disclosed in the present application includes a plurality of electric components, a cooler in which a plurality of electric components are arranged side by side on one surface, and a bus bar module arranged so as to face one surface of the cooler. A circuit board on which a plurality of circuit components are mounted, which is arranged so as to face one surface of the cooler, and the plurality of electric components may be provided with the plurality of connection ends or circuit boards provided in the bus bar module. The plurality of connection ends provided by the bus bar module are connected to a plurality of electric components or circuit boards, and the circuit board is connected to a plurality of connection ends or a plurality of electric components provided by the bus bar module. It is a thing.

According to the bus bar module disclosed in the present application, the other surface of the plate-shaped portion of the sheet metal member having a plate-shaped portion in which one surface faces the conductor portion of the sheet metal bus bar provided in the bus bar module is outward from the resin member. Since the sheet metal bus bar and the sheet metal member are integrated with a resin member while being exposed, the heat generated in the sheet metal bus bar is dissipated through the sheet metal member, so that the bus bar module suppresses the temperature rise of the sheet metal bus bar. Can be miniaturized.

According to the power conversion device disclosed in the present application, the other surface of the plate-shaped portion of the sheet metal member is exposed to the outside from the resin member, and the sheet metal bus bar and the sheet metal member are integrated with the resin member. Since it is provided, the power conversion device can be miniaturized.

It is a block diagram which shows the outline of the structure of the power conversion apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the circuit structure of the DC / DC converter part of the power conversion apparatus which concerns on Embodiment 1. FIG. It is a perspective view which shows the appearance of the power conversion apparatus which concerns on Embodiment 1. FIG. It is sectional drawing of the power conversion apparatus cut at the AA sectional position of FIG. It is an exploded perspective view of the main part of the power conversion apparatus which concerns on Embodiment 1. FIG. It is a perspective view of the bus bar module of the power conversion apparatus which concerns on Embodiment 1. FIG. It is a perspective view of the bus bar module of the power conversion apparatus which concerns on Embodiment 1. FIG. It is a top view of the bus bar module of the power conversion apparatus which concerns on Embodiment 1. FIG. It is sectional drawing of the bus bar module cut at the BB sectional position of FIG. It is an exploded perspective view of the main part of the bus bar module of the power conversion apparatus which concerns on Embodiment 1. FIG. It is sectional drawing of the power conversion apparatus which concerns on Embodiment 2. FIG. It is sectional drawing of the main part of the power conversion apparatus which concerns on Embodiment 2. FIG.

Hereinafter, the bus bar module according to the embodiment of the present application and the power conversion device using the bus bar module will be described with reference to the drawings. In each figure, the same or corresponding members and parts will be described with the same reference numerals.

Embodiment 1.
FIG. 1 is a block diagram showing an outline of the configuration of the power conversion device 1 according to the first embodiment, FIG. 2 is a diagram showing a circuit configuration of the DC / DC converter unit 4a of the power conversion device 1, and FIG. 3 is a power conversion device 1. 4 is a cross-sectional view of the power conversion device 1 cut at the AA cross-sectional position of FIG. 3, FIG. 5 is an exploded perspective view of a main part of the power conversion device 1, and FIG. 6 is a power conversion device. 1 is a perspective view showing the other side of the bus bar module 20 of 1, FIG. 7 is a perspective view showing one side of the bus bar module 20 of the power conversion device 1, and FIG. 8 is a perspective view showing the other side of the bus bar module 20 of the power conversion device 1. A plan view, FIG. 9 is a cross-sectional view of the bus bar module 20 cut at the BB cross-sectional position of FIG. 8, and FIG. 10 is an exploded perspective view of a main part of the bus bar module 20 of the power conversion device 1. FIG. 3 is a view showing the cooler 8 with the cover 9 covering the opening surrounded by the outer peripheral wall 8b removed, and the other side of the bus bar module 20 is the side facing the circuit board 15. The power conversion device 1 that converts electric power is used by being mounted on a vehicle such as an electric vehicle or a hybrid vehicle that uses a motor as one of the drive sources.

<Outline of configuration of power converter 1>
As shown in FIG. 1, the power conversion device 1 converts the power supplied from the AC power supply 2 and supplies it to the load 3. For example, commercial AC power is supplied from the AC power supply 2. The converted power is, for example, DC power, which is supplied to a load 3 such as a high-voltage battery or a motor. When the load 3 is a drive battery for an electric vehicle, the power converter 1 boosts a commercial input AC voltage of 100 to 200 V and converts it into a DC voltage of about 300 to 400 V. The power conversion device 1 includes a power system main circuit unit 4 that performs power conversion, a control circuit unit 5 that controls the operation of the power system main circuit unit 4, and an input that suppresses the outflow of noise to the outside of the power conversion device 1. It is composed of a filter circuit unit 6 and an output filter circuit unit 7.

<Outline of circuit configuration of DC / DC converter unit 4a>
The power system main circuit unit 4 includes an AC / DC converter unit, a DC / DC converter unit 4a, and a capacitor unit provided between the converters. Hereinafter, the DC / DC converter unit 4a will be described as a main part of the power conversion device 1. As shown in FIG. 2, the DC / DC converter unit 4a includes a transformer 201, a rectifier circuit unit 202, a smoothing circuit unit 203, and a switching circuit unit (not shown). The transformer 201 and the rectifying circuit unit 202, and the rectifying circuit unit 202 and the smoothing circuit unit 203 are connected by a power line 205. The DC / DC converter unit 4a includes an input line 206 that transmits AC power to the transformer 201 via a switching circuit unit, and an output line 207 that outputs the power converted from the smoothing circuit unit 203 to the output filter circuit unit 7. ..

The transformer 201 has a transformer function of boosting and outputting the voltage input by the primary coil 201a and the secondary coil 201b. The transformer 201 boosts the voltage of the battery, which is the load 3 connected to the power conversion device 1, while insulating the voltage input from the switching circuit unit. The transformation ratio of the transformer 201 is determined according to the ratio of the number of turns of the primary coil 201a of the transformer 201 to the number of turns of the secondary coil 201b. In this boosting example, the number of turns of the secondary coil 201b is set to be larger than the number of turns of the primary coil 201a.

The rectifying circuit unit 202 includes a plurality of diodes 202a that are rectifying elements. The rectifier circuit unit 202 here has four diodes 202a, but the number of diodes 202a is not limited to this. The rectifier circuit unit 202 converts the high-voltage alternating current output from the secondary coil 201b of the transformer 201 into direct current. The smoothing circuit unit 203 includes a smoothing reactor 203a and a smoothing capacitor (not shown). The smoothing circuit unit 203 smoothes the DC waveform rectified by the rectifying circuit unit 202 and outputs it to the output line 207.

<Internal configuration of power converter 1>
The internal configuration of the power conversion device 1 will be described. In the power conversion device 1, a plurality of power system main circuit components, which are electrical components constituting the DC / DC converter unit 4a, and a plurality of power system main circuit components are arranged side by side on an arrangement surface 8c, which is one surface. It includes a cooler 8, a bus bar module 20 arranged to face the arrangement surface 8c, and a circuit board 15 arranged to face the arrangement surface 8c and on which a plurality of circuit components are mounted. The housing of the power conversion device 1 accommodating the plurality of power system main circuit components, the bus bar module 20, and the circuit board 15 is such that the cooler 8 and the outer peripheral wall of the cooler 8 face the arrangement surface 8c of the cooler 8. It is composed of a cover 9 that covers 8b. The plurality of power system main circuit components are connected to the plurality of connection end portions 101 or the circuit board 15 provided in the bus bar module 20. The plurality of connection end portions 101 included in the bus bar module 20 are connected to a plurality of power system main circuit components or circuit boards 15. The circuit board 15 is connected to a plurality of connection end portions 101 provided in the bus bar module 20 or terminals of power system main circuit components.

The power conversion device 1 includes a PFC reactor 204, a transformer 201, a rectifier circuit unit 202, a smoothing circuit unit 203, an AC / DC converter circuit unit (not shown), and an AC / DC converter circuit unit (not shown) as power system main circuit components that convert high voltage and large current. A DC / DC converter circuit unit (not shown) is provided. The transformer 201, the rectifier circuit unit 202, the smoothing reactor 203a, and the PFC reactor 204 are mounted on the arrangement surface 8c of the cooler 8 as shown in FIG. Here, the transformer 201, the rectifier circuit unit 202, the smoothing reactor 203a, and the PFC reactor 204 are provided side by side in this order from one side to the other side in the arrangement direction along the arrangement surface 8c of the cooler 8. In 202, the protruding height of the cooler 8 from the arrangement surface 8c is lower than that of the transformer 201 and the smoothing reactor 203a. The rectifier circuit unit 202 is used in the power conversion device 1 in the form of a secondary diode metal substrate module, the AC / DC converter circuit unit in the form of an AC / DC metal substrate module, and the DC / DC converter circuit unit in the form of a DC / DC metal substrate module. .. Although the arrangement surface 8c is omitted in FIG. 5 and shown in a plane, the arrangement surface 8c is formed with recesses in which each of the power system main circuit components is arranged as shown in FIG. Each of the recesses is formed in a shape that matches the size of the power system main circuit component to be arranged. By forming the recess, the power system main circuit component is easily positioned and arranged on the arrangement surface 8c, so that the productivity of the power conversion device 1 can be improved.

The transformer 201, the rectifier circuit unit 202, the smoothing reactor 203a, and the PFC reactor 204 include terminals protruding in the direction of the cover 9. Some of the terminals provided by these power system main circuit components are joined to the connection ends 101a1, 101b1, 101d1, 101c1, 101f2, 101g1, 101h1 of the bus bar module 20 shown in FIG. 6, for example, by TiG welding. NS. The connection portion between the connection end portions 101a1, 101b1, 101d1, 101c1, 101f2, 101g1, 101h1 and the terminals of the power system main circuit component is covered with the resin cover 16. As shown in FIG. 5, the resin cover 16 is provided between the bus bar module 20 and the circuit board 15. By covering the connecting portion with the resin cover 16, the distance between the connecting portion and the circuit board 15 can be shortened while ensuring the insulation between the connecting portion and the circuit board 15.

The circuit board 15 is separated from the arrangement surface 8c and installed on the bus bar module 20 by, for example, screwing. A control circuit unit 5 is provided on the circuit board 15, and the circuit board 15 controls the operation of the power system main circuit unit 4 composed of power system main circuit components and the like. The circuit board 15 includes wiring for connecting the PFC reactor 204, the AC / DC converter circuit unit, and the link capacitor (not shown). The wiring provided in the circuit board 15 is not limited to the wiring for connecting these electric components, but also includes the wiring for connecting other power system main circuit components and the bus bar module 20. As shown in FIG. 3, the circuit board 15 includes a plurality of through holes such as through holes 15a and 15b. The terminals included in the power system main circuit component connected to the circuit board 15 and the connection end 101 provided in the bus bar module 20 are inserted into the through holes and soldered to the power system main circuit components and the bus bar module 20. The wiring is connected. For example, the terminal 204a of the PFC reactor 204 and the wiring of the circuit board 15 are connected via the through hole 15a. Further, the connection ends 101h2 and 101g2 provided in the bus bar module 20 are connected to the wiring of the circuit board 15 via the through hole 15b. By this connection, the smoothing reactor 203a and the output filter circuit unit 7 (not shown) are connected.

As shown in FIG. 5, the cooler 8 is composed of a rectangular parallelepiped main body 8a and an outer peripheral wall 8b erected from an arrangement surface 8c which is one surface of the main body 8a along the outer circumference of the main body 8a. NS. As shown in FIG. 4, a cooling water channel 8d through which the refrigerant 11 flows is formed on the other surface of the main body 8a of the cooler 8. The cooling water channel 8d is covered with a water channel cover 10 and sealed. The transformer 201, the rectifying circuit unit 202, the smoothing circuit unit 203, and the PFC reactor 204 mounted on the arrangement surface 8c are cooled by the refrigerant 11 flowing through the cooling water channel 8d through the arrangement surface 8c and the outer peripheral wall 8b. By providing the cooling water channel 8d through which the refrigerant 11 flows, it is possible to suppress heat generation of these mounted power system main circuit components. Further, by providing the cooling water channel 8d on the side of the other surface of the main body 8a of the cooler 8, the arrangement surface 8c serving as the cooling surface can be secured in a wide range. Therefore, a sufficient heat dissipation area of the power system main circuit component mounted on the arrangement surface 8c can be sufficiently secured, and the degree of freedom in arrangement of the power system main circuit component is improved.

As shown in FIG. 4, the opening surrounded by the outer peripheral wall 8b is covered with a cover 9 provided so as to face the arrangement surface 8c. The cover 9 is made of, for example, metal. By covering the opening with the cover 9, the inside of the power conversion device 1 can be made waterproof and dustproof, and interference of electromagnetic waves can be prevented.

<Configuration and arrangement of bus bar module 20>
The bus bar module 20 which is a main part of the present application will be described. The bus bar module 20 is a connecting member that connects the power system main circuit component and the circuit board 15. As shown in FIG. 9, the bus bar module 20 includes a sheet metal bus bar 100, a sheet metal member 110, and a resin member 120 that surrounds each of the sheet metal bus bar 100 and the sheet metal member 110. As shown in FIG. 10, the sheet metal bus bar 100 includes a plurality of plate-shaped connection end portions 101 connected to a power system main circuit component or a circuit board 15 which are components constituting an electric circuit, and a plurality of connection end portions 101. It has a plate-shaped conductor portion 102 that connects between the two. The sheet metal member 110 has a plate-shaped portion 111 whose one surface faces the conductor portion 102. The sheet metal bus bar 100 is made of a metal such as copper or a copper alloy having good conductivity and high thermal conductivity. The sheet metal member 110 is made of a metal such as copper or a copper alloy having high thermal conductivity. As shown in FIG. 8, the other surface of the plate-shaped portion 111 of the sheet metal member 110 is exposed to the outside from the resin member 120 at a plurality of locations. The bus bar module 20 further includes a nut 115 and a bush 116. The nut 115 and the bush 116 are used to fix and fasten the circuit board 15. The sheet metal bus bar 100, the sheet metal member 110, the nut 115, and the bush 116 are integrated by the resin member 120.

The bus bar module 20 is arranged between the power system main circuit component and the circuit board 15. When the bus bar module 20 is mounted on the cooler 8, as shown in FIG. 5, the bus bar module 20 is positioned by inserting the positioning pin 20a of the bus bar module 20 into the positioning hole 8e of the cooler 8. Here, as shown in FIG. 4, in the bus bar module 20 provided so as to face the transformer 201, the rectifier circuit unit 202, and the smoothing reactor 203a, the portion facing the rectifier circuit unit 202 faces the transformer 201. Steps are formed on both side portions of the rectifier circuit unit 202 in the arrangement direction so as to be closer to the arrangement surface 8c of the cooler 8 than the portion facing the smoothing reactor 203a and the portion facing the smoothing reactor 203a. By arranging the bus bar module 20 between the power system main circuit component and the circuit board 15 and connecting the power system main circuit component and the circuit board 15 by the bus bar module 20, high voltage and large current transmission can be circuited. The bus bar module 20 can be three-dimensionally wired, not only by the pattern of the substrate 15. Since the transmission of high voltage and large current is not performed only by the pattern of the circuit board 15, the flat area of the power conversion device 1 can be reduced by reducing the area of the circuit board 15, and the power conversion device 1 can be miniaturized. Can be done. Further, by providing a step on the bus bar module 20, it is possible to absorb the height difference of the protrusion height of the power system main circuit component arranged on the arrangement surface 8c from the arrangement surface 8c, and the power system main circuit component and the circuit board can be absorbed. The insulation distance between 15 and 15 can be shortened. Further, a circuit component having a high height can be provided on the side of the circuit board 15.

<Sheet metal member 110>
The bus bar module 20 includes three sheet metal members 110a, 110b, and 110c as sheet metal members 110. The sheet metal member 110 faces the conductor portion 102 of the sheet metal bus bar 100 on one surface of the plate-shaped portion 111 provided by the sheet metal member 110. In the sheet metal member 110, the other surface of the plate-shaped portion 111 included in the sheet metal member 110 is exposed to the outside from the resin member 120. The sheet metal member 110 is arranged on the side of the circuit board 15 in the bus bar module 20. Since the plate-shaped portion 111 faces the conductor portion 102, the heat generated in the sheet metal bus bar 100 is efficiently dissipated through the sheet metal member 110. Since the sheet metal member 110 has a plate shape, the heat generated by the sheet metal bus bar 100 can be dissipated without increasing the thickness of the bus bar module 20. Since the other surface of the plate-shaped portion 111 is exposed to the outside from the resin member 120, the sheet metal member 110 can efficiently dissipate heat. Since the sheet metal member 110 is arranged on the side of the circuit board 15, the circuit board 15 and the circuit components of the control system mounted on the circuit board 15 are not fanned by the heat generated by the sheet metal bus bar 100, and the power conversion device. 1 can operate stably.

On one side of the sheet metal member 110, as shown in FIG. 7, the cooling portion 112, which is a part of the sheet metal member 110, is exposed from the resin member 120. The cooling unit 112 and the outer peripheral wall 8b of the cooler 8 are in contact with each other. The cooling portions 112a and 112b are in contact with the contact portions 8f provided on the outer peripheral wall 8b shown in FIG. 5, respectively. When the cooling unit 112 and the outer peripheral wall 8b of the cooler 8 are in contact with each other, the heat generated by the sheet metal bus bar 100 can be dissipated to the cooler 8 via the sheet metal member 110. By bringing the cooling unit 112 into contact with the outer peripheral wall 8b adjacent to the cooling unit 112, heat can be easily dissipated. The location where the cooling unit 112 comes into contact is not limited to the outer peripheral wall 8b, and for example, the main body 8a of the cooler 8 and the cooling unit 112 may come into contact with each other via a metal contact member having high thermal conductivity. ..

<Sheet metal bus bar 100>
The bus bar module 20 includes a plurality of sheet metal bus bars 100a, 100b, 100c, 100d, 100e, 100f, 100g, 100h. The conductor portions 102 provided by the sheet metal bus bars 100a and 100c, the sheet metal bus bars 100b and 100d, the sheet metal bus bars 100e and 100f, and the sheet metal bus bars 100g and 100h are provided on the same plane at intervals. By providing the conductor portion 102 on the same plane, the thickness of the bus bar module 20 can be made uniform, and the bus bar module 20 can be made thinner. Further, by providing the conductor portion 102 on the same plane, the distance between the conductor portion 102 and the sheet metal member 110 can be made uniform, and the heat dissipation path through the sheet metal member 110 can be made uniform.

As shown in FIG. 9, the sheet metal bus bars 100c and 100f are laminated via the resin member 120. When a plurality of sheet metal bus bars 100 are crossed and laminated, the insulation between the laminated sheet metal bus bar 100 and the sheet metal bus bar 100 can be easily ensured by laminating via the resin member 120. In addition, insulation can be easily ensured without increasing the thickness of the bus bar module 20.

<Connection end 101>
As shown in FIG. 6 or 7, the connection end 101 of the sheet metal bus bar 100 is exposed to the outside from the resin member 120. By exposing the connection end 101 to the outside, the connection end 101 can be easily connected to the power system main circuit component or the circuit board 15. The sheet metal bus bar 100 and the sheet metal member 110 may be sealed with the resin member 120 including the connection portion after the connection end portion 101 is connected to other parts without exposing the connection end portion 101 to the outside. ..

As shown in FIG. 10, the connection end portion 101 is bent at a right angle to the conductor portion 102. The bus bar module 20 can be miniaturized by bending the conductor portion 102. Further, it can be easily connected to the power system main circuit component or the circuit board 15 provided so as to face the bus bar module 20. Depending on the arrangement of the terminals connected to the connection end 101, the connection end 101 may be provided without being bent at a right angle and connected to other terminals.

In the connection end 101 on both sides of the sheet metal bus bars 100a, 100c, 100e, 100f, and the connection ends 101b1, 101d1, 101g1, 101h1 on one side of the sheet metal bus bars 100b, 100d, 100g, 100h, the connection end 101 and the conductor portion 102 The portion of the conductor portion 102 adjacent to the bent portion between the resin member 120 is exposed to the outside from the resin member 120. By exposing the portion of the adjacent conductor portion 102 to the outside from the resin member 120, when the sheet metal bus bar 100 is insert-molded by the resin member 120, the conductor portion 102 adjacent to the connection end portion 101 of the sheet metal bus bar 100 is formed by the molding die. Both parts of can be reliably held. Since both can be reliably held, the molding accuracy of the connection end 101 can be improved. Further, at the portion where the bent portion between the connection end portion 101 and the conductor portion 102 is sealed by the resin member 120, insulation from the outer peripheral wall 8b and the arrangement surface 8c close to the connection end portion 101 is ensured. Also, the distance to the adjacent electrical parts can be shortened.

The connection ends 101g2 and 101h2 are connected to the circuit board 15 via, for example, soldering through holes provided in the circuit board 15. The other connection end 101 is joined to the terminal provided in the power system main circuit component by, for example, TiG welding. By connecting the connection end 101, the power system main circuit component, and the circuit board 15 in this way, the structure is such that the bus bars are fastened with screws or the lug terminals are mounted on the board and joined via the lug terminals. In comparison, the mounting area can be reduced.

At the connection end portions 101g2 and 101h2, the width of the connection end portion 101 is reduced in the direction of the end of the connection end portion 101. By reducing the width of the connection end 101, the hole diameter of the through hole of the circuit board 15 can be reduced. Further, since the heat capacity of the connection end 101 is reduced, the solder connecting the connection end 101 and the land of the circuit board 15 is easily melted, so that the solderability of the connection end 101 can be improved. When the width of the connection end 101 is reduced to such an extent that it has a certain width, it is possible to suppress an increase in resistance at the connection end 101 when a large amount of power is applied.

<Conductor portion 102>
As shown in FIG. 9, the conductor portion 102f of the sheet metal bus bar 100f is provided with a step portion 103 which is bent to form a step. As shown in FIG. 10, the step portion 103 is also provided on the sheet metal bus bars 100a, 100c, and 100e. By providing the step portion 103 in the conductor portion 102, the height of the connection end portion 101 can be easily changed. By changing the height of the connection end 101, it can be easily connected to the terminals of the rectifier circuit unit 202 whose protrusion height from the arrangement surface 8c of the cooler 8 is lower than that of the transformer 201 and the smoothing reactor 203a.

<Resin member 120>
The resin member 120 surrounding each of the sheet metal bus bar 100 and the sheet metal member 110 integrates the sheet metal bus bar 100 and the sheet metal member 110. Since the resin member 120 surrounds and integrates each of the sheet metal bus bar 100 and the sheet metal member 110, it is possible to secure insulation between each of the sheet metal bus bar 100 and between the sheet metal bus bar 100 and the sheet metal member 110. Further, it is possible to maintain the insulation from the parts arranged in the vicinity of the sheet metal bus bar 100 and the sheet metal member 110.

<Through hole 117>
Through holes 117 are provided in the conductor portion 102 and the sheet metal member 110 of the sheet metal bus bar 100. By providing the through hole 117, when the bus bar module 20 is sealed with the resin member 120, the resin member 120 can be easily filled between the sheet metal bus bar 100 and the sheet metal member 110 where the resin member 120 is difficult to wrap around. Since the occurrence of unfilled portions of the resin member 120 is suppressed, the bus bar module 20 with high productivity can be manufactured.

The conductor portion 102 and the sheet metal member 110 each have two through holes 117, and the through holes 117 of the conductor portion 102 and the through holes 117 of the sheet metal member 110 are formed on the surface of the conductor portion 102 as shown by the alternate long and short dash line in FIG. It is provided at an overlapping position when viewed in the orthogonal direction. Since the through holes 117 provided in both the conductor portion 102 and the sheet metal member 110 are provided at overlapping positions when viewed in a direction orthogonal to the surface of the conductor portion 102, when the sheet metal bus bar 100 and the sheet metal member 110 are integrally molded by the resin member 120. By inserting a pin into both through holes 117, the sheet metal bus bar 100 and the sheet metal member 110 can be prevented from rotating, and the horizontal positional accuracy of the sheet metal bus bar 100 and the sheet metal member 110 can be improved. Further, when the sheet metal bus bar 100 and the sheet metal member 110 are integrally molded by the resin member 120, a stepped pin is inserted into the through hole 117 and the sheet metal bus bar 100 is pressed at the stepped portion, whereby the position accuracy of the sheet metal bus bar 100 in the horizontal direction is accurate. , And the position accuracy in the vertical direction can be improved. Further, when the through hole 117 is provided only in the sheet metal member 110 and one side of the sheet metal bus bar 100 is pressed with a pin, the distance between the sheet metal bus bar 100 and the sheet metal member 110 can be kept constant.

The inner diameter of the through hole 117 of the conductor portion 102a is smaller than the inner diameter of the through hole 117 of the sheet metal member 110b. By reducing the diameter of the through hole 117 provided in the sheet metal bus bar 100, it is possible to suppress a reduction in the cross-sectional area of the sheet metal bus bar 100 through which a large current flows. Further, since the reduction of the cross-sectional area of the sheet metal bus bar 100 is suppressed, the heat generation of the sheet metal bus bar 100 can be suppressed.

As described above, in the bus bar module 20 according to the first embodiment, the other surface of the plate-shaped portion 111 facing the conductor portion 102 of the sheet metal bus bar 100 is exposed to the outside from the resin member 120, and the sheet metal bus bar 100 and the sheet metal member are exposed to the outside. Since the 110 is integrated with the resin member 120, the heat generated by the sheet metal bus bar 100 is efficiently dissipated through the sheet metal member 110, so that the bus bar module 20 can be moved while suppressing the temperature rise of the sheet metal bus bar 100. It can be miniaturized. When the connection end 101 of the sheet metal bus bar 100 is exposed to the outside from the resin member 120, the connection end 101 can be easily connected to the power system main circuit component or the circuit board 15. When the connection end 101 is bent at a right angle to the conductor 102, the bus bar module 20 can be miniaturized and connected to a power system main circuit component or a circuit board 15 provided opposite to the bus bar module 20. The end 101 can be easily connected. When the portion of the conductor portion 102 adjacent to the bent portion between the connection end portion 101 and the conductor portion 102 is exposed to the outside from the resin member 120, when the sheet metal bus bar 100 is insert-molded by the resin member 120, the molding die Both the connection end 101 of the sheet metal bus bar 100 and the adjacent conductor 102 can be reliably held by the mold. Further, since both can be reliably held, the molding accuracy of the connection end portion 101 can be improved.

Further, when the width of the connection end portion 101 is reduced in the direction of the end of the connection end portion 101, the hole diameter of the through hole of the circuit board 15 connected to the connection end portion 101 can be reduced. Further, since the heat capacity of the connection end 101 is reduced, the solder connecting the connection end 101 and the land of the circuit board 15 is easily melted, so that the solderability of the connection end 101 can be improved. Further, when the conductor portion 102 is provided with the step portion 103 which is bent to form a step, the height of the connection end portion 101 can be easily changed.

Further, when the conductor portion 102 of the sheet metal bus bar 100 and the sheet metal member 110 are provided with through holes 117, when the bus bar module 20 is sealed with the resin member 120, the sheet metal bus bar 100 and the sheet metal member 110 are difficult to wrap around. The resin member 120 is easily filled between the spaces. The conductor portion 102 and the sheet metal member 110 each have two through holes 117, and the through holes 117 of the conductor portion 102 and the through holes 117 of the sheet metal member 110 are provided at positions where they overlap when viewed in a direction orthogonal to the surface of the conductor portion 102. If the sheet metal bus bar 100 and the sheet metal member 110 are integrally molded with the resin member 120, the sheet metal bus bar 100 and the sheet metal member 110 can be prevented from rotating by inserting a pin into both through holes 117. The horizontal positional accuracy of the 100 and the sheet metal member 110 can be improved. Further, since the position accuracy of the sheet metal bus bar 100 in the horizontal direction is improved, the reliability of the connection between the portion connected to the sheet metal bus bar 100 and the sheet metal bus bar 100 can be improved. Further, when the inner diameter of the through hole 117 of the conductor portion 102 is smaller than the inner diameter of the through hole 117 of the sheet metal member 110, it is possible to suppress the reduction of the cross-sectional area of the sheet metal bus bar 100 through which a large current flows.

Further, when the conductor portions 102 provided in each of the plurality of sheet metal bus bars 100 are provided on the same plane, the thickness of the bus bar module 20 can be made uniform, and the bus bar module 20 can be made thinner. Further, since the distance between the conductor portion 102 and the sheet metal member 110 is made uniform, it is possible to make the heat radiation path through the sheet metal member 110 uniform. When the plurality of sheet metal bus bars 100 are laminated via the resin member 120, the insulation between the laminated sheet metal bus bar 100 and the sheet metal bus bar 100 can be easily ensured by laminating via the resin member 120. can. In addition, insulation can be easily secured without increasing the thickness of the bus bar module 20.

Further, in the power conversion device 1 according to the first embodiment, the other surface of the plate-shaped portion 111 of the sheet metal member 110 is exposed to the outside from the resin member 120, and the sheet metal bus bar 100 and the sheet metal member 110 are integrated by the resin member 120. Since the bus bar module 20 is provided and the high voltage and the large current are not transmitted only by the pattern of the circuit board 15, the power conversion device 1 can be miniaturized. Further, when the bus bar module 20 is arranged between the power system main circuit component and the circuit board 15, the height difference of the protrusion height from the arrangement surface 8c of the power system main circuit component arranged on the arrangement surface 8c is increased. It can be absorbed and the insulation distance between the power system main circuit component and the circuit board 15 can be shortened. Further, when the sheet metal member 110 provided in the bus bar module 20 is arranged on the side of the circuit board 15, the circuit board 15 and the circuit components of the control system mounted on the circuit board 15 are heated by the heat generated by the sheet metal bus bar 100. The power conversion device 1 can operate stably without being affected. Further, when the connection portion between the connection end portion 101 and the power system main circuit component is covered with the resin cover 16, the connection portion and the circuit board 15 are connected while ensuring insulation between the connection portion and the circuit board 15. The distance can be shortened.

Further, when the connection end 101 and the circuit board 15 are connected via a through hole provided in the circuit board 15, a structure in which the bus bars are fastened with screws or a lug terminal is mounted on the board and the lug terminal is used. The mounting area can be reduced as compared with the structure in which the joints are joined. Further, when the cooling unit 112, which is a part of the sheet metal member 110 exposed from the resin member 120, and the cooler 8 are in contact with each other, the heat generated by the sheet metal bus bar 100 is dissipated to the cooler 8 via the sheet metal member 110. can do. Further, the cooler 8 has an outer peripheral wall 8b erected from one surface of the main body 8a along the outer periphery of the main body 8a of the rectangular parallelepiped cooler 8, and the outer peripheral wall 8b and the cooling portion 112 are in contact with each other. If so, the outer peripheral wall 8b and the cooling unit 112 are adjacent to each other, so that heat can be easily dissipated to the cooler 8. Further, when a cooling water channel 8d through which the refrigerant 11 flows is formed on the other surface of the cooler 8 and the cooling water channel 8d is covered with a cover, the power system main circuit component mounted on the arrangement surface 8c of the cooler 8 Fever can be suppressed. Further, by providing the cooling water channel 8d on the side of the other surface of the main body 8a of the cooler 8, the arrangement surface 8c serving as the cooling surface can be secured in a wide range, so that the power system main circuit component mounted on the arrangement surface 8c can be secured. It is possible to secure a sufficient heat dissipation area and improve the degree of freedom in arranging the power system main circuit components. Further, when the arrangement surface 8c of the cooler 8 is formed with a recess in which each of the plurality of power system main circuit components is arranged, the power system main circuit component is easily positioned and arranged on the arrangement surface 8c. Therefore, the productivity of the power conversion device 1 can be improved.

Embodiment 2.
The power conversion device 1 according to the second embodiment will be described. FIG. 11 is a cross-sectional view of the power conversion device 1 according to the second embodiment, and FIG. 12 is a cross-sectional view of a main part of the power conversion device 1 in which a part of FIG. 11 is enlarged. The power conversion device 1 according to the second embodiment has a configuration in which the cooler 8 includes an inner side wall 8 g.

FIG. 11 is a cross-sectional view of the power conversion device 1 cut at the CC cross-sectional position of FIG. The cooler 8 stands inside the outer peripheral wall 8b from the arrangement surface 8c of the main body 8a between the transformer 201 and the rectifier circuit portion 202, which are the main circuit components of the power system, and the inner side wall connected to the outer peripheral wall 8b. It has 8 g. The transformer 201 surrounded by the inner side wall 8g and the outer peripheral wall 8b is sealed with the heat radiating resin 201c. Although the inner side wall 8 g provided between the transformer 201 and the rectifier circuit unit 202 is shown here, the inner side wall 8 g is provided between the transformer 201 and the rectifier circuit unit 202 to provide another power system main circuit component. May be sealed with the heat radiating resin 201c.

As described above, in the power conversion device 1 according to the second embodiment, the cooler 8 stands between the main circuit components of the power system from the arrangement surface 8c of the main body 8a and has an inner side wall 8g connected to the outer peripheral wall 8b. Since the transformer 201 having the inner side wall 8g and surrounded by the outer peripheral wall 8b is sealed with the heat radiating resin 201c, the heat radiating effect of the transformer 201 can be further improved.

The present application also describes various exemplary embodiments and examples, although the various features, embodiments, and functions described in one or more embodiments are those of a particular embodiment. It is not limited to application, but can be applied to embodiments alone or in various combinations.
Therefore, innumerable variations not illustrated are envisioned within the scope of the techniques disclosed herein. For example, it is assumed that at least one component is modified, added or omitted, and further, at least one component is extracted and combined with the components of other embodiments.

1 Power converter, 2 AC power supply, 3 load, 4 power system main circuit, 4a DC / DC converter, 5 control circuit, 6 input filter circuit, 7 output filter circuit, 8 cooler, 8a main body , 8b outer wall, 8c placement surface, 8d cooling water channel, 8e positioning hole, 8f contact part, 8g inner side wall, 9 cover, 10 water channel cover, 11 refrigerant, 15 circuit board, 15a through hole, 15b through hole, 16 resin cover , 20 bus bar module, 20a positioning pin, 100 sheet metal bus bar, 101 connection end, 102 conductor part, 103 step part, 110 sheet metal member, 111 plate-shaped part, 112 cooling part, 115 nut, 116 bush, 117 through hole, 120 Resin member, 201 transformer, 201a primary side coil, 201b secondary side coil, 201c heat dissipation resin, 202 rectifying circuit part, 202a diode, 203 smoothing circuit part, 203a smoothing reactor, 204 PFC reactor, 205 power line, 206 input line , 207 Output line

Claims (21)

A sheet metal bus bar having a plurality of plate-shaped connection ends connected to components constituting an electric circuit, and a plate-shaped conductor portion connecting between the plurality of connection ends.
A sheet metal member having a plate-shaped portion whose one surface faces the conductor portion,
A sheet metal bus bar and a resin member surrounding each of the sheet metal members are provided.
A bus bar module in which the other surface of the plate-shaped portion is exposed to the outside from the resin member, and the sheet metal bus bar and the sheet metal member are integrated with the resin member. The bus bar module according to claim 1, wherein the connection end is exposed to the outside from the resin member. The bus bar module according to claim 2, wherein the connecting end portion is bent at a right angle to the conductor portion. The bus bar module according to claim 3, wherein the portion of the conductor portion adjacent to the bent portion between the connection end portion and the conductor portion is exposed to the outside from the resin member. The bus bar module according to claim 2, wherein the width of the connection end is reduced in the direction of the end of the connection end. The bus bar module according to claim 2, wherein the conductor portion is provided with a step portion formed by bending to form a step portion. The bus bar module according to claim 1, wherein the conductor portion and the sheet metal member of the sheet metal bus bar are provided with through holes. The conductor portion and the sheet metal member each have two through holes.
The through hole of the conductor portion and the through hole of the sheet metal member are provided at positions where they overlap each other when viewed in a direction orthogonal to the surface of the conductor portion.
The bus bar module according to claim 7, wherein the inner diameter of the through hole of the conductor portion is smaller than the inner diameter of the through hole of the sheet metal member. Equipped with multiple sheet metal busbars
The bus bar module according to claim 1, wherein the conductor portion provided in each of the plurality of sheet metal bus bars is provided on the same plane. Equipped with multiple sheet metal busbars
The bus bar module according to claim 1, wherein the plurality of sheet metal bus bars are laminated via the resin member. With multiple electrical components
A cooler in which a plurality of the electric components are arranged side by side on one surface, and
The bus bar module according to any one of claims 1 to 10, which is arranged so as to face one surface of the cooler.
A circuit board on which a plurality of circuit components are mounted, which is arranged so as to face one surface of the cooler, is provided.
The plurality of the electric components are connected to the plurality of connection ends or the circuit boards provided by the bus bar module, and the plurality of the connection ends provided by the bus bar module are the plurality of the electric components or the circuit boards. The circuit board is a power conversion device connected to a plurality of the connection ends or the electric components included in the bus bar module. The power conversion device according to claim 11, wherein the bus bar module is arranged between the electric component and the circuit board. The power conversion device according to claim 12, wherein the sheet metal member provided in the bus bar module is arranged on the side of the circuit board. The power conversion device according to claim 11, wherein the connection portion between the connection end portion and the electric component is covered with a resin cover. The power conversion device according to claim 11, wherein the connection end portion and the circuit board are connected to each other through a through hole provided in the circuit board. The power conversion device according to claim 11, wherein a cooling unit that is a part of the sheet metal member exposed from the resin member and the cooler are in contact with each other. The claim that the cooler has an outer peripheral wall erected from one surface of the main body along the outer periphery of the main body of the rectangular parallelepiped cooler, and the outer peripheral wall and the cooling portion are in contact with each other. 16. The power conversion device according to 16. The cooler has an inner side wall that is erected from one surface of the main body and is connected to the outer peripheral wall between each of the plurality of electric parts inside the outer peripheral wall, and has an inner side wall that is connected to the outer peripheral wall. The power conversion device according to claim 17, wherein the electric component surrounded by the outer peripheral wall is sealed with a resin. The power conversion device according to any one of claims 11 to 18, wherein a water channel through which a refrigerant flows is formed on the other surface of the cooler, and the water channel is covered with a cover. The power conversion device according to any one of claims 11 to 19, wherein a recess in which each of the plurality of electric components is arranged is formed on one surface of the cooler. Along one surface of the cooler, the transformer, the rectifier circuit unit, and the smoothing reactor, which are the electric components, are provided side by side from one side to the other side in the arrangement direction.
The rectifier circuit unit has a height protruding from one surface of the cooler lower than that of the transformer and the smoothing reactor.
In the transformer, the rectifier circuit unit, and the bus bar module provided so as to face the smoothing reactor, the portion facing the rectifier circuit unit faces the transformer and the smoothing reactor. The power conversion device according to claim 12, wherein steps are formed on both side portions of the rectifier circuit unit in the arrangement direction so as to be closer to one surface of the cooler than the portion.

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