EP2024197A1

EP2024197A1 - Transmission for transmitting a drive torque from one drive shaft to two output shafts

Info

Publication number: EP2024197A1
Application number: EP07729511A
Authority: EP
Inventors: Alois BÖCK; Detlef Baasch; Robert Peter; Florian Knedler; Michael Donaubauer
Original assignee: ZF Friedrichshafen AG
Current assignee: ZF Friedrichshafen AG
Priority date: 2006-05-30
Filing date: 2007-05-25
Publication date: 2009-02-18
Also published as: DE102006025062A1; WO2007138001A1; US20090192006A1; JP2009539044A

Abstract

The invention relates to a transmission, in particular a rear axle transmisssion for transmitting a drive torque from one drive shaft (2) to two output shafts (3, 5) by means of a differential unit (15) and a continuously variable device (14) for influencing the distribution rate of the drive torque to the output shafts (3, 5), said device being activated by means of at least one motor (37). The differential unit (15) comprises a differential (17) and a differential cage (19) that is operatively connected to the drive shaft (2) and the device (14) for influencing the distribution rate of the drive torque has at least one planetary gear set as the transmission ratio stage (39), which is operatively connected to the differential cage (19) and an associated output shaft (3 and 5) and which has a braking device (61). According to the invention, the braking device (51) is laterally offset in the direction of a planetary gear axis (Z) and lies next to planetary gears (69, 71) of the transmission ratio stage (39), at least approximately inside the radial extension area of the planetary gears (69, 71) and around the longitudinal axis (X) of the output shafts (3, 5).

Description

Transmission unit for guiding a drive torque from a drive shaft to two output shafts

The invention relates to a Getriebeeinheif for guiding a drive torque from a drive shaft to two output shafts according to the closer defined in the preamble of claim 1. Art.

Such a gear unit is known for example from FR 2 864 190. It describes an asymmetrical transfer case which distributes a drive torque generated by a drive motor by means of a differential unit to two wheels connected to an output shaft. A differential of the differential unit divides the drive torque evenly on the two output shafts.

In order to achieve a different torque distribution required, for example, due to cornering, each of the two output shafts is associated with a so-called torque vectoring unit with a planetary set, which is arranged between a differential cage of the differential unit and the respective output shaft and with which to the respective Output shaft acting drive torque can be influenced. For this purpose, the web of the planetary gear set to generate a so-called Torque-Vectoring- be braked by means of a brake relative to a transmission housing, whereby the supported on the gearbox torque vectoring torque by means realized with the planetary gears and the sun gears of the planetary gear set stage on the respective wheel is guided.

The respective output shaft and the differential cage are in each case fixedly connected to a sun gear of the planetary gear set, wherein the sun gears each have a planet gear arranged on the planet. menwirken. Furthermore, a planetary carrier of the planetary gearset is rotatably connected to the planets, wherein a bearing of the planet carrier is located in a region of the planetary gearset facing away from a transmission center. The brake, which is arranged on the planet carrier of the planetary gear set, is arranged with respect to a longitudinal axis of the output shafts radially outside of an axis of the planets.

In the case of the gear unit known from FR 2 864 190 with an arrangement of a braking device described above, the brake subsequently takes on a very large installation space, which results in correspondingly high material and manufacturing costs.

The present invention has for its object to design a transmission unit of the type mentioned above such that a braking device for operating a device for influencing the degree of distribution of the drive torque to the driven wheels while ensuring the secure functionality with a small size is inexpensive to deploy,

According to the invention this object is achieved with a gear unit for guiding a drive torque to two output shafts with the features of claim 1.

It is thus a transmission unit, in particular a Hinterachsgetriebeeinheit, provided for guiding a drive torque from a drive shaft to two output shafts via a differential unit and a switchable by means of at least one motor, continuously adjustable device for influencing the degree of distribution of the drive torque to the output shafts, wherein the differential unit is a differential and a differential cage operatively connected to the drive shaft, and the device for influencing the degree of distribution of the drive torque sung tion of the degree of distribution of the drive torque has at least one planetary gear set as a translation stage, which is operatively connected to the differential cage and an associated output shaft and which has a braking device. It is inventively provided that the braking device is laterally offset in the direction of a planetary axis next to Planenten the translation stage and at least approximately within a radial Erstre- ckungsbereiches of the planet around a longitudinal axis of the output shafts.

In a gear unit designed according to the invention, the braking device and in particular its actuator due to the positioning laterally next to the planets and radially in the vicinity of the longitudinal axis of the output shafts advantageously be made very small, thereby saving space and also the manufacturing costs are reduced. By reducing the space of the brake device, the entire transmission unit can be made smaller or space for other components can be created.

Depending on the application, it may be expedient if the braking device is arranged with respect to a transmission center axis which is perpendicular to the longitudinal axis of the output shafts either in a region facing a transmission center or in a region remote from the transmission center next to the planet.

Preferably, the braking device with a switching element such. Depending on the space requirements imposed on the gear unit technical requirements, the switching element can both on one of the transmission center facing away on one side of the gearset and the planetary gear set in the direction of the planetary axis between be arranged the means for axial adjustment and the planetary gear set. Furthermore, the device for axial adjustment can also be arranged on one of the transmission center facing away as well as on a side facing away from the transmission center side planetary gear set in the direction of the planetary axis between the switching element and the planetary gearset.

In an advantageous embodiment of the transmission unit according to the invention, the switching element of the braking device is designed as a multi-disc brake. Here, the smaller dimensionability of the braking device in smaller diameters of the slats affects. As a result of the positioning of the brake device according to the invention occur in the multi-disc brake when not in operation only small drag losses, since the fins rotate at about the wheel speed, and the friction speeds are relatively low at high speeds.

The multi-disc brake can be actuated by means of an operable by at least one motor for axial adjustment such that the drive shaft of the motor interacts with a pivot wheel of the device for axial adjustment, wherein the swivel wheel formed by particular trained as balls rolling elements in depth varying grooves of the swivel wheel and in correspondingly arranged grooves of a housing fixed ball ramp disc of the device for axial adjustment, cooperating with the ball ramp disc.

If the drive shaft of the motor interacts with the swivel wheel of the axial adjustment device by means of an at least single-stage spur gear stage, a very simple mechanism for actuating the shifting element can be realized. With regard to the device for axial adjustment of the multi-disc brake, the positioning of the brake device according to the invention has the advantageous effect that there is greater freedom in the choice of manufacturing technology of the actuator and the manufacturing costs can be reduced accordingly. When using a ball ramp disk as an actuator, the pressure axis of the ball ramp disk can advantageously be in the range of the diameter of the slats.

Further advantages and advantageous developments of the invention will become apparent from the claims and the embodiment described in principle with reference to the drawings. It shows:

Figure 1 is a partially schematic sectional view of a Hinterachsgetriebeeinheit of a motor vehicle with a planetary gear set designed as a translation stage, which is formed with a with a switching element and a switching element actuated means for axial adjustment formed braking device. and

2 shows a partially sectional view of the Hintersachssgetriebeeinheit of FIG. 1 with an alternative arrangement of the braking device.

In Fig. 1, a portion of a transmission unit 1 is shown which one of a only schematically illustrated engine or internal combustion engine 10, transmitted via a drive shaft 2 drive torque to a first output shaft 3 and a coaxial thereto and with respect to the drive shaft 2 symmetrically arranged second Abfriebswelle 5 distributed. The gear unit 1 is provided for installation in a motor vehicle and is designed in the embodiment shown as Hinterachsgetriebeeinheit, but it is also conceivable that a substantially analog gear unit is used as Vorderachsgetriebeeinheit. It is also conceivable to use the present transmission unit both as a front axle transmission unit and as a rear axle transmission unit, for example in a four-wheel drive motor vehicle.

The output shafts 3 and 5, which are rotatably mounted about a common longitudinal axis X, are connected at their free ends in each case with a vehicle wheel, not shown, wherein in the installed state of the Hinterachsgetriebeeinheit 1 a vehicle with respect to the output shaft 3 on a viewed in the vehicle front left Transmission side 7 and a vehicle wheel with respect to the output shaft 5 on a right side gear 9 is located.

The Hinterachsgetriebeeinheit 1 includes a transmission housing 11, which with a substantially surrounding the drive shaft 2 front gear housing part 12, with one of the left side gear 7 associated side gear housing part 13 from which protrudes the first output shaft 3 side, and with a not shown the right side of the transmission 9 associated lateral gear housing part, from which the second output shaft 5 protrudes laterally, is formed.

The rear axle transmission unit 1 distributes the drive torque transmitted from the drive shaft 2 to the two output shafts 3 and 5 and can thereby also effect an uneven torque distribution on the two output shafts 3 and 5 and thus actively improve the driving characteristics. The drive torque is introduced from the drive shaft 2 in a differential unit 15, which with a differential 17 and a differential cage 19th is formed and connected to a device 14 for influencing the drive torque to the output shafts 3 and 5.

For operative connection between the drive shaft 2 and the differential cage 19 is fixedly connected to the drive shaft 2 drive pinion 21 with a fixed connected to the differential cage 19 ring gear 23 into engagement, wherein the differential cage 19 is rotatably mounted about the longitudinal axis X and in the transmission housing 11th supported.

The differential 17 is formed in a manner known per se with two output-side bevel gears 25 and 27 connected to the respective output shaft 3 and 5 and with two bevel gears 29 and 31 meshing with the two bevel gears 25 and 27. The two bevel gears 29 and 31 are rotatably mounted on a bolt 33 which is fixed in the differential cage 19 with respect to a rotation about the longitudinal axis X.

Fig. 1 shows two embodiments of the drive side bevel gears 29 and 31 and the cooperating output side bevel gears 27 and 25, which are each engaged with each other, the expert can select an alternative according to the particular application.

If a drive torque is transmitted by the internal combustion engine 10 via the drive shaft 2, this is transmitted via the drive pinion 21 to the ring gear 23 and the differential cage 19 firmly connected thereto. By means of the bolt 33 of the differential 17 connected to the differential cage 19, the drive torque is transmitted to the drive-side bevel gears 29 and 31 of the differential 17, which in turn transmit the drive torque the abgetriefasseitigen bevel gears 25 and 27 and thus drive the Abfriebswellen 3 and 5 drive.

If there is no differential speed between the two output shafts 3 and 5, the bevel gears 29 and 31 rotate with the bolt 33 exclusively about the longitudinal axis X. Should an output shaft in the installed state, for example, rotate faster than when cornering at different speeds rotating vehicle wheels the other, then rotate the drive side bevel gears 29 and 31 to compensate for the speed difference around the bolt 33, wherein the bolt 33 further passes the drive torque via its rotation about the longitudinal axis X on the two output shafts 3, 5.

In addition to balancing a different rotational speed of the two output shafts 3 and 5, a different torque distribution to the two output shafts 3 and 5 can be achieved with the rear axle transmission unit 1. For this purpose, the device 14 is provided for influencing the drive torque to the output shafts 3 and 5 with two symmetrical to the transmission axis Y arranged identical Torque vectoring units, of the two torque vectoring units in Fig. 1, only the left transmission side 7 associated with torque-representing unit 35, which will be described below.

The torque vectoring units are arranged in the gear housing 11 and are in the present case continuously adjusted and actuated by an associated, switchable electric motor 37.

As can be seen in the illustrated torque vectoring unit 35, it has a planetary gear set formed as an upper stage 39 and an actuatable by the electric motor 37 brake device 51, wherein the Translation stage 39 is formed with two sun gears 61 and 63, of which a first sun gear 61 fixed to the differential cage 19 and of which a second sun gear 63 is fixedly connected to the output shaft 3. The sun gears 61 and 63 cooperate with present three rotatably mounted on a planetary carrier 65 planet, of which two planets 69 and 71 are visible, and which have a continuous toothing 73.

The braking device 51 is formed with a designed as a multi-disc brake 77 switching element and a cooperating with the switching element means 87 for axial adjustment. The with respect to their transmission capability infinitely adjustable multi-disc brake 77 has arranged on the planet carrier 65 inner plates 75 which cooperate with defined in the gear housing 11 outer plates 79 by their axial adjustability such that they can be brought into a frictional contact or from a frictional contact.

The electric motor 37 actuates the axial adjustment device 87 provided with a swivel wheel 89 and a ball ramp disk 91 via an idler gear 85 which is driven by its drive shaft 83 and which is connected on one side to the drive shaft 83 of the electric motor 37 and on the other side with the pivot wheel 89 of the means 87 for axial adjustment is engaged.

The intermediate gear 85 serves to set a gear ratio between the electric motor 37 and the swing gear 89, which is determined by a number of teeth of the electric motor 37 and a number of teeth of the pivot wheel 89, and for bridging the distance of the electric motor 37 from the longitudinal axis X, wherein the distance is bridged in particular by the diameter of the intermediate gear 85. It is left to the skilled person to use for bridging the distance between the electric motor and the longitudinal axis in addition to the embodiment formed as an intermediate single-stage spur gear according to the particular space conditions also a two-stage or multi-stage spur gear.

The ball ramp disk 91, which is mounted so as to be non-rotatable and axially displaceable in the gearbox housing 11, has at least three grooves 93 which vary in their depth over their radius. In with the grooves 93 of the ball ramp disk 91 corresponding also varying in depth grooves 95 of the pivot wheel 89 are at least three trained as balls 97 rolling elements over which an axial movement of the ball ramp disk 91 results in a caused by the electric motor 37 turning the pivot wheel 89 , so that upon an axial movement in the direction of the Y-axis, the housing-fixed outer disks 79, after overcoming a clearance of the means for axial position 87 with the inner disk 75 of the brake device 51 enter into a frictional engagement.

In an open state of the multi-disc brake 77, the transfer stage 39 runs around the longitudinal axis X without torque transfer. If a friction connection in the multi-disc brake 77 is triggered via the electric motor 37, a torque vectoring torque acting on the respective output shaft 3 or 5 is generated from the drive torque. This is done by a support of the planet carrier 65 via the brake device 51 in the gear housing 11. It is thus a torque transfer from the drive shaft 2 via the differential cage 19 and from there by means of the planet carrier 65 from the first sun gear 61 to the respective output shaft 3 and 5 connected second sun gear 63 generated by means of which a different torque distribution to the left output shaft 3 and the right Abfriebswelle 5 can be achieved. In the case of the transmission unit 1 shown in FIG. 1, the brake device 51 is arranged on a region of the transmission stage 39 facing away from the transmission center 8, whereby the braking device 51 is approximately the same distance from the longitudinal axis X as a planetary axis Z and thus advantageously small in size having

The multi-disc brake 77 is presently arranged in the direction of the planetary axis Z between the translation stage 39 and the axial actuation device 87 which can be actuated by the motor 37, whereby the swivel wheel 89 of the axial adjustment device 87 is easy to actuate.

2 shows the gear unit 1 with an alternative arrangement of the brake device 51 'with respect to the gear stage 39 ", wherein the brake device 51' is arranged on a region of the gear stage 39 'facing the gear center 8. The disk brake 77' is corresponding to that in FIG Fig. 1 embodiment shown in the direction of the planetary axis Z between the means 87 'for axial adjustment and the translation stage 39',

It remains up to the expert to arrange the means for axial adjustment both in a center of the transmission facing area as well as in a gear center remote from the area of the translation stage between the multi-disc brake and the translation stage and thereby meet the specific space requirements. reference numeral

1 rear axle unit

2 drive shaft

3 first output shaft

5 second output shaft

7 left transmission side

8 gear center

9 right transmission side

10 internal combustion engine

11 gearbox housing

12 front gear housing part

13 lateral gear housing part

14 Device for influencing the degree of distribution of the Antriebsmo management on the output shafts

15 differential unit

17 differential

19 differential basket

21 drive pinion

23 ring gear

25 left output side bevel gear

27 right driven bevel gear

29 upper drive side bevel gear

31 lower drive side bevel gear

33 bolts

35 left torque vectoring unit

37 electric motor

39 translation level

39 'translation level 51 brake device

51 'brake device

61 first sun

63 second sun wheel

65 planet carrier

69 planet

71 planet

73 toothing planet

75 inner fins

77 Multi-disc brake of the left torque vectoring unit

77 'multi-disc brake of the left torque vectoring unit

79 outer fins

83 Drive shaft electric motor

85 intermediate wheel

87 Device for axial adjustment

87 'Axial adjustment device

89 Pivoting wheel

91 Ball ramp disc

93 grooves of the ball ramp disc

95 grooves of the swivel wheel

97 balls

X longitudinal axis

Y gear center axis

Z planet axis

Claims

claims

1. gear unit, in particular Hinterachsgetriebeeinheit, for guiding a drive torque from a drive shaft (2) on two output shafts (3, 5) via a differential unit (15) and by means of at least one motor (37) switchable, continuously adjustable device (14) for influencing the degree of distribution of the drive torque to the output shafts (3, 5), wherein the differential unit (15) has a differential (17) and a differential cage (19) operatively connected to the drive shaft (2) and the device (14) for influencing the degree of distribution of the drive torque at least one planetary gear set as a translation stage (39, 39 ') which is operatively connected to the differential cage (19) and an associated output shaft (3 bzw.5) and which a braking device (51, 51') characterized in that the braking device (51, 51 ') in the direction of a planetary axis (Z) offset laterally next to Planenten (69, 71) of the translation stage ( 39, 39 ^! ) and at least approximately within a radial extension region of the planets (69, 71) about a longitudinal axis (X) of the output shafts (3, 5) is arranged.

2. Transmission unit according to claim 1, characterized in that the braking device (51 ') with respect to a transmission center axis (Y) which is perpendicular to a longitudinal axis (X) of the output shafts (3, 5), in a transmission center (8) facing region is arranged next to the planets (69, 71)

3. Transmission unit according to claim 1, characterized in that the braking device (51) with respect to the transmission center axis (Y) in a transmission center (8) facing away from the area next to the planet (69, 71) is arranged.

4, transmission unit according to one of claims 1 to 3, characterized in that the braking device is formed with a switching element and a device for axial adjustment of the switching element, wherein the means for axial adjustment in the direction of the planetary axis between the planet and the switching element is arranged.

5. Transmission unit according to one of claims 1 to 3, characterized in that the braking device (51, 51 '} with a switching element (77, 77'} and means (87, 87 ') for axial adjustment of the switching element (77, 77 ¹ ) is formed, wherein the switching element in the direction of the planetary axis (Z) between the planet (69, 71) and the means (87, 87 ') is arranged for axial adjustment

8. Gear unit according to one of claims 1 to 5, characterized in that the device (14) for influencing the degree of distribution of the drive torque with two relative to a transmission center axis (Y) at least approximately symmetrically arranged torque vectoring units (35) is formed.

7. Transmission unit according to claim 6, characterized in that the at least one transmission stage (39, 39 ') with the non-rotating, with respect to the transmission capability continuously adjustable, in particular frictional switching element (77, 77') of the respective torque vectoring unit ( 35) is connectable, wherein the transmission capability of the respective switching element (77, 77 ^:) via the at least one motor (37) is adjustable.

8. Gear unit according to one of claims 1 to 7, characterized - characterized in that the switching element of the braking device (51, 51 ') as a multi-disc brake (77, 77') is formed, wherein the multi-disc brake (77, 77 ') by means of the at least one motor (37) operable means for axial adjustment (87, 87') of the braking device (51, 51 ') is actuated

9. Transmission unit according to claim 8, characterized in that a drive shaft (83) of the motor (37) interacts with a swivel wheel (89) of the device (87, 87 ') for axial adjustment, wherein the swivel wheel (89) by means in particular as balls ( 97) formed rolling bodies, which are in depth-varying grooves (95) of the pivot wheel (89) and in correspondingly arranged grooves (93) of a housing-fixed ball ramp disc (91) of the means (87, 87 ") for axial adjustment, with the ball ramp disc (91) cooperates

10. Transmission unit according to claim 9, characterized in that the drive shaft (83) of the motor (37) with the swivel wheel (89) by means of an at least single-stage spur gear (85) cooperates.