JP2019120313A - Drive unit for vehicle - Google Patents

Abstract

A first transmission member and a second transmission member coaxially disposed on both sides of a wall portion of a case in the axial direction are provided with a helical gear and the wall portion via a bearing. Thus, the vehicle drive device can be realized that can be downsized as a whole when it is directly supported.
SOLUTION: The twisting direction of the teeth of the first helical gear 21a provided in the first transmission member 21 and the twisting direction of the teeth of the second helical gear 22a provided in the second transmission member 22 are opposite to each other. is there.
[Selected figure] Figure 5

Description

  The present invention relates to a drive system for a vehicle.

  A first drive source, a second drive source rotatable independently of the first drive source, a first connection portion drivingly connected to the first wheel, and a second connection portion driveably connected to the second wheel A vehicle for transmitting the torque of the first drive source to at least the first connection portion and transmitting the torque of the second drive source to the at least second connection portion; and a case for containing the transmission device Drives are known. An example of a vehicle drive device having such a configuration is disclosed in JP-A-2017-141889 (Patent Document 1). Hereinafter, reference numerals in parentheses in the description of the background art are those of Patent Document 1.

  As shown in FIGS. 1 and 7 of Patent Document 1, the vehicle drive device (1) of Patent Document 1 is drivingly connected to two electric motors (2L, 2R) and left and right drive wheels (61L, 61R). Gear unit (30) configured by using two output gear shafts (14L, 14R) and two planetary gear mechanisms (30L, 30R), and a reduction gear housing (9) that accommodates the gear unit (30) ) And. This gear device (30) has an input gear (13a) meshing with an input gear (12a) to which power is transmitted from the electric motor (2L, 2R), and an output gear (14L, 14R). And an output-side small-diameter gear (13b) meshing with 14a). Then, the gear device (30) is configured as described in paragraph 0110 of Patent Document 1 to transmit the torque input to the input-side external gear (13a) from the side of the electric motor (2L, 2R). When outputting from the output-side small-diameter gear (13b) to the drive wheels (61L, 61R), the torque difference between the two electric motors (2L, 2R) is amplified and distributed to the left and right drive wheels (61L, 61R) It is configured to be possible (paragraphs 0108 and 0166).

  By the way, as described in paragraph 0099 of Patent Document 1, the reduction gear housing (9) for housing the gear unit (30) is fixed to the central housing (9a) and both side surfaces of the central housing (9a). It has a three-piece structure with side housings (9bL, 9bR). Then, as described in paragraphs 0101 and 0136 of Patent Document 1, the central housing (9a) is provided with a partition wall (11), and the output gear shafts (14L, 14R) are of the central housing (9a). It is rotatably supported by the partition wall (11) and the side housings (9bL, 9bR). Therefore, when the gear unit (30) is transmitting torque, the load received by the output gear (14a) of the left output gear shaft (14L) from the output-side small diameter gear (13b) on the left of the gear unit (30) (Load due to meshing force) and load that the output gear (14a) of the right output gear shaft (14R) receives from the output small diameter gear (13a) on the right side of the gear device (30) It is transmitted to the partition wall (11) of 9). Similarly, when the gear unit (30) is transmitting torque, the input gear (12a) of the input gear shaft (12L) on the left side is received from the input-side external gear (13a) on the left side of the gear unit (30) Both the load and the load that the input gear (12a) of the right input gear shaft (12R) receives from the input side external gear (13a) of the gear unit (30) are transmitted to the partition wall (11) . That is, the first transmission member is in a state where the transmission device including the first transmission member and the second transmission member which are coaxially divided on both sides in the axial direction with respect to the wall portion of the case is transmitting torque. Both the load received by the gear provided by the other transmission member and the load received by the gear provided by the second transmission member are transmitted to the wall. Therefore, when helical gears are used as these gears, the wall direction of the gear teeth of the first transmission member and the wall direction of the gear teeth of the second transmission member are not properly set. It is necessary to increase the strength required for the vehicle, which may hinder the downsizing of the vehicle drive device. However, Patent Document 1 does not mention such a subject.

JP, 2017-141889, A

  Therefore, each of the first transmission member and the second transmission member that are coaxially divided on both sides in the axial direction with respect to the wall portion of the case includes a helical gear and the wall portion via the bearing. It is desirable to realize a vehicle drive device capable of achieving downsizing of the entire device when it is directly supported.

  The characteristic configuration of the vehicle drive device in view of the above includes a first drive source, a second drive source that can be rotated independently of the first drive source, and a first connecting portion that is drivingly connected to the first wheel. A second connection portion drivingly connected to the second wheel, and at least transmitting the torque of the first drive source to the first connection portion, and transmitting a torque of the second drive source to at least the second connection portion And a case for housing the transmission device, the transmission device being a first transmission member disposed on one side in the axial direction with respect to a wall portion of the case, and the wall portion A second transmission member coaxially arranged with the first transmission member is provided on the other side of the axial direction, and the first transmission member is provided to another transmission member of the transmission device. A first helical gear meshing with the helical gear is provided, and The second transmission member is directly supported by the wall, and the second transmission member includes a second helical gear engaged with a helical gear provided on another transmission member of the transmission device, and the second transmission member includes the bearing via a bearing. Directly supported on the wall, the point at which the twisting direction of the teeth of the first helical gear and the twisting direction of the teeth of the second helical gear are opposite.

According to the above feature configuration, the twisting direction of the teeth of the first helical gear provided in the first transmission member and the twisting direction of the teeth of the second helical gear provided in the second transmission member are opposite to each other Be done. Therefore, in a state in which the transmission device transmits torque, the direction of the thrust load received by the first helical gear and the direction of the thrust load received by the second helical gear may be opposite to each other. it can. That is, the directions of the thrust loads generated in the first transmission member and the second transmission member which are coaxially divided on both sides in the axial direction with respect to the wall portion of the case are made opposite to each other. As a result, it is possible to minimize the load that is biased to one side in the axial direction that can act on the wall. As a result, the strength required for the wall portion is reduced as compared with the case where the twisting direction of the first helical gear teeth and the twisting direction of the second helical gear teeth are in the same direction. As a result, the entire device can be miniaturized accordingly.
As described above, according to the above-described characteristic configuration, each of the first transmission member and the second transmission member that are coaxially divided on both sides in the axial direction with respect to the wall portion provided in the case is a helical gear. In the case of being directly supported by the wall portion via the bearing, the vehicle drive device capable of achieving downsizing of the entire device can be realized.

  Further features and advantages of the vehicle drive are evident from the following description of the embodiments described with reference to the drawings.

Sectional view of a vehicle drive device according to an embodiment Partially enlarged view of Figure 1 Skeleton view of a drive device for a vehicle according to an embodiment Velocity diagram of the differential gear device according to the embodiment Simplified view of the teeth of each gear according to the embodiment Skeleton view of a vehicle drive device according to another embodiment

  Embodiments of a vehicle drive system will be described with reference to the drawings. In the present embodiment, the first rotating electrical machine 11 corresponds to the “first drive source”, the second rotating electrical machine 12 corresponds to the “second drive source”, and the fifth case portion 35 “the wall portion included in the case”. The first axial side L1 corresponds to the "first side", and the second axial side L2 corresponds to the "second side". Further, in the present embodiment, the “first transmission member” is the first drive member 21, and the first drive gear 21 a included in the first drive member 21 corresponds to the “first helical gear”, and the thirteenth bearing B13 corresponds to the "first support bearing", and the fourteenth bearing B14 corresponds to the "second support bearing". Further, in the present embodiment, the “second transmission member” is the second drive member 22, and the second drive gear 22a included in the second drive member 22 corresponds to the “second helical gear”, and the fifteenth bearing B15 corresponds to the "third support bearing", and the sixteenth bearing B16 corresponds to the "fourth support bearing". And in this embodiment, "the axis in which the 1st transmission member and the 2nd transmission member are arranged" is the 1st axis A1, the 1st diameter direction K1 is "the 1st transmission member and the 2nd transmission member are arranged. Corresponds to the “radial direction based on the axis to be

  As used herein, “drive connection” means a state in which two rotating elements are connected to transmit driving force. This concept includes the state in which two rotating elements are connected to rotate integrally, and the state in which two rotating elements are connected to be able to transmit a driving force via one or more transmission members. . Such transmission members include various members (shafts, gear mechanisms, belts, chains, etc.) that transmit rotation at the same speed or at different speeds, and an engagement device that selectively transmits rotation and driving force. (A frictional engagement device, a meshing engagement device, etc.) may be included. However, when each rotary element of the differential gear device or the differential gear mechanism is referred to as “drive connection”, other rotary elements are mutually different with respect to the differential gear device or three or more rotary elements provided in the differential gear mechanism. It refers to the state of being driven and connected without intervention.

  Furthermore, in this specification, “rotary electric machine” is used as a concept including any of a motor (motor), a generator (generator), and a motor generator that fulfills both functions of the motor and the generator as required. There is. Further, in the present specification, with regard to the arrangement of two members, “overlap in a specific direction view” refers to the case where a virtual straight line parallel to the viewing direction is moved in each direction orthogonal to the virtual straight line. It means that there is a region where at least a portion of the virtual straight line intersects both of the two members. For example, “overlap in radial direction” means that a region where the virtual straight line intersects both of the two members is present in at least a partial region in the circumferential direction. In addition, the direction about each member in the following description represents the direction in the state assembled | attached to the drive device for vehicles. Moreover, the term regarding the direction, the position, etc. about each member is a concept including the state which has a difference by an error (error in the degree which can be permitted in manufacture).

  As shown in FIGS. 1 and 3, the vehicle drive device 1 includes a first connecting portion 7 drivingly connected to a first rotating electric machine 11, a second rotating electric machine 12, and a first wheel W1, and a second wheel A second connecting portion 8 drivingly connected to W2 and a transmission device 2 are provided. The first wheel W1 and the second wheel W2 are a pair of left and right wheels coaxially arranged with each other. Further, as shown in FIG. 1, the vehicle drive device 1 includes a case 3 that houses the transmission device 2. The case 3 also accommodates the first rotary electric machine 11, the second rotary electric machine 12, the first drive member 21, the second drive member 22, the first connection member 51, and the second connection member 52. Here, "to contain" means to accommodate at least a part of the contained object. For example, as shown in FIG. 1, in the present embodiment, the entire first connecting member 51 is accommodated in the case 3 (ie, disposed inside the case 3), but a part of the first connecting member 51 is Only in the case 3 can be accommodated. The vehicle drive device 1 further includes a first drive member 21 which rotates integrally with the first rotary electric machine 11, a second drive member 22 which rotates integrally with the second rotary electric machine 12, and a first connecting portion 7. And a second connecting member 52 that rotates integrally with the second connecting portion 8.

  The transmission device 2 is a device that transmits the torque of the first rotating electrical machine 11 to at least the first connecting portion 7 and transmits the torque of the second rotating electrical machine 12 to at least the second connecting portion 8. The transmission device 2 includes a first drive member 21, a second drive member 22, a first connection member 51, a second connection member 52, a first input member 71, a second input member 72, a first output member 81, and a second A plurality of transmission members (power transmission members) including the output member 82 are provided. The first wheel W1 is rotationally driven by the torque transmitted to the first connecting portion 7, and the second wheel W2 is rotationally driven by the torque transmitted to the second connecting portion 8. The vehicle on which the device 1 is mounted (the same applies hereinafter) travels.

  As shown in FIG. 3, the vehicle is provided with a first shaft member 53 that rotates integrally with the first wheel W1 and a second shaft member 54 that rotates integrally with the second wheel W2. The first connection portion 7 is a connection portion with the first shaft member 53 in the vehicle drive device 1, and the second connection portion 8 is a connection portion with the second shaft member 54 in the vehicle drive device 1. The first shaft member 53 constitutes at least a part of the drive shaft connected to the first wheel W1 (the end opposite to the first wheel W1), and the second shaft member 54 is provided to the second wheel W2 At least a part (the end opposite to the second wheel W2) of the drive shaft to be connected is configured. In the present embodiment, the first connection member 51 is disposed coaxially with the first shaft member 53, and the second connection member 52 is disposed coaxially with the second shaft member 54. When the first wheel W1 is disposed coaxially with the first shaft member 53, the first connecting member 51 is disposed coaxially with the first wheel W1, and the second wheel W2 is coaxial with the second shaft member 54. The second connection member 52 is disposed coaxially with the second wheel W2. Further, in the present embodiment, the first connection member 51 is connected to rotate integrally with the first wheel W1 via the first shaft member 53, and the second connection member 52 is connected to the second shaft member 54. The second wheel W2 is connected to rotate integrally with the second wheel W2. Specifically, the first connection member 51 includes the first connection portion 7 connected (here, spline connection) such that the first shaft member 53 rotates integrally, and the second connection member 52 The second shaft member 54 is provided with a second connection portion 8 connected (here, spline connection) such that the second shaft member 54 rotates integrally.

  Thus, in the present embodiment, the vehicle drive device 1 is provided in the vehicle so as to drive the left and right wheels. For example, when the vehicle includes a pair of left and right front wheels and a pair of left and right rear wheels, the vehicle drive device 1 is provided to drive the pair of left and right front wheels, or provided to drive the pair of left and right rear wheels be able to. In the former case, the pair of left and right front wheels is the first wheel W1 and the second wheel W2, and in the case of the latter, the pair of left and right rear wheels is the first wheel W1 and the second wheel W2. Thus, when the vehicle includes a pair of left and right front wheels and a pair of left and right rear wheels, the pair of left and right wheels that are not to be driven by the vehicle drive device 1 among the pair of left and right front wheels and the pair of left and right rear wheels is another The drive unit may be driven by a drive unit (which may be a drive unit having the same configuration as the vehicle drive unit 1).

  As shown in FIGS. 1 and 3, the first rotating electrical machine 11 and the second rotating electrical machine 12 are disposed on the first axis A1, and the first connecting member 51 and the second connecting member 52 are disposed on the first axis A1. It is disposed on a parallel second axis A2. In the present embodiment, the transmission device 2 (a differential gear device 6 described later) is disposed on an axis different from that of the first rotating electrical machine 11 and the second rotating electrical machine 12. Specifically, the differential gear device 6 provided in the transmission device 2 is disposed on a third axis A3 parallel to the first axis A1 and the second axis A2. The first axis A1, the second axis A2, and the third axis A3 are axes (virtual axes) different from one another. In the following, a direction parallel to the respective axes (first axis A1, second axis A2, and third axis A3) (axial direction common to the respective axes) is referred to as “axial direction L”. And one side of the axial direction L is made "the axial first side L1", and the other side of the axial direction L (the side opposite to the axial first side L1 in the axial direction L) "axial second side L2" I assume. In the present embodiment, the side on which the second rotary electric machine 12 is disposed with respect to the first rotary electric machine 11 in the axial direction L is the axial first side L1. Furthermore, in the following, the radial direction based on the first axis A1 is referred to as "first radial direction K1", and the radial direction based on the second axis A2 is referred to as "second radial direction K2" (see FIG. 1). .

  The first rotating electrical machine 11 includes a first stator 11 a fixed to a non-rotating member such as the case 3 and a first rotor 11 b rotatably supported with respect to the first stator 11 a. The first rotor 11b is connected to rotate integrally with the first rotor shaft 11c. The second rotating electrical machine 12 includes a second stator 12 a fixed to a non-rotating member such as the case 3 and a second rotor 12 b rotatably supported with respect to the second stator 12 a. The second rotor 12 b is connected to rotate integrally with the second rotor shaft 12 c. The second rotary electric machine 12 is a rotary electric machine that can rotate independently of the first rotary electric machine 11. That is, the second rotor shaft 12c is not connected so as to always rotate (for example, integrally rotate) in conjunction with the first rotor shaft 11c, and the second rotor shaft 12c is a first rotor shaft. It is a shaft member which can rotate independently of 11c. Each of the first rotating electrical machine 11 and the second rotating electrical machine 12 is electrically connected to a storage device such as a battery or a capacitor, receives power supply from the storage device and performs powering, or inertial force of a vehicle, etc. The generated power is supplied to the storage device for storage.

  In the present embodiment, the first rotary electric machine 11 is an inner rotor type rotary electric machine, and the first rotor 11b is the inner side of the first stator 11a in the first radial direction K1 and is the first in the first radial direction K1. It is arrange | positioned in the position which overlaps with the stator 11a. Further, in the present embodiment, the second rotary electric machine 12 is an inner rotor type rotary electric machine, and the second rotor 12b is more inward than the second stator 12a in the first radial direction K1 and viewed in the first radial direction K1. It is arrange | positioned in the position which overlaps with the 2nd stator 12a.

  As shown in FIG. 1, the vehicle drive device 1 includes a first drive member 21 drivingly connected to the first rotary electric machine 11 and a second drive member 22 drivingly connected to the second rotary electric machine 12. ing. The first drive member 21 and the second drive member 22 are disposed on the first axis A1. In the present embodiment, the first drive member 21 is connected to rotate integrally with the first rotor shaft 11c, and the second drive member 22 rotates integrally with the second rotor shaft 12c. It is connected. Thus, the first drive member 21 rotates integrally with the first rotary electric machine 11, and the second drive member 22 rotates integrally with the second rotary electric machine 12. In the present embodiment, although the first drive member 21 is a separate member from the first rotor shaft 11c, the first drive member 21 and the first rotor shaft 11c may be configured by a common shaft member. Similarly, the second drive member 22 and the second rotor shaft 12c may be configured by a common shaft member.

  As shown in FIGS. 2 and 3, the first drive member 21 includes a first drive gear 21 a that meshes with a first input gear 71 a of the transmission device 2, and the second drive member 22 includes a first drive gear 21 a of the transmission device 2. A second drive gear 22a meshing with the second input gear 72a is provided. In the present embodiment, the first input gear 71a, the second input gear 72a, the first drive gear 21a, and the second drive gear 22a are helical gears. The helical gear is a cylindrical gear with helical teeth. The first drive gear 21a is disposed on the first axial side L1 with respect to the first rotary electric machine 11, and the second drive gear 22a is disposed on the second axial side L2 with respect to the second rotary electric machine 12 There is. The torque of the first rotary electric machine 11 is input from the third meshing portion 93, which is a meshing portion between the first input gear 71a and the first drive gear 21a, to the differential gear device 6 provided in the transmission device 2, and the second rotary electric machine The torque of 12 is input from the fourth meshing portion 94 which is a meshing portion between the second input gear 72a and the second drive gear 22a to the differential gear device 6 provided in the transmission device 2. The third engagement portion 93 and the fourth engagement portion 94 are disposed at mutually different positions in the axial direction L. Specifically, the third meshing portion 93 is disposed on the second side L2 in the axial direction with respect to a fifth case portion 35 described later, and the fourth meshing portion 94 is arranged in the axial direction fifth with respect to the fifth case portion 35. It is arrange | positioned at 1 side L1. The transmission device 2 includes a first input member 71 and a second input member 72. The first input member 71 includes a first input gear 71a. The second input member 72 includes a second input gear 72a. . Thus, the first drive member 21 is a helical gear (first input gear 71 a) provided on the other transmission member (first input member 71) of the transmission device 2 and engaged with the helical gear (first input member 71 a). The second drive member 22 is engaged with a helical gear (second input gear 72a) provided on the other transmission member (second input member 72) of the transmission device 2. A gear (second drive gear 22a) is provided.

  As shown in FIGS. 1 to 3, the first connection member 51 includes a first driven gear 51 a that meshes with the first output gear 81 a of the transmission device 2, and the second connection member 52 includes the first connection gear 51 a of the transmission device 2. The second driven gear 52a is engaged with the two output gear 82a. The first output gear 81a, the second output gear 82a, the first driven gear 51a, and the second driven gear 52a are helical gears. The torque for rotationally driving the first wheel W1 is output from the first meshing portion 91, which is a meshing portion of the first output gear 81a and the first driven gear 51a, to the first connecting member 51, and the second wheel W2 is output. The torque for rotationally driving is output to the second connecting member 52 from the second meshing portion 92 which is a meshing portion of the second output gear 82a and the second driven gear 52a. The first engagement portion 91 and the second engagement portion 92 are disposed at mutually different positions in the axial direction L. Specifically, the first meshing portion 91 is arranged on the second axial side L2 with respect to the fifth case portion 35, and the second meshing portion 92 is arranged on the first axial side with respect to the fifth case portion 35. It is arranged in L1. The transmission device 2 includes a first output member 81 and a second output member 82. The first output member 81 includes a first output gear 81a. The second output member 82 includes a second output gear 82a. . Thus, the first connecting member 51 is a helical gear (first output gear 81 a) provided on the other transmission member (first output member 81) of the transmission device 2 (first output gear 81 a). The second connecting member 52 is engaged with a helical gear (second output gear 82a) provided on the other transmission member (second output member 82) of the transmission device 2. A gear (second driven gear 52a) is provided.

  In the present embodiment, the transmission device 2 includes a differential gear device 6. Here, the differential gear device is a gear device having a plurality of differentially rotatable rotating elements. That is, the differential gear device is configured using a differential gear mechanism having a plurality of differentially rotatable rotating elements. The differential gear unit is, for example, a planetary gear type differential gear unit (that is, a planetary gear unit), and in this case, the differential gear unit is a planetary gear type differential gear mechanism (that is, a planetary gear mechanism) Constructed using The differential gear device is, for example, a bevel gear differential gear device, and in this case, the differential gear device is configured using a bevel gear differential gear mechanism. In addition, although the non-rotating element fixed to non-rotating members, such as case 3 etc., may be contained in several rotating elements with which differential gear apparatus 6 is equipped, in this specification, a non-rotating element is also included. It is called "rotational element".

  The differential gear device 6 has a first rotation element E1, a second rotation element E2, a third rotation element E3, and a fourth rotation element E4 in the order of rotational speed (see FIG. 4). A first input member 71 is connected to the first rotating element E1, a first output member 81 is connected to the second rotating element E2, a second output member 82 is connected to the third rotating element E3, and a fourth rotating element E4 is provided. The second input member 72 is connected to the Thereby, the first rotary electric machine 11 is drivingly connected to the first rotary element E1, the first connection member 51 (first connecting portion 7) is drivingly connected to the second rotary element E2, and the second rotary element E3 is second The connecting member 52 (second connecting portion 8) is drivingly connected, and the second rotating electrical machine 12 is drivingly connected to the fourth rotating element E4. In the present embodiment, the differential gear device 6 has only the first rotation element E1, the second rotation element E2, the third rotation element E3, and the fourth rotation element E4 as the rotation elements.

  In the present embodiment, the differential gear device 6 is a planetary gear type differential gear device (i.e., the planetary gear device 60). As shown in FIGS. 2 and 3, the planetary gear device 60 includes a first planetary gear mechanism 61 having a first sun gear S1, a first carrier C1, and a first ring gear R1, a second sun gear S2, and a second carrier C2. And a second planetary gear mechanism 62 having a second ring gear R2. The first carrier C1 rotatably supports the first pinion gear P1 via the first pinion shaft 64a, and the second carrier C2 rotatably supports the second pinion gear P2 via the second pinion shaft 64b. There is. As a tooth line of each gear is simplified and shown in FIG. 5, in this embodiment, the sun gear (here, the first sun gear S1 and the second sun gear S2) provided in the differential gear device 6 and the pinion gear (here, the first gear The first pinion gear P1 and the second pinion gear P2) and the ring gears (here, the first ring gear R1 and the second ring gear R2) are spur gears. The spur gear is a cylindrical gear having straight teeth. The first planetary gear mechanism 61 is disposed on the second axial side L2 with respect to the second planetary gear mechanism 62. In addition, the first planetary gear mechanism 61 is disposed on the first axial side L1 with respect to the first rotary electric machine 11, and the second planetary gear mechanism 62 is disposed on the second axial side L2 with respect to the second rotary electric machine 12. Is located in

  The planetary gear device 60 is configured by connecting a first planetary gear mechanism 61 and a second planetary gear mechanism 62. Specifically, in the present embodiment, both of the first planetary gear mechanism 61 and the second planetary gear mechanism 62 are single pinion type planetary gear mechanisms. The first carrier C1 and the second sun gear S2 are connected to rotate integrally with each other, and the first sun gear S1 and the second carrier C2 are connected to rotate integrally with each other. As described above, the first planetary gear mechanism 61 and the second planetary gear mechanism 62 include four rotating elements as a whole by connecting two of the three rotating elements that each has to each other. It is configured to perform differential operation integrally. Then, as shown in FIG. 4, in the present embodiment, the first rotating element E1 is the first ring gear R1, and the second rotating element E2 is the first carrier C1 and the second sun gear S2, which rotate together. The third rotating element E3 is a first sun gear S1 and a second carrier C2 which rotate integrally, and the fourth rotating element E4 is a second ring gear R2. As described above, the order of the rotational speed is the order of the first rotation element E1, the second rotation element E2, the third rotation element E3, and the fourth rotation element E4.

  Note that "the order of the rotational speed" is the order of the rotational speed in the rotational state of each rotary element. The rotational speed of each rotary element changes according to the rotational state of the differential gear 6 (planet gear 60), but the arrangement order of the rotational speeds of the rotary elements is determined by the structure of the differential 6 Therefore, it becomes constant. Note that “the order of the rotational speeds of the respective rotating elements” is equal to the arrangement order in the velocity diagram (see the alignment chart, FIG. 4) of each of the rotating elements. Here, "the order of arrangement of the rotational elements in the velocity diagram" is the order of arrangement of the axes corresponding to the respective rotational elements in the velocity diagram (collinear diagram) along the direction orthogonal to the axes. It is. The arrangement direction of the axis corresponding to each rotation element in the velocity diagram (collinear diagram) varies depending on how the velocity diagram is drawn, but the arrangement order is determined by the structure of the differential gear 6, and Become. In FIG. 4, “0” on the vertical axis indicates that the rotational speed is zero, the upper side is positive, and the lower side is negative.

  In FIG. 4, “Ti1” represents torque (first input torque Ti1) input to the first rotary element E1 from the side of the first rotary electric machine 11, and “Ti2” represents the second torque of the fourth rotary element E4. The torque (2nd input torque Ti2) input from the side of the rotary electric machine 12 is represented. The magnitude of the first input torque Ti1 is determined according to the magnitude of the output torque of the first rotating electrical machine 11 and the gear ratio (first gear ratio) from the first rotating electrical machine 11 to the first rotating element E1. The magnitude of the 2 input torque Ti2 is determined according to the magnitude of the output torque of the second rotating electrical machine 12 and the gear ratio (second gear ratio) from the second rotating electrical machine 12 to the fourth rotating element E4. In the present embodiment, the first drive gear 21a and the second drive gear 22a are formed to have the same diameter, and the first input gear 71a and the second input gear 72a are formed to have the same diameter. The first gear ratio and the second gear ratio are equal to each other. Here, the first gear ratio and the second gear ratio are larger than 1 and the rotation of the first rotary electric machine 11 is decelerated and transmitted to the first rotary element E1, and the rotation of the second rotary electric machine 12 is decelerated and the fourth It is transmitted to the rotating element E4.

  Further, in FIG. 4, “To1” represents torque (first output torque To1) output from the second rotating element E2 to the side of the first wheel W1, and “To2” represents the third torque from the third rotating element E3. The torque (2nd output torque To2) output to the 2 wheel W2 side is represented. The magnitude of the driving force of the first wheel W1 is determined according to the magnitude of the first output torque To1 and the gear ratio (third gear ratio) from the second rotating element E2 to the first wheel W1, and the second wheel The magnitude of the driving force of W2 is determined according to the magnitude of the second output torque To2 and the gear ratio (fourth gear ratio) from the third rotating element E3 to the second wheel W2. In the present embodiment, the first output gear 81a and the second output gear 82a are formed to have the same diameter, and the first driven gear 51a and the second driven gear 52a are formed to the same diameter. The third gear ratio and the fourth gear ratio are equal to each other. Here, the third gear ratio and the fourth gear ratio are larger than 1 and the rotation of the second rotating element E2 is decelerated and transmitted to the first wheel W1, and the rotation of the third rotating element E3 is decelerated and the second wheel It is transmitted to W2.

  As described above, since the third gear ratio and the fourth gear ratio are equal to each other, when the vehicle travels straight, the rotational speed of the second rotary element E2 and the rotational speed of the third rotary element E3 become equal. All the rotating elements of are rotating at the same speed. On the other hand, at the time of turning of the vehicle, the rotational speed of the rotating element to which the outer wheel (the wheel farther from the turning center) of the first wheel W1 and the second wheel W2 is drive connected is the first wheel W1 and the second wheel W1. The inner wheel (the wheel closer to the turning center) of the wheels W2 is higher than the rotational speed of the drivingly connected rotating element. FIG. 4 shows the state of each of the rotating elements of the planetary gear device 60 in a state where the vehicle is turning in the direction in which the first wheel W1 becomes the outer wheel. As described above, in this embodiment, the sun gear (the first sun gear S1 and the second sun gear S2), the pinion gears (the first pinion gear P1 and the second pinion gear P2), and the ring gear (the first gear) included in the differential gear device 6 The ring gear R1 and the second ring gear R2) are spur gears, but the scene where the planetary gear device 60 performs differential operation in this way is limited when the vehicle turns, and the magnitude of the differential rotation when the vehicle turns (The difference in rotational speed between the different rotating elements of the planetary gear set 60) is also basically not so great. Therefore, it is possible to reduce the influence of gear noise that may occur when the planetary gear device 60 performs a differential operation.

From the balance of torques, each of the first output torque To1 and the second output torque To2 is represented by the following equations (1) and (2), the first input torque Ti1, the second input torque Ti2, the first planet It becomes settled according to the gear ratio (1st gear ratio λ1) of the gear mechanism 61 and the gear ratio (2nd gear ratio λ2) of the second planetary gear mechanism 62. Here, the first gear ratio λ1 is a ratio of the number of teeth of the first sun gear S1 to the number of teeth of the first ring gear R1, and the second gear ratio λ2 is a ratio of the number of teeth of the second ring gear R2 to the number of teeth of the second ring gear R2. It is a ratio of the number of teeth.
To1 = (1 + λ1) · Ti1-λ2 · Ti2 (1)
To2 = (1 + λ2) · Ti2-λ1 · Ti1 (2)

  Thus, each of the first output torque To1 and the second output torque To2 is determined according to both the first input torque Ti1 and the second input torque Ti2. That is, in the present embodiment, the transmission device 2 transmits the torque of the first rotating electrical machine 11 to both the first connecting portion 7 and the second connecting portion 8 and the torque of the second rotating electrical machine 12 as the first connecting portion It is comprised so that it may transmit to both 7 and the 2nd connection part 8. FIG. In other words, the transmission device 2 is configured to distribute and transmit the torque of the first rotating electrical machine 11 and the second rotating electrical machine 12 to the first connecting portion 7 and the second connecting portion 8. By configuring the vehicle drive device 1 in this manner, the power transmission path between the first rotary electric machine 11 and the first connecting portion 7 and the power transmission between the second rotary electric machine 12 and the second connecting portion 8 When making a difference in driving force between the first wheel W1 and the second wheel W2 compared to the case where the path is separated, the total driving force of the first wheel W1 and the second wheel W2 is large. By securing it, it is possible to improve the running performance at the time of turning of the vehicle.

  As a supplementary explanation, as an example, in a situation where the magnitude of the first input torque Ti1 is 200 [N · m], the difference between the first output torque To1 and the second output torque To2 is 160 [N · m]. Assume the case. In this case, in the configuration of the comparative example in which To1 = Ti1 and To2 = Ti2 unlike the vehicle drive device 1 according to the present embodiment, the difference between the first output torque To1 and the second output torque To2 is 160 [N ··· The magnitude of the second input torque Ti2 for setting m] is 40 [N · m]. Therefore, in the case of this comparative example, the sum of the first input torque Ti1 and the second input torque Ti2 (equal to the sum of the first output torque To1 and the second output torque To2) is 240 [N · m]. It becomes. On the other hand, in the vehicle drive device 1 according to the present embodiment, in a situation where the magnitude of the first input torque Ti1 is 200 [N · m], the first output torque To1 and the second output torque To2 The magnitude of the second input torque Ti2 for setting the difference to 160 [N · m] is the above equation when both the first gear ratio λ1 and the second gear ratio λ2 are “0.4”. From (1) and (2), it is 111 [N · m]. Therefore, in this case, the sum of the first input torque Ti1 and the second input torque Ti2 (the sum of the first output torque To1 and the second output torque To2) is 311 [N · m], and the above comparative example The total driving force of the first wheel W1 and the second wheel W2 corresponds to a torque difference of 71 [N · m] (= 311 [N · m] −240 [N · m]) compared to the case of Can be secured large.

  Next, the configuration of the case 3 in the vehicle drive device 1 of the present embodiment will be described. The case 3 includes a plurality of case portions 30 joined via the seal member 4. Each of the case portions 30 has a portion exposed to the outer surface of the case 3. That is, the joint between the case portions 30 is formed to be exposed to the outer surface of the case 3. In addition, case part 30 comrades are joined, for example using a bolt. The case 3 further includes a support member 40 described later in addition to the case portion 30.

  As shown in FIG. 1, the plurality of case portions 30 include a first case portion 31 and a second case portion 32. The first case portion 31 is joined to the second case portion 32 from an axial second side L2. The first case portion 31 includes a first peripheral wall 31c formed in a tubular shape extending in the axial direction L, and a space (first accommodation space H1) surrounded by the first peripheral wall 31c in the axial direction L view. The first rotary electric machine 11, the first drive member 21, the first connection member 51, and part of the transmission device 2 (specifically, the first input member 71, the first output member 81, and the first planetary gear A mechanism 61) is arranged. In addition, the second case portion 32 includes a second peripheral wall portion 32c formed in a tubular shape extending in the axial direction L, and a space surrounded by the second peripheral wall portion 32c in the axial direction L (a second accommodation space H2) the second rotary electric machine 12, the second drive member 22, the second connection member 52, and part of the transmission device 2 (specifically, the second input member 72, the second output member 82, and the second A planetary gear mechanism 62) is arranged. In the present embodiment, the first accommodation space H1 and the second accommodation space H2 are divided in the axial direction L by a fifth case portion 35 described later. That is, the first drive member 21 is disposed on one side (here, the second axial side L2) in the axial direction L with respect to the wall portion (here, the fifth case portion 35) included in the case 3; The second drive member 22 is disposed coaxially with the first drive member 21 on the other side in the axial direction L (here, the first axial side L1) with respect to the wall portion. Further, the first connecting member 51 is disposed on one side (here, the second axial side L2) of the axial direction L with respect to the wall portion (here, the fifth case portion 35) included in the case 3, and The second connecting member 52 is disposed coaxially with the first connecting member 51 on the other side in the axial direction L (here, the first axial side L1) with respect to the wall portion.

  The plurality of case portions 30 further include a third case portion 33 and a fourth case portion 34. In a portion of the first accommodation space H1 where the first rotary electric machine 11 is disposed, an opening is formed without the first case portion 31 defining the second side L2 in the axial direction, and the opening is closed. The third case portion 33 is joined to the first case portion 31 from the axial second side L2. Further, in the portion of the second accommodation space H2 where the second rotary electric machine 12 is disposed, an opening is formed without the first case L2 being partitioned by the second case portion 32, and the opening is closed. As described above, the fourth case portion 34 is joined to the second case portion 32 from the first axial direction L1.

  The plurality of case portions 30 further include a fifth case portion 35. The fifth case portion 35 is an internal space of the case 3 (a housing space H for housing the first rotary electric machine 11, the second rotary electric machine 12, the first connection member 51, the second connection member 52, and the transmission device 2). Function as an intermediate wall that divides the in the axial direction L. Specifically, the fifth case portion 35 is formed in a shape (for example, a plate shape) extending in a direction orthogonal to the axial direction L, and the joint portion 36 between the first case portion 31 and the second case portion 32 Are disposed at the position in the axial direction L at which is formed. Then, the fifth case portion 35 is configured such that the first case portion 31 (the first peripheral wall portion 31c) and the second case portion 32 (the second peripheral wall portion 32c) are sandwiched from both sides in the axial direction L. It is joined to each of the case portion 31 and the second case portion 32. That is, in the present embodiment, the first case portion 31 and the second case portion 32 are joined at the joining portion 36 via the fifth case portion 35. Therefore, in the joint portion 36, the joint portion between the first case portion 31 and the fifth case portion 35 and the joint portion between the second case portion 32 and the fifth case portion 35 are formed.

  In the joint portion 36, the seal member 4 is provided on the joint surface (first joint surface 36a) between the first case portion 31 and the fifth case portion 35, and the second case portion 32 and the fifth case portion 35. The seal member 4 is provided on the joint surface (second joint surface 36 b) with the above. The seal member 4 is a member for preventing the oil in the case 3 from leaking out of the case 3. For example, a liquid gasket can be used as the seal member 4. In FIG. 1, the seal member 4 is simplified and shown by a thick line.

  Next, a support structure of the first connecting member 51 and the second connecting member 52 in the vehicle drive device 1 of the present embodiment will be described.

  As shown in FIG. 1, the vehicle drive device 1 includes a support member 40 fixed to the case portion 30. The support member 40 is disposed inside the case portion 30. Therefore, the fixing portion between the support member 40 and the case portion 30 (in the present embodiment, the first fixing portion 37a and the second fixing portion 37b described later) is different from the joint portion between different case portions 30. It is not exposed to the outside. In the present embodiment, the vehicle drive device 1 includes the first support member 41 and the second support member 42 which are the support members 40 disposed in the inside of the case portion 30 respectively. The first support member 41 is disposed on the second side L2 in the axial direction with respect to the fifth case portion 35 (that is, disposed in the first accommodation space H1) and fixed to the first case portion 31. It is used in order to support the component which is arranged in 1 accommodation space H1. That is, the first support member 41 is fixed inside the first case portion 31 which is one of the plurality of case portions 30. Further, the second support member 42 is disposed on the first side L1 in the axial direction with respect to the fifth case portion 35 (that is, disposed in the second accommodation space H2) and fixed to the second case portion 32. , And is used to support members disposed in the second accommodation space H2. That is, the second support member 42 is fixed to the inside of the second case portion 32 which is one of the plurality of case portions 30 and different from the first case portion 31. The first support member 41 and the second support member 42 are fixed to the case 3 using, for example, bolts.

  As shown in FIG. 1, the first connection member 51 is rotatably supported at two places in the axial direction L by the first bearing B1 and the second bearing B2. In the present embodiment, each of the first bearing B1 and the second bearing B2 rotatably supports the first connection member 51 with respect to the case 3. That is, the first connection member 51 is rotatably supported at two places in the axial direction L by the case 3. The second connection member 52 is rotatably supported at two points in the axial direction L by the third bearing B3 and the fourth bearing B4. In the present embodiment, each of the third bearing B3 and the fourth bearing B4 rotatably supports the second connection member 52 with respect to the case 3. That is, the second connection member 52 is rotatably supported at two places in the axial direction L by the case 3.

  In the present embodiment, the first connecting member 51 is formed by the first supporting portion 31 a formed in the first case portion 31 and the fifth supporting portion 41 a formed in the first supporting member 41. It is rotatably supported at a location. In the present embodiment, the fifth support portion 41a is disposed closer to the first side L1 in the axial direction than the first support portion 31a. As described above, the first support member 41 rotatably supporting the first connecting member 51 at a position different from the first support portion 31 a is fixed to the inside of the first case portion 31. Therefore, due to the load that the first driven gear 51a receives from the first output gear 81a, these two cases are joined to the joint portion between the first case portion 31 and the other case portion 30 (for example, the fifth case portion 35). The configuration is such that the force in the direction to separate the portions 30 is unlikely to act, and as a result, it is possible to appropriately maintain the sealing performance between the first case portion 31 and the other case portion 30. ing.

  The first connection member 51 is supported from the outside of the second radial direction K2 by the first support portion 31a. Specifically, the first bearing B1 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the first support portion 31a and the outer peripheral surface of the first connecting member 51, and the first connection is made. The member 51 is supported from the outside of the second radial direction K2 by the first support portion 31a via the first bearing B1. The first connecting member 51 is supported by the fifth support portion 41a from the inside in the second radial direction K2. Specifically, the second bearing B2 (here, a radial type ball bearing) is disposed between the outer peripheral surface of the fifth support portion 41a and the inner peripheral surface of the first connecting member 51, and the first connection is established. The member 51 is supported from the inside of the second radial direction K2 by the fifth support portion 41a via the second bearing B2. The first driven gear 51a is a portion of the first connecting member 51 that is disposed outside the second bearing B2 in the second radial direction K2 so as to overlap the second bearing B2 in the second radial direction K2. Is formed on the outer peripheral surface of That is, the second bearing B2 is disposed so as to overlap the first driven gear 51a in the second radial direction K2.

  In the present embodiment, the second connecting member 52 is formed by the second supporting portion 32 a formed in the second case portion 32 and the sixth supporting portion 42 a formed in the second supporting member 42. It is rotatably supported at a location. In the present embodiment, the sixth support portion 42a is disposed closer to the second side L2 in the axial direction than the second support portion 32a. As described above, the second support member 42 rotatably supporting the second connection member 52 at a position different from the second support portion 32 a is fixed inside the second case portion 32. Therefore, due to the load that the second driven gear 52a receives from the second output gear 82a, these two cases are joined to the joint portion between the second case portion 32 and the other case portion 30 (for example, the fifth case portion 35). The configuration is such that the force in the direction to separate the portions 30 is unlikely to act, and as a result, it is possible to appropriately maintain the sealing performance between the second case portion 32 and the other case portion 30. ing.

  The second connection member 52 is supported by the second support portion 32a from the outside in the second radial direction K2. Specifically, the fourth bearing B4 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the second support portion 32a and the outer peripheral surface of the second connecting member 52, and the second connection is established. The member 52 is supported from the outside of the second radial direction K2 by the second support portion 32a via the fourth bearing B4. The second connecting member 52 is supported by the sixth support portion 42a from the inside in the second radial direction K2. Specifically, the third bearing B3 (here, a radial type ball bearing) is disposed between the outer peripheral surface of the sixth support portion 42a and the inner peripheral surface of the second connecting member 52, and the second connection is established. The member 52 is supported from the inside of the second radial direction K2 by the sixth support portion 42a via the third bearing B3. The second driven gear 52a is a portion of the second connecting member 52 that is disposed outside the third bearing B3 in the second radial direction K2 so as to overlap the third bearing B3 in the second radial direction K2. Is formed on the outer peripheral surface of That is, the third bearing B3 is disposed so as to overlap the second driven gear 52a in the second radial direction K2.

  As described above, the first output gear 81a, the second output gear 82a, the first driven gear 51a, and the second driven gear 52a are helical gears. Therefore, not only the radial load but also the thrust load is included in the load (load due to the meshing force) that the first driven gear 51a receives from the first output gear 81a in the first meshing portion 91. The load that the second driven gear 52a receives from the second output gear 82a in the second engagement portion 92 includes not only a radial load but also a thrust load. Therefore, in a state where the transmission device 2 is transmitting torque, a thrust load is generated on the first connecting member 51 including the first driven gear 51a and the second connecting member 52 including the second driven gear 52a. In the vehicle drive device 1 of the present embodiment, by providing the configuration described below, the overall size of the device can be reduced while appropriately supporting the first connection member 51 and the second connection member 52 by the case 3. It is possible.

  As a tooth line of each gear is simplified and shown in FIG. 5, in this vehicle drive device 1, the twisting direction of the teeth of the first driven gear 51a and the twisting direction of the teeth of the second driven gear 52a are reversed. It is the direction. Therefore, as indicated by arrows in FIG. 5 in the direction of the thrust load received by each gear, in a state in which the transmission device 2 is transmitting torque, the first driven gear 51a is the first output gear 81a at the first meshing portion 91. Direction of the thrust load received from the second connection gear 51 (ie, the direction of the thrust load generated in the first connection member 51), and the direction of the thrust load received by the second driven gear 52a from the second output gear 82a The direction of the thrust load generated in the second connection member 52) is opposite to each other. In FIG. 5, the direction of the thrust load received by each gear at the time of forward power running of the vehicle is indicated by an arrow, and at the time of forward regeneration and reverse power running of the vehicle, the thrust load opposite to the direction shown in FIG. Act on each gear. In the present embodiment, since the first connection member 51 and the second connection member 52 are indirectly supported with respect to the fifth case portion 35, the first connection member 51 coaxially disposed in this manner The direction of the thrust load generated in each of the first connection member 52 and the second connection member 52 is opposite to each other, whereby the thrust load generated in the first connection member 51 and the second connection member 52 with respect to the fifth case portion 35 A biased load on one side of the acting axial direction L can be reduced. As a result, compared with the case where the directions of the thrust loads generated in the first connection member 51 and the second connection member 52 are the same, the strength required for the fifth case portion 35 is suppressed to a low level, It is possible to miniaturize the entire device. In the present embodiment, the twist angle of the teeth of the first driven gear 51a and the twist angle of the teeth of the second driven gear 52a have the same size.

  Further, in the present embodiment, as shown in FIG. 1, the first driven gear 51a performs the first power running forward of the vehicle than the central position in the axial direction L between the first bearing B1 and the second bearing B2. The driven gear 51a is disposed close to the first axial side L1 opposite to the side to which the thrust load received from the first output gear 81a is directed. Note that arranging the gear to one side in the axial direction L with respect to a specific position in the axial direction L (here, the central position in the axial direction L between the first bearing B1 and the second bearing B2) This means that the central position of the gear in the axial direction L is disposed on the one side in the axial direction L with respect to the specific position. Here, the second bearing B2, which is a bearing disposed on the first axial direction L1 of the first bearing B1 and the second bearing B2, overlaps the first driven gear 51a in the second radial direction K2 Is located in In addition, the second driven gear 52a is an axial second side L2 (a side opposite to the axial first side L1 than the central position of the axial direction L between the third bearing B3 and the fourth bearing B4). That is, at the time of forward power running of the vehicle, the second driven gear 52a is disposed close to the side opposite to the side to which the thrust load received from the second output gear 82a faces). Here, the third bearing B3, which is a bearing disposed on the second axial direction L2 of the third bearing B3 and the fourth bearing B4, overlaps the second driven gear 52a in the second radial direction K2 Is located in

  By arranging the first driven gear 51a in this manner, during the forward power running of the vehicle, the thrust load received by the first driven gear 51a is mainly received by the first bearing B1, and the radial load received by the first driven gear 51a. Can be received mainly by the second bearing B2. That is, the support of the thrust load and the radial load received by the first driven gear 51a can be properly shared between the first bearing B1 and the second bearing B2, and these thrust load and the radial load are two bearings (B1). , And B2), and it is possible to miniaturize the two bearings (B1 and B2) in a well-balanced manner while avoiding acting on one of the two bearings. Similarly, the thrust and radial loads supported by the second driven gear 52a can be properly shared by the third bearing B3 and the fourth bearing B4, and these thrust and radial loads can be divided into two bearings (see FIG. It is possible to miniaturize the two bearings (B3, B4) in a well-balanced manner by avoiding acting on one of B3, B4). As a result, the bearings (B1 to B4) can be downsized in a well-balanced manner, and as a result, the overall size of the device can also be reduced.

  In the present embodiment, the first connecting member 51 is connected to rotate integrally with the first wheel W1, and the second connecting member 52 is connected to rotate integrally with the second wheel W2. Therefore, the first connection member 51 carries transmission of a relatively large torque (torque of the rotating electrical machine (11, 12) after being decelerated) equivalent to the drive torque of the first wheel W1, and the second connection member 52 The transmission of a relatively large torque (the torque of the rotating electrical machine (11, 12) after being decelerated) equal to the driving torque of the second wheel W2 is configured to transmit the first driven gear 51a from the first output gear 81a. The thrust load received and the thrust load received by the second driven gear 52a from the second output gear 82a tend to be large. In this regard, as described above, in the vehicle drive device 1, one of the axial directions L that can act on the fifth case portion 35 by the thrust load generated in the first connecting member 51 and the second connecting member 52 It is possible to reduce the load biased to the side. Therefore, in the configuration in which the first connecting member 51 is connected to rotate integrally with the first wheel W1, and the second connecting member 52 is connected to rotate integrally with the second wheel W2, the first While the connecting member 51 and the second connecting member 52 are appropriately supported by the case 3, the overall size of the device can be reduced.

  Next, the support structure of the first output member 81 and the second output member 82 in the vehicle drive device 1 of the present embodiment will be described. The radial direction in the following description of the support structure of the first output member 81 and the second output member 82 is a radial direction based on the third axis A3, unless otherwise specified.

  As shown in FIG. 1, the first output member 81 is rotatably supported at two places in the axial direction L by the fifth bearing B5 and the sixth bearing B6. In the present embodiment, each of the fifth bearing B5 and the sixth bearing B6 rotatably supports the first output member 81 with respect to the case 3. That is, the first output member 81 is rotatably supported at two places in the axial direction L by the case 3. The second output member 82 is rotatably supported at two points in the axial direction L by the seventh bearing B7 and the eighth bearing B8. In the present embodiment, each of the seventh bearing B7 and the eighth bearing B8 rotatably supports the second output member 82 with respect to the case 3. That is, the second output member 82 is rotatably supported at two places in the axial direction L by the case 3.

  As shown in FIG. 1, in the present embodiment, the first output member 81 includes a third support portion 31 b formed in the first case portion 31 and a seventh support portion 41 b formed in the first support member 41. Thus, it is rotatably supported at two places in the axial direction L. The seventh support portion 41b is disposed closer to the first axial side L1 than the third support portion 31b. Further, in the present embodiment, the second output member 82 includes the fourth support portion 32 b formed in the second case portion 32 and the eighth support portion 42 b formed in the second support member 42 in the axial direction L. It is rotatably supported at two places. The eighth support portion 42b is disposed on the second axial side L2 in the axial direction than the fourth support portion 32b.

  The first output member 81 is supported by the third support portion 31 b from the outer side in the radial direction. Specifically, a fifth bearing B5 (here, a radial type conical roller bearing) is disposed between the inner peripheral surface of the third support portion 31b and the outer peripheral surface of the first output member 81. The output member 81 is supported from outside in the radial direction by the third support portion 31 b via the fifth bearing B5. The first output member 81 is supported by the seventh support portion 41 b from the outer side in the radial direction. Specifically, a sixth bearing B6 (here, a radial type conical roller bearing) is disposed between the inner peripheral surface of the seventh support portion 41b and the outer peripheral surface of the first output member 81. The output member 81 is supported from outside in the radial direction by the seventh support portion 41b via the sixth bearing B6. The first output gear 81a is formed on the outer peripheral surface of a portion of the first output member 81, which is disposed between the fifth bearing B5 and the sixth bearing B6 in the axial direction L.

  The second output member 82 is supported from outside in the radial direction by the fourth support portion 32 b. Specifically, an eighth bearing B8 (here, a radial type conical roller bearing) is disposed between the inner peripheral surface of the fourth support portion 32b and the outer peripheral surface of the second output member 82. The output member 82 is supported from outside in the radial direction by the fourth support portion 32 b via the eighth bearing B8. The second output member 82 is supported by the eighth support portion 42b from the outer side in the radial direction. Specifically, a seventh bearing B7 (here, a radial type tapered roller bearing) is disposed between the inner peripheral surface of the eighth support portion 42b and the outer peripheral surface of the second output member 82. The output member 82 is supported from outside in the radial direction by the eighth support portion 42b via the seventh bearing B7. The second output gear 82 a is formed on the outer peripheral surface of a portion of the second output member 82 disposed between the seventh bearing B 7 and the eighth bearing B 8 in the axial direction L.

  In the present embodiment, the first output member 81 is connected so as to be movable relative to the first carrier C1 in the axial direction L, and the second output member 82 is moved relative to the second carrier C2 in the axial direction L It is linked possible. Therefore, compared with the case where the first output member 81 and the first carrier C1 can not move relative to each other in the axial direction L, the connecting portion between the first output member 81 and the first carrier C1 (third connecting portion 66a, FIG. Compared with the case where the second output member 82 and the second carrier C2 can not move relative to each other in the axial direction L, the second output member 82 and the second carrier C2 can be reduced. The transmission of the load at the connection portion (fourth connection portion 66b, see FIG. 2) can be reduced. As a result, the load transmitted from the first output member 81 to the first carrier C1 due to the thrust load received by the first output gear 81a from the first driven gear 51a is reduced, and the second output gear 82a is driven by the second driven gear It is possible to reduce the load transmitted from the second output member 82 to the second carrier C2 due to the thrust load received from the gear 52a.

  Next, the support structure of the first input member 71 and the second input member 72 in the vehicle drive device 1 of the present embodiment will be described. The radial direction in the following description of the support structure of the first input member 71 and the second input member 72 is a radial direction based on the third axis A3, unless otherwise specified.

  As shown in FIG. 2, the first input member 71 is rotatably supported at two places in the axial direction L by a ninth bearing B9 and a tenth bearing B10. In the present embodiment, each of the ninth bearing B9 and the tenth bearing B10 rotatably supports the first input member 71 with respect to the case 3. That is, the first input member 71 is rotatably supported at two places in the axial direction L by the case 3. The second input member 72 is rotatably supported at two places in the axial direction L by an eleventh bearing B11 and a twelfth bearing B12. In the present embodiment, each of the eleventh bearing B11 and the twelfth bearing B12 rotatably supports the second input member 72 with respect to the case 3. That is, the second input member 72 is rotatably supported at two places in the axial direction L by the case 3.

  As shown in FIG. 2, in the present embodiment, the first input member 71 includes a thirteenth support portion 35 a formed in the fifth case portion 35 and a ninth support portion 41 c formed in the first support member 41. Thus, it is rotatably supported at two places in the axial direction L. The ninth support portion 41c is disposed on the second axial side L2 in the axial direction than the thirteenth support portion 35a. Further, in the present embodiment, the second input member 72 includes the fourteenth support portion 35 b formed in the fifth case portion 35 and the tenth support portion 42 c formed in the second support member 42 in the axial direction L. It is rotatably supported at two places. The tenth support portion 42c is disposed closer to the first axial side L1 than the fourteenth support portion 35b.

  The first input member 71 is supported from the outer side in the radial direction by the thirteenth support portion 35 a. Specifically, the tenth bearing B10 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the thirteenth support portion 35a and the outer peripheral surface of the first input member 71, and the first input The member 71 is supported from outside in the radial direction by the thirteenth support portion 35a via the tenth bearing B10. In the present embodiment, the first input member 71 includes the first ring gear R1. The first ring gear R1 is formed on the inner circumferential surface of a portion of the first input member 71 which is disposed radially inward of the tenth bearing B10 and overlaps the tenth bearing B10 in the radial direction. It is done. That is, the tenth bearing B10 is disposed so as to overlap with the first ring gear R1 in the radial direction. In addition, the first input member 71 is supported from the inner side in the radial direction by the ninth support portion 41 c. Specifically, a ninth bearing B9 (here, a radial type ball bearing) is disposed between the outer peripheral surface of the ninth support portion 41c and the inner peripheral surface of the first input member 71. The member 71 is supported from inside in the radial direction by a ninth support portion 41 c via a ninth bearing B9. The first input gear 71a is formed on the outer peripheral surface of a portion of the first input member 71 which is disposed radially outward of the ninth bearing B9 so as to overlap the ninth bearing B9 in the radial direction. There is. That is, the ninth bearing B9 is disposed so as to overlap the first input gear 71a in the radial direction. The ninth bearing B9 is disposed to overlap with the sixth bearing B6 in the radial direction.

  The second input member 72 is supported from outside in the radial direction by the fourteenth support portion 35 b. Specifically, an eleventh bearing B11 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the fourteenth support portion 35b and the outer peripheral surface of the second input member 72. The member 72 is supported from outside in the radial direction by the fourteenth support portion 35b via the eleventh bearing B11. In the present embodiment, the second input member 72 includes the second ring gear R2. The second ring gear R2 is formed on the inner peripheral surface of a portion of the second input member 72 which is disposed radially inward of the eleventh bearing B11 so as to overlap the eleventh bearing B11 in the radial direction. It is done. That is, the eleventh bearing B11 is disposed so as to overlap the second ring gear R2 in the radial direction. Further, the second input member 72 is supported from the inside in the radial direction by the tenth support portion 42c. Specifically, a twelfth bearing B12 (here, a radial type ball bearing) is disposed between the outer peripheral surface of the tenth support portion 42c and the inner peripheral surface of the second input member 72. The member 72 is supported from inside in the radial direction by the tenth support portion 42c via the twelfth bearing B12. The second input gear 72a is formed on the outer peripheral surface of a portion of the second input member 72 which is disposed radially outward of the twelfth bearing B12 so as to overlap the twelfth bearing B12 in the radial direction. There is. That is, the twelfth bearing B12 is disposed so as to overlap the second input gear 72a in the radial direction. Further, the twelfth bearing B12 is disposed so as to overlap with the seventh bearing B7 in the radial direction.

  Next, the support structure of the first drive member 21 and the second drive member 22 in the vehicle drive device 1 of the present embodiment will be described.

  As shown in FIGS. 1 and 2, the first drive member 21 is rotatably supported at two places in the axial direction L by a thirteenth bearing B13 and a fourteenth bearing B14. In the present embodiment, each of the thirteenth bearing B13 and the fourteenth bearing B14 rotatably supports the first drive member 21 with respect to the case 3. That is, the first drive member 21 is rotatably supported at two places in the axial direction L by the case 3. The second drive member 22 is rotatably supported at two points in the axial direction L by a fifteenth bearing B15 and a sixteenth bearing B16. In the present embodiment, each of the fifteenth bearing B15 and the sixteenth bearing B16 rotatably supports the second drive member 22 with respect to the case 3. That is, the second drive member 22 is rotatably supported at two places in the axial direction L by the case 3.

  As shown in FIGS. 1 and 2, in the present embodiment, the first drive member 21 includes a fifteenth support portion 35 c formed in the fifth case portion 35 and an eleventh support formed in the first support member 41. It is rotatably supported at two places in the axial direction L by the portion 41 d. The eleventh support portion 41d is disposed closer to the second axial side L2 than the fifteenth support portion 35c. Further, in the present embodiment, the second drive member 22 is formed in the axial direction L by the sixteenth support portion 35d formed in the fifth case portion 35 and the twelfth support portion 42d formed in the second support member 42. It is rotatably supported at two places. The twelfth support portion 42d is disposed closer to the first axial side L1 than the sixteenth support portion 35d. Thus, the first drive member 21 is directly supported by the fifth case portion 35 via the fourteenth bearing B14, and the second drive member 22 is connected to the fifth case portion 35 via the fifteenth bearing B15. It is directly supported. The first drive member 21 and the second drive member 22 can be supported by rotatably supporting the first drive member 21 and the second drive member 22 by the same wall portion (here, the fifth case portion 35). It is possible to improve the centering accuracy (centering accuracy) between

  The first drive member 21 is supported by the fifteenth support portion 35c from the outside in the first radial direction K1. Specifically, a fourteenth bearing B14 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the fifteenth support portion 35c and the outer peripheral surface of the first drive member 21. The member 21 is supported from the outside of the first radial direction K1 by the fifteenth support portion 35c via the fourteenth bearing B14. The fourteenth bearing B14 is disposed to overlap with the tenth bearing B10 in a radial direction with respect to the third axis A3. The first drive member 21 is supported by the eleventh support portion 41d from the outside in the first radial direction K1. Specifically, a thirteenth bearing B13 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the eleventh support portion 41d and the outer peripheral surface of the first drive member 21. The member 21 is supported from the outside of the first radial direction K1 by the eleventh support portion 41d via a thirteenth bearing B13. The thirteenth bearing B13 is disposed to overlap the second bearing B2 in a radial direction (that is, a second radial direction K2) with respect to the second axis A2. The first drive gear 21 a is formed on the outer peripheral surface of a portion of the first drive member 21 which is disposed between the thirteenth bearing B 13 and the fourteenth bearing B 14 in the axial direction L.

  The second drive member 22 is supported by the sixteenth support portion 35d from the outside of the first radial direction K1. Specifically, a fifteenth bearing B15 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the sixteenth support portion 35d and the outer peripheral surface of the second drive member 22. The member 22 is supported by the sixteenth support portion 35d from the outside in the first radial direction K1 via the fifteenth bearing B15. The fifteenth bearing B15 is disposed to overlap with the eleventh bearing B11 in a radial direction with respect to the third axis A3. The second drive member 22 is supported by the twelfth support portion 42d from the outside in the first radial direction K1. Specifically, a sixteenth bearing B16 (here, a radial type ball bearing) is disposed between the inner peripheral surface of the twelfth support portion 42d and the outer peripheral surface of the second drive member 22. The member 22 is supported from the outside of the first radial direction K1 by a twelfth support portion 42d via a sixteenth bearing B16. The sixteenth bearing B16 is disposed to overlap the third bearing B3 in a radial direction (that is, a second radial direction K2) with respect to the second axis A2. The second drive gear 22 a is formed on the outer peripheral surface of a portion of the second drive member 22 which is disposed between the fifteenth bearing B 15 and the sixteenth bearing B 16 in the axial direction L.

  As described above, in the present embodiment, the first input gear 71a, the second input gear 72a, the first drive gear 21a, and the second drive gear 22a are helical gears. Then, as shown in FIG. 5, in the vehicle drive device 1, the twist direction of the teeth of the first drive gear 21a and the twist direction of the teeth of the second drive gear 22a are opposite to each other. Therefore, in the state where the transmission device 2 is transmitting torque, the direction of the thrust load that the first drive gear 21a receives from the first input gear 71a in the third meshing portion 93 (that is, the thrust generated in the first drive member 21) The direction of the load) and the direction of the thrust load received by the second drive gear 22a from the second input gear 72a at the fourth meshing portion 94 (that is, the direction of the thrust load generated at the second drive member 22) are opposite to each other. It becomes the direction. In the present embodiment, since the first drive member 21 and the second drive member 22 are directly supported with respect to the fifth case portion 35, the first drive member 21 coaxially disposed in this manner The direction of the thrust load generated in each of the first drive member 22 and the second drive member 22 is opposite to each other, whereby the thrust load generated in the first drive member 21 and the second drive member 22 with respect to the fifth case portion 35 A biased load on one side of the acting axial direction L can be reduced. In the present embodiment, the twist angle of the teeth of the first drive gear 21a and the twist angle of the teeth of the second drive gear 22a have the same size.

  Since the twisting direction of the teeth of the first drive gear 21a is opposite to the twisting direction of the teeth of the second drive gear 22a, the twisting direction of the teeth of the first input gear 71a and the teeth of the second input gear 72a The twisting direction is opposite. Therefore, in the present embodiment, although the first input member 71 and the second input member 72 are directly supported with respect to the fifth case portion 35, the first input member 71 and the first input member 71 arranged coaxially are The directions of the thrust loads generated in the two input members 72 are opposite to each other. From this point as well, it is possible to suppress a load that is biased to one side in the axial direction L that can act on the fifth case portion 35 to a small value.

  Further, in the present embodiment, as shown in FIGS. 2 and 5, the first drive gear 21a is more in forward power running of the vehicle than the central position in the axial direction L between the thirteenth bearing B13 and the fourteenth bearing B14. At the same time, the first drive gear 21a is disposed close to the first axial side L1 which is the opposite side to the side to which the thrust load received from the first input gear 71a is directed. In addition, the second drive gear 22a has a thrust that the second drive gear 22a receives from the second input gear 72a during forward power running of the vehicle than the central position in the axial direction L between the fifteenth bearing B15 and the sixteenth bearing B16. It arrange | positions on the axial direction 2nd side L2 which is an opposite side to the side to which a load turns, and is arrange | positioned. Furthermore, in the present embodiment, the first input gear 71a is driven by the first drive during forward power running of the vehicle than the central position of the first input gear 71a in the axial direction L between the ninth bearing B9 and the tenth bearing B10. It is disposed close to the second axial side L2 which is the opposite side to the side to which the thrust load received from the gear 21a is directed. In addition, the second input gear 72a has a thrust that the second input gear 72a receives from the second drive gear 22a during forward power running of the vehicle than the central position in the axial direction L between the eleventh bearing B11 and the twelfth bearing B12. It arrange | positions on the axial direction 1st side L1 which is an opposite side to the side to which a load turns, and is arrange | positioned.

  As described above, in the vehicle drive device 1, the twisting direction of the teeth of the first driven gear 51a and the twisting direction of the teeth of the second driven gear 52a are opposite to each other on the second axis A2. In the first and second connection members 51 and 52 separately disposed on both sides in the axial direction L with respect to the fifth case portion 35, thrust loads in opposite directions are generated. Further, in the present embodiment, the fifth case portion 35 on the first axis A1 is formed by setting the twist direction of the teeth of the first drive gear 21a and the twist direction of the teeth of the second drive gear 22a in opposite directions. On the other hand, in the first drive member 21 and the second drive member 22 which are disposed separately on both sides in the axial direction L, thrust loads in opposite directions are generated. And as a result of having such a configuration, the first output member 81 and the second output member 82 separately disposed on both sides in the axial direction L with respect to the fifth case portion 35 on the third axis A3 are mutually separated. A thrust load in the opposite direction is generated, and the first input member 71 and the second input member 72 separately disposed on both sides in the axial direction L with respect to the fifth case portion 35 on the third axis A3 The configuration is such that a reverse thrust load is generated.

  That is, the vehicle drive device 1 of the present embodiment has a pair of corresponding rotating members on each axis (in the present embodiment, on the first axis A1, on the second axis A2, and on the third axis A3) The thrust loads in the directions opposite to each other are generated. In the present embodiment, the first connecting member 51 and the second connecting member 52, the first driving member 21 and the second driving member 22, the first output member 81 and the second output member 82, and the first input member 71. Each of the second input members 72 is a corresponding pair of rotating members. Thereby, one side of the axial direction L which can act on a portion (in the present embodiment, the fifth case portion 35) to which both of the thrust loads generated in the corresponding pair of rotating members in the case 3 are transmitted It is possible to reduce the biased load at each axis.

  Furthermore, in the present embodiment, a plane orthogonal to the axial direction L (in the present embodiment, a plane orthogonal to the axial direction L at the position of the fifth case portion 35 in the axial direction L) is taken as a plane of symmetry. The pair of rotating members are formed in shapes that are mirror images of each other, and are arranged at positions of mirror images of each other. As described above, in addition to the configuration in which thrust loads in opposite directions are generated in the corresponding pair of rotating members, bearings having the same specifications can be used as the corresponding pair of bearings. Also from this point, it is easy to miniaturize the entire device. In the present embodiment, the first bearing B1 and the fourth bearing B4, the second bearing B2 and the third bearing B3, the fifth bearing B5 and the eighth bearing B8, the sixth bearing B6 and the seventh bearing B7, and the ninth bearing Each of the B9 and twelfth bearings B12, the tenth bearings B10 and the eleventh bearings B11, the thirteenth bearings B13 and the sixteenth bearings B16, and the fourteenth bearings B14 and the fifteenth bearings B15 is a corresponding pair of bearings.

Other Embodiments
Next, other embodiments of the vehicle drive device will be described.

(1) In the above embodiment, the first driven gear 51a is disposed closer to the first axial side L1 than the central position in the axial direction L between the first bearing B1 and the second bearing B2, The configuration in which the 2 driven gear 52a is disposed closer to the second axial side L2 than the central position in the axial direction L between the third bearing B3 and the fourth bearing B4 has been described as an example. However, without being limited to such a configuration, the first driven gear 51a (the center position of the first driven gear 51a in the axial direction L) is the axial direction L between the first bearing B1 and the second bearing B2. The first driven gear 51a is disposed closer to the second axial side L2 than the central position in the axial direction L between the first bearing B1 and the second bearing B2. It can also be configured. In this case, it is preferable to secure a large capacity of the first bearing B1 compared to the configuration of the above embodiment, in consideration of the fact that a larger load can act on the first bearing B1 compared to the configuration of the above embodiment. It is. The second driven gear 52a (the central position in the axial direction L of the second driven gear 52a) is disposed at the central position in the axial direction L between the third bearing B3 and the fourth bearing B4, or The second driven gear 52a may be disposed closer to the first axial side L1 than the central position in the axial direction L between the third bearing B3 and the fourth bearing B4. In this case, it is preferable to secure a large capacity of the fourth bearing B4 compared to the configuration of the above-described embodiment, considering that a larger load may act on the fourth bearing B4 compared to the configuration of the above-described embodiment. It is.

(2) In the above embodiment, the second bearing B2, which is the bearing disposed on the first axial side L1 of the first bearing B1 and the second bearing B2, is the first driven in the second radial direction K2 A third bearing B3, which is a bearing disposed on the second axial side L2 of the third bearing B3 and the fourth bearing B4 and disposed so as to overlap the gear 51a, is a second bearing in a second radial direction K2 The configuration arranged to overlap with the driven gear 52a has been described as an example. However, without being limited to such a configuration, the first driven gear 51a is at a position different from the first driven gear 51a in the axial direction L so that the second bearing B2 does not overlap with the first driven gear 51a in the second radial direction K2. It can also be arranged. In this case, the first connection member 51 may be supported from the outside in the second radial direction K2 via the second bearing B2. The second driven gear 52a may be disposed at a position different from the second driven gear 52a in the axial direction L so that the third bearing B3 does not overlap the second driven gear 52a in the second radial direction K2. In this case, the second connection member 52 may be supported from the outside in the second radial direction K2 via the third bearing B3.

(3) In the above embodiment, the first drive gear 21a is disposed closer to the first axial side L1 than the central position in the axial direction L between the thirteenth bearing B13 and the fourteenth bearing B14. The configuration in which the two drive gears 22a are disposed closer to the second axial side L2 than the central position in the axial direction L between the fifteenth bearing B15 and the sixteenth bearing B16 has been described as an example. However, without being limited to such a configuration, the first drive gear 21a (the central position in the axial direction L of the first drive gear 21a) is the axial direction L between the thirteenth bearing B13 and the fourteenth bearing B14. The first drive gear 21a is disposed closer to the second axial side L2 than the central position in the axial direction L between the thirteenth bearing B13 and the fourteenth bearing B14. It can also be configured. Further, the second drive gear 22a (the central position in the axial direction L of the second drive gear 22a) is disposed at the central position in the axial direction L between the fifteenth bearing B15 and the sixteenth bearing B16, or The second drive gear 22a may be disposed closer to the first axial side L1 than the central position in the axial direction L between the fifteenth bearing B15 and the sixteenth bearing B16.

(4) In the above embodiment, the fourteenth bearing B14, which is the bearing disposed on the first axial side L1 of the thirteenth bearing B13 and the fourteenth bearing B14, is the first drive in the first radial direction K1. The first drive gear 21a is disposed at a position different from the first drive gear 21a in the axial direction L so as not to overlap with the gear 21a, and is a bearing disposed on the second axial side L2 of the fifteenth bearing B15 and the sixteenth bearing B16. The configuration in which the fifteenth bearing B15 is disposed at a position different from the second drive gear 22a in the axial direction L so as not to overlap the second drive gear 22a in the first radial direction K1 has been described as an example. However, without being limited to such a configuration, the first drive member 21 is supported from the inside of the first radial direction K1 via the fourteenth bearing B14, and the fourteenth bearing B14 is the first radial direction K1. It may be configured to be disposed so as to overlap with the first drive gear 21a visually. Further, the second drive member 22 is supported from the inside of the first radial direction K1 via the fifteenth bearing B15, and the fifteenth bearing B15 overlaps the second drive gear 22a in the first radial direction K1. It can also be configured to be placed in

(5) In the above embodiment, the sun gear (the first sun gear S1 and the second sun gear S2), the pinion gears (the first pinion gear P1 and the second pinion gear P2), and the ring gear (the first ring gear R1 and The configuration in which the second ring gear R2) is a spur gear has been described as an example. However, without being limited to such a configuration, the sun gear, the pinion gear, and the ring gear provided in the differential gear device 6 may be helical gears.

(6) In the above embodiment, the configuration in which the first connection member 51 and the second connection member 52 are indirectly supported with respect to the fifth case portion 35 has been described as an example. However, without being limited to such a configuration, the first connecting member 51 and the second connecting member 52 may be configured to be directly supported with respect to the fifth case portion 35. That is, as in the example shown in FIG. 6, the first connecting member 51 is directly supported by the fifth case portion 35 via the second bearing B2, and the second connecting member 52 is via the third bearing B3. Thus, the fifth case portion 35 can be directly supported. In this case, the "first transmission member" is the first connection member 51, the first driven gear 51a included in the first connection member 51 corresponds to the "first helical gear", and the first bearing B1 is the "first transmission member". The second bearing B2 corresponds to a "second support bearing". Further, in this case, the "second transmission member" is the second connection member 52, the second driven gear 52a included in the second connection member 52 corresponds to the "second helical gear", and the third bearing B3 is It corresponds to a "third support bearing", and the fourth bearing B4 corresponds to a "fourth support bearing". And, in this case, “the axis on which the first transmission member and the second transmission member are arranged” is the second axis A2, and the second radial direction K2 is “the first transmission member and the second transmission member are arranged. It corresponds to “radial direction with reference to the axis”. In the example shown in FIG. 6, the first drive member 21 and the second drive member 22 are directly supported by the fifth case portion 35 as in the above embodiment. Therefore, in the example shown in FIG. 5, the first drive member 21 and the second drive member 22 correspond to the “first transmission member” and the “second transmission member” coaxially disposed, and the first connection member 51. The second connection member 52 corresponds to the “first transmission member” and the “second transmission member” coaxially disposed. Note that unlike the above embodiment, the first drive member 21 and the second drive member 22 are indirectly (that is, via the support member 40 fixed to the case portion 30) to the fifth case portion 35. It may be a supported configuration.

(7) In said embodiment, the 5th case part 35 demonstrated as an example the structure corresponded to "the wall part with which a case is provided." However, without being limited to such a configuration, the support member 40 fixed to the case portion 30 may be configured to correspond to “a wall portion provided to the case”. For example, a support member 40 having a support function of a rotation member similar to that of the fifth case portion 35 is provided instead of the fifth case portion 35, and the support member 40 corresponds to "a wall portion of the case". can do.

(8) In the above embodiment, the configuration in which the axial first side L1 corresponds to the "first side" and the axial second side L2 corresponds to the "second side" has been described as an example. However, without being limited to such a configuration, the axial second side L2 may correspond to the "first side", and the axial first side L1 may correspond to the "second side". . In this case, the direction of the thrust load received by each gear at the time of forward power running of the vehicle is opposite to the direction shown in FIG.

(9) In the above embodiment, the first carrier C1 and the second sun gear S2 are connected, and the first sun gear S1 and the second carrier C2 are connected, whereby the first planetary gear mechanism 61 and the first carrier C2 are connected. The configuration has been described as an example in which the two-planet gear mechanism 62 includes four rotating elements (E1 to E4) as a whole to integrally perform differential operation. However, without being limited to such a configuration, for example, the first carrier C1 and the second ring gear R2 are connected, and the first ring gear R1 and the second carrier C2 are connected, for example. The gear mechanism 61 and the second planetary gear mechanism 62 may be configured to include four rotating elements (E1 to E4) as a whole to integrally perform differential operation. In this case, the first rotary electric machine 11 is drivably connected to the first sun gear S1, and the first connection member 51 is drivably connected to the first carrier C1 and the second ring gear R2 that rotate integrally, and the second connection member 52 is integrated. The second rotary electric machine 12 is drivingly connected to the first ring gear R1 and the second carrier C2, and the second rotating electric machine 12 is drivingly connected to the second sun gear S2. In order, the first rotating element E1 drivingly connected to the first rotating electric machine 11, the second rotating element E2 drivingly connected to the first connecting member 51, and the third rotating element E3 drivingly connected to the second connecting member 52 And the structure which becomes order of the 4th rotation element E4 drive-connected to the 2nd rotary electric machine 12 is realizable.

(10) In the above embodiment, the configuration in which both the first planetary gear mechanism 61 and the second planetary gear mechanism 62 are single pinion type planetary gear mechanisms has been described as an example. However, without being limited to such a configuration, for example, both of the first planetary gear mechanism 61 and the second planetary gear mechanism 62 may be double pinion type planetary gear mechanisms. In this case, the first carrier C1 and the second ring gear R2 are connected, and the first ring gear R1 and the second carrier C2 are connected, so that the first planetary gear mechanism 61 and the second planetary gear mechanism 62 As a whole, four rotation elements (E1 to E4) can be provided to perform differential operation integrally. In this case, the first rotary electric machine 11 is drivably connected to the first sun gear S1, and the first connection member 51 is drivably connected to the first ring gear R1 and the second carrier C2 that rotate integrally, and the second connection member 52 is integrated. In the same manner as in the above-described embodiment, the second electric rotating machine 12 is drivingly connected to the first carrier C1 and the second ring gear R2 that rotate in a rotating manner, and the second rotating electric machine 12 is drivingly connected to the second sun gear S2. In order, the first rotating element E1 drivingly connected to the first rotating electric machine 11, the second rotating element E2 drivingly connected to the first connecting member 51, and the third rotating element E3 drivingly connected to the second connecting member 52 And the structure which becomes order of the 4th rotation element E4 drive-connected to the 2nd rotary electric machine 12 is realizable.

(11) In the above embodiment, the transmission device 2 transmits the torque of the first rotating electric machine 11 to both the first connecting portion 7 and the second connecting portion 8, and the torque of the second rotating electric machine 12 is the first The configuration for transferring to both the connecting portion 7 and the second connecting portion 8 has been described as an example. However, without being limited to such a configuration, the transmission device 2 transmits the torque of the first rotary electric machine 11 only to the first connection portion 7 of the first connection portion 7 and the second connection portion 8. Alternatively, the torque of the second rotating electrical machine 12 may be transmitted only to the second connecting portion 8 of the first connecting portion 7 and the second connecting portion 8. That is, the power transmission path between the first rotary electric machine 11 and the first connection portion 7 and the power transmission path between the second rotary electric machine 12 and the second connection portion 8 can be separated. .

  For example, without connecting the first planetary gear mechanism 61 and the second planetary gear mechanism 62 as in the above embodiment, the first planetary gear mechanism 61 and the second planetary gear mechanism 62 perform differential operation independently of each other. The power transmission path between the first rotary electric machine 11 and the first connection portion 7 and the power transmission path between the second rotary electric machine 12 and the second connection portion 8 are separated by The configuration can be realized. In this case, the first planetary gear mechanism 61 includes a first rotating element E1 drivingly connected to the first rotating electric machine 11, a second rotating element E2 drivingly connected to the first connecting portion 7, and a fifth rotating element , And the second planetary gear mechanism 62 includes a third rotating element E3 drivingly connected to the second connecting portion 8, a fourth rotating element E4 drivingly connected to the second rotating electric machine 12, and a sixth rotating element And. That is, differential gear device 6 (planet gear device 60) has six rotating elements as a whole. In this case, for example, the fifth rotation element may be fixed to the non-rotation member, and the sixth rotation element may be fixed to the non-rotation member.

  In addition, as in the above-described embodiment, the transmission device 2 does not include the differential gear device 6, and the transmission device 2 does not include the differential gear device 6 so that the first rotary electric machine 11 and the first connection are connected. A configuration may be realized in which the power transmission path between the unit 7 and the power transmission path between the second rotary electric machine 12 and the second connecting portion 8 are separated. That is, unlike the above embodiment, the transmission device 2 may be configured without the differential gear device 6. For example, a gear or a gear mechanism (a mechanism having a plurality of gears such as a counter gear mechanism, and the same applies hereinafter) in which the transmission device 2 couples the first drive gear 21a and the first driven gear 51a, and a second drive gear 22a. And the second driven gear 52a may be configured to include a gear or a gear mechanism. Further, as shown in FIG. 6 as an example, the first drive gear 21a and the first driven gear 51a may be engaged with each other, and the second drive gear 22a and the second driven gear 52a may be engaged with each other.

(12) In the above embodiment, the first drive gear 21a meshes with the first input gear 71a, and the second drive gear 22a meshes with the second input gear 72a. However, without being limited to such a configuration, the first drive gear 21a and the first input gear 71a are connected via another gear or gear mechanism, and the second drive gear 22a and the second input gear 72a May be connected via another gear or gear mechanism.

(13) In the above embodiment, the configuration in which the first rotary electric machine 11 is used as the first drive source and the second rotary electric machine 12 is used as the second drive source has been described as an example. However, without being limited to such a configuration, a drive source other than the rotating electrical machine can be used as one or both of the first drive source and the second drive source. As a drive source used in place of the rotating electrical machine, for example, an internal combustion engine can be exemplified. The internal combustion engine is a motor (such as a gasoline engine or a diesel engine) driven by combustion of fuel inside the engine to take out the power.

(14) Note that the configurations disclosed in each of the above-described embodiments may be combined with the configurations disclosed in the other embodiments and applied as long as no contradiction occurs (the embodiments described as the other embodiments Combinations are also possible. With regard to other configurations, the embodiments disclosed herein are merely exemplary in all respects. Therefore, various modifications can be made as appropriate without departing from the spirit of the present disclosure.

[Summary of the above embodiment]
Hereinafter, an outline of the vehicle drive device described above will be described.

  The vehicle drive device (1) drives a first drive source (11), a second drive source (12) rotatable independently of the first drive source (11), and a first wheel (W1) The first connecting portion (7) to be connected, the second connecting portion (8) drivingly connected to the second wheel (W2), and the torque of the first drive source (11) 7) A transmission device (2) for transmitting the torque of the second drive source (12) to at least the second connection portion (8) and a case (3) for housing the transmission device (2) And the transmission device (2) includes a first transmission member (21, 51) disposed on one side in an axial direction (L) with respect to the wall portion (35) of the case (3). The first transmission member (21, 51) is coaxially disposed on the other side of the axial direction (L) with respect to the wall portion (35); A transmission member (22, 52), and the first transmission member (21, 51) is a first screw engaged with a helical gear provided on another transmission member of the transmission device (2) Gear (21a, 51a) and is directly supported by the wall portion (35) through a bearing, and the second transmission member (22, 52) includes the other transmission member (2). A second helical gear (22a, 52a) engaged with a helical gear provided on the transmission member and directly supported by the wall (35) through a bearing, the first helical gear The twisting direction of the teeth of the gear (21a, 51a) and the twisting direction of the teeth of the second helical gear (22a, 52a) are opposite to each other.

According to this configuration, the twist direction of the teeth of the first helical gear (21a, 51a) provided in the first transmission member (21, 51) and the second tooth provided in the second transmission member (22, 52) For example, the twisting direction of the teeth of the gear (22a, 52a) is reversed. Therefore, in a state where the transmission device (2) is transmitting torque, the direction of the thrust load received by the first helical gear (21a, 51a) and the thrust received by the second helical gear (22a, 52a) The directions of the load can be opposite to each other. That is, the first transmission member (21, 51) and the second transmission member (22, 52) are coaxially divided on both sides in the axial direction (L) with respect to the wall portion (35) of the case (3). ) Because the direction of the thrust load generated in each of the above can be opposite to each other, thus reducing the load that is biased to one side in the axial direction (L) that can act on the wall portion (35). It becomes possible to suppress. As a result, compared with the case where the twisting direction of the teeth of the first helical gear (21a, 51a) and the twisting direction of the teeth of the second helical gear (22a, 52a) are in the same direction, the wall The strength required for the part (35) can be reduced, and accordingly, the overall size of the apparatus can be reduced.
As described above, according to the above configuration, the first transmission member (21, 51) is disposed coaxially with the wall portion (35) of the case (3) divided on both sides in the axial direction (L). And when the second transmission member (22, 52) is provided with a helical gear and directly supported by the wall (35) via a bearing, the overall size of the device can be reduced. A possible vehicle drive (1) can be realized.

  Here, the first transmission member (21, 51) is a first drive member (21) that rotates integrally with the first drive source (11), and the second transmission member (22, 52) is Preferably, the second drive member (22) rotates integrally with the second drive source (12).

  According to this configuration, the first drive member (21) and the second drive member (22) are coaxially divided on both sides in the axial direction (L) with respect to the wall portion (35) of the case (3). When arranged, each of the first drive member (21) and the second drive member (22) comprises a helical gear and is directly supported on the wall (35) via a bearing. Thus, the vehicle drive device (1) capable of achieving downsizing of the entire device can be realized.

  The first transmission member (21, 51) is a first connection member (51) that rotates integrally with the first connection portion (7), and the second transmission member (22, 52) is It is preferable that it is a 2nd connection member (52) rotated integrally with the said 2nd connection part (8).

  According to this configuration, the first connection member (51) and the second connection member (52) are coaxially divided on both sides in the axial direction (L) with respect to the wall portion (35) of the case (3). When arranged, each of the first connection member (51) and the second connection member (52) includes a helical gear and is directly supported by the wall portion (35) via a bearing. Thus, the vehicle drive device (1) capable of achieving downsizing of the entire device can be realized.

  The first transmission member (21, 51) is rotatably supported at two places in the axial direction (L) by the first support bearing (B13, B1) and the second support bearing (B14, B2). The second transmission member (22, 52) is rotatably supported at two places in the axial direction (L) by the third support bearing (B15, B3) and the fourth support bearing (B16, B4), The first helical gear (21a, 51a) is closer to the central position in the axial direction (L) between the first support bearing (B13, B1) and the second support bearing (B14, B2). The first helical gear (21a, 51a) is disposed close to the first side (L1) opposite to the side to which the thrust load to which the first helical gear (21a, 51a) is directed is directed, and the second helical gear (22a, 52a) are the third support bearing (B15, B3) and the fourth support bearing B16, B4) are preferably disposed closer to the second side (L2) opposite to the first side (L1) than the central position in the axial direction (L) between B16 and B4). .

According to this configuration, the first helical gear (21a, 51a) is at the central position in the axial direction (L) between the first support bearing (B13, B1) and the second support bearing (B14, B2). Since the first helical gear (21a, 51a) receives the first load (l1), the first helical gear (21a, 51a) is disposed closer to the first side (L1) opposite to the side to which the thrust load is directed. Of the first support gear (21a, 51a) among the first support bearing (B13, B1) and the second support bearing (B14, B2), the radial load received by the gear (21a, 51a) It can be made to act on a different bearing from the bearing on which a load acts large. Therefore, during forward power running of the vehicle, the first load bearing (B13, B1) and the second support bearing (B14, B2) support the thrust load and radial load that the first helical gear (21a, 51a) receives. To avoid sharing these thrust loads and radial loads on one of the first support bearing (B13, B1) and the second support bearing (B14, B2). The first support bearing (B13, B1) and the second support bearing (B14, B2) can be miniaturized in a well-balanced manner.
Further, according to the above configuration, the second helical gear (22a, 52a) is in the axial direction (L) between the third support bearing (B15, B3) and the fourth support bearing (B16, B4). Is disposed closer to the second side (L2) than the center position of. As described above, since the twist direction of the teeth of the first helical gear (21a, 51a) and the twist direction of the teeth of the second helical gear (22a, 52a) are opposite to each other, the second side L2) is the opposite side in the axial direction (L) to the side to which the thrust load received by the second helical gear (22a, 52a) is directed during forward power running of the vehicle. Therefore, at the time of forward power running of the vehicle, the support of the thrust load and the radial load which the second helical gear (22a, 52a) receives, the third support bearing (B15, B3) and the fourth support bearing (B16, B4) To avoid sharing these thrust loads and radial loads on one of the third support bearing (B15, B3) and the fourth support bearing (B16, B4). The third support bearing (B15, B3) and the fourth support bearing (B16, B4) can be miniaturized in a well-balanced manner.
During forward power regeneration of the vehicle or during reverse power transmission, the direction of the thrust load received by the first helical gear (21a, 51a) or the second helical gear (22a, 52a) corresponds to that during forward power running of the vehicle. Although the direction is reversed, the frequency of forward regeneration and reverse power running is generally lower than the frequency of forward power running, and the magnitude of the torque transmitted by the transmission device (2) at the time of forward regeneration and reverse power running of the vehicle is also forward of the vehicle. Generally smaller than the magnitude of the torque transmitted by the transmission device (2) during powering. Therefore, the first support bearing (B13, B1) supporting the first transmission member (21, 51) that the direction of the thrust load is opposite to that during forward power regeneration of the vehicle during regenerative regeneration or reverse power running of the vehicle. And the second support bearing (B14, B2), the third support bearing (B15, B3) for supporting the second transmission member (22, 52), and the capacity (B16, B4) required for the fourth support bearing (B16, B4) The impact on the size of the load that can be supported is relatively small.

  As described above, the first helical gear (21a, 51a) is the axial direction (L) between the first support bearing (B13, B1) and the second support bearing (B14, B2). And the second helical gear (22a, 52a) comprises the third support bearing (B15, B3) and the fourth support bearing (B16, B4). And the first support bearing (B13, B1) and the second support bearing (B14, B2), which are disposed on the second side (L2) than the central position in the axial direction (L) between Of the first transmission member (21, 51) and the second transmission member (22, 52) are disposed on the first side (L1) of the shaft (A1, A2) Overlap with the first helical gear (21a, 51a) in the radial direction (K1, K2) as a reference And the bearings disposed on the second side (L2) of the third support bearings (B15, B3) and the fourth support bearings (B16, B4) are arranged in the radial direction (K1, K2). Preferably, the second helical gear (22a, 52a) is disposed so as to overlap with the second helical gear (22a, 52a).

According to this configuration, most of the radial load received by the first helical gear (21a, 51a) is the first of the first support bearing (B13, B1) and the second support bearing (B14, B2). 1) The helical gear (21a, 51a) can be configured to act on a different bearing from the one on which the thrust load received by the helical gear (21a, 51a) acts largely. Therefore, during forward power running of the vehicle, the first load bearing (B13, B1) and the second support bearing (B14, B2) support the thrust load and radial load that the first helical gear (21a, 51a) receives. Can be shared more appropriately. Similarly, at the time of forward power running of the vehicle, the support of the thrust load and radial load which the second helical gear (22a, 52a) receives, the third support bearing (B15, B3) and the fourth support bearing (B16, B4) Can be allocated more appropriately.
Further, according to the above configuration, one of the first support bearing (B13, B1) and the second support bearing (B14, B2) is the first helical gear (21a, 51a) in the radial direction (K1, K2). ) And one of the third support bearing (B15, B3) and the fourth support bearing (B16, B4) has a second helical gear (22a) in the radial direction (K1, K2). , 52a), so that the entire apparatus can be miniaturized in the axial direction (L).

  In the vehicle drive device (1) of each configuration described above, the transmission device (2) includes a planetary gear type differential gear device (6), and a sun gear (S1, S1) included in the differential gear device (6). S2), pinion gears (P1, P2), and ring gears (R1, R2) are preferably spur gears.

According to this configuration, the load received by the sun gear (S1, S2), the pinion gear (P1, P2), and the ring gear (R1, R2) included in the differential gear device (6) can mainly be the radial load. . Therefore, the configuration for supporting the gears of the differential gear device (6) in the axial direction (L) is simplified to reduce the overall size of the device and reduce the manufacturing cost of the vehicle drive device (1). Can.
In this configuration, the differential is compared with the case where the sun gear (S1, S2), the pinion gear (P1, P2), and the ring gear (R1, R2) included in the differential gear device (6) are helical gears. Although the gear noise when the gear device (6) performs the differential operation may increase, the configuration in which the differential gear device (6) does not perform the differential operation when the vehicle travels straight (that is, the differential gear when the vehicle travels straight By making the respective rotating elements of (6) rotate at the same speed), the influence of gear noise can be reduced by limiting the scene in which the differential gear device (6) performs the differential operation at the time of turning of the vehicle. Can.

  In addition, the transmission device (2) is a difference having a first rotating element (E1), a second rotating element (E2), a third rotating element (E3), and a fourth rotating element (E4) in the order of rotational speed. The first drive unit (11) is drivingly connected to the first rotary element (E1), and the first connection portion (7) is driven to the second rotary element (E2). It is preferable that the second connection portion (8) is drivingly connected to the third rotating element (E3) and the second driving source (12) is drivingly connected to the fourth rotating element (E4). It is.

  According to this configuration, the torque of the first drive source (11) and the second drive source (12) is distributed to the first connection portion (7) and the second connection portion (8) by the transmission device (2). As it can be transmitted, the power transmission path between the first drive source (11) and the first connection portion (7), and the power between the second drive source (12) and the second connection portion (8) The traveling performance at the time of turning of the vehicle can be improved as compared with the case where the transmission path is separated.

  The vehicle drive device according to the present disclosure only needs to be able to exhibit at least one of the above-described effects.

1: Vehicle drive device 2: Transmission device 3: Case 6: Differential gear device 7: First connecting portion 8: Second connecting portion 11: first rotary electric machine (first drive source)
12: Second rotary electric machine (second drive source)
21: first drive member (first transmission member)
21a: first drive gear (first helical gear)
22: Second drive member (second transmission member)
22a: Second drive gear (second helical gear)
35: Fifth case portion (wall portion provided in the case)
51: first connection member (first transmission member)
51a: first driven gear (first helical gear)
52: Second connecting member (second transmitting member)
52a: Second driven gear (second helical gear)
A1: first shaft (shaft on which the first transmission member and the second transmission member are disposed)
A2: Second axis (an axis on which the first transmission member and the second transmission member are disposed)
B1: first bearing (first support bearing)
B2: Second bearing (second support bearing)
B3: Third bearing (third support bearing)
B4: Fourth bearing (fourth support bearing)
B13: Thirteenth bearing (first support bearing)
B14: 14th bearing (2nd support bearing)
B15: 15th bearing (third support bearing)
B16: 16th bearing (4th support bearing)
E1: first rotation element E2: second rotation element E3: third rotation element E4: fourth rotation element K1: first radial direction (diameter based on the axis on which the first transmission member and the second transmission member are arranged direction)
K2: second radial direction (radial direction based on the axis on which the first transmission member and the second transmission member are disposed)
L: axial direction L1: axial direction first side (first side)
L2: Axial direction second side (second side)
P1: 1st pinion gear (pinion gear)
P2: Second pinion gear (pinion gear)
R1: First ring gear (ring gear)
R2: 2nd ring gear (ring gear)
S1: First sun gear (sun gear)
S2: Second sun gear (sun gear)
W1: first wheel W2: second wheel

Claims (7)

The first drive source,
A second drive source rotatable independently of the first drive source;
A first connecting portion drivingly connected to the first wheel;
A second connecting portion drivingly connected to the second wheel;
A transmission device for transmitting the torque of the first drive source to at least the first connection portion and transmitting the torque of the second drive source to at least the second connection portion;
And a case for housing the transmission device.
The transmission device is coaxial with the first transmission member, and a first transmission member disposed on one side in the axial direction with respect to the wall portion provided in the case, and the other side in the axial direction with respect to the wall portion. And a second transmission member disposed on the
The first transmission member includes a first helical gear that meshes with a helical gear provided on another transmission member of the transmission device, and is directly supported by the wall through a bearing.
The second transmission member includes a second helical gear engaged with a helical gear provided on another transmission member included in the transmission device, and is directly supported by the wall through a bearing.
The drive device for a vehicle, wherein a twist direction of the teeth of the first helical gear and a twist direction of the teeth of the second helical gear are opposite to each other. The first transmission member is a first drive member that rotates integrally with the first drive source,
The vehicle drive device according to claim 1, wherein the second transmission member is a second drive member that rotates integrally with the second drive source. The first transmission member is a first connection member that rotates integrally with the first connection portion,
The vehicle drive device according to claim 1, wherein the second transmission member is a second connection member that rotates integrally with the second connection portion. The first transmission member is rotatably supported at two places in the axial direction by a first support bearing and a second support bearing,
The second transmission member is rotatably supported at two places in the axial direction by a third support bearing and a fourth support bearing,
The first helical gear has a thrust load received by the first helical gear during forward power running of the vehicle than a central position in the axial direction between the first support bearing and the second support bearing. It is placed close to the first side which is the opposite side to the facing side,
The second helical gear is disposed closer to the second side opposite to the first side than the axial center position between the third support bearing and the fourth support bearing. The vehicle drive device according to any one of claims 1 to 3, wherein The bearing disposed on the first side of the first support bearing and the second support bearing is the bearing in the radial direction based on the axis on which the first transmission member and the second transmission member are disposed. Arranged to overlap with the first helical gear,
The bearing disposed on the second side of the third support bearing and the fourth support bearing is disposed so as to overlap the second helical gear in the radial direction. The drive device for vehicles as described. The transmission device comprises a planetary gear type differential gear device,
The vehicle drive device according to any one of claims 1 to 5, wherein the sun gear, the pinion gear, and the ring gear included in the differential gear device are spur gears. The transmission device comprises a differential gear device having a first rotation element, a second rotation element, a third rotation element, and a fourth rotation element in order of rotational speed,
The first driving source is drivingly connected to the first rotating element,
The first connection portion is drivingly connected to the second rotating element;
The second connection portion is drivingly connected to the third rotating element;
The vehicle drive device according to any one of claims 1 to 6, wherein the second drive source is drivingly connected to the fourth rotating element.

Images