JPWO2020040279A1 - Inverter unit, motor unit - Google Patents

Abstract

An inverter unit that can be attached to a motor and includes a power unit including an inverter circuit, an inverter housing that houses the power unit, and an externally connected bus bar that is electrically connected to the power unit. , Has a lower case with a bottom wall and a tubular side wall extending upward from the periphery of the bottom wall, and an externally connected busbar is arranged to penetrate the bottom wall or side wall of the lower case in and out and power. The inverter unit is connected to the external connection bus bar at the bus bar connection portion located above the upper end surface of the side wall of the lower case. [Selection diagram] Fig. 1

Description

The present invention relates to an inverter unit and a motor unit.

Conventionally, an inverter unit including an inverter and a case for accommodating the inverter for controlling a motor is known. Japanese Patent Application Laid-Open No. 2003-199363 describes an electric drive unit (inverter unit) that is stacked and fixed in the order of the size of each part in consideration of compactness, assembling property, manufacturability, earthquake resistance, etc. Will be disclosed.

Japanese Publication No. 2003-199363

The inverter and capacitor of the inverter unit were housed in a tubular case having a bottom wall. In this configuration, if you try to connect a busbar or wiring to a part located near the bottom wall of the case, you have to operate the connection part through a narrow gap between the case and the part, which reduces the efficiency of the assembly work. There was a challenge.

According to one aspect of the present invention, an inverter unit that can be attached to a motor, includes a power unit including an inverter circuit, an inverter housing that houses the power unit, and an external device that is electrically connected to the power unit. The inverter housing includes a connecting bus bar, and the inverter housing has a lower case having a bottom wall and a tubular side wall extending upward from the peripheral edge of the bottom wall, and the external connecting bus bar has the lower case. The power unit and the external connection bus bar are connected to each other at a bus bar connection portion located above the upper end surface of the side wall of the lower case. , Inverter unit is provided.

According to one aspect of the present invention, there is provided an inverter unit capable of efficiently performing assembly work, and a motor unit including the inverter unit.

FIG. 1 is a perspective view of the inverter unit of the present embodiment as viewed from above. FIG. 2 is a perspective view of the inverter unit of the present embodiment as viewed from below. FIG. 3 is a partial cross-sectional view of the inverter unit of the present embodiment. FIG. 4 is a plan view showing the internal structure of the inverter unit of the present embodiment. FIG. 5 is a perspective view showing the internal structure of the inverter unit of the present embodiment. FIG. 6 is an exploded perspective view showing a connection structure around an externally connected bus bar.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the following description, the direction of gravity will be defined based on the positional relationship when the inverter unit 1 is mounted on a vehicle located on a horizontal road surface. Further, in the drawings, the XYZ coordinate system is shown as a three-dimensional Cartesian coordinate system as appropriate. In the XYZ coordinate system, the Z-axis direction indicates the vertical direction (that is, the vertical direction), the + Z direction is the upper side (opposite the gravity direction), and the −Z direction is the lower side (gravity direction). Further, the X-axis direction is a direction orthogonal to the Z-axis direction, and in the present embodiment, a direction along the short side of the inverter unit 1 is shown. The Y-axis direction is a direction orthogonal to both the X-axis direction and the Z-axis direction, and in the present embodiment, indicates a direction along the long side of the inverter unit 1.

As shown in FIG. 3, the inverter unit 1 is provided in the motor unit 3. The motor unit 3 includes an inverter unit 1 and a motor 2. The inverter unit 1 is installed on the upper surface of the motor 2. Therefore, the lower surface of the inverter unit 1 is the motor connection portion 10A connected to the motor 2. The motor connection portion 10A is a portion that mechanically connects the inverter unit 1 and the motor 2. Bolt fastening can be used as the connection structure between the inverter unit 1 and the motor 2. If it is not necessary to attach / detach the inverter unit 1 and the motor 2, rivet fastening or welding may be used. A bracket may be attached to the motor connection portion 10A, and the inverter unit 1 and the motor 2 may be connected via the bracket.
The motor 2 is supplied with an alternating current from the inverter unit 1. The motor 2 is controlled by the inverter unit 1. The inverter unit 1 is connected to the coil wire of the stator of the motor 2.

The motor unit 3 of the present embodiment is mounted on a vehicle powered by a motor, such as a hybrid electric vehicle (HEV), a plug-in hybrid electric vehicle (PHV), and an electric vehicle (EV), and is used as the power source thereof. The motor unit 3 may include a speed reducer (not shown) for decelerating the rotation of the motor 2.

The inverter unit 1 converts a direct current into an alternating current and supplies it to the motor 2. As shown in FIGS. 1 to 4, the inverter unit 1 includes an inverter housing 10, a control board 20, a power unit 30 including an inverter circuit, a capacitor 40, and a plurality of externally connected bus bars 50.

The inverter housing 10 has a lower case 11 and a cover member 12 attached to the opening of the lower case 11. The lower case 11 has a bottom wall 11a and a tubular side wall 11b extending upward from the peripheral edge of the bottom wall 11a. The cover member 12 has a top wall 12a and a tubular side wall 12b extending downward from the peripheral edge of the top wall 12a. The lower case 11 and the cover member 12 are bolted together with the upper end surface 11c of the side wall 11b and the lower end surface 12c of the side wall 12b facing each other.

The lower case 11 has a storage chamber 13 surrounded by a bottom wall 11a and a side wall 11b. The control board 20, the power unit 30, the capacitor 40, and the external connection bus bar 50 are arranged inside the accommodation chamber 13 when viewed from above.
The containment chamber 13 includes a first containment chamber 13A and a second containment chamber 13B which are horizontally partitioned. That is, the inverter housing 10 has a first storage chamber 13A and a second storage chamber 13B. The power unit 30 and the external connection bus bar 50 are arranged in the first accommodation chamber 13A. The control board 20 and the capacitor 40 are arranged in the second accommodating chamber 13B.

As shown in FIG. 4, the first storage chamber 13A has a substantially rectangular shape in a plan view. As shown in FIG. 2, a cooling unit 60 is provided at the bottom of the first storage chamber 13A. The cooling unit 60 has a refrigerant flow path 11d. The refrigerant flow path 11d is a recess that opens on the upper surface side of the bottom wall 11a. The refrigerant flow path 11d has a substantially rectangular shape in a plan view. The refrigerant flow path 11d is connected to the pipe connection terminals 14 and 15 on the side surface of the lower case 11 via a tubular flow path penetrating the bottom wall 11a. The pipe connection terminals 14 and 15 are connected to an external refrigerant pipe. The power unit 30 is fixed on the refrigerant flow path 11d.

As shown in FIG. 4, the second storage chamber 13B has a substantially rectangular shape elongated in the X-axis direction with respect to the first storage chamber 13A. The capacitor 40 is fixed to the bottom of the second storage chamber 13B. The control board 20 is fixed to the upper surface of the capacitor 40.

The control board 20 supplies a drive signal to the motor 2 via the power unit 30 to control the motor 2. The control board 20 is electrically connected to an encoder such as a resolver provided in the motor unit 3. The control board 20 feedback-controls the rotation speed and torque according to the rotation speed and current of the motor 2 based on the rotation information of the motor 2 output from the encoder.

As shown in FIGS. 1 and 4, the capacitor 40 is connected to the external power supply device 9 via the wiring 9a. The wiring 9a is connected to the capacitor input terminal 41 of the capacitor 40 via the wiring terminal 9b provided at the end of the wiring 9a. The external power supply device 9 is, for example, a secondary battery mounted on a vehicle. The inverter unit 1 converts the direct current supplied from the external power supply device 9 into an alternating current and supplies the direct current to the motor 2 via the externally connected bus bar 50.

The power unit 30 includes a power board 31 and a semiconductor module 32 located below the power board 31. In the case of this embodiment, the power substrate 31 and the semiconductor module 32 are both flat plates.

The semiconductor module 32 incorporates a three-phase inverter having six IGBTs (insulated gate bipolar transistors) in a case. As shown in FIG. 3, the semiconductor module 32 has a heat sink 32a composed of a plurality of columnar bodies extending downward from the lower surface of the semiconductor module 32. The semiconductor module 32 is fixed to the bottom wall 11a with the refrigerant flow path 11d covered from above. The heat sink 32a is arranged in the refrigerant flow path 11d. A ring-shaped sealing member 33 is arranged around the refrigerant flow path 11d. The refrigerant flow path 11d is sealed by a sealing member 33 sandwiched between the upper surface of the bottom wall 11a and the semiconductor module 32.

A power substrate 31 for driving the semiconductor module 32 is arranged on the upper surface of the semiconductor module 32. The power substrate 31 and the semiconductor module 32 are electrically connected to each other via a plurality of connection pins 34 extending upward from the semiconductor module 32.

As shown in FIG. 4, the semiconductor module 32 has six inverter input terminals 35 on the side surface facing the capacitor 40. The inverter input terminals 35 are connected to six capacitor output terminals (not shown) extending from the capacitor 40. The semiconductor module 32 has three output terminals 36U, 36V, and 36W on the side surface opposite to the capacitor 40. That is, the power unit 30 has output terminals 36U, 36V, and 36W.

The output terminals 36U, 36V and 36W are connected to the relay bus bars 57U, 57V and 57W, respectively. In the following description, the output terminals 36U, 36V, and 36W of the power unit 30 may be collectively referred to as the output terminal 36. Further, the relay bus bars 57U, 57V, and 57W may be collectively referred to as the relay bus bar 57.

As shown in FIGS. 4 to 6, the relay bus bar 57 is a strip-shaped metal plate. The two relay bus bars 57U and 57W are L-shaped when viewed from above, and the other relay bus bar 57U is linear when viewed from above. The relay bus bars 57U, 57V, 57W extend in the horizontal direction from the connection portion with the output terminals 36U, 36V, 36W, and are bent upward in the vicinity of the external connection bus bar 50. The tip portions of the relay bus bars 57U, 57V, and 57W are located above the upper end surface 11c of the lower case 11.

The relay bus bar 57 is connected to the output terminal 36 at the relay connection unit 70 located on the side of the power unit 30. As shown in FIGS. 3 and 6, the relay connection unit 70 includes a relay unit support base 71 that supports the output terminal 36 of the power unit 30 and the relay bus bar 57 from below, and the output terminals 36U and 36V of the power unit 30. , A bolt 72 that connects the 36W and the relay bus bar 57.

The bolt 72 is a relay portion fixing member in the relay connection portion 70. The bolt 72 penetrates the relay bus bar 57 in the vertical direction and is tightened into the screw hole of the output terminal 36 of the power unit 30. With this configuration, the relay bus bar 57 and the output terminal 36 can be easily and firmly fixed.

As shown in FIGS. 5 and 6, the relay portion support base 71 is a rod-shaped member extending in the X-axis direction along the side surface of the power portion 30. The relay portion support base 71 has three terminal support portions 71a arranged at intervals along the length direction (Y-axis direction). That is, the relay portion support base 71 has a plurality of terminal support portions 71a arranged in a direction intersecting the vertical direction. A relay section partition wall 71b extending in the vertical direction is located between the adjacent terminal support portions 71a. According to this configuration, the output terminals 36 can be insulated from each other by the relay section partition wall 71b.

The relay portion support base 71 has a first positioning wall 71c extending upward from an end portion of the terminal support portion 71a opposite to the power portion 30 at the three terminal support portions 71a.
The relay support base 71 has three columnar positioning pins 71d extending from the upper surface to the upper side. The two positioning pins 71d extend upward from the upper surface of the relay section partition wall 71b. The other positioning pin 71d extends upward from the upper end surface of the first positioning wall 71c located at the center.
The relay portion support base 71 has a second positioning wall 71e extending upward from each end on the central portion side of the upper surface of the two relay portion partition walls 71b. The second positioning wall 71e also functions as a partition wall that insulates the relay bus bars 57 arranged adjacent to each other.

The relay portion support base 71 has one flange portion 71f at both ends in the length direction. The flange portion 71f has a through hole that penetrates the flange portion 71f in the vertical direction. As shown in FIG. 3, the relay portion support base 71 is fastened to the bottom wall 11a of the lower case 11 by bolts 73 that are passed through the through holes of the flange portion 71f.

The output terminal 36 of the power unit 30 and the relay bus bar 57 are fastened on the terminal support portion 71a of the relay portion support base 71. As shown in FIG. 6, the output terminal 36 is arranged on the upper surface of the terminal support portion 71a. The upper surface of the output terminal 36 and the upper surface of the relay section partition wall 71b are substantially the same height. Three relay bus bars 57 are arranged on the relay unit support base 71.

The L-shaped relay bus bar 57U in a plan view is arranged on the upper surface of the output terminal 36U and the relay section partition wall 71b. The positioning pin 71d is passed through the through hole of the relay bus bar 57U. The side surface of the relay bus bar 57U is positioned by the first positioning wall 71c and the second positioning wall 71e. The bolt 72 is passed through the bolt insertion hole of the relay bus bar 57U and tightened into the screw hole of the output terminal 36U, whereby the relay bus bar 57U and the output terminal 36U are bolted together.

The relay bus bar 57V is arranged on the output terminal 36V and the first positioning wall 71c. The positioning pin 71d is passed through the through hole of the relay bus bar 57V. The two side surfaces of the relay bus bar 57V facing the X-axis direction are positioned by the second positioning wall 71e. The bolt 72 is passed through the bolt insertion hole of the relay bus bar 57V and tightened into the screw hole of the output terminal 36V, whereby the relay bus bar 57V and the output terminal 36V are bolted together.
Like the relay bus bar 57U, the relay bus bar 57W is arranged in a positioned state on the output terminal 36W and the relay section partition wall 71b, and is fastened by using the bolt 72.

In the inverter unit 1 of the present embodiment, by providing the relay unit support base 71, when the output terminal 36 and the relay bus bar 57 are fastened, the bolt 72 is tightened while the output terminal 36 is supported from below. Can be done. As a result, it is possible to prevent bending stress from being applied to the power portion 30 when the bolt 72 is tightened.
Further, the relay bus bar 57 is positioned by the first positioning wall 71c, the positioning pin 71d, and the second positioning wall 71e of the relay portion support base 71. This facilitates the assembly work of the relay connection portion 70.
A component in which the relay unit support base 71 and the relay bus bar 57 are integrated may be used. According to this configuration, workability when attaching the relay bus bar 57 to the externally connected bus bar 50 is improved.

The relay bus bars 57U, 57V, 57W are connected to the externally connected bus bars 50U, 50V, 50W at the bus bar connection portion 55, respectively. In the following description, the externally connected bus bars 50U, 50V, and 50W may be collectively referred to as the externally connected bus bar 50.

The external connection bus bar 50 is a strip-shaped metal plate as shown in FIGS. 4 to 6. The externally connected bus bars 50U, 50V, and 50W all have a linear shape extending in the vertical direction. The tips of the externally connected bus bars 50U, 50V, and 50W are located above the upper end surface 11c of the lower case 11.

The externally connected bus bar 50 is held by the bus bar holder 52 shown in FIG. In the case of this embodiment, the external connection bus bar 50 is insert-molded into the resin bus bar holder 52. The bus bar holder 52 has a main body 52a that holds three externally connected bus bars 50, four partition walls 52b that extend upward from the upper surface of the main body 52a, and a horizontal direction from the lower end of the outer peripheral surface of the main body 52a. It has an expanding flange portion 52c.

The externally connected bus bars 50U, 50V, and 50W are arranged side by side in the short side direction (X-axis direction) of the lower case 11 with their plate surfaces facing the power unit 30 side. The externally connected bus bars 50U, 50V and 50W are each located between the two partition walls 52b. The partition wall 52b insulates the externally connected bus bars 50 adjacent to each other in the X-axis direction.

As shown in FIGS. 2 and 3, the bus bar holder 52 is inserted into the case through hole 11e that penetrates the bottom wall 11a of the lower case 11 in the vertical direction from the lower surface side of the lower case 11. The bus bar holder 52 is positioned in the vertical direction by abutting the upper surface of the flange portion 52c against the lower surface of the lower case 11. The bus bar holder 52 is fastened to the bottom wall 11a of the lower case 11 by a bolt that is passed through the through hole of the flange portion 52c. With this configuration, the external connection bus bar 50 is arranged so as to penetrate the bottom wall 11a of the lower case 11 inside and outside.

With the bus bar holder 52 fixed to the lower case 11, the upper ends of the externally connected bus bars 50U, 50V, 50W are arranged at substantially the same height as the upper ends of the relay bus bars 57U, 57V, 57W. The relay bus bar 57U and the external connection bus bar 50U are fastened by a bolt 54 extending in the horizontal direction in a state where the plate surfaces of the relay bus bar 57U and the external connection bus bar 50U are overlapped with each other. The relay bus bar 57V and the externally connected bus bar 50V, and the relay bus bar 57W and the externally connected bus bar 50W are also fastened with bolts 54 in a state where the plate surfaces are overlapped with each other.
That is, the relay bus bar 57 and the externally connected bus bar 50 are fastened by using a bolt 54 extending in a direction intersecting the vertical direction.

The connection portion between the relay bus bar 57 and the external connection bus bar 50 by the bolt 54 is the bus bar connection portion 55 in the inverter unit 1.
In the present embodiment, as shown in FIGS. 3 and 5, the bus bar connecting portion 55 is located above the upper end surface 11c of the lower case 11. That is, with the cover member 12 removed, the bus bar connecting portion 55 is located outside the accommodation chamber 13 of the lower case 11. According to this configuration, in the connection work between the relay bus bar 57 and the external connection bus bar 50, the side wall 11b of the lower case 11 does not get in the way, and the assembly work can be efficiently performed.

In the present embodiment, at the bus bar connecting portion 55, the relay bus bar 57 and the external connecting bus bar 50 are fastened by using a bolt 54 extending in a direction intersecting the vertical direction. Since the bus bar connecting portion 55 is located above the upper end surface 11c of the lower case 11, the fastening work with the bolt 54 extending in the horizontal direction with respect to the vertical direction can be easily performed. Further, since the bolts can be easily fastened in any direction, the parts can be efficiently arranged inside the inverter housing 10. As a result, the inverter unit 1 can be miniaturized.

In the present embodiment, in the bus bar connecting portion 55, the relay bus bar 57 and the external connecting bus bar 50 are fastened in a state where the respective plate surfaces are overlapped with each other, so that the space occupied by the bus bar connecting portion 55 can be reduced.

The inverter unit 1 of the present embodiment has a relay bus bar 57 that connects the power unit 30 and the externally connected bus bar 50. By using the relay bus bar 57, the bus bar connection portion 55 can be arranged above the upper end surface 11c of the lower case 11 without changing the position of the output terminal 36 of the power portion 30. According to this configuration, the work of screwing the relay bus bar 57 to the externally connected bus bar 50 becomes easy.

In the above embodiment, the configuration in which the power unit 30 and the externally connected bus bar 50 are connected via the relay bus bar 57 has been described, but the configuration is not limited to this configuration.
For example, the output terminals 36U, 36V, 36W of the power unit 30 may have a shape extending upward from the semiconductor module 32. According to this configuration, the power unit 30 and the externally connected bus bar 50 can be directly connected to each other in the bus bar connection unit 55 without using the relay bus bar 57. Also in this case, at the bus bar connecting portion 55 located above the upper end surface 11c of the lower case 11, the inverter unit 1 is formed by fastening the power portion 30 and the external connecting bus bar 50 with a bolt 54 extending in the horizontal direction. Can be easily assembled.

Further, in the above embodiment, the externally connected bus bar 50 is arranged so as to penetrate the bottom wall 11a inside and outside, but the externally connected bus bar 50 may be arranged so as to penetrate the side wall 11b inside and outside. Also in this case, the workability improvement effect can be obtained by arranging the bus bar connecting portion 55 above the upper end surface 11c of the lower case 11.

As shown in FIG. 3, the bus bar connecting portion 55 may be provided with a protective cover 55a that covers the fastening portion between the relay bus bar 57 and the externally connected bus bar 50. The protective cover 55a is a square tubular insulating member having a top wall. The protective cover 55a covers the upper side and the side surface of the fastening portion by the bolt 54. By providing the protective cover 55a, the bus bar connecting portion 55 and the cover member 12 can be insulated from each other.

1 ... Inverter unit, 2 ... Motor, 3 ... Motor unit, 10 ... Inverter housing, 11 ... Lower case, 11a ... Bottom wall, 11b, 12b ... Side wall, 11c ... Upper end surface, 30 ... Power unit, 36, 36U , 36V, 36W ... Output terminal, 50, 50U, 50V, 50W ... External connection bus bar, 52b ... Partition wall, 54, 72, 73 ... Bolt, 55 ... Bus bar connection, 57, 57U, 57V, 57W ... Relay bus bar, 70 ... Relay connection part, 71 ... Relay part support base, 71a ... Terminal support part, 71b ... Relay part partition wall

Claims (8)

An inverter unit that can be attached to a motor
A power unit including an inverter circuit, an inverter housing accommodating the power unit, and an externally connected bus bar electrically connected to the power unit are provided.
The inverter housing has a lower case having a bottom wall and a tubular side wall extending upward from the peripheral edge of the bottom wall.
The externally connected bus bar is arranged so as to penetrate the bottom wall or the side wall of the lower case in and out.
The power unit and the external connection bus bar are connected at a bus bar connection unit located above the upper end surface of the side wall of the lower case.
Inverter unit. In the bus bar connecting portion, the power portion and the external connecting bus bar are fastened by using bolts extending in a direction intersecting the vertical direction.
The inverter unit according to claim 1. It has a relay bus bar that connects the power unit and the externally connected bus bar.
The inverter unit according to claim 1 or 2. The external connection bus bar and the relay bus bar are both strip-shaped metal plates.
At the bus bar connection portion, the relay bus bar and the external connection bus bar are bolted together with their plate surfaces overlapped with each other.
The inverter unit according to claim 3. It has a relay connection unit that connects the output terminal of the power unit and the relay bus bar.
The relay connection part
A relay unit support base that supports the output terminal of the power unit and the relay bus bar from below, and
A relay unit fixing member that connects the output terminal of the power unit and the relay bus bar,
Have,
The inverter unit according to claim 3 or 4. The relay portion fixing member is a bolt that penetrates the relay bus bar in the vertical direction and is tightened into a screw hole provided in an output terminal of the power portion.
The inverter unit according to claim 5. It has a plurality of the relay bus bars, and the power unit has a plurality of the output terminals.
The relay unit support base has a plurality of terminal support units to which the output terminal of the power unit and the relay bus bar are fixed.
The plurality of terminal support portions are arranged side by side in a direction intersecting the vertical direction.
A relay section partition wall extending in the vertical direction is located between the adjacent terminal support portions.
The inverter unit according to claim 5 or 6. The inverter unit according to any one of claims 1 to 7.
With the motor to which alternating current is supplied from the inverter unit,
A motor unit.

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