JP7484113B2 - Drive unit - Google Patents

Description

The present invention relates to a drive device.

Rotating electric machines are known that cool the stator with a refrigerant flow passage through which a refrigerant flows. For example, Patent Document 1 describes a rotating electric machine that cools the stator by supplying cooling oil from multiple pipes.

JP 2019-9967 A

In rotating electric machines like the one described above, there was a need to more efficiently cool the stator using the coolant supplied from the coolant flow path.

In view of the above circumstances, one of the objectives of the present invention is to provide a drive unit having a structure that can improve the cooling efficiency of the stator.

One aspect of the drive device of the present invention includes a motor having a rotor rotatable around a motor shaft and a stator located radially outside the rotor, and a refrigerant flow path through which a refrigerant flows. The stator has a stator core surrounding the rotor. The refrigerant flow path has a first supply port and a second supply port that supply the refrigerant to the stator core radially outside the stator core. The second supply port is located vertically above the stator core. When viewed in the axial direction of the motor shaft, the first supply port opens in a direction in which a tangent line passing through the first supply port and touching the outer circumferential surface of the stator core is inclined radially outward from a direction extending from the first supply port toward the outer circumferential surface of the stator core, and when viewed in the axial direction of the motor shaft, the second supply port opens in a direction vertically downward from a direction in which a tangent line passing through the second supply port and touching the outer circumferential surface of the stator core is inclined radially outward from a direction extending from the second supply port toward the outer circumferential surface of the stator core.
Also, one aspect of the drive device of the present invention includes a motor having a rotor rotatable around a motor shaft and a stator located radially outside the rotor, and a refrigerant flow path through which a refrigerant flows. The stator has a stator core surrounding the rotor. The refrigerant flow path has a first supply port and a second supply port that supply the refrigerant to the stator core radially outside the stator core. When viewed in the axial direction of the motor shaft, the first supply port opens in a direction in which a tangent line passing through the first supply port and touching the outer circumferential surface of the stator core is inclined radially outward from a direction extending from the first supply port toward the outer circumferential surface of the stator core. When viewed in the axial direction of the motor shaft, the second supply port opens in a direction in which a tangent line passing through the second supply port and touching the outer circumferential surface of the stator core is inclined radially inward from a direction extending from the second supply port toward the outer circumferential surface of the stator core.

According to one aspect of the present invention, the cooling efficiency of the stator in the drive unit can be improved.

FIG. 1 is a schematic diagram showing a drive device according to a first embodiment. FIG. 2 is a perspective view showing a stator, a first pipe, and a second pipe according to the first embodiment. FIG. 3 is a cross-sectional view showing a part of the drive device of the first embodiment, taken along line III-III in FIG. FIG. 4 is a cross-sectional view showing a part of the drive device of the first embodiment, taken along line IV-IV in FIG. FIG. 5 is a perspective view showing the first pipe of the first embodiment. FIG. 6 is a view of a part of the stator, a first pipe, and a second pipe according to the first embodiment, as viewed from the left side. FIG. 7 is a view of a part of a stator, a first pipe, and a second pipe according to the second embodiment, as viewed from the left side.

In the following description, the vertical direction is defined based on the positional relationship when the drive device 1 of this embodiment shown in each figure is mounted on a vehicle located on a horizontal road surface. In addition, in the drawings, the XYZ coordinate system is appropriately shown as a three-dimensional orthogonal coordinate system. In the XYZ coordinate system, the Z axis direction is the vertical direction. The +Z side is the upper side in the vertical direction, and the -Z side is the lower side in the vertical direction. In the following description, the upper side in the vertical direction is simply called the "upper side", and the lower side in the vertical direction is simply called the "lower side". The X axis direction is a direction perpendicular to the Z axis direction and is the front-rear direction of the vehicle on which the drive device 1 is mounted. In the following embodiment, the +X side is the front side of the vehicle, and the -X side is the rear side of the vehicle. The Y axis direction is a direction perpendicular to both the X axis direction and the Z axis direction, and is the left-right direction of the vehicle, that is, the vehicle width direction. In the following embodiment, the +Y side is the left side of the vehicle, and the -Y side is the right side of the vehicle. The front-rear direction and the left-right direction are horizontal directions perpendicular to the vertical direction.

The positional relationship in the front-rear direction is not limited to that in the following embodiment, and the +X side may be the rear side of the vehicle and the -X side may be the front side of the vehicle. In this case, the +Y side is the right side of the vehicle and the -Y side is the left side of the vehicle.

The motor shaft J1, which is shown appropriately in each figure, extends in a direction intersecting the vertical direction. More specifically, the motor shaft J1 extends in the Y-axis direction, i.e., in the left-right direction of the vehicle. In the following description, unless otherwise specified, the direction parallel to the motor shaft J1 will be simply referred to as the "axial direction", the radial direction centered on the motor shaft J1 will be simply referred to as the "radial direction", and the circumferential direction centered on the motor shaft J1, i.e., around the axis of the motor shaft J1, will be simply referred to as the "circumferential direction". Note that in this specification, "parallel direction" includes a direction that is approximately parallel, and "orthogonal direction" includes a direction that is approximately orthogonal.

First Embodiment
A drive device 1 according to the present embodiment shown in Fig. 1 is mounted on a vehicle powered by a motor, such as a hybrid electric vehicle (HEV), a plug-in hybrid electric vehicle (PHV), or an electric vehicle (EV), and is used as the power source thereof. As shown in Fig. 1, the drive device 1 includes a motor 2, a transmission device 3 including a reduction gear 4 and a differential gear 5, a housing 6, an oil pump 96, a cooler 97, and a pipe 10. Note that in this embodiment, the drive device 1 does not include an inverter unit. In other words, the drive device 1 is structured separately from the inverter unit.

The housing 6 accommodates the motor 2 and the transmission device 3 therein. The housing 6 has a motor accommodating section 61, a gear accommodating section 62, and a partition wall 61c. The motor accommodating section 61 accommodates the rotor 20 and the stator 30 described below. The gear accommodating section 62 accommodates the transmission device 3 therein. The gear accommodating section 62 is located on the left side of the motor accommodating section 61. The bottom 61a of the motor accommodating section 61 is located above the bottom 62a of the gear accommodating section 62. The partition wall 61c axially divides the interior of the motor accommodating section 61 from the interior of the gear accommodating section 62. A partition wall opening 68 is provided in the partition wall 61c. The partition wall opening 68 connects the interior of the motor accommodating section 61 to the interior of the gear accommodating section 62. The partition wall 61c is located on the left side of the stator 30. That is, in this embodiment, the partition wall 61c corresponds to the axial wall portion located on one axial side of the stator 30.

The housing 6 contains oil O as a refrigerant inside. In this embodiment, the oil O is contained inside the motor housing portion 61 and inside the gear housing portion 62. An oil reservoir P in which the oil O accumulates is provided in the lower region inside the gear housing portion 62. The oil O in the oil reservoir P is sent to the inside of the motor housing portion 61 by an oil passage 90 described below. The oil O sent to the inside of the motor housing portion 61 accumulates in the lower region inside the motor housing portion 61. At least a portion of the oil O that has accumulated inside the motor housing portion 61 moves to the gear housing portion 62 through the partition opening 68 and returns to the oil reservoir P.

In this specification, "oil is stored inside a certain part" means that oil is located inside a certain part at least part of the time while the motor is running, and oil does not have to be located inside a certain part when the motor is stopped. For example, in this embodiment, oil O is stored inside the motor housing part 61 means that oil O is located inside the motor housing part 61 at least part of the time while the motor 2 is running, and when the motor 2 is stopped, all of the oil O inside the motor housing part 61 may have moved to the gear housing part 62 through the partition opening 68. Note that a portion of the oil O sent to the inside of the motor housing part 61 by the oil passage 90 described later may remain inside the motor housing part 61 when the motor 2 is stopped.

The oil O circulates in the oil passage 90, which will be described later. The oil O is used to lubricate the reduction gear 4 and the differential gear 5. The oil O is also used to cool the motor 2. As the oil O, it is preferable to use an oil equivalent to the lubricating oil for automatic transmissions (ATF: Automatic Transmission Fluid), which has a relatively low viscosity, in order to function as a lubricating oil and a cooling oil.

In this embodiment, the motor 2 is an inner rotor type motor. The motor 2 includes a rotor 20, a stator 30, and bearings 26 and 27. The rotor 20 can rotate around a motor axis J1 that extends in the horizontal direction. The rotor 20 includes a shaft 21 and a rotor body 24. Although not shown, the rotor body 24 includes a rotor core and a rotor magnet fixed to the rotor core. The torque of the rotor 20 is transmitted to the transmission device 3.

The shaft 21 extends in the axial direction around the motor shaft J1. The shaft 21 rotates around the motor shaft J1. The shaft 21 is a hollow shaft with a hollow section 22 inside. The shaft 21 is provided with a communication hole 23. The communication hole 23 extends radially to connect the hollow section 22 to the outside of the shaft 21.

The shaft 21 extends across the motor housing 61 and the gear housing 62 of the housing 6. The left end of the shaft 21 protrudes into the gear housing 62. A first gear 41 (described later) of the transmission device 3 is fixed to the left end of the shaft 21. The shaft 21 is rotatably supported by bearings 26 and 27.

The stator 30 faces the rotor 20 in the radial direction with a gap therebetween. More specifically, the stator 30 is located radially outside the rotor 20. The stator 30 has a stator core 32 and a coil assembly 33. The stator core 32 surrounds the rotor 20. The stator core 32 is fixed to the inner circumferential surface of the motor housing 61. As shown in FIG. 2 and FIG. 3, the stator core 32 has a stator core body 32a and a fixing portion 32b. As shown in FIG. 3, the stator core body 32a has a cylindrical core back 32d extending in the axial direction and a plurality of teeth 32e extending radially inward from the core back 32d. The plurality of teeth 32e are arranged at equal intervals around one circumference in the circumferential direction.

The fixing portion 32b protrudes radially outward from the outer peripheral surface of the stator core body 32a. The fixing portion 32b is the portion that is fixed to the housing 6. A plurality of fixing portions 32b are provided at intervals along the circumferential direction. For example, four fixing portions 32b are provided. The four fixing portions 32b are arranged at equal intervals around one circumference in the circumferential direction.

One of the fixing portions 32b protrudes upward from the stator core body 32a. The other of the fixing portions 32b protrudes downward from the stator core body 32a. Yet another of the fixing portions 32b protrudes forward (+X side) from the stator core body 32a. The remaining fixing portion 32b protrudes rearward (-X side) from the stator core body 32a.

In the following description, the fixing portion 32b protruding upward from the stator core body 32a is simply referred to as the "upper fixing portion 32b," and the fixing portion 32b protruding forward from the stator core body 32a is simply referred to as the "front fixing portion 32b."

As shown in FIG. 2, the fixing portion 32b extends in the axial direction. For example, the fixing portion 32b extends from the left end (+Y side) of the stator core body 32a to the right end (-Y side) of the stator core body 32a. The fixing portion 32b has a through hole 32c that penetrates the fixing portion 32b in the axial direction. As shown in FIG. 3, a bolt 34 extending in the axial direction is passed through the through hole 32c. The bolt 34 is passed through the through hole 32c from the right side (-Y side) and screwed into the female screw hole 35 shown in FIG. 4. The female screw hole 35 is provided in the partition wall 61c. The fixing portion 32b is fixed to the partition wall 61c by screwing the bolt 34 into the female screw hole 35. In this way, the stator 30 is fixed to the housing 6 by the bolt 34.

As shown in FIG. 1, the coil assembly 33 has multiple coils 31 attached to the stator core 32 in the circumferential direction. The multiple coils 31 are attached to each tooth 32e of the stator core 32 via insulators (not shown). The multiple coils 31 are arranged in the circumferential direction. More specifically, the multiple coils 31 are arranged at equal intervals around the circumference. Although not shown, the coil assembly 33 may have a bundling member or the like that bundles the coils 31 together, or may have jumper wires that connect the coils 31 together.

The coil assembly 33 has coil ends 33a and 33b that protrude from the stator core 32 in the axial direction. The coil end 33a is a portion that protrudes to the right from the stator core 32. The coil end 33b is a portion that protrudes to the left from the stator core 32. The coil end 33a includes a portion of each coil 31 included in the coil assembly 33 that protrudes to the right of the stator core 32. The coil end 33b includes a portion of each coil 31 included in the coil assembly 33 that protrudes to the left of the stator core 32. As shown in FIG. 2, in this embodiment, the coil ends 33a and 33b are annular with the motor shaft J1 as the center. Although not shown, the coil ends 33a and 33b may include a bundling member that bundles the coils 31 together, or may include a crossover wire that connects the coils 31 together.

As shown in FIG. 1, the bearings 26 and 27 rotatably support the rotor 20. The bearings 26 and 27 are, for example, ball bearings. The bearing 26 rotatably supports a portion of the rotor 20 located to the right of the stator core 32. In this embodiment, the bearing 26 supports a portion of the shaft 21 located to the right of the portion to which the rotor body 24 is fixed. The bearing 26 is held by a wall portion 61b of the motor housing portion 61 that covers the right side of the rotor 20 and the stator 30.

The bearing 27 rotatably supports a portion of the rotor 20 located to the left of the stator core 32. In this embodiment, the bearing 27 supports a portion of the shaft 21 located to the left of the portion to which the rotor body 24 is fixed. The bearing 27 is held by the partition wall 61c.

The transmission device 3 is accommodated in the gear accommodating portion 62 of the housing 6. The transmission device 3 is connected to the motor 2. More specifically, the transmission device 3 is connected to the left end of the shaft 21. The transmission device 3 has a reduction gear 4 and a differential gear 5. The torque output from the motor 2 is transmitted to the differential gear 5 via the reduction gear 4.

The reduction gear 4 is connected to the motor 2. The reduction gear 4 reduces the rotational speed of the motor 2 and increases the torque output from the motor 2 according to the reduction ratio. The reduction gear 4 transmits the torque output from the motor 2 to the differential gear 5. The reduction gear 4 has a first gear 41, a second gear 42, a third gear 43, and an intermediate shaft 45.

The first gear 41 is fixed to the outer peripheral surface at the left end of the shaft 21. The first gear 41 rotates together with the shaft 21 around the motor axis J1. The intermediate shaft 45 extends along an intermediate axis J2 parallel to the motor axis J1. The intermediate shaft 45 rotates around the intermediate axis J2. The second gear 42 and the third gear 43 are fixed to the outer peripheral surface of the intermediate shaft 45. The second gear 42 and the third gear 43 are connected via the intermediate shaft 45. The second gear 42 and the third gear 43 rotate around the intermediate axis J2. The second gear 42 meshes with the first gear 41. The third gear 43 meshes with a ring gear 51 of the differential device 5, which will be described later.

The torque output from the motor 2 is transmitted to the ring gear 51 of the differential device 5 via the shaft 21, the first gear 41, the second gear 42, the intermediate shaft 45, and the third gear 43 in this order. The gear ratio of each gear and the number of gears can be changed according to the required reduction ratio. In this embodiment, the reduction device 4 is a parallel shaft gear type reducer in which the axes of the gears are arranged in parallel.

The differential device 5 is connected to the motor 2 via the reduction gear 4. The differential device 5 is a device for transmitting the torque output from the motor 2 to the wheels of the vehicle. When the vehicle turns, the differential device 5 transmits the same torque to the axles 55 of the left and right wheels while absorbing the speed difference between the left and right wheels. In this manner, in this embodiment, the transmission device 3 transmits the torque of the motor 2 to the axles 55 of the vehicle via the reduction gear 4 and the differential device 5. The differential device 5 has a ring gear 51, a gear housing (not shown), a pair of pinion gears (not shown), a pinion shaft (not shown), and a pair of side gears (not shown). The ring gear 51 rotates around a differential shaft J3 that is parallel to the motor shaft J1. The torque output from the motor 2 is transmitted to the ring gear 51 via the reduction gear 4.

The motor 2 is provided with an oil passage 90 through which the oil O circulates inside the housing 6. The oil passage 90 is a path for the oil O that supplies the oil O from the oil reservoir P to the motor 2 and guides it back to the oil reservoir P. The oil passage 90 is provided across the interior of the motor housing portion 61 and the interior of the gear housing portion 62.

In this specification, "oil passage" means the path of oil. Therefore, "oil passage" is a concept that includes not only a "flow path" that creates a steady flow of oil in one direction, but also paths that temporarily hold oil and paths through which oil drips. A path that temporarily holds oil includes, for example, a reservoir that stores oil.

The oil passage 90 has a first oil passage 91 and a second oil passage 92. The first oil passage 91 and the second oil passage 92 each circulate the oil O inside the housing 6. The first oil passage 91 has a scooping passage 91a, a shaft supply passage 91b, an inner shaft passage 91c, and an inner rotor passage 91d. In addition, a first reservoir 93 is provided in the first oil passage 91. The first reservoir 93 is provided in the gear housing portion 62.

The scooping path 91a is a path through which the oil O is scooped up from the oil pool P by the rotation of the ring gear 51 of the differential device 5, and is received in the first reservoir 93. The first reservoir 93 opens to the upper side. The first reservoir 93 receives the oil O scooped up by the ring gear 51. In addition, when the liquid level S of the oil pool P is high, such as immediately after the motor 2 is driven, the first reservoir 93 also receives the oil O scooped up by the second gear 42 and the third gear 43 in addition to the ring gear 51.

The shaft supply path 91b guides the oil O from the first reservoir 93 to the hollow portion 22 of the shaft 21. The shaft internal path 91c is a path through which the oil O passes inside the hollow portion 22 of the shaft 21. The rotor internal path 91d is a path through which the oil O passes from the communication hole 23 of the shaft 21 through the inside of the rotor body 24 and splashes onto the stator 30.

In the shaft internal passage 91c, centrifugal force is applied to the oil O inside the rotor 20 as the rotor 20 rotates. As a result, the oil O is continuously scattered radially outward from the rotor 20. As the oil O is scattered, the passage inside the rotor 20 becomes negative pressure, and the oil O that has accumulated in the first reservoir 93 is sucked into the rotor 20, filling the passage inside the rotor 20 with oil O.

Oil O that reaches the stator 30 removes heat from the stator 30. After cooling the stator 30, the oil O drips downward and accumulates in the lower area of the motor housing 61. The oil O that accumulates in the lower area of the motor housing 61 moves to the gear housing 62 through the partition opening 68 provided in the partition 61c. In this way, the first oil passage 91 supplies oil O to the rotor 20 and the stator 30.

In the second oil passage 92, oil O is drawn up from the oil reservoir P and supplied to the stator 30. The second oil passage 92 is provided with an oil pump 96, a cooler 97, and a pipe 10. The second oil passage 92 has a first flow path 92a, a second flow path 92b, a third flow path 92c, and a fourth flow path 94. In this embodiment, the pipe 10 corresponds to a refrigerant flow path through which the oil O flows as a refrigerant.

The first flow path 92a, the second flow path 92b, and the third flow path 92c are provided in the wall of the housing 6. The first flow path 92a connects the oil reservoir P and the oil pump 96. The second flow path 92b connects the oil pump 96 and the cooler 97. The third flow path 92c connects the cooler 97 and the fourth flow path 94. The third flow path 92c is provided, for example, in the front (+X side) wall of the motor housing section 61.

The fourth flow passage 94 is provided in the partition wall 61c. The fourth flow passage 94 connects the first pipe 11 and the second pipe 12 of the pipe 10, which will be described later. As shown in FIG. 4, the fourth flow passage 94 has an inlet portion 94a, a first branch portion 94c, and a second branch portion 94f. The inlet portion 94a is a portion of the fourth flow passage 94 into which oil O flows from the third flow passage 92c. The inlet portion 94a extends rearward (-X side) from the third flow passage 92c. The inlet portion 94a is located on the front side (+X side) of the shaft 21, and extends linearly in the front-rear direction of the radial direction. The inner diameter of the inlet portion 94a is larger at the front end. In this embodiment, the front end of the inlet portion 94a is the radially outer end of the inlet portion 94a.

The front (+X) end of the inlet portion 94a is located radially outward from the fixed portion 32b. The rear (-X) end of the inlet portion 94a is located radially inward from the fixed portion 32b. That is, in this embodiment, the inlet portion 94a extends in the front-rear direction from radially outward from the fixed portion 32b to radially inward from the fixed portion 32b. The inlet portion 94a is located above the front (+X) fixed portion 32b.

The rear end (-X side) of the inlet portion 94a is a connection portion 94b where the first branch portion 94c and the second branch portion 94f are connected. The inner diameter of the inlet portion 94a is larger at the connection portion 94b. The connection portion 94b is located radially inward from the fixing portion 32b.

The inlet portion 94a, excluding the connection portion 94b, is made, for example, by drilling holes from the front side (+X side) of the housing 6. The front end of the inlet portion 94a is blocked by tightening a bolt 95a. The connection portion 94b of the inlet portion 94a is made, for example, by drilling holes from the left side (+Y side) of the partition wall 61c. Although not shown in the figure, the left end of the connection portion 94b is blocked by tightening a bolt.

The first branch portion 94c is a portion that branches off from the inlet portion 94a and extends to the first pipe 11, which will be described later. The first branch portion 94c extends diagonally upward and rearward from the rear (-X side) end of the inlet portion 94a, i.e., the connection portion 94b. The first branch portion 94c passes through a portion of the partition wall 61c that is located below the upper fixed portion 32b and above the shaft 21, and extends to the upper end of the partition wall 61c. The radial position of the upper end of the first branch portion 94c is approximately the same as the radial position of the fixed portion 32b. The upper end of the first branch portion 94c is located rearward of the upper fixed portion 32b.

The first branch 94c has an extension 94d that extends in a straight line from the connection 94b diagonally upward toward the rear, and a connection 94e that connects to the upper end of the extension 94d. The connection 94e is the upper end of the first branch 94c, and is the part to which the first pipe 11 described below is connected. The inner diameter of the connection 94e is larger than the inner diameter of the extension 94d. The connection 94e is made, for example, by drilling a hole from the top of the housing 6. The upper end of the connection 94e is closed by tightening a bolt 95b. The extension 94d is made, for example, by drilling a hole from the top of the housing 6 diagonally downward toward the front through the inside of the connection 94e.

The second branch portion 94f is a portion that branches off from the inlet portion 94a and extends to the second pipe 12, which will be described later. In this embodiment, the second branch portion 94f extends obliquely upward toward the front from the connection portion 94b. The second branch portion 94f extends linearly, inclined toward the right side (-Y side) in the front-to-rear direction. The radial position of the front (+X side) end of the second branch portion 94f is approximately the same as the radial position of the fixing portion 32b. The front (+X side) end of the second branch portion 94f is located above the front fixing portion 32b. The front end of the second branch portion 94f and the front fixing portion 32b are located at approximately the same position in the front-to-rear direction. The second branch portion 94f is made, for example, by drilling a hole from the left side (+Y side) of the bulkhead 61c through the inside of the connection portion 94b.

In the fourth flow passage 94, the rear portion of the inlet 94a, the portion of the extension 94d excluding the upper end, and the rear portion of the second branch 94f are provided in a portion of the partition 61c that is located radially inward from the fixed portion 32b. That is, in this embodiment, the fourth flow passage 94 has a portion that passes radially inward from the fixed portion 32b.

As shown in FIG. 1, the pipe 10 extends in the axial direction. The left end of the pipe 10 is fixed to the partition wall 61c. As shown in FIG. 2, the pipe 10 includes a first pipe 11 and a second pipe 12. That is, the drive unit 1 includes the first pipe 11 and the second pipe 12. In this embodiment, the first pipe 11 corresponds to the upper refrigerant flow path, and the second pipe 12 corresponds to the lower refrigerant flow path.

In this embodiment, the first pipe 11 and the second pipe 12 are cylindrical and extend linearly in the axial direction. The first pipe 11 and the second pipe 12 are parallel to each other. As shown in FIG. 3, the first pipe 11 and the second pipe 12 are accommodated inside the housing 6. The first pipe 11 and the second pipe 12 are located radially outside the stator 30. The first pipe 11 and the second pipe 12 are arranged with a gap between them in the circumferential direction. The radial position of the first pipe 11 and the radial position of the second pipe 12 are, for example, the same.

In this specification, "the first pipe and the second pipe extend linearly in the axial direction of the motor shaft" includes not only the case where the first pipe and the second pipe extend linearly in the axial direction strictly, but also the case where the first pipe and the second pipe extend linearly in the axial direction approximately. That is, in this embodiment, "the first pipe 11 and the second pipe 12 extend linearly in the axial direction" may mean, for example, that the first pipe 11 and the second pipe 12 extend slightly tilted relative to the axial direction. In this case, the tilt direction of the first pipe 11 relative to the axial direction and the tilt direction of the second pipe 12 relative to the axial direction may be the same or different.

In this embodiment, the first pipe 11 is located above the stator 30. The first pipe 11 is located above the second pipe 12. In this embodiment, the radial position of the first pipe 11 is the same as the radial position of the fixed portion 32b. The first pipe 11 is located behind (on the -X side) the upper fixed portion 32b. As shown in FIG. 5, the first pipe 11 has a first pipe main body 11a, a small diameter portion 11b provided at the left end (+Y side) of the first pipe main body 11a, and a small diameter portion 11c provided at the right end (-Y side) of the first pipe main body 11a.

The small diameter portion 11b is the end portion on the left side (+Y side) of the first pipe 11. The small diameter portion 11c is the end portion on the right side (-Y side) of the first pipe 11. The outer diameter of the small diameter portions 11b and 11c is smaller than the outer diameter of the first pipe main body portion 11a. The first pipe 11 is fixed to the partition wall 61c by inserting the small diameter portion 11b into the partition wall 61c from the right side. The small diameter portion 11b opens to the left side. As shown in FIG. 4, the small diameter portion 11b opens to the connection portion 94e of the first branch portion 94c. This connects the first pipe 11 to the fourth flow path 94.

As shown in FIG. 5, an attachment member 16 is provided on the right-side (-Y side) end of the first pipe 11. The attachment member 16 is a rectangular plate with its plate surface facing the axial direction. The attachment member 16 has a recess 16a recessed to the right from the left-side (+Y side) face. The right-side end of the first pipe 11, i.e., the small diameter portion 11c, is fitted into and fixed to the recess 16a. The right-side end of the first pipe 11 is blocked by the attachment member 16.

The mounting member 16 has a hole 16b that passes through the mounting member 16 in the axial direction. As shown in FIG. 2, a bolt 18 is passed through the hole 16b from the right side (-Y side). The bolt 18 passes through the hole 16b and is fastened from the right side to a protrusion 61d shown in FIG. 3. The protrusion 61d protrudes radially inward from the inner circumferential surface of the motor housing 61. The mounting member 16 is fixed to the protrusion 61d by fastening the bolt 18 to the protrusion 61d. As a result, the right end of the first pipe 11 is fixed to the motor housing 61 via the mounting member 16.

As shown in FIG. 5, the first pipe 11 has a plurality of first upper supply ports 13 and a plurality of second upper supply ports 14. That is, the pipe 10 as a refrigerant flow path has the first upper supply port 13 and the second upper supply port 14. In this embodiment, the first upper supply port 13 and the second upper supply port 14 correspond to refrigerant supply ports that supply refrigerant to the stator 30. Also, in this embodiment, the second upper supply port 14 corresponds to the second supply port.

Oil O that has flowed into the first pipe 11 is discharged from the first upper supply port 13 and the second upper supply port 14. The first upper supply port 13 and the second upper supply port 14 are provided on the outer peripheral surface of the first pipe 11. The first upper supply port 13 and the second upper supply port 14 are holes that penetrate the first pipe 11 from the inner peripheral surface to the outer peripheral surface. The first upper supply port 13 and the second upper supply port 14 are, for example, circular. As shown in Figures 2 and 5, the first upper supply port 13 and the second upper supply port 14 face downward.

In this embodiment, the first upper supply ports 13 are provided in multiples at both axial ends of the first pipe body 11a. For example, four first upper supply ports 13 are provided at both axial ends of the first pipe body 11a. The four first upper supply ports 13 provided at the right end (-Y side) of the first pipe body 11a are arranged in a zigzag pattern along the circumferential direction. The four first upper supply ports 13 provided at the right end of the first pipe body 11a include one first upper supply port 13 that opens directly below, two first upper supply ports 13 that open diagonally forward below, and one first upper supply port 13 that opens diagonally backward below. The four first upper supply ports 13 provided at the left end (+Y side) of the first pipe body 11a are arranged in the same manner as the four first upper supply ports 13 provided at the right portion of the first pipe body 11a, except for their axial positions.

As shown in FIG. 2, the four first upper supply ports 13 provided on the right side (-Y side) of the multiple first upper supply ports 13 are located above the coil end 33a. The four first upper supply ports 13 provided on the left side (+Y side) of the multiple first upper supply ports 13 are located above the coil end 33b. Therefore, oil O discharged from the first upper supply ports 13 is supplied to the coil ends 33a and 33b from above. That is, in this embodiment, the first upper supply ports 13 are supply ports that supply oil O to the coil ends 33a and 33b.

The second upper supply port 14 is provided in the central portion of the axial direction of the first pipe 11. In this embodiment, two second upper supply ports 14 are provided at an axial distance from each other in the central portion of the axial direction of the first pipe main body portion 11a. As shown in FIG. 3, in this embodiment, the second upper supply port 14 opens downward and diagonally forward. As shown in FIGS. 2 and 3, the second upper supply port 14 is located above the stator core 32. Therefore, the oil O discharged from the second upper supply port 14 is supplied to the stator core 32 from above. This allows the oil O to flow from the upper side of the stator core 32 to the lower side by utilizing gravity. Therefore, the oil O can be easily supplied to a wide range of the stator core 32, and the cooling efficiency of the stator 30 can be improved.

In this embodiment, the oil O injected diagonally downward and forward from the second upper supply port 14 is, for example, blocked by the upper fixed portion 32b and flows rearward and downward along the outer circumferential surface of the rear portion of the stator core 32. Thus, in this embodiment, the second upper supply port 14 is a supply port that supplies oil O to the stator core 32 on the radial outside of the stator core 32. In this embodiment, the second upper supply port 14 is located rearward (-X side) of the upper fixed portion 32b. Note that the oil O injected diagonally downward and forward from the second upper supply port 14 may flow rearward without coming into contact with the upper fixed portion 32b.

In this specification, "the supply port faces vertically downward" means that the direction of the supply port includes a downward component, and the supply port may face directly downward, or may face a direction inclined relative to directly downward. As described above, in this embodiment, the first upper supply port 13 includes the first upper supply port 13 facing directly downward, the first upper supply port 13 facing a direction inclined diagonally forward relative to directly downward, and the first upper supply port 13 facing a direction inclined diagonally backward relative to directly downward. In this embodiment, the second upper supply port 14 as the second supply port faces a direction inclined diagonally forward relative to directly downward. In this embodiment, "the second upper supply port 14 faces downward" means that the second upper supply port 14 may face, for example, directly downward, or may face a direction inclined diagonally backward relative to directly downward.

As shown in FIG. 6, when viewed in the axial direction, the direction DI1 in which the second upper supply port 14 opens is a direction in which the tangent line TL1a that passes through the second upper supply port 14 and touches the outer peripheral surface of the stator core 32 is inclined radially inward from the direction in which it extends from the second upper supply port 14 toward the outer peripheral surface of the stator core 32. This makes it possible to prevent the oil O injected from the second upper supply port 14 from flying far away from the area to which the oil O is to be supplied. This allows the oil O to be supplied to the stator core 32 in an optimal manner. This further improves the cooling efficiency of the stator 30.

In this embodiment, the direction DI1 in which the second upper supply port 14 opens is lower than the direction in which the tangent line TL1a that passes through the second upper supply port 14 and touches the outer peripheral surface of the stator core 32 extends from the second upper supply port 14 toward the outer peripheral surface of the stator core 32. Therefore, the oil O injected from the second upper supply port 14 located on the upper side of the stator core 32 can be prevented from flying far away from the upper part of the stator core 32. In this embodiment, the oil O injected from the second upper supply port 14 can be prevented from flying forward over the upper fixed part 32b. This allows the oil O from the second upper supply port 14 to be suitably supplied to the upper part of the stator core 32. Therefore, the cooling efficiency of the stator 30 can be further improved. The oil O injected from the second upper supply port 14 may or may not be supplied to the upper fixed part 32b.

In this embodiment, the tangent TL1a is, for example, a tangent that passes through the center point CP1 at the end of the circular second upper supply port 14 provided on the outer circumferential surface of the first pipe 11 and is in contact with the outer circumferential surface of the upper fixed portion 32b. The direction DI1 in which the second upper supply port 14 opens is the direction in which the second upper supply port 14 penetrates from the inner circumferential surface to the outer circumferential surface of the first pipe 11. The angle θ1a of the direction DI1 in which the second upper supply port 14 opens with respect to the direction in which the tangent TL1a extends from the second upper supply port 14 toward the outer circumferential surface of the stator core 32 is, for example, about 20° or more and 45° or less. The angle θ1a is the smaller angle between the imaginary line L1 that passes through the center point CP1 and extends parallel to the direction in which the second upper supply port 14 penetrates the first pipe 11, and the tangent TL1a, as viewed in the axial direction.

When viewed in the axial direction, the direction DI1 in which the second upper supply port 14 opens is a direction in which the tangent line TL1b that passes through the second upper supply port 14 and touches the outer peripheral surface of the stator core body 32a is inclined radially inward from the direction in which the tangent line TL1b that passes through the second upper supply port 14 and touches the outer peripheral surface of the stator core body 32a extends from the second upper supply port 14 toward the outer peripheral surface of the stator core body 32a. In this embodiment, when viewed in the axial direction, the direction DI1 in which the second upper supply port 14 opens is downward from the direction in which the tangent line TL1b that passes through the second upper supply port 14 and touches the outer peripheral surface of the stator core body 32a extends from the second upper supply port 14 toward the outer peripheral surface of the stator core body 32a. Therefore, it is easier to spray oil O from the second upper supply port 14 toward the stator core body 32a. This makes it more difficult for the oil O sprayed from the second upper supply port 14 to overcome the upper fixing portion 32b. Therefore, the oil O supplied to the stator core 32 from the second upper supply port 14 can be appropriately flowed to the rear portion of the stator core 32.

In this embodiment, the tangent line TL1b is, for example, a tangent line that passes through the center point CP1 of the second upper supply port 14 and is tangent to the outer peripheral surface of the cylindrical stator core body 32a. In this embodiment, the upper fixing portion 32b is provided at the position where the tangent line TL1b is tangent to the stator core body 32a. Therefore, in FIG. 6, the outer peripheral surface of the stator core body 32a is virtually shown by a two-dot chain line at the position where the upper fixing portion 32b is provided. The tangent line TL1b is tangent to the outer peripheral surface of the stator core body 32a virtually shown by the two-dot chain line.

The angle θ1b between the direction in which the tangent TL1b extends from the second upper supply port 14 toward the outer circumferential surface of the stator core body 32a and the direction DI1 in which the second upper supply port 14 opens is, for example, about 10° or more and 30° or less. The angle θ1b is the smaller angle between the virtual line L1 and the tangent TL1b when viewed in the axial direction.

As shown in Figures 2 and 3, the second pipe 12 is located on the front side (+X side) of the stator 30. In this embodiment, the radial position of the second pipe 12 is the same as the radial position of the fixed portion 32b. The second pipe 12 is located above the front fixed portion 32b. The fixed portion 32b located on the upper side is located between the first pipe 11 and the second pipe 12 in the circumferential direction. In other words, the first pipe 11 and the second pipe 12 are arranged in the circumferential direction with the fixed portion 32b in between.

2, the second pipe 12 has a second pipe body 12a and a small diameter portion 12b provided at the left end (+Y side) of the second pipe body 12a. Although not shown, the second pipe 12 has a small diameter portion provided at the right end (-Y side) of the second pipe body 12a, similar to the first pipe 11.

The small diameter portion 12b is the left end (+Y side) of the second pipe 12. The outer diameter of the small diameter portion 12b is smaller than the outer diameter of the second pipe body portion 12a. The second pipe 12 is fixed to the partition wall 61c by inserting the small diameter portion 12b into the partition wall 61c from the right side (-Y side). The small diameter portion 12b opens to the left side. As shown in FIG. 4, the small diameter portion 12b opens to the end of the front side (+X side) of the second branch portion 94f. This connects the second pipe 12 to the fourth flow path 94. Therefore, the first pipe 11 and the second pipe 12 are connected to each other via the fourth flow path 94. More specifically, the first pipe 11 and the second pipe 12 are connected to each other via the first branch portion 94c, the connection portion 94b, and the second branch portion 94f.

As shown in FIG. 2, a mounting member 17 is provided on the right end (-Y side) of the second pipe 12. The mounting member 17 is a rectangular plate with a plate surface facing the axial direction. The right end of the second pipe 12 is fixed to the mounting member 17 in the same manner as the first pipe 11. The right end of the second pipe 12 is blocked by the mounting member 17. Although not shown, the mounting member 17 is fixed with a bolt to the protruding portion 61e shown in FIG. 3, in the same manner as the mounting member 16. As a result, the right end of the second pipe 12 is fixed to the motor housing portion 61 via the mounting member 17. The protruding portion 61e protrudes radially inward from the inner circumferential surface of the motor housing portion 61.

2, the second pipe 12 has a plurality of lower supply ports 15. That is, the pipe 10 as a refrigerant flow path has the lower supply ports 15. In this embodiment, the lower supply ports 15 correspond to the refrigerant supply ports that supply refrigerant to the stator 30. In addition, in this embodiment, the lower supply ports 15 correspond to the first supply port. Oil O that flows into the second pipe 12 is discharged from the lower supply port 15. The lower supply port 15 is provided on the outer circumferential surface of the second pipe 12. More specifically, the lower supply port 15 is provided on the outer circumferential surface of the second pipe main body portion 12a. The multiple lower supply ports 15 are arranged at intervals along the axial direction. For example, six lower supply ports 15 are provided. The lower supply ports 15 are holes that penetrate the second pipe 12 from the inner circumferential surface to the outer circumferential surface. The lower supply ports 15 are, for example, circular.

3, the lower supply port 15 faces upward. Therefore, the oil O discharged from the lower supply port 15 to the upper side can be supplied to the upper part of the stator 30. This allows the oil O from the second pipe 12 to flow from the upper side of the stator 30 to the lower side by using gravity, making it easier to cool the entire stator 30. In this embodiment, the lower supply port 15 faces diagonally backward upward. Therefore, the oil O discharged from the lower supply port 15 located in front of the stator 30 can easily reach the upper part of the stator 30. This makes it easier to cool the stator 30 by the oil O discharged from the second pipe 12. The oil O sprayed from the lower supply port 15 may or may not be supplied to the upper fixing part 32b.

The lower supply port 15 is located on the front side (+X side) of the stator core 32. In this embodiment, the lower supply port 15 is located below the upper end of the stator core 32. In this embodiment, the upper end of the stator core 32 is, for example, the upper end of the upper fixing portion 32b. In this embodiment, the lower supply port 15 is located below the upper end of the stator core main body 32a and above the motor shaft J1.

As shown in FIG. 6, the oil O discharged from the lower supply port 15 is sprayed diagonally rearward and supplied to the outer circumferential surface of the stator core body 32a. That is, in this embodiment, the lower supply port 15 is a supply port that supplies oil O to the stator core 32 on the radial outside of the stator core 32.

In this specification, "the supply port faces upward" means that the orientation of the supply port includes an upward component, and the supply port may face directly upward, or may face in a direction tilted from directly upward. As described above, the lower supply port 15 in this embodiment faces in a direction tilted diagonally backward from directly upward. In this embodiment, "the lower supply port 15 faces upward" means that the lower supply port 15 may face, for example, directly upward, or may face in a direction tilted diagonally forward from directly upward.

When viewed in the axial direction, the direction DI2 in which the lower supply port 15 opens is a direction in which the tangent line TL2 that passes through the lower supply port 15 and touches the outer peripheral surface of the stator core 32 is inclined radially outward from the direction in which it extends from the lower supply port 15 toward the outer peripheral surface of the stator core 32. Therefore, as shown in FIG. 6, the oil O injected from the lower supply port 15 is more likely to fly farther than the contact point TP1 between the tangent line TL2 and the outer peripheral surface of the stator core 32. This makes it easier to supply the oil O injected from the lower supply port 15 to a wide area of the stator core 32. This improves the cooling efficiency of the stator 30.

In this embodiment, the tangent line TL2 is, for example, a tangent line that passes through the center point CP2 at the end of the circular lower supply port 15 provided on the outer circumferential surface of the second pipe 12 and is in contact with the outer circumferential surface of the stator core body 32a. The direction DI2 in which the lower supply port 15 opens is the direction in which the lower supply port 15 penetrates from the inner circumferential surface to the outer circumferential surface of the second pipe 12. The angle θ2 between the direction in which the tangent line TL2 extends from the lower supply port 15 toward the outer circumferential surface of the stator core 32 and the direction in which the lower supply port 15 opens is, for example, about 5° or more and 15° or less. The angle θ2 is the smaller angle between the tangent line TL2 and a virtual line L2 that passes through the center point CP2 and extends parallel to the direction in which the lower supply port 15 penetrates the second pipe 12, as viewed in the axial direction.

In this embodiment, when viewed in the axial direction, the direction DI2 in which the lower supply port 15 opens is more upward than the direction in which the tangent TL2 extends from the lower supply port 15 toward the outer peripheral surface of the stator core 32. This makes it easier for the oil O injected from the lower supply port 15, which is located below the upper end of the stator core 32, to reach the portion of the stator core 32 that is located above the contact point TP1 between the tangent TL2 and the outer peripheral surface of the stator core 32. This makes it easier to supply the oil O to the upper portion of the stator core 32 and to cool the stator 30. Therefore, the cooling efficiency of the stator 30 can be further improved.

In this embodiment, the pipe 10 as the refrigerant flow path includes the second pipe 12 provided with the lower supply port 15 as the first supply port, and the first pipe 11 provided with the second upper supply port 14 as the second supply port and positioned above the second pipe 12. Therefore, the lower supply port 15 and the second upper supply port 14 can suitably supply oil O to the upper portion of the stator core 32. This makes it easier to supply oil O to the entire stator core 32, and further improves the cooling efficiency of the stator 30.

Specifically, in this embodiment, the first pipe 11 is located behind the upper fixed portion 32b. Therefore, the oil O discharged from the second upper supply port 14 of the first pipe 11 is more likely to flow rearward than the upper fixed portion 32b. This makes it easier for the first pipe 11 to supply the oil O to the rear portion of the stator core 32. On the other hand, the second pipe 12 is located forward of the upper fixed portion 32b. Therefore, the oil O discharged upward from the lower supply port 15 of the second pipe 12 is more likely to be supplied to the portion forward of the upper fixed portion 32b. This makes it easier for the second pipe 12 to supply the oil O to the front portion of the stator core 32. Therefore, the first pipe 11 and the second pipe 12 make it easier to supply the oil O to both sides of the stator core 32 in the front-rear direction, and the entire stator core 32 is more likely to be cooled. This makes it easier to improve the cooling efficiency of the stator 30.

3, in the circumferential region from the lower supply port 15 to the contact point TP1 where the tangent line TL2 contacts the outer peripheral surface of the stator core 32, a gap G is provided between the inner peripheral surface of the housing 6 and the outer peripheral surface of the stator core 32 in the radial direction. Therefore, the gap G makes it easy to secure a path through which the oil O injected from the lower supply port 15 passes. As a result, the oil O injected from the lower supply port 15 can reach a location farther than the contact point TP1 through the gap G. Therefore, the oil O injected from the lower supply port 15 can be suitably supplied to a wide range of the stator core 32. Therefore, the cooling efficiency of the stator 30 can be further improved. In this embodiment, the oil O injected from the lower supply port 15 can be suitably supplied to a portion of the stator core 32 located above the contact point TP1 through the gap G. Therefore, the oil O can be suitably supplied to the upper portion of the stator core 32.

The oil pump 96 shown in FIG. 1 is a pump that sends oil O as a coolant. In this embodiment, the oil pump 96 is an electric pump that is driven by electricity. The oil pump 96 sucks up oil O from the oil reservoir P through the first flow path 92a, and supplies the oil O to the motor 2 through the second flow path 92b, the cooler 97, the third flow path 92c, the fourth flow path 94, and the pipe 10. That is, the oil pump 96 sends the oil O contained inside the housing 6 to the fourth flow path 94, the first pipe 11, and the second pipe 12. Therefore, the oil O can be easily sent to the first pipe 11 and the second pipe 12.

The oil O sent to the third flow path 92c by the oil pump 96 flows into the fourth flow path 94 from the inlet 94a. As shown in FIG. 4, the oil O that flows into the inlet 94a flows to the rear side (-X side) and branches into the first branch 94c and the second branch 94f. The oil O that flows into the first branch 94c flows into the first pipe 11 from the left end (+Y side) of the first pipe 11. The oil O that flows into the first pipe 11 flows to the right (-Y side) inside the first pipe 11 and is supplied to the stator 30 from the first upper supply port 13 and the second upper supply port 14. On the other hand, the oil O that flows into the second branch 94f flows into the second pipe 12 from the left end of the second pipe 12. The oil O that flows into the second pipe 12 flows to the right inside the second pipe 12 and is supplied to the stator 30 from the lower supply port 15.

In this way, the oil O can be supplied from the first pipe 11 and the second pipe 12 to the stator 30, and the stator 30 can be cooled. In addition, the oil O that flows into the inlet 94a can be branched into the first branch 94c and the second branch 94f and supplied to the first pipe 11 and the second pipe 12, respectively. Therefore, compared to the case where the oil O flows from one pipe 10 of the first pipe 11 and the second pipe 12 to the other pipe 10, it is easier to suppress the occurrence of bias in the amount of oil O supplied to the first pipe 11 and the amount of oil O supplied to the second pipe 12. In addition, since it is easy to shorten the paths until the oil O is supplied to each pipe 10, it is easy to maintain the temperature of the oil O supplied to the stator 30 relatively low. Therefore, it is easy to preferably cool the stator 30.

Oil O supplied to the stator 30 from the first pipe 11 and the second pipe 12 drips downward and accumulates in the lower region of the motor housing 61. The oil O that accumulates in the lower region of the motor housing 61 moves to the oil reservoir P of the gear housing 62 through the partition opening 68 provided in the partition 61c. In this way, the second oil passage 92 supplies oil O to the stator 30.

The cooler 97 shown in FIG. 1 cools the oil O passing through the second oil passage 92. The second flow path 92b and the third flow path 92c are connected to the cooler 97. The second flow path 92b and the third flow path 92c are connected via an internal flow path of the cooler 97. The cooler 97 is connected to a cooling water pipe 98 that passes cooling water cooled by a radiator (not shown). The oil O passing through the inside of the cooler 97 is cooled by heat exchange with the cooling water passing through the cooling water pipe 98.

According to this embodiment, the first pipe 11 and the second pipe 12 are connected by the fourth flow path 94. Therefore, for example, by sending oil O to the inlet portion 94a of the fourth flow path 94 as in this embodiment, it is possible to supply oil O to both the first pipe 11 and the second pipe 12. In other words, the number of oil paths provided in the housing 6 can be reduced compared to the case where separate oil paths are provided to supply oil O to each of the first pipe 11 and the second pipe 12. Therefore, it is possible to prevent the housing 6 from becoming large.

The fourth flow passage 94 is provided in the partition wall 61c located on the left side of the stator 30. Therefore, the fourth flow passage 94 can be arranged at a position overlapping with the stator 30 in the axial direction. This makes it easier to arrange the fourth flow passage 94 while avoiding interference with the fixed portion 32b of the stator 30. In addition, compared to, for example, a case in which the fourth flow passage 94 is provided on the radial outside of the stator 30, the housing 6 can be prevented from becoming large in the radial direction. In addition, since the fourth flow passage 94 is provided in the partition wall 61c of the housing 6, the entire drive device 1 can be easily made small in size compared to a case in which a flow passage connecting the first pipe 11 and the second pipe 12 by piping or the like is provided on the outside of the housing 6. Therefore, according to this embodiment, the drive device 1 can be prevented from becoming large.

In addition, according to this embodiment, the fourth flow passage 94 has a portion that passes radially inward from the fixed portion 32b. This makes it easier to arrange the fourth flow passage 94 to avoid the fixed portion 32b, and also makes it possible to prevent the housing 6 from becoming large in the radial direction. This makes it possible to further prevent the drive unit 1 from becoming large.

In addition, according to this embodiment, the first pipe 11 and the second pipe 12 are arranged in the circumferential direction with the fixed portion 32b in between. Therefore, the first pipe 11 and the second pipe 12 can be arranged in a position that does not interfere with the fixed portion 32b, and the first pipe 11 and the second pipe 12 can be arranged radially close to the stator core body 32a. This makes it easier to supply oil O from the first pipe 11 and the second pipe 12 to the stator 30, and prevents the drive unit 1 from becoming too large in the radial direction.

In addition, according to this embodiment, the first pipe 11 and the second pipe 12 extend linearly in the axial direction. Therefore, compared to a case where the first pipe 11 and the second pipe 12 extend with a bent radial direction, the drive unit 1 can be prevented from becoming large in the radial direction. In addition, since the shape of the first pipe 11 and the shape of the second pipe 12 can be made simple, the first pipe 11 and the second pipe 12 are easy to manufacture. In addition, the first pipe 11 and the second pipe 12 are easy to arrange facing the stator 30 over a wide range in the axial direction. Therefore, it is easy to supply oil O from the first pipe 11 and the second pipe 12 to a wide range in the axial direction of the stator 30. Therefore, the stator 30 can be cooled more effectively.

In addition, according to this embodiment, the motor shaft J1 extends in a horizontal direction perpendicular to the vertical direction. Therefore, by supplying oil O from the pipe 10 to the upper side of the stator 30, the oil O can be made to flow from the upper side to the lower side of the stator 30 by utilizing gravity. This makes it easy to supply oil O to the entire stator 30, and makes it easy to cool the entire stator 30 by the oil O.

In addition, according to this embodiment, the first upper supply port 13 of the first pipe 11 is a supply port that supplies oil O to the coil ends 33a, 33b. Therefore, the coil ends 33a, 33b can be suitably cooled by the oil O supplied from the first pipe 11. In this embodiment, the first pipe 11 is located above the stator 30, so the oil O from the first upper supply port 13 can be supplied from the upper side of the coil ends 33a, 33b. This allows the oil O from the first upper supply port 13 to flow from the upper side of the coil ends 33a, 33b to the lower side by utilizing gravity. Therefore, it is easy to supply oil O to the entire coil ends 33a, 33b, and it is easy to cool the entire coil ends 33a, 33b.

In addition, according to this embodiment, the first upper supply ports 13 of the first pipe 11 are arranged in multiples on the upper side of each coil end 33a, 33b. Therefore, the amount of oil O supplied from the first pipe 11 to the coil ends 33a, 33b can be increased. This allows the coil 31, which is a heat generating body, to be cooled effectively, and the stator 30 to be cooled more effectively.

In addition, according to this embodiment, the multiple first upper supply ports 13 located above each coil end 33a, 33b are arranged in a zigzag pattern along the circumferential direction. Therefore, the axial positions of the multiple first upper supply ports 13 arranged along the circumferential direction are shifted alternately. This makes it easier to supply oil O to the entire coil ends 33a, 33b than when the axial positions of the multiple first upper supply ports 13 located above each coil end 33a, 33b are the same.

In addition, according to this embodiment, the first upper supply ports 13 located above each coil end 33a, 33b include a first upper supply port 13 facing downward diagonally forward and a first upper supply port 13 facing downward diagonally backward. Therefore, it is easy to supply oil O supplied from the multiple first upper supply ports 13 to both the front and rear portions of the coil ends 33a, 33b, and it is easy to supply oil O to the entire coil ends 33a, 33b. This allows the coil ends 33a, 33b to be cooled more effectively, and the stator 30 to be cooled even more effectively.

In addition, according to this embodiment, the right end of the first pipe 11 is blocked by the mounting member 16, and the right end of the second pipe 12 is blocked by the mounting member 17. In this embodiment, the right end of the first pipe 11 is the end opposite to the side where the oil O flows into the first pipe 11. The right end of the second pipe 12 is the end opposite to the side where the oil O flows into the second pipe 12. That is, among the axial ends of each pipe, the end opposite to the side where the oil O flows in is blocked. Therefore, it is easier to increase the pressure of the oil O flowing in each pipe, compared to when the axial ends of each pipe opposite to the side where the oil O flows in are open. This makes it easier to forcefully spray the oil O from the oil supply port of each pipe. Therefore, it is easier to suitably supply the oil O discharged from each oil supply port to the stator 30.

In particular, in the second pipe 12 of this embodiment, the lower supply port 15 faces upward. Therefore, the oil O can be forcefully sprayed upward from the lower supply port 15. This makes it easier for the oil O discharged from the lower supply port 15 to reach the upper portion of the stator core 32. Therefore, the oil O discharged from the second pipe 12 can be easily supplied over a wide area of the stator core 32, and the stator core 32 can be cooled more effectively.

Second Embodiment
As shown in Fig. 7, in the stator 130 of the drive device 101 of this embodiment, the stator core 132 does not have a fixing portion 32b that protrudes radially outward. The pipe 110 of this embodiment includes, for example, only the second pipe 112. The second pipe 112 is disposed at approximately the same position as the upper end of the stator core 132 in the vertical direction. In this embodiment, the upper end of the stator core 132 is the upper end of the stator core main body 32a. In this embodiment, the pipe 110 corresponds to a refrigerant flow path.

The supply port 115 of the second pipe 112 is located slightly below the upper end of the stator core 132. In this embodiment, the supply port 115 corresponds to the first supply port. The supply port 115 faces diagonally upward toward the front. When viewed in the axial direction, the direction DI3 in which the supply port 115 opens is higher than the direction in which the tangent line TL3 that passes through the supply port 115 and touches the outer peripheral surface of the stator core 132 extends from the supply port 115 toward the outer peripheral surface of the stator core 132. Therefore, the oil O injected from the supply port 115 can easily reach a portion of the stator core 132 that is located above the contact point TP2 between the tangent line TL3 and the outer peripheral surface of the stator core 132. In this embodiment, the oil O injected from the supply port 115 can easily reach the rear side of the contact point TP2. Therefore, the cooling efficiency of the stator 130 can be improved.

In this embodiment, the oil O injected from the supply port 115 is supplied to the top of the stator core body 32a. Here, the stator core 132 of this embodiment does not have a fixed portion 32b that protrudes radially outward. Therefore, the oil O supplied to the outer peripheral surface of the stator core body 32a from the supply port 115 can move circumferentially on the outer peripheral surface of the stator core body 32a without being hindered by the fixed portion 32b. Therefore, the oil O supplied to the top of the stator core body 32a can easily flow to both sides in the front-rear direction along the outer peripheral surface of the stator core body 32a, making it easier to spread the oil O around the entire circumference of the stator core 132. Therefore, the cooling efficiency of the stator 130 can be further improved. In addition, since the entire stator core 132 can be appropriately cooled only by the second pipe 112, the number of pipes 110 can be reduced, and the number of parts of the drive device 101 can be reduced.

In this embodiment, the tangent line TL3 is, for example, a tangent line that passes through the center point CP3 at the end of the circular supply port 115 provided on the outer circumferential surface of the second pipe 112 and is in contact with the outer circumferential surface of the stator core body 32a. The direction DI3 in which the supply port 115 opens is the direction in which the supply port 115 penetrates from the inner circumferential surface to the outer circumferential surface of the second pipe 112. The angle θ3 between the direction in which the tangent line TL3 extends from the supply port 115 toward the outer circumferential surface of the stator core 132 and the direction in which the supply port 115 opens, is, for example, about 15° or more and 45° or less. The angle θ3 is the smaller angle between the tangent line TL3 and a virtual line L3 that passes through the center point CP3 and extends parallel to the direction in which the supply port 115 penetrates the second pipe 112, as viewed in the axial direction.

In this embodiment, the first pipe 11 may be provided as in the first embodiment. Also, the second pipe 112 may be provided with a supply port for supplying oil O to the coil ends 33a and 33b.

The present invention is not limited to the above-described embodiment, and other configurations may be adopted within the scope of the technical concept of the present invention. In the above-described embodiment, the refrigerant is oil O, but this is not limited to the above. The refrigerant is not particularly limited as long as it can be supplied to the stator to cool the stator. The refrigerant may be, for example, an insulating liquid or water. If the refrigerant is water, an insulating treatment may be applied to the surface of the stator.

The refrigerant flow path may have any shape and may be arranged in any manner as long as it has a first supply port. The number of first supply ports is not particularly limited as long as it is one or more. The number of second supply ports is not particularly limited. The second supply port does not have to be provided. The shape and size of the first supply port may be different from the shape and size of the second supply port.

In the above-described embodiment, the lower supply port 15 as the first supply port and the second upper supply port 14 as the second supply port are provided in different pipes 10, but this is not limited to the above. The first supply port and the second supply port may be provided in the same pipe. The refrigerant flow path may be provided with a supply port that supplies oil as a lubricant to bearings such as the rotor. The refrigerant flow path does not have to be a pipe. In this case, the refrigerant flow path may be a flow path formed by a hole provided in the housing.

The shape of the first pipe as the upper refrigerant flow path and the shape of the second pipe as the lower refrigerant flow path are not particularly limited. The first pipe and the second pipe may be rectangular tubular. The first pipe and the second pipe may be bent or curved. The ends of the first pipe and the second pipe opposite the side into which the refrigerant flows may be open.

The flow path connecting the first pipe and the second pipe may have any shape and may be provided at any position. For example, in the above-mentioned embodiment, a flow path connecting the first pipe 11 and the second pipe 12 may be provided in the wall portion 61b located on the right side of the stator 30. The flow path connecting the first pipe and the second pipe may be, for example, a branched pipe. A flow path connecting the first pipe and the second pipe may not be provided. In this case, the refrigerant may flow into the first pipe and the second pipe separately. The configuration may be such that the refrigerant that flows into one of the first pipe and the second pipe flows into the other of the first pipe and the second pipe. The pump may be a mechanical pump. A pump may not be provided.

The driving device is not particularly limited as long as it is a device that can move a target object using a motor as a power source. The driving device does not need to have a transmission mechanism. The torque of the motor may be output directly to the target from the motor shaft. In this case, the driving device corresponds to the motor itself. The direction in which the motor shaft extends is not particularly limited. The motor shaft may extend in the vertical direction. In this specification, "the motor shaft extends in a horizontal direction perpendicular to the vertical direction" includes the case in which the motor shaft extends in a substantially horizontal direction in addition to the case in which the motor shaft extends in a strictly horizontal direction. In other words, in this specification, "the motor shaft extends in a horizontal direction perpendicular to the vertical direction" may mean that the motor shaft is slightly inclined with respect to the horizontal direction. In the above embodiment, the case in which the driving device does not include an inverter unit has been described, but this is not limited to this. The driving device may include an inverter unit. In other words, the driving device may be integral with the inverter unit.

The use of the drive unit is not particularly limited. The drive unit does not have to be mounted on a vehicle. The configurations described in this specification can be combined as appropriate within the scope of not being mutually inconsistent.

1,101...Driver, 2...Motor, 3...Transmission device, 6...Housing, 10,110...Pipe (refrigerant flow path), 11...First pipe (upper refrigerant flow path), 12...Second pipe (lower refrigerant flow path), 14...Second upper supply port (second supply port), 15...Lower supply port (first supply port), 20...Rotor, 30,130...Stator, 32,132...Stator core, 55...Axle, 115...Supply port (first supply port), G...Gap, J1...Motor shaft, O...Oil (refrigerant), TL1a, TL1b, TL2, TL3...Tangent, TP1, TP2...Contact point

Claims (7)

a motor having a rotor rotatable about a motor shaft and a stator positioned radially outward of the rotor;
a refrigerant flow path through which a refrigerant flows;
Equipped with
The stator has a stator core surrounding the rotor,
the refrigerant flow path has a first supply port and a second supply port that supply the refrigerant to the stator core on a radially outer side of the stator core,
The second supply port is located on a vertically upper side of the stator core,
When viewed in the axial direction of the motor shaft, a direction in which the first supply port opens is such that a tangent line that passes through the first supply port and touches the outer peripheral surface of the stator core is inclined radially outward with respect to a direction in which the tangent line extends from the first supply port toward the outer peripheral surface of the stator core,
When viewed in the axial direction of the motor shaft, a direction in which the second supply port opens is vertically downward with respect to a direction in which a tangent line that passes through the second supply port and touches the outer peripheral surface of the stator core extends from the second supply port toward the outer peripheral surface of the stator core.
Drive unit. a motor having a rotor rotatable about a motor shaft and a stator positioned radially outward of the rotor;
a refrigerant flow path through which a refrigerant flows;
Equipped with
The stator has a stator core surrounding the rotor,
the refrigerant flow path has a first supply port and a second supply port that supply the refrigerant to the stator core on a radially outer side of the stator core,
When viewed in the axial direction of the motor shaft, a direction in which the first supply port opens is such that a tangent line that passes through the first supply port and touches the outer peripheral surface of the stator core is inclined radially outward with respect to a direction in which the tangent line extends from the first supply port toward the outer peripheral surface of the stator core,
When viewed in the axial direction of the motor shaft, a direction in which the second supply port is opened is such that a tangent line that passes through the second supply port and touches the outer peripheral surface of the stator core is inclined radially inward with respect to a direction that extends from the second supply port toward the outer peripheral surface of the stator core.
Drive unit. The motor shaft extends in a direction intersecting a vertical direction,
the first supply port is located vertically below an upper end of the stator core in the vertical direction,
3. The drive device according to claim 1, wherein, when viewed in the axial direction of the motor shaft, the direction in which the first supply port opens is vertically upward relative to the direction in which the tangent line extends from the first supply port toward the outer peripheral surface of the stator core. The refrigerant flow path is
a lower refrigerant flow path provided with the first supply port;
an upper refrigerant flow path in which the second supply port is provided and which is located vertically above the lower refrigerant flow path;
The drive arrangement according to claim 1 or 2, comprising: a housing for accommodating the motor therein;
5. The drive device according to claim 1, wherein a gap is provided radially between the inner surface of the housing and the outer surface of the stator core in a circumferential region from the first supply port to a contact point where the tangent meets the outer surface of the stator core. A drive device mounted on a vehicle,
The drive device according to claim 1 , further comprising a transmission device connected to the motor and configured to transmit a torque of the motor to an axle of the vehicle. The stator core is
A stator core body;
a fixing portion protruding radially outward from an outer circumferential surface of the stator core body;
having
the coolant flow passage has a second supply port that supplies the coolant to the stator core on a radially outer side of the stator core,
the fixing portion and the second supply port are provided on a vertically upper side of the stator core body,
the fixed portion is provided on one side of the motor shaft in a front-rear direction intersecting an axial direction and a vertical direction,
The second supply port is provided on the other side in the front-rear direction with respect to the motor shaft.
A drive arrangement according to any one of claims 1 to 6 .

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