JP6534414B2 - Power plant - Google Patents

Description

  The present invention relates to a power unit provided in an electric vehicle.

  An electric motor for driving left and right wheels of a vehicle, a transmission disposed on a power transmission path between the electric motor and the left and right wheels, and an output shifted by the transmission, the left and right wheels. And a differential gear for distributing power. This type of power unit is provided as a front wheel drive unit or a rear wheel drive unit in an electric vehicle such as a hybrid vehicle or an electric vehicle, and accommodates an electric motor, a transmission and a differential gear for appropriate power transmission. It is necessary to properly lubricate these motors, transmissions and differentials with lubricating oil stored in the storage section of the housing.

  Therefore, in Patent Document 1, a plurality of ribs (fins) that scrape the lubricating oil according to the rotation of the differential case are provided in the differential case (differential ring gear) of the differential gear in which the flange portion is located in the storage portion A power plant has been proposed.

JP 2012-57641 A

  However, the plurality of ribs described in Patent Document 1 are set on the assumption that the differential case rotates in the normal direction, and do not consider the case in which the differential case rotates in the reverse direction. Depending on the rotational direction of the differential case, the ability to pick up the lubricating oil changes, and there is a risk that the necessary parts can not be lubricated properly. In addition, it is possible to provide an oil pump that forcibly supplies the lubricating oil stored in the oil tank to the part that needs lubrication, but in this case, a space for providing the oil pump and the oil tank is required. Not only that, there is a risk of increasing weight and cost.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a power unit capable of scraping up a liquid medium and appropriately lubricating a necessary portion regardless of the rotation direction of the differential case.

In order to achieve the above object, the invention according to claim 1 is
An electric motor for driving left and right wheels of the vehicle (for example, an electric motor 2 according to an embodiment described later);
A transmission (for example, a transmission 5 of an embodiment described later) disposed on a power transmission path between the motor and the left and right wheels;
A differential gear (for example, a differential gear 6 in an embodiment described later) for distributing the output shifted by the transmission to the left wheel and the right wheel;
A housing (for example, a housing 4 in an embodiment described later) for housing the motor, the transmission, and the differential device;
A storage section (for example, a storage section 44 of an embodiment described later) provided at the bottom of the housing and storing a liquid medium;
A counter holder (for example, a counter holder 54 of an embodiment described later) for rotatably supporting a counter gear (for example, a counter gear 53 of an embodiment described later) ;
A power unit (e.g., the flange portion 61b of an embodiment described later, for example, a flange portion 61b of the embodiment described later) is located in the storage portion. , A power unit 1) of an embodiment described later,
The differential case is provided with a plurality of ribs (for example, ribs 61f, 61m, 61n in an embodiment described later) for scraping the liquid medium in the flange portion,
The plurality of ribs are a first guide surface (for example, first guide surfaces 61h and 61j in the embodiment described later) recessed to one side in the rotational direction, and a second guide surface (for example, described later) recessed to the other side in the rotational direction. second guide surface 61i of the embodiments, possess a 61k), and
One end of the differential case is rotatably supported by a bearing support (for example, a bearing support 45 of an embodiment described later) through a bearing (for example, a bearing 66 described in embodiment described below).
The other end of the differential case is rotatably supported by the counter holder via another bearing (for example, a bearing 65 in an embodiment described later),
The plurality of ribs scatter the liquid medium toward the bearing support portion,
The counter holder has a storage space (for example, a space S in an embodiment described later) for storing the liquid medium scraped up by a rotating body (for example, a counter gear 53 in an embodiment described later),
The liquid medium is supplied to the other bearing through the storage space .

The invention according to claim 2 is
The power plant according to claim 1, wherein
The plurality of ribs have a bidirectional rib (for example, a rib 61 f in an embodiment described later) in which both the first guide surface and the second guide surface are formed.

The invention according to claim 3 is
The power plant according to claim 1, wherein
The plurality of ribs are a first rib (for example, a first rib 61m in an embodiment described later) in which the first guide surface is formed, and a second rib (for example, described later) in which the second guide surface is formed. And a second rib 61n of the embodiment;
The plurality of first ribs and the plurality of second ribs are arranged symmetrically with respect to an imaginary line (for example, an imaginary line L2 in an embodiment described later) passing through the axial center of the differential device.

The invention according to claim 4 is
The power plant according to any one of claims 1 to 3 , wherein
An oil passage (for example, an oil passage 46 in an embodiment described later) for guiding the liquid medium toward the bearing is provided on the inner surface of the housing.

The invention according to claim 5 is
The power plant according to claim 4 , wherein
The oil passage is a stepped portion (for example, a stepped portion 42b in an embodiment described later) provided on the inner surface of the housing.

According to the first aspect of the present invention, the differential case is provided with a plurality of ribs for scraping the liquid medium in the flange portion, and the plurality of ribs are the first guide surface recessed to one side in the rotational direction Since it has a second guide surface recessed to the other side in the rotational direction, the liquid medium can be scraped up regardless of the rotational direction of the differential case, and a portion where the liquid medium scraped up by the ribs needs to be lubricated By supplying the oil, it is possible to properly lubricate the necessary parts even if there is no oil pump or oil tank. Further, since the first guide surface and the second guide surface are recessed, the liquid medium temporarily collected on each guide surface can be scattered by centrifugal force.
Further, one end of the differential case is rotatably supported by the bearing support of the housing via the bearing, and the plurality of ribs scatter the liquid medium toward the bearing support, so that the liquid medium which the ribs scrape Thus, the bearing that rotatably supports one end of the differential case can be lubricated.
Furthermore, the power unit includes a counter holder that rotatably supports the counter gear, the other end of the differential case of the differential device is rotatably supported by the counter holder via another bearing, and the counter holder is Because the rotating body has a storage space for storing the scraped liquid medium, and the other bearing is supplied with the liquid medium through the storage space, the counter holder is used to use the other end of the differential case. It can lubricate the rotatably supported bearings.

  According to the invention as set forth in claim 2, since the plurality of ribs have bi-directional ribs in which both the first guide surface and the second guide surface are formed, the number of guide surfaces is increased. The amount of scattering can be increased.

  According to the third aspect of the present invention, the plurality of ribs have a first rib on which the first guide surface is formed, and a second rib on which the second guide surface is formed, and the plurality of first ribs are formed. Since the rib and the plurality of second ribs are arranged symmetrically with respect to an imaginary line passing through the axial center of the differential device, when the rotation number of the differential case is the same, a certain amount of liquid does not The medium can be scraped up.

According to the fourth aspect of the invention, since the oil passage for guiding the liquid medium toward the bearing is provided on the inner surface of the housing, the lubricating performance of the bearing can be improved.

According to the fifth aspect of the present invention, since the oil passage is a step provided on the inner surface of the housing, the lubricating performance of the bearing can be improved with a simple configuration.

It is sectional drawing of the power unit which concerns on one Embodiment of this invention, and is AA sectional drawing of FIG. It is an internal side view of the power unit which saw a partition and a counter gear from the differential gear side. It is the perspective view which looked at the counter gear, the 2nd gear, and the counter holder (bearing omitted) from the differential device side. It is a BB sectional view of FIG. It is the perspective view which looked at the principal part of the counter holder from the counter gear side. It is a fragmentary sectional view of the power plant of FIG. 1, and is CC sectional drawing of FIG. It is a perspective view of a differential case. It is a perspective view showing the inside of the 2nd case. It is a perspective view which shows the modification of a differential case. It is DD sectional drawing of FIG.

Hereinafter, an embodiment of a power plant 1 according to the present invention will be described based on FIGS. 1 to 8.
The power unit 1 of the present embodiment uses the electric motor 2 as a drive source for driving an axle, and is provided in an electric vehicle such as a hybrid vehicle or an electric vehicle as a front wheel drive device or a rear wheel drive device.

[Power unit]
In FIG. 1, reference numerals 3A and 3B denote left and right axles, which are coaxially arranged along the vehicle width direction. The entire housing 4 of the power unit 1 is formed in a substantially cylindrical shape, and inside thereof, a motor 2 for driving an axle, a transmission 5 for decelerating driving rotation of the motor 2, and a drive decelerated by the transmission 5 A differential 6 which distributes the rotation to the axles 3A, 3B is arranged.

  The housing 4 includes a first case 41 accommodating the electric motor 2 and a second case 42 accommodating the transmission 5 and the differential gear 6. A partition 43 is provided at the boundary between the first case 41 and the second case 42, and the partition 43 divides the internal space of the first case 41 and the internal space of the second case 42. The partition wall 43 is fastened to the step portion 41 b provided on the outer peripheral portion of the first case 41 via the bolt 47. Therefore, the mating surface A1 of the first case 41 and the partition wall 43 is located closer to the first case 41 than the mating surface A2 of the first case 41 and the second case 42. The bottom of the housing 4 functions as a reservoir 44 for storing lubricating oil (liquid medium), and the lubricating oil is stored up to the stationary oil level L shown in FIG. The stationary oil level L is an air gap G of the motor 2 (a gap secured between the inner periphery of the stator 21 and the It is set lower than). In addition, as shown also in FIG. 2, the communication port 43a which permits the distribution | circulation of lubricating oil to the lower part of the partition 43 is formed.

[Electric motor]
The motor 2 includes a stator 21 fixed to the inner circumferential portion of the first case 41 and a rotor 22 rotatably disposed on the inner circumferential side of the stator 21. The rotor shaft 23 surrounding the outer periphery of one axle 3A is connected to the inner peripheral portion of the rotor 22, and the end of the first case 41 is rotatable relative to the axle 3A coaxially with the axle 3A. It is supported on the wall 41 a and the partition wall 43 via bearings 24 and 25. Further, one end side of the axle 3A and the rotor shaft 23 penetrates the partition wall 43 and extends into the second case 42, and the other end side of the axle 3A penetrates the end wall 41a of the first case 41 to be a housing It extends outward of 4.

[transmission]
The transmission 5 has a first gear 51 mechanically connected to the motor 2 and a rotational axis identical to the first gear 51, and is mechanically connected to the differential case 61 of the differential gear 6. A second gear 52, a plurality of counter gears 53 meshing with the first gear 51 and the second gear 52, and a counter holder 54 supporting the plurality of counter gears 53 rotatably and non-reversibly, the first gear When the drive rotation of the motor 2 is input from 51, the drive rotation decelerated through the counter gear 53 and the second gear 52 is output to the differential case 61 of the differential device 6.

  The first gear 51 is an external gear and is integrally formed with the rotor shaft 23. The counter gear 53 includes a large diameter gear 53a formed of an external gear, a small diameter gear 53b formed of an external gear, and a countershaft 53c supporting the large diameter gear 53a and the small diameter gear 53b so as to be integrally rotatable. The large diameter gear 53 a is coupled to the motor 2 side of the counter shaft 53 c and meshes with the first gear 51. The small diameter gear 53 b is integrally formed on the side of the countershaft 53 c with respect to the differential gear 6 and meshes with the second gear 52. The end portion of the counter shaft 53c on the motor 2 side is rotatably supported by the partition wall 43 via the bearing 55, and the end portion on the differential device 6 side is supported by the counter gear support 54a of the counter holder 54 via the bearing 56. It is rotatably supported.

  As shown in FIG. 2, the transmission 5 of the present embodiment includes three counter gears 53. The three counter gears 53 are arranged at equal intervals (120 ° intervals) in the circumferential direction around the first gear 51. At least one of the three counter gears 53 is partially or entirely located in the above-described storage portion 44, and functions as a rotating body that scrapes the lubricating oil in the storage portion 44 by rotation accompanying driving of the motor 2. ing. In the example shown in FIG. 2, the lowermost counter gear 53 disposed immediately below the first gear 51 is made to function as a rotating body that scrapes the lubricating oil, and the scraped lubricating oil is supplied to the upper two counter gears 53. doing. Here, assuming that the counter gear 53 rotates counterclockwise toward FIG. 2, the lubricant oil scraped up by the rotation of the lowermost counter gear 53 is mainly supplied to the counter gear located at the upper left, Further, the lubricating oil splashed by the rotation of the counter gear located at the upper left is mainly sequentially supplied to the counter gear located at the upper right.

  In the second gear 52, the gear portion 52a is an internal gear, and meshes with the small diameter gear 53b of the counter gear 53. The second gear 52 includes a connecting portion 52b extending from the gear portion 52a to the differential device 6 across the outer peripheral side of the counter holder 54 (counter gear support portion 54a), and this connecting portion 52b is a connection such as a spline It is mechanically connected to the differential case 61 of the differential 6 via a means. In other words, the second gear 52 includes a second gear large diameter portion 52c that constitutes the connection portion 52b with the differential case 61, a second gear small diameter portion 52d that constitutes the gear portion 52a that meshes with the counter gear 53, and The second gear connecting portion 52e connecting the 2-gear large diameter portion 52c and the second gear small diameter portion 52d is provided, and the outer diameter of the second gear small diameter portion 52d is the same as that of the second gear large diameter portion 52c. It is smaller than the outer diameter. The second gear 52 also has a lower end portion located in the storage portion 44 described above, and also functions as a rotating body that scrapes the lubricating oil in the storage portion 44 by the rotation accompanying the drive of the motor 2.

  As shown in FIGS. 3 to 5, the counter holder 54 includes three counter gear support portions 54 a rotatably supporting the counter shaft 53 c of the counter gear 53 via the bearings 56, and three fixed to the partition wall 43. A stationary portion 54b and a bottomed cylindrical cup portion 54c formed at a central portion of the counter holder 54 (inner diameter side of the counter gear support portion 54a and the stationary portion 54b) are provided.

  The difference between the differential gear 6 and the meshing portion M between the second gear 52 mechanically connected to the differential case 61 of the differential gear 6 and the small diameter gear 53 b of the counter gear 53 is the counter gear support 54 a. It is disposed on the moving case 61 side. Thus, by supporting the other end of the counter shaft 53c supported by the partition 43 through the bearing 55 at one end by the counter gear support 54a through the bearing 56, the counter gear 53 can be properly held in a double-held state It becomes possible to support.

  The three fixing portions 54 b are located at intermediate portions of the counter gear support portions 54 a adjacent in the circumferential direction, and are each fastened to the partition wall 43 via the bolts 57. Thus, the partition wall 43 is used both as a support member for the counter shaft 53 c and a support member for the counter holder 54.

  The cup portion 54c surrounds the outer periphery of one axle 3A via the space portion S on the inner peripheral side of the meshing portion M from the one end side to the other end side of the meshing portion M in the axial direction and in the radial direction. A through hole 54e through which one axle 3A passes is formed in the bottom 54d at one end side. Further, an inner peripheral portion on the other end side of the cup portion 54 c rotatably supports one end side of the differential case 61 via a bearing 65. Thus, the counter holder 54 is used both as a support member for the counter gear 53 and a support member for the differential case 61.

[Differential]
The differential gear 6 is differential in order to allow the rotational difference between the left and right axles 3A, 3B while distributing the drive rotation inputted from the second gear 52 to the differential case 61 to the left and right axles 3A, 3B. A case 61, a differential pinion shaft 62, a differential pinion gear 63, and left and right side gears 64A and 64B are provided.

  The differential case 61 includes a spherical differential case main body 61a accommodating the differential pinion shaft 62, the differential pinion gear 63 and the left and right side gears 64A and 64B, and extends radially from the outer peripheral portion of the differential case main body 61a. A flange portion 61b mechanically connected to the 2-gear 52, and left and right extending portions 61c and 61d axially extending from both sides of the differential case main body 61a are provided. The one extension portion 61 c rotatably supports one axle 3 A at an inner peripheral portion, and an outer peripheral portion is rotatably supported by a counter holder 54 via a bearing 65. The other extension 61 d rotatably supports the other axle 3 B at the inner circumferential portion, and the outer circumferential portion is provided on the end wall 42 a of the second case 42 via the bearing 66. Is rotatably supported.

  The differential pinion shaft 62 is supported by the differential case main body 61a in a direction orthogonal to the axles 3A and 3B, and can rotate two differential pinion gears 63 formed of bevel gears inside the differential case main body 61a. In favor of That is, the differential pinion shaft 62 allows rotation of the differential pinion gear 63 while revolving the differential pinion gear 63 according to the rotation of the differential case 61.

  The left and right side gears 64A, 64B are bevel gears and rotatably supported inside the differential case main body 61a so as to mesh with the differential pinion gear 63 from both sides, and via connecting means such as splines It is mechanically connected to the left and right axles 3A, 3B. When the differential pinion gear 63 revolves without rotating, for example, when traveling straight, the left and right side gears 64A, 64B rotate at a constant speed, and the drive rotation is transmitted to the left and right axles 3A, 3B. Further, when traveling on a curve or turning left and right, the left and right side gears 64A, 64B rotate relative to each other by rotating the differential pinion gear 63, and the rotation difference between the left and right axles 3A, 3B is allowed.

[Counter holder lubrication function]
Next, the lubricating function of the counter holder 54 will be described.

  The counter holder 54 has a storage space for storing the lubricating oil scraped up from the storage portion 44 of the housing 4 by the second gear 52 and the counter gear 53. This storage space is the above-mentioned space portion S formed of the cup portion 54c and one of the axles 3A, and the lubricating oil scraped up by the second gear 52 and the counter gear 53 communicates with the space portion S described later. It flows into the space S through the communication holes 54f and 54g.

  The lubricating oil which has flowed into the space S is supplied to the above-mentioned bearing 65 which is disposed adjacent to the space S and rotatably supports one end side of the differential case 61, and is appropriately lubricated. The lubricating oil is also distributed from the space S to the inside of the differential 6 requiring lubrication and the electric motor 2 requiring cooling by the lubricating oil. More specifically, the lubricating oil is supplied from the space S to the inside of the differential gear 6 through the gap between the axle 3A and the extension 61c of the differential case 61, and the space S from the axle 3A and the like. It is supplied to the motor 2 side through a gap with the rotor shaft 23.

  As shown in FIG. 5, the counter holder 54 is provided with a first guide portion 54i on the first surface 54h facing the counter gear 53 to receive the lubricating oil scraped up by the second gear 52 and the counter gear 53. The first guide portion 54i is a protrusion formed on both sides of the cup portion 54c and linearly extending toward the cup portion 54c, and guides the received lubricating oil to the cup portion 54c. A communication hole 54f is formed in the connection between the first guide portion 54i and the cup portion 54c, and the lubricating oil received by the first guide portion 54i is stored in the space S via the communication hole 54f. .

  As shown in FIG. 3, the counter holder 54 receives the lubricating oil scraped up by the second gear 52 and the counter gear 53 on the second surface 54 j facing the differential case 61 of the differential device 6. Equipped with The second guide portion 54k is a protrusion which is formed above the cup portion 54c and extends in an arc shape below the uppermost fixing portion 54b, and guides the received lubricating oil to the cup portion 54c. A communication hole 54g is formed at the connection between the second guide portion 54k and the cup portion 54c, and the lubricating oil received by the second guide portion 54k is stored in the space S via the communication hole 54g. . The communication hole 54g also communicates with the first surface 54h of the counter holder 54.

  As shown in FIGS. 3 and 4, among the counter gear support portions 54 a of the counter holder 54, the counter gear support portions 54 a that support the above-mentioned upper two counter gears 53 are a differential case 61 of the differential gear 6. A pocket 54m for storing lubricating oil is provided at the open end on the side of the second surface 54j opposite to the second surface 54j. The pocket 54m enables appropriate lubrication of the bearing 56 by temporarily retaining the lubricating oil supplied to the counter gear support 54a.

  By the way, a part of the lubricating oil supplied from the space S to the bearing 65 passes through the inside of the bearing 65 and flows to the outer periphery of the differential case 61, and receives a centrifugal force accompanying the rotation of the differential case 61. It moves in the outer diameter direction along the portion 61b. The flange portion 61b of the present embodiment is provided with a third guide portion 61e that guides the lubricating oil moving in the outer diameter direction along the flange portion 61b to the upper two counter gear support portions 54a. The third guide portion 61e is an edge portion of an annular recess formed on the surface of the flange portion 61b facing the counter gear 53, and the edge portion is formed at a position facing the counter gear support portion 54a in the radial direction. The lubricating oil moving in the outer diameter direction along the flange portion 61b is guided to the counter gear support portion 54a. A part of the lubricating oil scraped up by the second gear 52 also has the same flow.

[Rib and through hole]
Next, the rib 61f and the through hole 61g provided in the differential case 61 will be described with reference to FIG.

  The lower end portion of the flange portion 61 b of the differential case 61 is located in the storage portion 44 described above, and also functions as a rotating body that scrapes the lubricating oil in the storage portion 44 by rotation accompanying driving of the motor 2. Among the front and back surfaces of the flange portion 61b facing in the axial direction, a plurality of ribs 61f that scrape the lubricating oil are provided on the surface facing the above-described bearing support portion 45. The differential case 61 of the present embodiment includes ten ribs 61 f aligned in the circumferential direction on the surface of the flange portion 61 b.

  Each rib 61f is provided on the surface of the flange portion 61b so as to extend in the radial direction, and on both sides in the circumferential direction, a first guide surface 61h recessed toward one side in the rotational direction, and recessed toward the other side in the rotational direction And a second guide surface 61i. Specifically, the rib 61f of the present embodiment is provided with the guide surfaces 61h and 61i which are recessed in a circular arc shape on both sides in the circumferential direction, and the rib center line L1 passing through the axial center of the differential device 6 (see FIG. 7) ) Has a symmetrical shape.

  According to such a rib 61 f, the lubricating oil in the storage portion 44 can be reliably scraped up regardless of the rotation direction of the differential case 61. In addition, the first guide surface 61h and the second guide surface 61i are recessed, so that lubricating oil is temporarily collected on each of the guide surfaces 61h and 61i, and the collected lubricating oil is scattered by centrifugal force. it can. In addition, since the rib 61f of the present embodiment constitutes a bidirectional rib in which both the first guide surface 61h and the second guide surface 61i are formed, the first guide surface 61h and the second guide surface 61i The number of guide surfaces 61h and 61i can be increased to increase the scattering amount of the lubricating oil, as compared with the case where they are formed on separate ribs.

  The first guide surface 61h and the second guide surface 61i are formed to have a predetermined gradient θ1 (see FIG. 10) without rising at a right angle from the surface of the flange portion 61b. Specifically, the angle θ2 (see FIG. 10) between the surface of the flange portion 61b and each of the guide surfaces 61h and 61i is set to be an obtuse angle. According to the rib 61f having such first guide surface 61h and second guide surface 61i, the lubricating oil collected by each of the guide surfaces 61h and 61i along with the rotation of the differential case 61 is axially oriented by the gradient θ1. Since the lubricant can be scattered, the lubricating oil scraped up by the rib 61 f can be supplied to the bearing support 45 to lubricate the bearing 66 that rotatably supports one end of the differential case 61.

  The differential case 61 is arranged to divide the internal space of the second case 42 into one axial side and the other axial side. The liquid level of the lubricating oil in the reservoir 44 is uniform on the front and back sides of the differential case 61 if the power unit 1 is stationary, but if the differential case 61 is rotating. Since the lubricating oil is scraped up by the ribs 61f on the surface side of the differential case 61, the liquid level of the lubricating oil in the reservoir 44 becomes lower on the surface side of the differential case 61, and the lubricating oil by the ribs 61f Performance may be reduced.

  Therefore, in the differential case 61, a through hole 61g is provided which penetrates the front surface and the back surface of the flange portion 61b. The differential case 61 of the present embodiment has six through holes 61g aligned in the circumferential direction, and the lubricating oil is caused to flow through these through holes 61g, thereby the surface side of the flange portion 61b of the differential case 61 The difference in the liquid level of the reservoir 44 on the back side is reduced.

  The through holes 61 g are provided at positions avoiding the plurality of ribs 61 f in the flange portion 61 b of the differential case 61. Specifically, through holes 61g are formed to be located between adjacent ribs 61f on the surface of the flange portion 61b. According to such a differential case 61, it is possible to suppress the decrease in liquid level due to the scraping of the rib 61f without the through hole 61g from inhibiting the scraping function of the lubricating oil by the rib 61f.

[Oil passage]
Next, the oil passage 46 provided in the second case 42 will be described with reference to FIG.

  On the inner surface of the second case 42, an oil passage 46 for guiding the lubricating oil scraped up by the plurality of ribs 61f of the differential case 61 toward the bearing 66 is provided. The oil passage 46 of the present embodiment is a stepped portion 42 b provided on the inner surface of the second case 42, and the oil passage 46 can be configured with a simple configuration to improve the lubricating performance of the bearing 66.

  Specifically, the second case 42 of the present embodiment is at the lower side portion of the inner surface area facing the flange portion 61 b of the differential case 61 where the scraping of the lubricating oil by the rib 61 f is actively performed. A bulging portion 42c is provided which improves the scraping efficiency of the lubricating oil by the rib 61f by bulging the case inward to reduce the clearance with the rib 61f. Step portions 42 b which are boundaries between the non-blow-out portions 42 d are formed at both circumferential end portions of the bulging portions 42 c, and the step portions 42 b function as the oil passage 46. That is, when the lubricating oil scraped up by the rib 61 f is scattered toward the inner surface of the second case 42, the scattered lubricating oil flows down along the inner surface (non-expansion portion 42 d) of the second case 42. After being received by the step 42b, the bearing 66 is supplied along the step 42b. The stepped portion 42 b may be an inclined surface which becomes lower toward the bearing 66.

  As described above, according to the power unit 1 of the present embodiment, the differential case 61 is provided with the plurality of ribs 61f that scrape the lubricating oil in the flange portion 61b, and the plurality of ribs 61f are in the rotational direction Since the first guide surface 61 h recessed to one side and the second guide surface 61 i recessed to the other side in the rotational direction, lubricating oil can be scraped up regardless of the rotational direction of the differential case 61, By supplying the lubricant oil scraped up by the ribs 61f to a portion requiring lubrication, the necessary portion can be appropriately lubricated even if there is no oil pump or oil tank. Further, since the first guide surface 61h and the second guide surface 61i are recessed, the lubricating oil temporarily collected on each of the guide surfaces 61h and 61i can be scattered by centrifugal force.

  In addition, since the plurality of ribs 61f are bi-directional ribs in which both the first guide surface 61h and the second guide surface 61i are formed, the number of guide surfaces 61h and 61i is increased to increase the scattering amount of lubricating oil. Can.

  Further, one end of the differential case 61 is rotatably supported by the bearing support 45 of the housing 4 via the bearing 66, and the plurality of ribs 61f scatter the lubricating oil toward the bearing support 45, The lubricating oil scraped by the ribs 61f can lubricate the bearing 66 rotatably supporting one end of the differential case 61.

  The power unit 1 further includes a counter holder 54 that supports the counter gear 53 so that the counter gear 53 can rotate, and the other end of the differential case 61 of the differential device 6 can be rotated by the counter holder 54 via another bearing 65. Supported by the counter holder 54 has a space S for storing the lubricating oil scraped up by the counter gear 53, and the other bearing 65 is supplied with the lubricating oil through the space S. The holder 54 can be used to lubricate the bearing 65 that rotatably supports the other end of the differential case 61.

  In addition, since the oil passage 46 for guiding the lubricating oil toward the bearing 66 is provided on the inner surface of the housing 4, the lubricating performance of the bearing 66 can be improved.

  Further, since the oil passage 46 is the stepped portion 42 b provided on the inner surface of the housing 4, the lubricating performance of the bearing 66 can be improved with a simple configuration.

[Modification]
Next, a modification of the differential case 61 will be described with reference to FIGS. 9 and 10. However, about the same composition as the above-mentioned embodiment, explanation of the above-mentioned embodiment is used by using the same numerals as the above-mentioned embodiment.

  As shown in FIGS. 9 and 10, the differential case 61B according to the modification is recessed on the other side in the rotational direction with a plurality of first ribs 61m in which the first guide surface 61j recessed on one side in the rotational direction is formed. The point which is provided with a plurality of second ribs 61n in which a second guide surface 61k is formed is different from the differential case 61 of the embodiment.

  When the number of first ribs 61m (for example, five) and the number of second ribs 61n (for example, five) are the same, and the rotation number of the differential case 61B is the same, a constant amount regardless of the rotation direction Can scoop up the lubricating oil. Further, in the differential case 61B shown in FIG. 9, since the plurality of first ribs 61m and the plurality of second ribs 61n are arranged symmetrically with respect to the imaginary line L2 passing through the axial center of the differential device 6, Not only the number of the first ribs 61m and the number of the second ribs 61n become equal to each other, the plurality of first ribs 61m and the plurality of second ribs 61n can be efficiently arranged.

  Further, as shown in FIG. 10, the first guide surface 61j and the second guide surface 61k of the differential case 61B according to the modification are also flanged as in the first guide surface 61h and the second guide surface 61i described above. It is formed to have a predetermined gradient θ1 without rising at a right angle from the surface of 61b. Specifically, an angle θ2 between the surface of the flange portion 61b and each of the guide surfaces 61j and 61k is set to be an obtuse angle.

The present invention is not limited to the embodiments described above, and appropriate modifications, improvements, etc. are possible.
For example, the power unit 1 may adopt a forced lubrication method using an oil pump, as well as a scraping type lubrication method.
In addition, any shape can be adopted as long as the plurality of ribs have a first guide surface recessed to one side in the rotational direction and a second guide surface recessed to the other side in the rotational direction.

REFERENCE SIGNS LIST 1 power unit 2 motor 4 housing 42 b stepped portion 45 bearing support portion 46 oil passage 44 reservoir 5 transmission 53 counter gear 54 counter gear 54 counter holder 6 differential gear 61, 61 B differential case 61 b flange portion 61 f rib 61 h first guide surface 61 i Second guide surface 61j First guide surface 61k Second guide surface 61m First rib 61n Second rib 65 Bearing (other bearings)
66 Bearing L2 Virtual Line S Space

Claims (5)

An electric motor for driving left and right wheels of the vehicle;
A transmission disposed on a power transmission path between the motor and the left and right wheels;
A differential gear for distributing an output shifted by the transmission to the left wheel and the right wheel;
A housing for accommodating the motor, the transmission, and the differential device;
A reservoir provided at the bottom of the housing for storing a liquid medium;
A counter holder rotatably supporting the counter gear ;
A power unit, wherein a flange portion of a differential case of the differential device is located in the storage portion,
The differential case is provided with a plurality of ribs for scraping the liquid medium in the flange portion,
Ribs and the plurality of, possess a first guide surface that is recessed to one side in the rotational direction with a second guide surface that is recessed in the direction of rotation the other side, a
One end of the differential case is rotatably supported on a bearing support of the housing via a bearing,
The other end of the differential case is rotatably supported by the counter holder via another bearing,
The plurality of ribs scatter the liquid medium toward the bearing support portion,
The counter holder has a storage space for storing the liquid medium scraped up by the rotating body,
A power unit, wherein the liquid medium is supplied to the other bearing through the storage space . The power plant according to claim 1, wherein
The plurality of ribs includes a bidirectional rib in which both the first guide surface and the second guide surface are formed. The power plant according to claim 1, wherein
The plurality of ribs have a first rib in which the first guide surface is formed, and a second rib in which the second guide surface is formed,
The power device, wherein the plurality of first ribs and the plurality of second ribs are arranged symmetrically with respect to an imaginary line passing through an axial center of the differential device. The power plant according to any one of claims 1 to 3 , wherein
An inner surface of the housing is provided with an oil passage for guiding the liquid medium toward the bearing. The power plant according to claim 4 , wherein
The power passage is a step provided on the inner surface of the housing.

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