JP3701014B2 - Vehicle drive device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a drive device for a vehicle such as an electric vehicle that drives a drive wheel using an electric mechanism as a drive source, or a hybrid vehicle of an electric mechanism and an internal combustion engine.
[0002]
[Prior art]
Conventionally, as a driving device for a vehicle such as an electric vehicle or a hybrid vehicle of an electric mechanism and an internal combustion engine, for example, disclosed in Japanese Patent Laid-Open No. 10-75506, and the output of the electric mechanism 110 is a reduction mechanism as shown in FIG. 111 is decelerated at a constant ratio and transmitted to the differential mechanism 112. Further, differential distribution is performed by the differential mechanism 112 and transmitted to the left and right drive wheels 114 via each drive shaft 113. The output of the electric mechanism 110 is controlled according to the operation amount of the accelerator pedal 115 in the driver's seat in the normal control. That is, the operation amount of the accelerator pedal 115 is detected by the control unit 116, and the control unit 116 supplies electric power corresponding to the operation amount to the electric mechanism 110 to control the output of the electric mechanism 110. During turning, the differential mechanism 112 absorbs the difference in rotational speed between the left and right drive wheels 114, thereby enabling smooth turning.
[0003]
However, the speed reduction mechanism 111 and the differential mechanism 112 are arranged in series in the axial direction with respect to the electric mechanism 110, and the axial dimension of the drive device is increased. For this reason, the drive shaft 113 is shortened, and the operating angle of the drive shaft 113 is increased to affect the steering stability, or the interference with the chassis frame and the arrangement space of the suspension device are limited, thereby causing various effects on the vehicle. There is concern that it will be a factor.
[0004]
As a countermeasure against this, for example, a driving device disclosed in Japanese Patent Laid-Open No. 7-156673 and shown in FIG. 5 has been proposed. In this drive device, a cylindrical stator 123 is disposed in a housing 121, and a rotor 126 is provided on the outer periphery of a hollow output shaft 125 that is rotatably supported by a bearing 124 interposed in the housing 121. Configure. On the other hand, a differential case 131, a pair of pinion gears 132, a pair of side gears 133 respectively connected to the left and right output shafts 128, and a pinion shaft 134 that rotatably supports the differential case 131 in the output shaft 125 via a bearing 127. Bevel gear type differential mechanism 130 constituted by the like, a sun gear 136 spline-fitted to a sun gear support 121a of a housing 121 formed in a cylindrical shape so as to surround the output shaft 128, and an inner periphery of the output shaft 125 An internal gear 137 provided and a planetary gear unit having a pinion 139 rotatably supported by a planetary carrier 138 fixed to the differential case 131 and meshing with the sun gear 136 and the internal gear 137. Placing the reduction gear mechanism 135.
[0005]
When the electric mechanism 122 is operated, the output shaft 125 attached to the rotor 126 is rotationally driven. The rotation of the output shaft 125 is transmitted to the internal gear 137 of the reduction mechanism 135, and the rotation reduced according to the gear specifications of the planetary gear unit rotates the differential case 131 of the differential mechanism 130 from the planetary carrier 138. The reduction ratio at this time is represented by the following formula: Re = (S + I) / I where Re is the reduction ratio, S is the number of teeth of the sun gear 136, and I is the number of teeth of the internal gear 137.
become that way.
[0006]
The output decelerated by the speed reduction mechanism 135 is output to the differential case 131 of the differential mechanism 130, and is differentially distributed to the left and right output shafts 128 by the differential mechanism 130, and the left and right outputs from each output shaft 128 via the drive shaft. It is transmitted to the drive wheel.
[0007]
[Problems to be solved by the invention]
According to the driving device disclosed in the above-mentioned JP-A-7-156673, the differential mechanism 130 and the speed reduction mechanism 135 are built in the output shaft 125 of the electric mechanism 122 formed in a hollow shape. A reduction in the axial direction A is obtained, and the operating angle of the drive shaft can be reduced when mounted on a vehicle, which has an effect on steering stability, interference with the chassis frame, etc., and restrictions on the layout space of the suspension device, etc. It is alleviated to some extent.
[0008]
However, since the sun gear 136 of the speed reduction mechanism 135 is spline-fitted to the sun gear support 121a of the housing 121 formed in a cylindrical shape so as to surround the output shaft 128, restrictions on the diameter dimensions of the output shaft 128 and the sun gear support 121a. As a result, the diameter reduction is restricted and the reduction of the number of teeth is restricted. On the other hand, the internal gear 137 is constrained by the inner diameter of the output shaft 125, so that the increase in diameter is constrained and the number of teeth is limited. As a result, it is difficult to ensure a sufficient reduction ratio by the reduction mechanism 135.
[0009]
For this reason, in order to ensure the driving force required from the vehicle specifications, the electric mechanism 122 having a large output is required, and the electric mechanism 122 must be enlarged. With the increase in size of the electric mechanism 122, there is a concern that the outer dimension of the housing 121 increases and the arrangement space in the radial direction B increases, which affects the on-vehicle performance of the drive device. Further, with the increase in size of the electric mechanism 122, the cost of a control element such as an inverter may increase, leading to an increase in manufacturing cost.
[0010]
On the other hand, in order to increase the number of teeth of the internal gear 137 in order to ensure the reduction ratio, a large internal gear 137 is required, and the output shaft 125 that accommodates the internal gear 137 has a large diameter. As the diameter of the output shaft 125 increases, the rotor 126 becomes larger in diameter, and there is a concern that the outer dimensions of the housing 121 increase and the arrangement space in the radial direction B increases, which affects the on-vehicle performance.
[0011]
Accordingly, an object of the present invention made in view of such a point is to provide a vehicle drive device that has a sufficient driving force and is compact and excellent in in-vehicle performance with reduced axial and radial outer dimensions. It is in.
[0012]
[Means for Solving the Problems]
The invention of the vehicle drive device according to claim 1 includes an electric mechanism housed in a housing, a reduction mechanism that decelerates the output of the electric mechanism, and a differential mechanism that differentially distributes the reduced output. And a pair of output shafts that transmit the differentially distributed output to the left and right drive wheels, respectively, on the same axis, the housing includes an electric mechanism housing the housing in the axial direction. And a partition wall portion having a shaft hole formed therein, and the electric mechanism is housed in the electric mechanism housing portion and fixed to the inner periphery of the housing; A cylindrical output shaft that is disposed in a rotor disposed in the stator and is rotatably supported by the partition wall with one end interposed between the shaft hole and a bearing. Housed in the output shaft Disposed Te, the speed reduction mechanism is outside of the output shaft at the output shaft coaxially arranged on the speed reduction mechanism accommodating portion, a sun gear which output from one end of the output shaft is input, around the said housing A planetary gear unit comprising: a stopped internal gear; a planetary carrier that rotatably supports a pinion that meshes with the sun gear and the internal gear and that transmits an output to the differential mechanism; and the output shaft. The output from one end side of the motor is decelerated and transmitted to the differential device, and the partition wall portion of the housing is in contact with the side surface of the internal gear that is prevented from rotating around the housing to hold the internal gear. The gear holding portion is integrally formed .
[0013]
According to the invention of claim 1, the differential mechanism is accommodated in the output shaft of the electric mechanism accommodated in the electric mechanism accommodating portion in the housing partitioned by the partition wall portion, and the axial shortening of the drive device is obtained. In addition, since the speed reduction mechanism is accommodated in the speed reduction mechanism accommodating portion outside the output shaft, the speed reduction mechanism can be set without being restricted by the output shaft, and a large reduction ratio can be ensured. As a result, the rotor of the electric mechanism can be driven to rotate at high speed, the output torque of the electric mechanism can be improved, the electric mechanism can be reduced in size, and the radial reduction of the drive device can be obtained. This improves the in-vehicle performance.
[0014]
Further, one end of the output shaft on the output side of the output shaft to the speed reduction mechanism is supported in a stable and freely rotatable manner via the bearing, so that the output can be satisfactorily transmitted from the output shaft to the speed reduction mechanism. This bearing can use a relatively small-diameter bearing, and the sliding resistance of the portion is suppressed, so that smoother operation of the drive device can be ensured.
[0015]
Furthermore, optimization can be easily ensured without oil lubrication in the electric mechanism housing portion and the speed reduction mechanism housing portion interfering with each other. In particular, sufficient storage of lubricating oil can be ensured in the speed reduction mechanism accommodating portion, and heat generated at each sliding portion of the speed reduction mechanism is suppressed by the stored lubricating oil, and damage to the speed reduction mechanism is avoided and durability is improved. improves.
[0017]
In addition, since the speed reduction mechanism is constituted by a planetary gear unit, an increase in the axial direction of the drive device due to the arrangement of the speed reduction mechanism can be suppressed as much as possible, a large-diameter internal gear can be used, and a sun gear from the output shaft can be used. Is input to the planetary carrier and output from the planetary carrier to the differential mechanism, thereby ensuring a large reduction ratio according to the gear specifications of the planetary gear unit.
[0021]
In addition, the internal gear that is prevented from rotating around the housing by the contact of the internal gear holding part integrally formed with the partition wall is prevented from coming off, and the snap ring for preventing the internal gear from being removed is abolished. The number of parts can be reduced and the assembling work can be simplified.
[0022]
According to a second aspect of the present invention, in the vehicle drive device according to the first aspect, the partition wall is integrally formed with a position sensor mounting portion.
[0023]
According to the invention of claim 2 , by integrally forming the position sensor mounting portion on the partition wall, the position sensor can be directly fixed to the partition wall, the effective use of the space in the housing can be obtained, and the assembly workability can be obtained. In addition, it is not necessary to provide a dedicated means for attaching the position sensor , thereby simplifying the structure.
[0024]
According to a third aspect of the present invention, in the vehicle drive device according to the first or second aspect, the differential mechanism is rotatably supported at the outer periphery with a bearing interposed on the inner periphery of the output shaft. A hollow case that is formed with axially extending portions that respectively support the output shafts at both ends, and that outputs from the speed reduction mechanism, and is housed in the differential case via a pinion shaft. A pair of pinion gears rotatably supported by the differential case, and a pair of side gears coupled to the inner ends of the output shafts and meshing with the pinion gears, and located on the other end side of the output shaft. The axially extending portion of the differential case is rotatably supported by the housing via a bearing.
[0025]
According to a third aspect of the present invention, the differential mechanism is a bevel gear type differential mechanism, and a bearing is interposed between the outer periphery of the differential case of the differential mechanism and the inner periphery of the output shaft to hold the differential mechanism rotatably. The relative position between the output shaft and the differential case is reliably maintained, and the power transmission from the output shaft to the differential case via the speed reduction mechanism is performed stably, and the axial extension portion of the differential case via the bearing in the housing Since the bearing is supported in a rotatable manner, the bearing supporting the housing can have a small diameter. As the diameter of the bearing decreases, the weight can be reduced and the sliding resistance of the bearing can be reduced, and the required output for the electric mechanism can be reduced. . As a result, the electric mechanism can be miniaturized, the drive device can be reduced in the radial direction, and the in-vehicle performance is improved.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of a vehicle drive device according to the present invention will be described with reference to the drawings.
[0027]
(First embodiment)
FIG. 1 is a cross-sectional view showing an outline of a drive device 1 according to the present embodiment, and FIG. 2 is an enlarged view of a main part of FIG.
[0028]
The drive device 1 includes a hollow housing 10, an electric mechanism 20 accommodated in the housing 10, a differential mechanism 30 disposed coaxially and coaxially within the electric mechanism 20, and a differential mechanism 30. A speed reduction mechanism 40 that is coaxially disposed adjacent to and decelerates the power from the electric mechanism 20 and transmits it to the differential mechanism 30; and output shafts 51 and 52 that are disposed coaxially and extend in the axial direction. Have.
[0029]
The housing 10 is formed in a hollow shape by a housing body 11, a housing cover 12, and a speed reduction mechanism cover 13.
[0030]
The housing body 11 has a cylindrical portion 11A and a partition wall portion 11B whose outer periphery is integrally formed continuously at one end of the cylindrical portion 11A. The partition wall portion 11B forms an interior of the housing 10 into an electric mechanism housing portion 10A and a speed reduction mechanism housing portion 10B. It is partitioned. A shaft hole 11a is opened at the center of the partition wall portion 11B. The partition wall portion 11B protrudes toward the speed reduction mechanism housing portion 10B and the tip abuts against a side surface of an internal gear 43 of the speed reduction mechanism 40 described later. An internal gear holding portion 11C for holding the position sensor and a position sensor attaching portion 11D for attaching a position sensor 27 described later are integrally formed.
[0031]
The housing cover 12 has an outer periphery coupled to the opening end formed in the cylindrical portion 11A of the housing body 11 by a bolt 15 to form an electric mechanism housing portion 10A facing the partition wall portion 11B, and a shaft hole 12a in the central portion. And a stator attachment portion 12A is formed in the vicinity of the inner peripheral edge.
[0032]
The speed reducer cover 13 has a cylindrical portion 13A whose outer periphery is coupled to the outer periphery on the partition wall 11B side of the housing body 11 by a bolt 14 and a side wall portion 13B whose outer periphery is integrally formed with the cylindrical portion 13A. The speed reduction mechanism accommodating portion 10B is formed between the partition wall portion 11B and the side wall portion 13B, and a shaft hole 13a is formed in the central portion of the side wall portion 13B. Further, the internal gear 43 of the planetary gear unit 41 Spline grooves 13b whose outer periphery is spline-fitted are formed concentrically.
[0033]
The electric mechanism 20 includes a stator 22 positioned along the inner periphery of the cylindrical portion 11A of the housing main body 11 and fixed to the stator mounting portion 12A of the housing cover 12 by bolts 21, and a cylindrical shape disposed in the stator 22. It is formed as a synchronous motor having a rotor 23 and a cylindrical output shaft 24 coupled to the inner periphery of the rotor 23. The output shaft 24 is formed with a small diameter portion at one end, and this portion is rotatably supported by the shaft hole 11a of the partition wall portion 11B via a relatively small diameter bearing 25, and a differential case of the differential mechanism 30 described later. It is rotatably held at both ends of the outer periphery of 31 via bearings 28 and 29. A magnet 26 is disposed on the outer periphery of one end of the output shaft 24, and the magnetic pole position of the rotor 23 is detected by detecting the position of the magnet 26 by the position sensor 27 provided in the position sensor mounting portion 11 </ b> D of the housing body 11. Thus, high efficiency operation is performed by performing vector control. A sun gear 42 of the speed reduction mechanism 40 is integrally formed at one end of the output shaft 24.
[0034]
The differential mechanism 30 is a bevel gear type, and is a hollow and axially extending differential case in which each outer peripheral end is rotatably supported via bearings 28 and 29 on each inner peripheral portion of the output shaft 24. 31, a pair of pinion gears 32 and 33 and a pair of side gears 34 and 35 accommodated in the differential case 31, and the pinion gears 32 and 33 are rotatably supported by the differential case 31 by a pinion shaft 36.
[0035]
The side gear 34 is spline-fitted to the inner end 51 a of the output shaft 51 rotatably supported by the axially extending portion 31 </ b> A of the differential case 31 and meshed with the pinion gears 32 and 33. On the other hand, the side gear 35 is similarly spline-fitted to the inner end 52a of the output shaft 52 rotatably supported by the axially extending portion 31B of the differential case 31, and is arranged to mesh with the pinion gears 32 and 33. ing. Further, a spline groove 31a is formed on the outer periphery of one axially extending portion 31B of the differential case 31, and the other axially extending portion 31A is rotatable through the bearing 37 to the shaft hole 12a of the housing cover 12. It is supported.
[0036]
With this configuration, the end portions of the differential case 31 and the output shaft 24 are rotatably held with respect to each other via the bearings 28 and 29, and one end of the output shaft 24 is supported by the partition wall portion of the housing body 11 via the bearing 25. An axially extending portion 31A of the differential case 31 that is rotatably supported by 11B and is located on the other end side of the output shaft 24 is rotatably supported by the shaft hole 12a of the housing cover 12 via a bearing 37, and outputs The shaft 24 and the differential case 31 are coaxially supported by the housing 10 so as to be rotatable relative to each other.
[0037]
The speed reduction mechanism 40 includes a planetary gear unit 41 that has a relatively small dimension in the axial direction A and can provide a large speed reduction ratio. The speed reduction mechanism 40 is coaxial with the electric mechanism 20 and the differential mechanism 30 and outside the end of the output shaft 24. It arrange | positions in the accommodating part 10B.
[0038]
The planetary gear unit 41 is cylindrical from the inner periphery of the disc-shaped flange 42A whose outer periphery is continuously formed at the end of the output shaft 24 and protrudes outward in the axial direction along the outer periphery of the axially extending portion 31B of the differential case 31. By the contact between the sun gear 42 having the cylindrical portion 42 </ b> B and the spline groove 13 b formed in the speed reduction mechanism cover 13 so as to be prevented from rotating by being spline-fitted and protruding from the housing body 11. An internal gear 43 that is secured to be removed, a plurality of pinions 44 that mesh with the sun gear 42 and the internal gear 43, and a planetary carrier 46 that rotatably supports the pinion 44 via a needle bearing 45. ing. The planetary carrier 46 has a pinion shaft 47 that rotatably supports the pinion 44 via a needle bearing 45, and a spline fit in a spline groove 31a that is coupled to the pinion shaft 47 and formed on the outer periphery of the axially extending portion 31B. A mating carrier plate 48 is provided.
[0039]
The pinion shaft 47 is formed with an oil hole 47a having one end opened on its axial end surface and extending in the axial direction, and the other end opened on the outer peripheral surface with which the needle bearing 45 is slidably contacted, and the oil hole 47a is opened. A lubricating cover 49 is provided to cover the shaft end surface of the pinion shaft 47 with a gap.
[0040]
Therefore, the electric mechanism 20 accommodated in the housing 10, the speed reduction mechanism 40 including the planetary gear unit 41 that reduces the output of the electric mechanism 20, and the bevel gear type differential that differentially distributes the output reduced by the speed reduction mechanism 40. The mechanism 30 and a pair of output shafts 51 and 52 for transmitting the output differentially distributed by the differential mechanism 30 to the left and right drive wheels, respectively, are coaxially arranged, and the electric mechanism 20 and the differential mechanism 30 are coaxially arranged. The speed reduction mechanism 40 is disposed at the position and across the partition wall 11B.
[0041]
Then, the rotation of the output shaft 24 is transmitted to the sun gear 42 of the speed reduction mechanism 40, is decelerated according to the gear specifications of the planetary gear unit 41, is output to the planetary carrier 46, and rotates the differential case 31 that is splined to the planetary carrier 46. . The reduction ratio at this time is represented by the following equation: Re = (S + I) / S where Re is the reduction ratio, S is the number of teeth of the sun gear 42, and I is the number of teeth of the internal gear 43.
become that way.
[0042]
Here, the outer diameter of the internal gear 43 can be formed large without being influenced by the output shaft 24, the number of teeth of the internal gear 43 can be increased, and the internal gear 43 of the planetary gear unit 41 can be increased. It is possible to secure a very large reduction ratio in combination with being fixed to the housing 10 and inputting the rotation of the output shaft 24 to the sun gear 42 and outputting it from the planetary carrier 46 to the differential case 31.
[0043]
In the output shafts 51 and 52, the inner ends 51a and 52a protruding into the differential case 31 are spline-fitted to the side gears 34 and 35, and the outer ends 51b and 52b are respectively connected to the left and right drive wheels via joints. It is connected to a drive shaft that transmits power. In addition, an oil seal 53 is disposed between the shaft hole 12a of the housing cover 12 and the output shaft 51, and an oil seal 54 is disposed between the shaft hole 13a of the reduction mechanism cover 13 and the output shaft 52 so as to prevent dust and dirt. Prevents ingress of water droplets.
[0044]
Next, the operation of the drive device 1 configured as described above will be described.
[0045]
When the electric mechanism 20 is operated, the output shaft 24 to which the rotor 23 is attached is rotationally driven. The rotation of the output shaft 24 is transmitted to the sun gear 42 of the speed reduction mechanism 40, decelerated according to the gear specifications of the planetary gear unit 41, output to the planetary carrier 46, and the differential case 31 in which the carrier plate 48 of the planetary carrier 46 is spline-fitted. It is rotationally driven and transmitted to the differential mechanism 30, and further distributed and transmitted to the output shafts 51 and 52 by the differential mechanism 30.
[0046]
As a result, the electric mechanism 20 is decelerated by the reduction mechanism 40 and the left and right drive wheels are rotationally driven by the operation mechanism 30 and the output shafts 51 and 52 via the joint and the drive shaft. Further, the differential mechanism 30 absorbs the difference in the rotational speed between the left and right drive wheels during turning, and enables smooth turning.
[0047]
Therefore, according to the drive device 1 configured as described above, the differential mechanism 30 is built in the electric mechanism 20 and is disposed at a coaxial position, so that the axial direction A of the drive device 1 can be shortened. Further, the speed reduction mechanism 40 is interposed between the electric mechanism 20 and the differential mechanism 30, and the speed reduction mechanism 40 is disposed outside the end of the output shaft 24 of the electric mechanism 20 with the partition wall 11 </ b> B interposed therebetween. The internal gear 43 that determines the reduction ratio can be formed with a large diameter without being limited by the diameter of the output shaft 24. As the internal gear 43 has a large diameter, the number of teeth of the internal gear 43 can be effectively increased.
[0048]
Further, the internal gear 43 of the planetary gear unit 41 is fixed, the sun gear 42 is rotated by the input shaft 24, and the differential case 31 that is spline-fitted by the planetary carrier 46 is rotationally driven. Compared with the case where 43 is rotationally driven and the differential case 31 is rotationally driven by the planetary carrier 46, a very large reduction ratio can be ensured in combination with the fact that a large reduction ratio can be obtained. As a result, the electric mechanism 20 can be rotationally driven at a high speed, and an increase in the output torque of the electric mechanism 20 can be achieved efficiently. In other words, since the output torque of the electric mechanism 20 can be increased, the electric mechanism 20 having a relatively small output can be used. As a result, the radial direction B of the drive device 1 can be reduced and the arrangement can be made compact. Space can be significantly reduced, and weight reduction can be achieved, improving onboard performance.
[0049]
Further, since the inside of the housing 10 is partitioned into the electric mechanism housing portion 10A and the speed reduction mechanism housing portion 10B by the partition wall portion 11B, and the electric mechanism 20 and the speed reduction mechanism 40 are respectively disposed, the inside of the electric mechanism housing portion 10A and the speed reduction mechanism. Each optimization can be easily ensured without interfering with the oil lubrication in the accommodating portion 10B. In particular, the lubricating oil can be sufficiently stored and secured in the speed reduction mechanism accommodating portion 10B, and the retained lubricating oil can sufficiently ensure the lubrication of the meshing portions of the internal gear 43 of the planetary gear unit 41 and each pinion 44, and Lubricating oil scattered by the centrifugal force of the sun gear 42 and the pinion 44 is received by the lubricating cover 49 and guided to the oil hole 47a that opens in the shaft end surface of the pinion shaft 47, and the pinion shaft 47 and the needle bearing 45 through the oil hole 47a. Is supplied to the sliding contact surface of the pinion shaft 47, and the needle bearing 45 interposed between the outer peripheral surface of the pinion shaft 47 and the inner peripheral surface of the pinion 44 is lubricated to suppress heat generation at each sliding portion of the planetary gear unit 41, and the planetary gear unit. Durability is improved by avoiding damage to 41 and the like.
[0050]
Furthermore, a shaft hole 11a is formed in the partition wall 11B, and an end of the output shaft 24 on the side where the sun gear 42 of the output shaft 24 is connected to the shaft hole 11a via a bearing 25 is rotatably supported. The end portion is stably supported, and the output can be transmitted to the planetary gear unit 41 through the sun gear 42. In addition, the degree of freedom of setting the bearing 25 can be secured, and the bearing 25 can be supported by a relatively small diameter bearing 25. The sliding resistance of the portion is suppressed as the diameter of the bearing 25 is reduced, so that the smoother drive device 1 can be provided. Operation can be secured.
[0051]
Further, since the internal gear 43 that is spun-fitted to the speed reduction mechanism cover 13 by the abutment of the internal gear holding portion 11C formed integrally with the partition wall portion 11B is prevented from coming off, the internal gear 43 is prevented from coming off. The snap ring for preventing the removal is eliminated, the number of parts can be reduced, and the assembling work is simplified.
[0052]
Further, by integrally forming the position sensor mounting portion 11D on the partition wall portion 11B, the position sensor 27 can be fixed, the space in the housing can be effectively used, the assembly workability is improved, and a dedicated position sensor is provided. Simplification of the structure can be ensured because it is not necessary to provide mounting means for mounting.
[0053]
(Second Embodiment)
FIG. 3 is a cross-sectional view showing an outline of the driving apparatus 2 according to the present embodiment. 1 and 2 are denoted by the same reference numerals, detailed description thereof will be omitted, and different portions will be mainly described. The present embodiment is characterized in that a speed reduction mechanism 60 capable of securing a larger speed reduction ratio is provided in place of the speed reduction mechanism 40 of the first embodiment.
[0054]
The speed reduction mechanism 60 is a cylindrical sun gear 62 that extends along the axially extending portion 31 </ b> B of the differential case 31 by being fitted with a spline formed on the inner peripheral end portion of the output shaft 24 and fixed by a snap ring 91. And an internal gear 63 fixed by a snap ring 92, the outer periphery of which is spline-fitted to the spline groove 13b formed on the inner peripheral surface of the cylindrical portion 13A of the speed reducer cover 13, and the shaft of the differential case 31 A carrier plate 66 is spline-fitted into a spline groove 31a formed on the outer periphery of the end portion of the direction extending portion 31B, and a planetary carrier 64 fixed by a snap ring 93 and a plurality of pinion shafts 65 of the planetary carrier 64 are respectively needled. A planetary gear having a stepped pinion 68 rotatably supported via a bearing 67 Constituted by a knit 61. In each stepped pinion 68, a large-diameter pinion 69 meshing with the sun gear 62 and a small-diameter pinion 70 meshing with the internal gear 63 are integrally formed in the axial direction. Therefore, when the sun gear 62 is rotationally driven by the output shaft 24, the planetary carrier 64 is rotated at a reduction ratio according to the gear specifications of the planetary gear unit 61 using the internal gear 63 as a reaction force element, and the differential case 31 is rotationally driven. A thrust washer 71 is interposed between the sun gear 62 and the carrier plate 66.
[0055]
Next, the operation of the drive device 2 configured as described above will be described.
[0056]
When the electric mechanism 20 is operated, the output shaft 24 to which the rotor 23 is attached is rotationally driven, and the rotation of the output shaft 24 is transmitted to the sun gear 62 of the speed reduction mechanism 60, and is decelerated according to the gear specifications of the planetary gear unit 61. The differential case 31 output to the carrier 64 and spline-fitted to the carrier plate 66 of the planetary carrier 64 is rotationally driven and transmitted to the differential mechanism 30, and further distributed and transmitted to the output shafts 51 and 52 by the differential mechanism 30. The
[0057]
As a result, the electric mechanism 20 is decelerated by the reduction mechanism 60 and the right and left drive wheels are rotated by the differential mechanism 30 and the output shafts 51 and 52 via the joint and the drive shaft. Further, the differential mechanism 30 absorbs the difference in the rotational speed between the left and right drive wheels during turning, and enables smooth turning.
[0058]
Therefore, according to the drive device 60 configured as described above, the differential mechanism 30 is built in the electric mechanism 20 and arranged at the coaxial position as in the first embodiment, and the axial direction A of the drive device 1 is set. In addition, a large-diameter pinion 69 that meshes with the sun gear 62 and a small-diameter pinion 70 that meshes with the internal gear 62 are integrally formed in the axial direction as a pinion of the planetary gear unit 61 that constitutes the speed reduction mechanism 60. The stepped pinion 68 is used, and the large-diameter pinion 69 and the internal gear 63 of the stepped pinion 68 can be increased in diameter without being affected by the output shaft 24. Although the dimension in the axial direction A slightly increases with respect to the speed reduction mechanism 40, a larger speed reduction ratio can be ensured for the speed reducer 40.
[0059]
As a result, the electric mechanism 20 can be rotationally driven at a higher speed, and an increase in the output torque of the electric mechanism 20 can be achieved more efficiently. In other words, since the output torque of the electric mechanism 20 can be increased, the electric mechanism 20 having a smaller output can be used. As a result, the radial direction B of the drive device 1 can be reduced, and the arrangement space can be reduced. Can be drastically reduced, and the weight reduction can be obtained, so that the in-vehicle performance is greatly improved.
[0060]
In addition, by forming the output shaft 24 and the sun gear 62 independently of each other in this way, the output shaft 24 and the sun gear 62 are integrally formed, so that the simplification of the shape is obtained and the processing becomes easy. The heat treatment of the sun gear 42 is facilitated, productivity can be improved, and a reduction in manufacturing cost can be expected.
[0061]
The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the invention. For example, in the first embodiment, the output shaft 24 of the electric mechanism 20 and the sun gear 42 of the speed reduction mechanism 40 are integrally formed. However, as in the second embodiment, the output shaft 24 and the sun gear 42 can be coupled separately. Thus, simplification of each shape can be obtained to facilitate the processing, and heat treatment of the sun gear 42 can be facilitated to improve the productivity and to reduce the manufacturing cost.
[0062]
【The invention's effect】
According to the driving apparatus for the vehicle according to the present invention described above, the electric mechanism housed in the housing, the reduction mechanism for reducing the output of the electric mechanism, the differential mechanism for differentially distributing the reduced output, and the differential In a vehicle drive device in which a pair of output shafts that respectively transmit the distributed output to the left and right drive wheels are coaxially arranged, the inside of the housing is partitioned into an electric mechanism housing portion and a speed reduction mechanism housing portion by a partition wall, Since the differential mechanism is accommodated in the output shaft of the electric mechanism to shorten the axial direction of the drive device, and the speed reduction mechanism is accommodated in the speed reduction mechanism accommodating portion outside the output shaft, the output shaft is restricted. A reduction mechanism can be set without any problem, and a large reduction ratio can be secured. As a result, the rotor of the electric mechanism can be rotationally driven at high speed. In other words, the electric mechanism can be miniaturized, and the drive device can be reduced in the radial direction, thereby improving the onboard performance.
[0063]
In addition, one end on the output side of the output shaft to the speed reduction mechanism is supported by the partition wall through a bearing so as to be stably rotatable, and the oil lubrication of the electric mechanism and the speed reduction mechanism is optimized without interfering with each other. Can be secured easily. Therefore, heat generation at each sliding portion of the speed reduction mechanism due to the lubricant is suppressed, and damage to the speed reduction mechanism is avoided and durability is improved.
[0064]
In addition, by configuring the speed reduction mechanism with a planetary gear unit, an increase in the axial direction of the drive device due to the arrangement of the speed reduction mechanism can be suppressed as much as possible, a large-diameter internal gear can be used, and a sun gear from the output shaft can be used. Is input to the planetary carrier and output from the planetary carrier to the differential mechanism, a large reduction ratio according to the gear specifications of the planetary gear unit can be secured, and the output improvement by the high-speed rotation drive of the electric mechanism can be efficiently achieved.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an outline of a first embodiment of a vehicle drive apparatus according to the present invention;
2 is an enlarged view of the main part of FIG.
FIG. 3 is a cross-sectional view showing an outline of a second embodiment of a vehicle drive apparatus according to the present invention;
FIG. 4 is a schematic explanatory diagram of a conventional vehicle drive device.
FIG. 5 is a cross-sectional view schematically showing a conventional drive device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Drive apparatus 2 Drive apparatus 10 Housing 11 Housing main body 11A Cylindrical part 11B Bulkhead part 11C Internal gear holding part 11D Position sensor attaching part 11a Shaft hole 12 Housing cover 12A Stator attaching part 13 Reducer cover 13a Shaft hole 13b Spline groove 20 Electric Mechanism 22 Stator 23 Rotor 24 Output shaft 24a Spline groove 25 Bearing 28, 29 Bearing 30 Differential mechanism 31 Differential case 31A, 31B Axial extending portion 31a Spline groove 32, 33 Pinion gear 34, 35 Side gear 36 Pinion shaft 40 Reduction mechanism 41 Planetary gear Unit 42 Sun gear 43 Internal gear 44 Pinion 45 Needle bearing 46 Planetary carrier 47 Pinion shaft 48 Carrier plates 51 and 52 Output shaft DOO 60 reduction mechanism 61 planetary gear unit 62 the sun gear 63 the internal gear 64 planetary carrier 65 the pinion shaft 68 Step pinion 69 diameter pinion 70 small pinion

Claims (3)

An electric mechanism housed in the housing, a speed reduction mechanism that decelerates the output of the electric mechanism, a differential mechanism that differentially distributes the decelerated output, and the differentially distributed output to the left and right drive wheels In a vehicle drive device in which a pair of output shafts for transmission are arranged coaxially,
The housing is
Partitioning the inside of the housing in an axial direction into an electric mechanism housing portion and a speed reduction mechanism housing portion and having a partition wall with a shaft hole bored;
The electric mechanism is
A stator housed in the electric mechanism housing portion and fixed to the inner periphery of the housing;
A cylindrical output shaft disposed in the rotor disposed in the stator and having one end rotatably supported by the partition wall with a bearing interposed between the shaft hole,
The differential mechanism is
Housed in the output shaft,
The deceleration mechanism is
A sun gear disposed coaxially with the output shaft and outside the output shaft in the speed reduction mechanism housing portion, to which an output from one end side of the output shaft is input, an internal gear that is prevented from rotating by the housing, and A planetary gear unit that includes a planetary carrier that rotatably supports a pinion that meshes with a sun gear and an internal gear, and that transmits an output to the differential mechanism, and decelerates an output from one end of the output shaft. To the above differential device ,
The partition of the housing is
A drive device for a vehicle, wherein an internal gear holding portion for holding the internal gear is formed integrally with a side surface of the internal gear that is prevented from rotating by the housing . The partition is
The vehicle drive device according to claim 1, wherein the position sensor mounting portion is integrally formed . The differential mechanism is
The output shaft is hollow and the outer periphery is rotatably supported with a bearing interposed therebetween, and axially extending portions that respectively support the respective output shafts are formed at both ends, and from the speed reduction mechanism. A differential case to which the output is transmitted,
A pair of pinion gears housed in the differential case and rotatably supported by the differential case via a pinion shaft;
A pair of side gears coupled to the inner ends of the output shafts and meshing with the pinion gears;
3. The vehicle according to claim 1, wherein an axially extending portion of the differential case located on the other end side of the output shaft is rotatably supported by the housing via a bearing . Drive device.

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