WO2010043193A1 - Drive shaft assembly for a transmission of a motor vehicle - Google Patents

Abstract

The invention relates to a drive shaft assembly for a transmission of a motor vehicle, particularly a crank-CVT, comprising a drive shaft mounted in a transmission housing, wherein on the drive shaft at least one cam part (4) is arranged in a non-rotatable manner, which is offset with respect to the rotational axis thereof and on the lateral surface of which an eccentric component (5) is rotatably mounted. On the lateral surface of the eccentric component, the one end of a connecting rod part is rotatably mounted by way of a bearing. The eccentricity of the eccentric component can be adjusted by way of an adjusting mechanism. The eccentric component has a compensating mass region, which at least partially compensates for torque which can be attributed to the centrifugal force developing during the rotation of the eccentric component and/or the connecting rod tractive force caused at the connecting rod part.

Description

 Drive shaft assembly for a transmission of a motor vehicle

The present invention relates to a drive shaft assembly for a transmission of a motor vehicle, in particular for a crank CVT

From DE 102 43 535 A1 discloses such a continuously variable transmission of a motor vehicle, which essentially comprises a drive shaft and an output shaft, which are aligned parallel to one another rotatably mounted in a transmission housing. In this case, the drive shaft and the output shaft via an eccentric device provided on the drive shaft, a freewheel device arranged on the output shaft and a connecting rod device arranged between the eccentric device and the freewheel device are connected to one another. The eccentric consists of a plurality of eccentric units, which are arranged axially next to one another on the drive shaft. The freewheel device consists of several freewheel units, which are arranged axially adjacent to each other on the output shaft. Correspondingly, the connecting rod device comprises a plurality of connecting rod parts, which each connect an eccentric unit and a freewheel unit.

In this case, the mounted in the gear housing 10 drive shaft 1 according to Figure 1 integrally formed with her, with respect to its axis of rotation 3 eccentrically offset, crescent-shaped cam parts 4, on whose lateral surfaces 2 each an eccentric 5 is rotatably mounted. On the Exzenterbauteil 5 one side of at least one Pleuelteiles 7 with a bearing 18 is rotatably mounted.

Each eccentric component 5 has a recess 15 (FIG. 3) for receiving the cam part 4, wherein an internal toothing 6 extends around the recess 15. The internal toothing 6 is matched to the lateral surface 2 of the cam part 4 such that the eccentric component 5 is centered on the cam part 4 via the internal toothing 6.

The drive shaft 1, or the cam parts 4 thereof, have a recess 8 which extends in the direction of the axis of rotation 3 of the drive shaft 1 and in which an adjusting shaft 9 is rotatably arranged. The adjusting shaft 9 has an external toothing 13 which engages in the internal toothing 6 of the eccentric components 5. The adjusting shaft 9 is mounted in the recess 8 of the drive shaft 1 via the sections of the outer toothing 13 which form the tip circle of the external toothing 13. The cam parts 4 are so crescent-shaped formed so that their recesses 8 are open over a certain angular range, so that in these open angle regions, the outer teeth 13 of the adjusting 9 protrudes radially relative to the outer surface 2 of the cam parts 4, wherein engagement in the internal teeth 6 of the Exzenterbauteiles 5 is made possible.

The cam parts 4 have with respect to their cylindrical surface 2 a central axis 16 (Figure 3), which is arranged eccentrically by a certain distance from the axis of rotation 3 of the drive shaft 1. The eccentric 5 have with respect to their cylindrical surfaces 12 a central axis 4, which is offset relative to the said central axis 16 of the cam parts 4 eccentrically by a distance so that the eccentricity of the central axis 14 of the Exzenterbauteile 5 relative to the axis of rotation 3 of the drive shaft 1, for example twice is as large as the eccentricity of the central axis 16 of the cam parts 4 with respect to the axis of rotation. 3

Due to the rotation of the adjusting shaft 9 in the recess 8 of the drive shaft 1, the eccentric 5 is rotated about the central axis 16 of the corresponding cam member 4. In this case, the central axis 14 of the Exzenterbauteiles 5 moves about the central axis 16 of the cam member 4, wherein the extent of the eccentricity of the Exzenterbauteiles 5 with respect to the axis of rotation 3 of the drive shaft 1 is changed. The adjusting shaft 9 is rotated by an adjusting drive in the form of an electric motor 17, wherein between the electric motor 17 and the adjusting shaft 9, a transmission gear 19 is connected.

A problem of such a drive shaft arrangement is that the result of the weight of the Exzenterbauteiles 5 during rotation of the drive shaft 1 is an outwardly acting torque that must be supported by the electric motor 17 with the associated transmission gear 19. For a constant travel of the motor vehicle or for slow adjustments, therefore, the electric motor 17 must be energized. The torque resulting from the Pleuelzugkraft is too small in many operating points to compensate for the torque from the centrifugal force.

The object of the present invention is therefore to design a drive shaft arrangement for a transmission, in particular for a crank CVT, so that the torques resulting from the centrifugal force and from the connecting rod tensile force on the eccentric component are compensated for in the main drive regions of the motor vehicle. This object is achieved by a drive shaft assembly for a transmission of a motor vehicle, in particular for a crank CVT, with a drive shaft mounted in a transmission housing, wherein on the drive shaft at least one offset relative to its axis of rotation cam member is rotatably disposed on the lateral surface of an eccentric rotatable is. On the lateral surface of the Exzenterbauteiles one end of a Pleuelteiles is rotatably mounted with a bearing. The eccentricity of the Exzenterbauteiles is adjustable by an adjustment. The eccentric component has a balancing mass range which at least partially compensates for torques which are due to the centrifugal force produced during the rotation of the eccentric component and / or to the connecting rod tensile force caused on the connecting rod part.

The essential advantage of the drive shaft arrangement according to the invention is that the provision of an additional or compensating mass on the eccentric component of a crank CVT ensures that the torques attributable to the centrifugal force and the connecting rod tensile force are compensated in the main driving ranges of a motor vehicle.

These torques must therefore not be compensated by the adjusting motor with the associated transmission gear. For a constant travel of the motor vehicle or for slow adjustments of the Exzenterbauteiles the electric motor must therefore advantageously not be energized.

In a preferred embodiment of the invention west the eccentric component as a particularly advantageous adjusting mechanism with respect to its central axis eccentrically offset recess in which the cam member is rotatably mounted, wherein the drive shaft has an axially extending recess in which an adjusting shaft rotatably arranged with an external toothing is. On the inner circumference of the eccentric recess of the eccentric component an internal toothing is arranged. The cam member is formed so crescent-shaped that the recess is open in its area over a certain angular range, so engages in this angular range, the outer toothing of the adjusting shaft in the internal toothing of the eccentric component. In this case, the internal toothing of the recess of the eccentric component can be matched to the lateral surface of the cam member in such a way that the eccentric component is centered on the cam portion via the head circle of its internal toothing. Furthermore, the outer toothing of the adjusting shaft can be dimensioned such that the adjusting shaft is rotatably supported via the head circle of its outer toothing in the recess of the drive shaft. - A -

Particularly advantageous is an embodiment in which the balancing mass range in such a way on Exzenterbautei! is arranged so that it is opposite to the center of gravity of the Exzenterbauteiles with respect to the central axis thereof. Appropriately, the balancing mass range is the center of gravity of the Exzenterbauteiles with respect to the center axis of the same diametrically opposite. However, it is also conceivable, depending on the type of force to be compensated, to arrange the balancing mass range from the center axis of the eccentric component on the side of the center of gravity in order to increase the centrifugal force.

In a particularly simple and compact embodiment of the present drive shaft arrangement, the balancing mass range is at least partially radially outside the inner diameter of the bearing for the connecting rod part, in particular axially seen on one side of the bearing. The balancing mass region may have a radially extending on one side of the bearing mass range, to which an axially extending holding portion may be integrally formed, which is held between the outer surface of the Exzenterbauteiles and the inner ring of the bearing.

Particularly preferred and structurally simple is the symmetrically arranged balancing mass range axially seen on both sides of the bearing, the balancing mass range having a first radially on one side of the bearing extending first mass range and at the first mass range axially opposite side of the bearing a radially extending second mass range can. In this case, an axially extending first holding region and to the second mass region a second axially extending holding region may be integrally formed on the first mass region, the first holding region and the second holding region being held between the lateral surface of the eccentric component and the inner ring of the bearing.

In order to reduce the weight, the eccentric component may have at least one material recess on the side opposite the balancing mass region with respect to its central axis. Expediently, a material recess is provided axially on each side of the eccentric component.

In the following, the invention and its embodiments will be explained in more detail in connection with the figures. Show it:

Figure 1 in section a known drive shaft assembly of a crank CVT's; Figure 2 is an illustration for explaining the principle of the invention;

Figure 3 partly in section a side view of a drive shaft arrangement according to the invention; and

FIG. 4 shows a longitudinal section through the drive shaft arrangement according to the invention of FIG. 3 along the line IV-IV.

According to FIG. 2, the following forces occur during operation of a transmission having the drive shaft arrangement according to FIG. 1. When the cam member 4 in the direction of the arrow P1, d. H. Thus, to the left, rotates, acts on the rotating about the central axis 16 eccentric 5 a tensile force K1, which is due to the centrifugal force. The result is the centrifugal force attributable to the torque D1 on the Extzenterbauteil 5. On the connecting rod 7, the tensile force K2 acts, which is due to the drive torque. This results in the Exzenterbauteil 5 attributable to the tensile force K2 torque D2. In order to compensate for the torques D1 and / or D2, it is possible according to the invention to provide a compensating mass region 22 on the eccentric component 5, as will be explained in more detail below in connection with FIGS. 3 and 4.

Details of Figure 3, which have already been explained in connection with the figure 1, are designated in the corresponding manner. In the apparent manner, an adjusting shaft 9 is arranged in a recess 8 of the cam part 4 and the drive shaft (not shown). The adjusting shaft 9 has an axial external toothing 13 and is rotatably supported in the recess 8 via the head circle of this external toothing 13.

The eccentric component 5 has an eccentric recess 15, on whose inner circumference an internal toothing 6 is located. This internal toothing 6 is matched to the lateral surface 2 of the cam part 4 such that the eccentric component 5 is centered on the cam part 4 via the internal toothing 6. As already mentioned, the cam areas 4 are designed in a crescent-shaped manner so that their recesses 8 are open over a certain angular range, so that in these open angle regions, the external teeth 13 of the adjusting shaft 9 project radially relative to the outer circumferential surface 2 of the cam parts 4, wherein a Intervention in the internal toothing 6 of the Exzenterbauteiles 5 is made possible. When rotating the adjusting shaft 9, therefore, the eccentricity of the Exzenterbauteiles 5 is changed with respect to the axis of rotation 3 of the drive shaft 1. The center of the cam member 4 is denoted by 16 and the center of the Exzenterbauteiles 5 14.

On the outer circumference 12 of the Exzenterbauteiles 5, a bearing 18 for the connecting rod 7 is arranged (Figure 4).

The eccentric component! 5 may have in a conventional manner for weight reduction two preferably axially opposite material recesses 20.

According to the invention, a compensation mass region 21, which is located substantially radially outside of the bearing 18 for the connecting rod 7, is provided in the manner shown on the circular disk-shaped eccentric component 5. The balancing mass region 21 is the center of gravity of the Exzenterbauteiles 5 with respect to the central axis 16 of the same preferably 180 ° opposite. It is also conceivable to place the mass on very slow motors on the same side as the center of gravity in order to increase the centrifugal force.

The size of the balancing mass range 21 is according to the invention laid so that in the main driving ranges of the motor vehicle caused by the centrifugal force and the Pleuelzugkraft torques D1, D2 just compensate. As a result, it is advantageously achieved that the holding torque on the adjusting shaft 9 drops to a minimum. In addition, a good emergency driving behavior of the transmission is achieved because automatically with increasing engine speed in the direction of overdrive and with decreasing engine speed or with increasing wheel torque in the direction of translation infinitely adjusted.

In the manner shown in FIGS. 3 and 4, in particular FIG. 4, the balancing mass region 21 is advantageously divided on both sides of the bearing 18 of the connecting rod 7. Accordingly, a first mass region 22 extends radially outward on one side of the bearing 18 and a second mass region 23 on the opposite side of the bearing 18 extends radially outward. To the first mass portion 22, an axially extending holding portion 24 is preferably integrally formed on the side facing the adjusting shaft 9, which extends up to half of the axial extent of the bearing 18. Correspondingly, an axially extending holding region 25 is integrally formed on the second mass region 23 on the side facing the adjusting shaft 9, which extends up to half of the axial extent of the bearing 18 in the direction of the holding region 24, preferably up to the same. By a sol- It is achieved that the two holding regions 24, 25 are held together by the press fit of the bearing 18 of the connecting rod 7.

It is also conceivable to arrange a balancing mass area only on one side of the bearing 18.

List of accessories List Drive shaft Sheathing face Rotary axis Cam part Eccentric component Internal toothing Connecting rod part Recessing Adjustment shaft Gearbox housing Outer surface Outer toothing Central axis Recess Center axis Electric motor Bearings Transmission gear Material recess Compensation mass range Mass range Mass range Holding range Holding range

Claims

claims 1. drive shaft assembly for a transmission of a motor vehicle, in particular for a crank CVT, with a transmission housing (10) mounted drive shaft (1), wherein at the drive shaft (1) at least one offset relative to its axis of rotation (3) cam member (4) is rotatably mounted on the lateral surface (2) an eccentric component (5) is rotatably mounted, wherein on the lateral surface (12) of the Exzenterbauteiles (5) one end of a Pleuelteiles (7) with a bearing (18) is rotatably mounted, and wherein the eccentricity of the eccentric component (5) is adjustable by means of an adjusting mechanism, characterized in that the eccentric component (5) has a balancing mass region (21) which compensates for torques (D1, D2) which correspond to those during the rotation of the eccentric component (5). resulting centrifugal force (K1) and / or on the connecting rod (7) caused Pleuelzugkraft (K2) are due. Second drive shaft assembly according to claim 1, characterized in that the eccentric component (5) as an adjusting mechanism with respect to its central axis (14) eccentrically offset recess (15) in which the cam member (4) is rotatably mounted, that the drive shaft ( 1) has an axially extending recess (8), in which an adjusting shaft (9) with an external toothing (13) is rotatably arranged, that on the inner periphery of the eccentric recess (15) of the Exzenterbauteiles (5) an internal toothing (6) is arranged in that the cam part (4) is designed in a crescent-shaped manner such that the recess (8) is open in its area over a certain angular range, so that in this angular range the external toothing (13) of the adjusting shaft (9) into the internal toothing (6) of the eccentric component (5) intervenes. 3. Drive shaft arrangement according to claim 2, characterized in that the internal toothing (6) of the recess (15) of the Exzenterbauteiles (5) on the lateral surface (2) of the cam part (4) is tuned such that the Exzenterbauteil (5) over the top circle its internal toothing (6) on the cam part (4) is centered. 4. drive shaft assembly according to claim 2 or 3, characterized in that the external toothing (13) of the adjusting shaft (9) is dimensioned such that the adjusting shaft (9) via the head circle of its external toothing (13) in the recess (8) of the drive shaft ( 1) is rotatably mounted. 5. Drive shaft arrangement according to one of claims 1 to 4, characterized in that the balancing mass region (21) is arranged on the eccentric component (5) such that it faces the center of gravity of the Exzenterbauteiles (5) with respect to the central axis (16) thereof. 6. Drive shaft assembly according to claim 5, characterized in that the balancing mass region (21) of the center of gravity of the Exzenterbauteiles (5) with respect to the central axis (14) of the same diametrically opposite. 7. Drive shaft arrangement according to one of claims 1 to 6, characterized in that the balancing mass region (21) is at least partially radially outside the inner diameter of the bearing (18) for the connecting rod part (7). 8. drive shaft assembly according to claim 7, characterized in that the balancing mass range (21) is axially seen on one side of the bearing (18). 9. drive shaft assembly according to claim 8, characterized in that the balancing mass region (21) has a radially on one side of the bearing (18) extending mass region (22). 10. Drive shaft arrangement according to claim 9, characterized in that on the mass region (22) an axially extending holding portion (24) is formed, which is held between the lateral surface (12) of the Exzenterbauteiles (5) and the bearing (18). 11. Drive shaft assembly according to claim 7, characterized in that the balancing mass region (21) axially seen on both sides of the bearing (18). 12. Drive shaft arrangement according to claim 11, characterized in that the balancing mass region (21) has a first radially on one side of the bearing (18) extending mass region (22) and on the first mass region (22) axially opposite side of the bearing (18) having radially extending second mass range (23). 13. A drive shaft assembly according to claim 10, characterized in that on the first mass range (22) an axially extending first holding portion (24) and at the two a second axially extending holding region (25) are formed, wherein the first holding region (24) and the second holding region (25) between the lateral surface (12) of the Exzenterbauteiles (5) and the bearing (18) are held. 14, drive shaft assembly according to one of claims 1 to 4, characterized in that the balancing mass range is arranged on the Exzenterbauteil (5) that it with respect to the central axis (16) thereof on the side of the center of gravity of the Exzenterbauteiles (5). 15. Drive shaft arrangement according to one of claims 1 to 14, characterized in that the Exzenterbautei! (5) for weight reduction at least one material recess (20) on the said mass balance area (21) with respect to the central axis (14) opposite side. 16, drive shaft assembly according to claim 15, characterized in that axially seen on each side of the Exzenterbauteiles (5) a material recess (20) is provided.