JP7586014B2 - Electrical equipment and rotating electrical equipment - Google Patents

Description

The disclosure herein relates to electrical devices and rotating electrical devices mounted on vehicles.

Patent Document 1 describes an electric vehicle that includes a PCU, a PCU case that houses the PCU, a transaxle housing that houses two motor generators, and a bracket that fixes the PCU case to the transaxle housing. The PCU case and transaxle housing are housed in the engine compartment of the electric vehicle.

JP 2013-193634 A

Even if an electric vehicle collides frontally against the corner of an external barrier and the corner of the barrier hits the PCU case inside the engine compartment, the bracket deforms to absorb the impact on the PCU case and reduce the impact on the PCU.

However, the number of parts increases due to the bracket, making it difficult to simultaneously reduce the impact on the PCU and the increase in the number of parts.

The objective of this disclosure is to provide an electrical device and a rotating electrical device that can simultaneously reduce the impact on the power module and prevent an increase in the number of parts.

According to one aspect of the present disclosure, there is provided an electrical component comprising:
An electric device (300) connected to a rotating device (410) having a rotating machine (400) accommodated in a first case (910) provided in a machine room (10) of a vehicle and having a first storage space (915) defined by a bottom (911) and a first annular wall (912) standing annularly from the bottom,
a second case (920) including a second annular wall (921) that is aligned with the first case in a height direction perpendicular to the bottom and includes a lower annular wall (925) located on the first annular wall side in the height direction and an upper annular wall (926) located on a side farther away from the first annular wall in the height direction than the lower annular wall;
a power module (391) accommodated in a space surrounded by the upper annular wall of a second storage space (928) partitioned by the second annular wall;
a portion of the upper annular wall on a front side of the vehicle is located on a rear side of the vehicle relative to a portion of the lower annular wall on a front side of the vehicle ,
a reactor (313) accommodated in a space surrounded by an upper annular wall of the second accommodation space and electrically connected to the power module;
The second storage space is accommodated in a space that is a combination of the space surrounded by the lower annular wall of the second storage space and the first storage space, and the second storage space is electrically connected to the power module and the reactor. The second storage space is accommodated in a space that is a combination of the space surrounded by the lower annular wall of the second storage space and the first storage space ...

Further, a rotating electric machine device according to one aspect of the present disclosure includes:
a rotating device (410) in which a rotating machine (400) is housed in a first case (910) provided in a machine room (10) of a vehicle and having a first storage space (915) defined by a bottom (911) and a first annular wall (912) standing annularly from the bottom;
a second case (920) including a second annular wall (921) that is aligned with the first case in a height direction perpendicular to the bottom and includes a lower annular wall (925) located on the first annular wall side in the height direction and an upper annular wall (926) located on a side farther away from the first annular wall in the height direction than the lower annular wall; and an electric device (300) including a power module (391) that is stored in a space surrounded by the upper annular wall within a second storage space (928) partitioned by the second annular wall,
a portion of the upper annular wall on a front side of the vehicle is located on a rear side of the vehicle relative to a portion of the lower annular wall on a front side of the vehicle ,
The electrical device (300) comprises:
a reactor (313) accommodated in a space surrounded by an upper annular wall of the second accommodation space and electrically connected to the power module;
The second storage space is accommodated in a space that is a combination of the space surrounded by the lower annular wall of the second storage space and the first storage space, and the second storage space is electrically connected to the power module and the reactor. The second storage space is accommodated in a space that is a combination of the space surrounded by the lower annular wall of the second storage space and the first storage space ...

As a result, even if the front of the vehicle collides with a corner of the external barrier and the corner of the barrier comes relatively close to the upper annular wall (926), the corner of the barrier is less likely to hit the upper annular wall (926). As a result, the power module (391) is less likely to receive an impact from the front of the vehicle.

In addition, the first case (910) and the second case (920) are directly connected, which helps prevent an increase in the number of parts.

It is now possible to both reduce the impact on the power module (391) and prevent an increase in the number of parts.

The reference numbers in parentheses above merely indicate the corresponding relationship to the configurations described in the embodiments described below, and do not limit the technical scope in any way.

FIG. 2 is a circuit diagram for explaining an in-vehicle system. FIG. 2 is a schematic diagram for explaining a state in which the rotating electric machine device is mounted on a vehicle. FIG. 2 is a schematic diagram for explaining a rotating electric machine device. FIG. 2 is a schematic diagram for explaining a rotating electric machine device. FIG. 2 is a schematic diagram for explaining a flow path. FIG. 2 is a schematic diagram showing the configuration inside the engine compartment together with an external barrier B in a side view. FIG. 13 is a schematic diagram for explaining a collision line. FIG. 13 is a schematic diagram illustrating a modified example.

Below, several embodiments for implementing the present disclosure will be described with reference to the drawings. In each embodiment, parts corresponding to matters described in the preceding embodiment may be given the same reference numerals, and duplicated explanations may be omitted. In each embodiment, when only a part of the configuration is described, the other embodiment described previously may be applied to the other parts of the configuration.

In addition to combinations of parts that are explicitly stated as possible in each embodiment, it is also possible to partially combine embodiments together, embodiments and variations, and variations together, even if not explicitly stated, as long as there are no particular problems with the combination.

First Embodiment
<In-vehicle system>
First, an in-vehicle system 100 will be described with reference to Fig. 1. The in-vehicle system 100 constitutes a hybrid system.

The vehicle-mounted system 100 has a rotating electric machine device 800 including an electric device 300 and a rotating machine 400, and a battery 200. The vehicle-mounted system 100 also has an engine 500 and a power distribution mechanism 600. The rotating machine 400 has a first MG 401 and a second MG 402. MG is an abbreviation for motor generator. In the drawings, the battery 200 is abbreviated as "BATT" and the engine 500 is abbreviated as "ENG".

The in-vehicle system 100 further has multiple ECUs (not shown). These multiple ECUs transmit and receive signals to each other via bus wiring. The multiple ECUs cooperate to control the hybrid vehicle. Through cooperative control of the multiple ECUs, the power running and power generation (regeneration) of the rotating machine 400 according to the SOC of the battery 200, and the output of the engine 500 are controlled. SOC stands for state of charge. ECU stands for electronic control unit.

The battery 200 has multiple secondary batteries. These multiple secondary batteries are connected in series to form a battery stack. The secondary batteries may be lithium ion secondary batteries, nickel hydrogen secondary batteries, organic radical batteries, or the like.

The electric device 300 performs power conversion between the battery 200 and the first MG 401. The electric device 300 also performs power conversion between the battery 200 and the second MG 402. The electric device 300 converts the DC power of the battery 200 into AC power at a voltage level suitable for powering the first MG 401 and the second MG 402. The electric device 300 converts the AC power generated by the power generation of the first MG 401 and the second MG 402 into DC power at a voltage level suitable for charging the battery 200.

The first MG 401, the second MG 402, and the engine 500 are each connected to the power distribution mechanism 600.

The first MG 401 generates electricity using the rotational energy supplied from the engine 500. The AC power generated by this power generation is converted to DC power and the voltage is reduced by the electric device 300. This DC power is supplied to the battery 200. The DC power is also supplied to various electrical loads installed in the hybrid vehicle.

The second MG 402 is connected to the output shaft of the hybrid vehicle. The rotational energy of the second MG 402 is transmitted to the running wheels via the output shaft. Conversely, the rotational energy of the running wheels is transmitted to the second MG 402 via the output shaft.

The second MG 402 is powered by AC power supplied from the electric device 300. The rotational energy generated by this powering is distributed to the engine 500 and the running wheels by the power distribution mechanism 600. This cranks the crankshaft and provides a propulsive force to the running wheels.

The second MG 402 also regenerates power using the rotational energy transmitted from the running wheels. The AC power generated by this regeneration is converted to DC power and reduced in voltage by the electrical device 300. This DC power is supplied to the battery 200 and various electrical loads.

The engine 500 generates rotational energy by burning fuel. This rotational energy is distributed to the first MG 401 and the second MG 402 via the power distribution mechanism 600. This allows the first MG 401 to generate electricity and provide propulsive force to the running wheels.

The power distribution mechanism 600 has a planetary gear mechanism. The power distribution mechanism 600 has a sun gear, planetary gears, planetary carrier, and ring gear, which are not shown.

The motor shaft of the first MG 401 is connected to the sun gear. The crankshaft of the engine 500 is connected to the planetary carrier. The motor shaft of the second MG 402 is connected to the ring gear. As a result, the rotation speeds of the first MG 401, engine 500, and second MG 402 are in a linear relationship on the alignment chart.

When AC power is supplied from the electric device 300 to the first MG 401 and the second MG 402, torque is generated in the sun gear and the ring gear. Torque is generated in the planetary carrier by the combustion drive of the engine 500. This causes the first MG 401 to generate electricity, the second MG 402 to power and regenerate, and the driving force to be applied to the running wheels.

The MG ECU, one of the multiple ECUs described above, determines the target torque for each of the first MG 401 and the second MG 402 based on physical quantities detected by various sensors mounted on the hybrid vehicle and vehicle information input from other ECUs. The MG ECU then controls the torque generated in each of the first MG 401 and the second MG 402 so that it becomes the target torque.

<Circuit configuration of power conversion device>
Next, the electric device 300 will be described. As shown in Fig. 1, the electric device 300 includes a converter 310 and an inverter 320 as components of a power conversion circuit. The converter 310 functions to step up and down the voltage level of DC power. The inverter 320 functions to convert DC power to AC power. The inverter 320 functions to convert AC power to DC power.

The converter 310 boosts the DC power of the battery 200 to a voltage level suitable for torque generation in the first MG 401 and the second MG 402. The inverter 320 converts this DC power to AC power. This AC power is supplied to the first MG 401 and the second MG 402. The inverter 320 also converts the AC power generated by the first MG 401 and the second MG 402 to DC power. The converter 310 reduces the DC power to a voltage level suitable for charging the battery 200.

As shown in FIG. 1, the converter 310 is electrically connected to the battery 200 via a positive bus bar 301 and a negative bus bar 302. The converter 310 is electrically connected to the inverter 320 via a P bus bar 303 and an N bus bar 304.

<Converter>
The converter 310 has, as electric elements, a filter capacitor 311, an A-phase switch module 312, a reactor 313, and a DCDC converter 340. The DCDC converter 340 will be described later.

As shown in FIG. 1, one end of the positive bus bar 301 is connected to the positive electrode of the battery 200. One end of the negative bus bar 302 is connected to the negative electrode of the battery 200. One of the two electrodes of the filter capacitor 311 is connected to the positive bus bar 301. The other of the two electrodes of the filter capacitor 311 is connected to the negative bus bar 302.

One end of the reactor 313 is connected to the other end of the positive bus bar 301. The other end of the reactor 313 is connected to the A-phase switch module 312 via the first connecting bus bar 711. This electrically connects the positive electrode of the battery 200 and the A-phase switch module 312 via the reactor 313 and the first connecting bus bar 711. Note that in FIG. 1, the connection points of the various bus bars are indicated by white circles. These connection points are electrically connected, for example, by bolts 1000 or by welding.

The A-phase switch module 312 has a high-side switch 331 and a low-side switch 332. The A-phase switch module 312 also has a high-side diode 331a and a low-side diode 332a. These semiconductor elements are covered and protected by a sealing resin (not shown).

In this embodiment, N-channel IGBTs are used as the high-side switch 331 and the low-side switch 332. The tips of the terminals connected to the collector electrode, emitter electrode, and gate electrode of each of the high-side switch 331 and the low-side switch 332 are exposed outside the sealing resin.

As shown in FIG. 1, the emitter electrode of the high-side switch 331 and the collector electrode of the low-side switch 332 are connected. This connects the high-side switch 331 and the low-side switch 332 in series.

The cathode electrode of the high-side diode 331a is connected to the collector electrode of the high-side switch 331. The anode electrode of the high-side diode 331a is connected to the emitter electrode of the high-side switch 331. This results in the high-side diode 331a being connected in inverse parallel to the high-side switch 331.

Similarly, the cathode electrode of the low-side diode 332a is connected to the collector electrode of the low-side switch 332. The anode electrode of the low-side diode 332a is connected to the emitter electrode of the low-side switch 332. This results in the low-side diode 332a being connected in inverse parallel to the low-side switch 332.

As described above, the high-side switch 331 and the low-side switch 332 are covered and protected by sealing resin. This sealing resin exposes the collector electrode and gate electrode of the high-side switch 331, the midpoint between the high-side switch 331 and the low-side switch 332, and the tips of the terminals connected to the emitter electrode and gate electrode of the low-side switch 332. Below, these terminals are referred to as collector terminal 330a, midpoint terminal 330c, emitter terminal 330b, and gate terminal 330d.

The collector terminal 330a is connected to the P bus bar 303. The emitter terminal 330b is connected to the N bus bar 304. This causes the high-side switch 331 and the low-side switch 332 to be connected in series in the order from the P bus bar 303 to the N bus bar 304.

The midpoint terminal 330c is also connected to the first connecting bus bar 711. The first connecting bus bar 711 is electrically connected to the positive electrode of the battery 200 via the reactor 313 and the positive electrode bus bar 301.

As a result, DC power from the battery 200 is supplied to the midpoint of the two switches in the A-phase switch module 312 via the positive bus bar 301, the reactor 313, and the first connecting bus bar 711. The AC power of the rotating machine 400 converted to DC power by the inverter 320 is supplied to the collector electrode of the high-side switch 331 of the A-phase switch module 312. This AC power of the rotating machine 400 converted to DC power is supplied to the battery 200 via the high-side switch 331, the first connecting bus bar 711, the reactor 313, and the positive bus bar 301.

In this way, DC power flows through the first connecting bus bar 711 to input and output the battery 200. In terms of the physical quantity that flows, DC current flows through the first connecting bus bar 711 to input and output the battery 200.

The gate terminals 330d of the high-side switch 331 and the low-side switch 332 are connected to a gate driver (not shown). The MGECU generates a control signal and outputs it to the gate driver. The gate driver amplifies the control signal and outputs it to the gate terminal 330d. As a result, the high-side switch 331 and the low-side switch 332 are controlled to open and close by the MGECU. As a result, the voltage level of the DC power input to the converter 310 is increased or decreased.

The MGECU generates a pulse signal as a control signal. The MGECU adjusts the on-duty ratio and frequency of this pulse signal to adjust the step-up/step-down level of the DC power. This step-up/step-down level is determined according to the target torque of the rotating machine 400 and the SOC of the battery 200.

When boosting the DC power of the battery 200, the MGECU alternately opens and closes the high-side switch 331 and the low-side switch 332. Conversely, when lowering the DC power supplied from the inverter 320, the MGECU fixes the control signal output to the low-side switch 332 to a low level. At the same time, the MGECU switches the control signal output to the high-side switch 331 between a high level and a low level in sequence.

Next, the DC-DC converter 340 will be described. Details of the DC-DC converter 340 will be omitted, but the DC-DC converter 340 includes the semiconductor elements described above. The semiconductor elements included in the DC-DC converter 340 are PWM controlled by some of the ECUs described above. This allows the high-voltage DC power supplied from the battery 200 to be down-converted to low-voltage DC power. Note that in the drawings, the DC-DC converter 340 is abbreviated to "DCDC".

As shown in FIG. 1, the DC-DC converter 340 is connected to the positive bus bar 301 and the negative bus bar 302. The DC-DC converter 340 is connected to an auxiliary battery (not shown) via a cable (not shown). The DC power down-converted by the DC-DC converter 340 is charged to the auxiliary battery via the cable.

The auxiliary equipment mounted on the vehicle is electrically connected to the auxiliary battery. Power is supplied from the auxiliary battery to the auxiliary equipment. Examples of the auxiliary equipment include a power steering device, a floodlight device, and various electronic control units.

<Inverter>
The inverter 320 has, as electric elements, a smoothing capacitor 321 , a discharge resistor (not shown), and a U-phase switch module 322 to a Z-phase switch module 327 .

One of the two electrodes of the smoothing capacitor 321 is connected to the P bus bar 303. The other of the two electrodes of the smoothing capacitor 321 is connected to the N bus bar 304. The discharge resistor is also connected to the P bus bar 303 and the N bus bar 304. The U-phase switch module 322 to the Z-phase switch module 327 are also connected to the P bus bar 303 and the N bus bar 304. The smoothing capacitor 321, the discharge resistor, and the U-phase switch module 322 to the Z-phase switch module 327 are each connected in parallel between the P bus bar 303 and the N bus bar 304.

Each of the U-phase switch module 322 to the Z-phase switch module 327 has the same components as the A-phase switch module 312. That is, each of the U-phase switch module 322 to the Z-phase switch module 327 has a high-side switch 331, a low-side switch 332, a high-side diode 331a, a low-side diode 332a, and a sealing resin. Each of these six-phase switch modules also has a collector terminal 330a, an emitter terminal 330b, a midpoint terminal 330c, and a gate terminal 330d. The high-side switch 331 and the low-side switch 332 correspond to switch elements.

The collector terminal 330a of each of these six-phase switch modules is connected to the P bus bar 303. The emitter terminal 330b is connected to the N bus bar 304.

The midpoint terminal 330c of the U-phase switch module 322 is connected to the U-phase stator coil of the first MG 401 via the second connecting bus bar 712. The midpoint terminal 330c of the V-phase switch module 323 is connected to the V-phase stator coil of the first MG 401 via the third connecting bus bar 713. The midpoint terminal 330c of the W-phase switch module 324 is connected to the W-phase stator coil of the first MG 401 via the fourth connecting bus bar 714.

Similarly, the midpoint terminal 330c of the X-phase switch module 325 is connected to the X-phase stator coil of the second MG 402 via the fifth connecting bus bar 715. The midpoint terminal 330c of the Y-phase switch module 326 is connected to the Y-phase stator coil of the second MG 402 via the sixth connecting bus bar 716. The midpoint terminal 330c of the Z-phase switch module 327 is connected to the Z-phase stator coil of the second MG 402 via the seventh connecting bus bar 717.

The gate terminal 330d of each of these six-phase switch modules is connected to the gate driver. When the first MG 401 and the second MG 402 are powered, the high-side switch 331 and the low-side switch 332 of the six-phase switch module are PWM-controlled by the output of a control signal from the MGECU. This generates three-phase AC in the inverter 320. When the first MG 401 and the second MG 402 generate (regenerate) power, the MGECU, for example, stops outputting the control signal. This causes the AC power generated by the power generation to pass through the diodes of the six-phase switch modules. As a result, the AC power is converted into DC power.

The AC power input to and output from the first MG 401 and the second MG 402 described above flows through the second connecting bus bar 712 to the seventh connecting bus bar 717 that connect the first MG 401 and the second MG 402 to the inverter 320. In terms of the physical quantity that flows, the AC power input to and output from the first MG 401 and the second MG 402 flows through the second connecting bus bar 712 to the seventh connecting bus bar 717.

The type of switch element provided in each of the A-phase switch module 312 and the U-phase switch module 322 to the Z-phase switch module 327 is not particularly limited, and for example, a MOSFET can be used. In this case, a reflux diode is connected in inverse parallel to each MOSFET. The diode may be a parasitic diode (body diode) of the MOSFET, or may be provided separately from the parasitic diode. The anode of the diode is connected to the source of the corresponding MOSFET, and the cathode is connected to the drain.

The semiconductor elements, such as switches and diodes, contained in these switch modules can be manufactured from semiconductors such as Si and wide-gap semiconductors such as SiC. There are no particular limitations on the materials used to make the semiconductor elements.

<Mechanical configuration of rotating electrical machine>
Next, the mechanical configuration of the rotating electric machine device 800 will be described. In the following, three directions that are mutually orthogonal are defined as the front-rear direction, the width direction, and the height direction. The height direction is the direction of gravity. The front-rear direction is the direction along the traveling direction of the vehicle. The front corresponds to the traveling direction of the vehicle. The rear corresponds to the backward moving direction of the vehicle. In Figures 2 to 8, the left corresponds to the front of the vehicle, and the right corresponds to the rear of the vehicle. The width direction is the direction that is orthogonal to the height direction and the front-rear direction.

As shown in FIG. 2, the vehicle has an engine compartment 10 at the front that houses an engine 500 and a rotating electrical device 800. The upper part of the engine compartment 10 is covered by a hood panel 11.

The rear of the engine room 10 is separated from the passenger compartment by a partition wall. As shown in FIG. 2, the rotating electric machine 800 is provided in the engine room 10 in a manner that tilts downward in the direction of gravity from the rear of the vehicle to the front of the vehicle. Note that the rotating electric machine 800 does not have to be tilted from the rear of the vehicle to the front of the vehicle. This disclosure is also applicable to systems that do not include an engine 500. The engine room 10 may also be called the vehicle's machinery room 10.

As shown in FIG. 2, the first case 910 is disposed below the vehicle in the direction of gravity, i.e., in the height direction. The second case 920 is disposed above the vehicle in the direction of gravity, i.e., in the height direction. Note that the engine 500 is not shown in the drawing.

In addition to the components described above, the rotating electrical machine 800 has a case for housing various electrical components, a cooler 390, a sensor unit 700, a first case 910, and a second case 920.

Cases for housing various electrical components include a filter capacitor case 311a, a smoothing capacitor case 321a, a reactor case 313a, and a DCDC converter case 340a, as shown in Figures 2 to 4.

The filter capacitor case 311a, the smoothing capacitor case 321a, and the reactor case 313a are each formed from an insulating resin material. The DCDC converter case 340a is formed by casting a metal member, etc.

The filter capacitor 311 is housed in the filter capacitor case 311a. The smoothing capacitor 321 is housed in the smoothing capacitor case 321a. The reactor 313 is housed in the reactor case 313a. The DC-DC converter 340 is housed in the DC-DC converter case 340a. The DC-DC converter 340 and the filter capacitor 311 correspond to low-profile components.

Note that the various bus bars and control boards on which the ECU and gate drivers are mounted that have been described so far have been omitted from the drawings.

The switch modules included in the converter 310 and inverter 320 are housed in the cooler 390. The cooler 390 functions to cool these multiple switch modules. The multiple switch modules housed in the cooler 390 form a power module 391. Details of the cooler 390 will be described later.

<Case 1 and Case 2>
Next, a description will be given of the first case 910 and the second case 920. The first case 910 is a case that houses the first MG 401 and the second MG 402. The second case 920 is a case that houses the power module 391, the filter capacitor case 311a, the smoothing capacitor case 321a, the reactor case 313a, the DCDC converter case 340a, and the sensor unit 700.

The first case 910 and the second case 920 are mechanically connected directly via the bolts 1000, without a bracket or the like. This forms a so-called mechanically and electrically integrated electric device 300. The specific configurations of the first case 910 and the second case 920 are described below.

<Case 1>
3, the first case 910 has a bottom 911, a first annular wall 912, and an opposing portion 913. The bottom 911 has a flat shape with a small thickness in the height direction. The bottom 911 has a first surface 911a and a first back surface 911b on the reverse side thereof.

The first annular wall 912 is connected to the first surface 911a. The first annular wall 912 stands up in an annular shape from the first surface 911a. The first annular wall 912 has a first lower portion 912a and a third lower portion 912c spaced apart from each other in the front-rear direction, and a second lower portion 912b and a fourth lower portion 912d spaced apart from each other in the width direction.

The first annular wall 912 is formed by connecting the first lower portion 912a to the fourth lower portion 912d in order in the circumferential direction about the height direction. The first lower portion 912a is disposed on the front side of the vehicle. The third lower portion 912c is disposed on the rear side of the vehicle. The second lower portion 912b is disposed on the right side of the vehicle. The fourth lower portion 912d is disposed on the left side of the vehicle.

The first case 910 is disposed lower in the vehicle height direction than the second case 920. For this reason, in this embodiment, the side portion of the first annular wall 912 is referred to as the lower portion.

As shown in FIG. 3, the first lower portion 912a and the third lower portion 912c are formed with a first fastening portion 914 that extends away from them in the front-rear direction. The first fastening portion 914 is fastened to a second fastening portion 924 described below via a bolt 1000, so that the first case 910 and the second case 920 are directly mechanically connected. Note that even if a packing or sealant is interposed between the first fastening portion 914 and the second fastening portion 924, the first fastening portion 914 and the second fastening portion 924 can be considered to be directly connected as long as they are fastened via a bolt 1000.

The first fastening portion 914 does not have to be formed on the first lower portion 912a and the third lower portion 912c. The first fastening portion 914 may be formed anywhere on the first annular wall 912 as long as it is formed thereon.

As shown in FIG. 3, a first storage space 915 is defined by the bottom 911 and the first annular wall 912. A first opening 910a is formed on the side of the first annular wall 912 away from the first surface 911a. An opposing portion 913 that faces the bottom 911 in the height direction and has a flat shape is provided between the portion of the first annular wall 912 facing the first surface 911a and the portion of the first opening 910a. Note that the opposing portion 913 does not have to be formed on the first annular wall 912.

The first storage space 915 is divided into two by the opposing portion 913. The first MG 401 and the second MG 402 are stored in the storage space on the bottom 911 side of the first storage space 915, which is divided into two. In this manner, the rotation device 410 is configured. The first MG 401 and the second MG 402 are stored in the storage space in a manner that they are spaced apart in the front-to-rear direction.

<Case 2>
As shown in Figure 3, the second case 920 has a second annular wall 921 that forms a ring in the circumferential direction around the height direction, a lid portion 923 that closes one of the openings of the second annular wall 921, and a partition portion 922 that partitions a second storage space 928 described below.

The second annular wall 921 has a first upper portion 921a and a third upper portion 921c spaced apart in the front-rear direction, and a second upper portion 921b and a fourth upper portion 921d spaced apart in the width direction. The first upper portion 921a to the fourth upper portion 921d are connected in order in the circumferential direction around the height direction to form the second annular wall 921. The first upper portion 921a is located in the front of the vehicle. The third upper portion 921c is located in the rear of the vehicle. The second upper portion 921b is located to the right of the vehicle. The fourth upper portion 921d is located to the left of the vehicle.

The second case 920 is disposed higher in the vehicle height direction than the first case 910. For this reason, in this embodiment, the side portion of the second annular wall 921 is referred to as the upper portion.

As shown in FIG. 3, the first upper portion 921a and the third upper portion 921c are formed with second fastening portions 924 that extend away from them in the front-rear direction. The second fastening portions 924 are fastened to the first fastening portions 914 via bolts 1000, thereby mechanically connecting the second case 920 and the first case 910. Note that the second fastening portions 924 do not have to be formed on the first upper portion 921a and the third upper portion 921c. The second fastening portions 924 may be formed anywhere on the second annular wall 921 as long as they are formed thereon.

Also, as shown in FIG. 3, the height projection area of the portion of the second annular wall 921 located on the first annular wall 912 side includes a portion of the second annular wall 921 located away from the first annular wall 912.

For ease of explanation, the portion of the second annular wall 921 located on the first annular wall 912 side is referred to as the lower annular wall 925. The portion of the second annular wall 921 located away from the first annular wall 912 is referred to as the upper annular wall 926. The upper annular wall 926 is included in the heightwise projection area of the lower annular wall 925.

The first upper portion 921a of the upper annular wall 926 is positioned to be shifted toward the rear of the vehicle in the front-to-rear direction from the first upper portion 921a of the lower annular wall 925. The third upper portion 921c of the upper annular wall 926 is positioned to be shifted toward the front of the vehicle in the front-to-rear direction from the third upper portion 921c of the lower annular wall 925.

The amount of deviation of the first upper portion 921a of the upper annular wall 926 toward the rear of the vehicle is longer than the diameter of the supply pipe 390a and the discharge pipe 390c described below. The diameters of the supply pipe 390a and the discharge pipe 390c may be either the inner diameter or the outer diameter. Furthermore, the amount of deviation of the first upper portion 921a of the upper annular wall 926 toward the rear of the vehicle may be longer than the diameter of either the supply pipe 390a or the discharge pipe 390c.

The second upper portion 921b of the upper annular wall 926 is disposed to the left of the vehicle in the vehicle width direction relative to the second upper portion 921b of the lower annular wall 925. The fourth upper portion 921d of the upper annular wall 926 is disposed to the right of the vehicle in the vehicle width direction relative to the fourth upper portion 921d of the lower annular wall 925.

As shown in FIG. 3, the second annular wall 921 has a connecting portion 927 that connects the lower annular wall 925 and the upper annular wall 926 in addition to the lower annular wall 925 and the upper annular wall 926. The end of the lower annular wall 925 on the upper annular wall 926 side and the end of the upper annular wall 926 on the lower annular wall 925 side are connected by the connecting portion 927.

A second opening 920a is formed at the end of the lower annular wall 925 on the side of the first annular wall 912. A third opening 920b is formed at the end of the upper annular wall 926 away from the first annular wall 912. A lid 923 is provided at the end of the upper annular wall 926 on the side of the third opening 920b in such a manner as to close the third opening 920b.

In this way, the second storage space 928 is defined by the lower annular wall 925, the upper annular wall 926, the connecting portion 927, and the lid portion 923. The second case 920 does not necessarily have to include the lid portion 923. The second storage space 928 may be defined by the lower annular wall 925, the upper annular wall 926, and the connecting portion 927.

<Electrical Equipment>
Next, a description will be given of the electric device 300. As shown in Fig. 3, a partition 922 is provided at the boundary between a lower annular wall 925 and an upper annular wall 926. Therefore, the second storage space 928 is divided into two by the partition 922.

The above-mentioned power module 391, reactor case 313a, smoothing capacitor case 321a, and sensor unit 700 are stored in the space between the partition 922 and the lid 923 in the second storage space 928. In other words, the power module 391, reactor case 313a, smoothing capacitor case 321a, and sensor unit 700 are stored in the space surrounded by the upper annular wall 926 in the second storage space 928.

The above-mentioned DC-DC converter case 340a and filter capacitor case 311a are stored in the area that combines the space between the partition 922 and the third opening 920b in the second storage space 928 and a part of the first storage space 915. In other words, the DC-DC converter case 340a and the filter capacitor case 311a are stored in the space that combines the space surrounded by the lower annular wall 925 in the second storage space 928 and the space on the first opening 910a side of the opposing portion 913 of the first storage space 915. In this manner, the electric device 300 is configured.

As shown in FIG. 3, the partition 922 has a first mounting portion 931 connected to the first inner wall surface 926a of the upper annular wall 926 and a second mounting portion 932 connected to the second inner wall surface 927a of the connecting portion 927. The first mounting portion 931 has a first mounting surface 931a spaced apart from each other in the height direction and a first mounting back surface 931b on the back side thereof. The second mounting portion 932 has a second mounting surface 932a spaced apart from each other in the height direction and a second mounting back surface 932b on the back side thereof. The first mounting portion 931 is provided on the first inner wall surface 926a with the first mounting surface 931a facing the lid portion 923. The second mounting portion 932 is provided on the second inner wall surface 927a with the second mounting back surface 932b facing the first mounting back surface 931b.

Furthermore, the power module 391, reactor case 313a, smoothing capacitor case 321a, and sensor unit 700 are mounted on the first mounting surface 931a. The DC-DC converter case 340a and filter capacitor case 311a described above are mounted on the second mounting surface 932a on the first case 910 side of the second mounting part 932. Note that the power module 391 does not have to be mounted on the first mounting part 931. The power module 391 may be fixed to the upper annular wall 926.

As shown in Figures 3 and 4, the height of the DC-DC converter case 340a in the height direction is lower than the height of the reactor case 313a in the height direction. The height of the filter capacitor case 311a in the height direction is lower than the height of the reactor case 313a in the height direction.

The height projection area of the DC-DC converter case 340a onto the second mounting surface 932a is larger than the height projection area of the reactor case 313a onto the first mounting surface 931a. The height projection area of the filter capacitor case 311a onto the second mounting surface 932a is smaller than the height projection area of the reactor case 313a onto the first mounting surface 931a.

As shown in Figures 3 and 4, the power module 391 is mounted further forward in the vehicle in the fore-and-aft direction than the reactor case 313a. The DCDC converter case 340a is mounted further forward in the vehicle in the fore-and-aft direction than the filter capacitor case 311a. The smoothing capacitor case 321a is mounted on the right side of the vehicle in the width direction than the power module 391. The sensor unit 700 is mounted on the left side of the vehicle in the direction than the power module 391.

As described above, the first mounting portion 931 is provided on the first inner wall surface 926a of the upper annular wall 926. The second mounting portion 932 is provided on the second inner wall surface 927a of the connecting portion 927. As shown in FIG. 3, the first mounting portion 931 and the second mounting portion 932 are arranged apart from each other in the height direction. A flow path 933 is provided between the first mounting portion 931 and the second mounting portion 932.

As shown in FIG. 5, the flow path 933 is substantially U-shaped when viewed in a plan view in the height direction. A refrigerant is passed through the flow path 933. This actively cools the power module 391, reactor case 313a, smoothing capacitor case 321a, DCDC converter case 340a, filter capacitor case 311a, and sensor unit 700.

<Cooling structure>
As described above, the flow path 933 is substantially U-shaped in a plan view in the height direction. The flow path 933 extends in one direction along the substantially U-shape. A supply port 933a through which the coolant is supplied is formed at one end of the flow path 933 in one direction. A discharge port 933b through which the coolant is discharged is formed at the other end of the flow path 933 in one direction.

As described above, the power module 391 includes a cooler 390. As shown in Figures 3 and 4, the cooler 390 has a supply pipe 390a, an exhaust pipe 390c, and multiple relay pipes 390b.

The supply pipe 390a and the discharge pipe 390c extend in the front-rear direction. The supply pipe 390a and the discharge pipe 390c are spaced apart in the width direction. Each of the multiple relay pipes 390b extends in the width direction from the supply pipe 390a to the discharge pipe 390c.

As shown in Figures 3 and 4, one end of the supply pipe 390a and the discharge pipe 390c protrudes outside the upper annular wall 926. One end of the supply pipe 390a is connected to the discharge port 933b of the flow path 933 described above by a connecting pipe (not shown).

When the refrigerant is supplied from the supply port 933a of the flow path 933 described above, the refrigerant passes through the flow path 933 and is discharged from the discharge port 933b. The refrigerant discharged from the discharge port 933b is supplied to the supply pipe 390a of the cooler 390 through a connecting pipe (not shown). The refrigerant supplied to the supply pipe 390a flows to the discharge pipe 390c through multiple relay pipes 390b. It is then discharged to the outside.

<Mounting of Rotating Electric Machine Device on Vehicle>
Fig. 6 is a diagram showing a schematic side view of the configuration inside the engine compartment 10 together with an external barrier B. The external barrier B shown in Fig. 6 is formed of, for example, a concrete block, an iron block, etc. Fig. 6 shows an example in which the external barrier B is provided between a position P1 spaced a predetermined height from the ground G and a position P2 spaced a predetermined height from the ground G.

This is because it is assumed that the vehicle will collide with the rear corner of the platform of a truck or the like, which has a higher height from the ground G to the chassis than a passenger car, and is on the side of the ground G. As shown in FIG. 6, position P1 is located higher on the vehicle's upper side in the height direction than the first upper portion 921a of the lower annular wall 925.

Figure 7 is a side view showing the state when the vehicle collides with an external barrier B from the front and the external barrier B advances toward the upper annular wall 926 in the engine compartment 10. The first upper portion 921a of the upper annular wall 926 is located behind the collision line L, which is the forefront of the external barrier B that approaches the upper annular wall 926 relatively due to the front collision.

This is because the hood panel 11 and a radiator (not shown) are placed between the external barrier B and the upper annular wall 926, and these absorb shocks from the outside. Therefore, the upper annular wall 926 is less likely to receive shocks than the hood panel 11 and the radiator.

<Action and effect>
As described above, the power module 391, the reactor case 313a, the smoothing capacitor case 321a, and the sensor unit 700 are housed in the space surrounded by the upper annular wall 926 of the second storage space 928. The first upper portion 921a of the upper annular wall 926 is disposed to be shifted toward the rear of the vehicle in the front-rear direction relative to the first upper portion 921a of the lower annular wall 925.

As a result, when the vehicle collides in front with, for example, the corner of the bed of a truck, even if the corner of the bed approaches the first upper portion 921a of the upper annular wall 926, the corner of the bed is less likely to hit the first upper portion 921a of the upper annular wall 926. This makes it less likely that an impact will be applied to electrical components such as the power module 391.

As explained above, the first case 910 and the second case 920 are mechanically connected directly via the bolts 1000 without a bracket or the like. This makes it possible to prevent an increase in the number of parts.

It is now possible to simultaneously suppress the impact on electrical components such as the power module 391 and prevent an increase in the number of components.

As explained above, the first upper portion 921a of the upper annular wall 926 is located behind the collision line L, which is the frontmost portion of the external barrier B that approaches the upper annular wall 926 relatively due to a collision in front of the vehicle.

As a result, when the vehicle collides in front with, for example, the corner of the bed of a truck, even if the corner of the bed comes relatively close to the first upper portion 921a of the upper annular wall 926, the corner of the bed will not come into contact with the first upper portion 921a of the upper annular wall 926. As a result, no impact is applied to electrical components such as the power module 391.

In addition, since the corners of the truck bed are expected to be located above the vehicle relative to the first upper portion 921a of the lower annular wall 925, they do not come into contact with the lower annular wall 925. As a result, the DCDC converter 340 and the filter capacitor 311 are also not subjected to impact.

As explained above, the power module 391, reactor case 313a, smoothing capacitor case 321a, and sensor unit 700 are mounted on the first mounting surface 931a. The DCDC converter case 340a and filter capacitor case 311a are mounted on the second mounting surface 932a of the second mounting section 932.

The height of the DC-DC converter case 340a in the height direction is lower than the height of the reactor case 313a in the height direction. The height of the filter capacitor case 311a in the height direction is lower than the height of the reactor case 313a in the height direction.

The DCDC converter case 340a and the filter capacitor case 311a are stored in the space that is the combination of the space surrounded by the lower annular wall 925 of the second storage space 928 and the space on the first opening 910a side of the opposing portion 913 of the first storage space 915.

Because the rotating machine 400 is stored in the space on the bottom 911 side of the first storage space 915, the space on the first opening 910a side is narrower than the opposing portion 913 of the first storage space 915. However, in this embodiment, low-profile parts that are shorter than the reactor case 313a are actively stored in the space that combines this space with the space surrounded by the lower annular wall 925 of the second storage space 928.

Furthermore, the height projection area of the DCDC converter case 340a is larger than the height projection area of the reactor case 313a. The height projection area of the filter capacitor case 311a is smaller than the height projection area of the reactor case 313a.

This makes it easier to efficiently arrange electrical components in the space surrounded by the lower annular wall 925 of the second storage space 928 and the space closer to the first opening 910a than the opposing portion 913 of the first storage space 915. As a result, dead space is less likely to occur in this space. It is easier to prevent the size of the electrical device 300 from increasing in height. For example, it is now possible to store engine parts in the space above the engine 500 in the engine compartment 10.

As explained above, a flow path 933 through which a coolant passes is provided between the first mounting portion 931 and the second mounting portion 932. This improves the cooling efficiency of the electrical components mounted on the first mounting portion 931 and the second mounting portion 932. It is possible to actively cool the various bus bars and filter capacitors 311 that become hot when a large current flows through the power conversion circuit shown in FIG. 1.

(First Modification)
In the present embodiment, the power module 391 is provided closer to the first upper portion 921a than the reactor case 313a. However, as illustrated in Fig. 8, the reactor case 313a may be provided closer to the first upper portion 921a than the power module 391. Even in this case, it is possible to suppress both the impact on the electric components such as the power module 391 and the increase in the number of components.

(Second Modification)
In this embodiment, the DC-DC converter case 340a and the filter capacitor case 311a are stored in a space that is a combination of the space surrounded by the lower annular wall 925 of the second storage space 928 and the space on the first opening 910a side of the opposing portion 913 of the first storage space 915. However, although not shown, the DC-DC converter case 340a does not have to be stored in this space.

The arrangement of the reactor case 313a, smoothing capacitor case 321a, sensor unit 700, DCDC converter case 340a, and filter capacitor case 311a housed in the second case 920 is not limited. Not all of the reactor case 313a, smoothing capacitor case 321a, sensor unit 700, DCDC converter case 340a, and filter capacitor case 311a need to be housed in the second case 920. It is sufficient that at least the power module 391 is housed in the space surrounded by the upper annular wall 926 of the second storage space 928.

Although the present disclosure has been described with reference to the embodiment, it is understood that the present disclosure is not limited to the embodiment or structure. The present disclosure also encompasses various modifications and modifications within the scope of equivalents. In addition, while various combinations and forms are shown in the present disclosure, other combinations and forms including only one element, more, or less are also within the scope and spirit of the present disclosure.

10...engine compartment, 300...electrical device, 311...filter capacitor, 313...reactor, 340...DC-DC converter, 391...power module, 400...rotating machine, 410...rotating device, 910...first case, 911...bottom, 912...first annular wall, 915...first storage space, 920...second case, 921...second annular wall, 922...partition, 925...lower annular wall, 926...upper annular wall, 928...second storage space

Claims (4)

An electric device (300) connected to a rotating device (410) having a rotating machine (400) housed in a first case (910) provided in a machine room (10) of a vehicle and having a first storage space (915) defined by a bottom (911) and a first annular wall (912) standing annularly from the bottom,
a second case (920) including a second annular wall (921) that is aligned with the first case in a height direction perpendicular to the bottom and includes a lower annular wall (925) located on the first annular wall side in the height direction and an upper annular wall (926) located on a side farther away from the first annular wall in the height direction than the lower annular wall;
a power module (391) accommodated in a space surrounded by the upper annular wall of a second storage space (928) partitioned by the second annular wall;
a portion of the upper annular wall on a front side of the vehicle is located rearward of the vehicle relative to the portion of the lower annular wall on the front side ,
a reactor (313) that is accommodated in a space surrounded by the upper annular wall of the second accommodation space and is electrically connected to the power module;
a low-profile component (340, 311) that is stored in a space that combines the space surrounded by the lower annular wall of the second storage space and the first storage space, and is electrically connected to the power module and the reactor, the low-profile component having a height lower than the reactor in the height direction . The electrical device according to claim 1, wherein the forward portion of the upper annular wall is disposed behind a predetermined collision line that is the frontmost surface of the barrier that approaches the upper annular wall relatively when the vehicle strikes an external barrier in front of the vehicle. The second case has a partition (922) that partitions the upper annular wall and the lower annular wall,
the power module, the reactor, and the low-profile component are mounted in the partition;
3. An electric device according to claim 1, wherein a coolant flows through said compartment. a rotating device (410) in which a rotating machine (400) is housed in a first case (910) provided in a machine room (10) of a vehicle and having a first storage space (915) defined by a bottom (911) and a first annular wall (912) standing annularly from the bottom;
a second case (920) including a second annular wall (921) that is aligned with the first case in a height direction perpendicular to the bottom and includes a lower annular wall (925) located on the first annular wall side in the height direction and an upper annular wall (926) located on a side farther away from the first annular wall in the height direction than the lower annular wall; and an electric device (300) including a power module (391) that is stored in a space surrounded by the upper annular wall within a second storage space (928) partitioned by the second annular wall,
a portion of the upper annular wall on a front side of the vehicle is located rearward of the vehicle relative to the portion of the lower annular wall on the front side ,
The electrical device (300) comprises:
a reactor (313) that is accommodated in a space surrounded by the upper annular wall of the second accommodation space and is electrically connected to the power module;
a low-profile component (340, 311) that is stored in a space that combines the space surrounded by the lower annular wall of the second storage space and the first storage space, is electrically connected to the power module and the reactor, and has a height that is shorter in the height direction than the reactor .

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