[11ACTUATING ASSEMBLY FOR A CENTRALLY SYNCHRONISED DUAL-CLUTCH TRANSMISSION

[2]
[3] The present invention concerns an actuating assembly for the actuation of synchronizing means of a centrally synchronized dual-clutch transmission, of the type defined in more detail in the preamble of Claim 1.

[4]
[5] For example, from the document DE 10 2006 015 898 A1 a clutch device with a clutch and a transmission brake for an internal combustion engine with a transmission is known. The clutch device provided for actuating the clutch also comprises a transfer element by means of which te movement of the clutch can be transmitted mechanically to, the transmission brake, so that individual control of the transmission brake is possible. Further more, from the document DE 10 2004 002 045 A1 a starting clutch system for a vehicle is known, which comprises a starting clutch and a transmission brake. The starting clutch and the transmission brake are actuated by an actuator. From the above documents, therefore, it is known that the actuator provided for actuating the clutch can also actuate a transmission brake.

[6] In the centrally synchronized transmissions with only one transmission input shaft described above, it also follows that only one synchronizing means is provided on the transmission input shaft. In contrast, in centrally synchronized dual-clutch transmissions a synchronizing element is associated with each part- transmission and thus with each transmission input shaft. Accordingly at least two actuators are needed, each actuating one synchronizing element. As synchronizing means various designs are known, such as classical synchronizers or transmission brakes for the compensation of rotation speed differences. It is also possible that at each shift point synchronizing means equal in number to the loose wheels to be engaged are arranged. In this design variant further actuators are needed in order to actuate the synchronizing means at each shift point.

[7]
[8] The purpose of the present invention is to propose an actuating assembly for a centrally synchronized dual-clutch transmission of the type described at the start, in which a particularly inexpensive and space-saving actuator system is provided.

[9] According to the invention, this objective is achieved by the characteristics specified in Claim 1. Further advantageous design features emerge from the subordinate claims and the drawings.

[10] Accordingly an actuating assembly is proposed for the actuation of synchronizing means in a centrally synchronized dual-clutch transmission with at least a first part-transmission and a second part-transmission, such that at least one synchronizing element is associated with each part-transmission. According to the invention it is provided that at least the synchronizing elements of the two part-transmissions can be actuated by a common actuator. Since only one actuator is required for both synchronizing elements, besides cost savings an advantage in term of structural space occupation is also obtained. In addition, in the electric control unit for controlling the actuator as well, savings related to the space required and the production costs are achieved. It is also possible for further synchronizing means in the transmission to be actuated by the actuator.

[11] In an advantageous further development of the invention it can be provided that depending on the respective direction of movement of the actuator away from its null position, the synchronizing element of the first part- transmission or the synchronizing element of the second part-transmission can be actuated. This gives the advantage of greater functional reliability of the dual- clutch transmission since in no case can both synchronizing elements be actuated at one and the same time. In this way the synchronizing elements can never act in opposition to one another. However, other control possibilities for the synchronizing means of the two part-transmissions are also conceivable.

[12] According to a possible design of the invention, it can be provided that to transmit the movement direction of the actuator to the synchronizing element, at least one transmission means or suchlike is provided between the actuator and the respective synchronizing element concerned. For example, the so-termed 'combo- actuator* of the actuating assembly according to the invention can act by means of transmission elements on both of the two synchronizing elements. It is also possible for two transmission elements to be provided on the actuator, each acting upon a respective synchronizing element. As transmission means, mechanical, hydraulic, pneumatic or suchlike means can be used.

[13] For example, an embodiment variant of the actuating assembly according to the invention can be provided with only one transmission element made as a component, the transmission element having at least one eccentric. In a preferred design variant two Eccentrics are arranged on a shaft and thus, in combination, form dual-eccentric shaft. The ends of the eccentrics are in each case connected to a movable end of the synchronizing element, for example made as a band brake. In this way the shaft with the eccentrics can actuate both synchronizing elements by means of the actuator. The dual-eccentric shaft can be designed such that the two eccentrics are aligned axially with one another. In this case the eccentrics can be formed as offset zones of the dual-eccentric shaft, which in the circumferential direction of the dual-eccentric shaft are arranged at a predetermined angle relative to one another. For example the eccentrics can be distributed around the circumference at an angle of approximately 180°. The eccentric shaft can be actuated, for example, by a segment of a toothed disk.

[14] Another design variant of the actuating assembly according to the invention, for example with two transmission elements, can provide that as transmission elements a lever element or suchlike is associated with each synchronizing element for example made as a transmission brake, such that the two lever elements can be actuated by a common actuating element a toothed segment disk or suchlike driven by the actuator. The transmission elements can be coupled to the common actuating element by means of push-rods. In this design variant the actuator drives the lever elements constituting the transmission elements, which then each act separately on the respective synchronizing element concerned.

[15] In the above embodiment variant a splined output shaft of an actuator in the form of an electric motor, can be engaged with teeth on the toothed segment disk, the rotational axle of the toothed segment disk being provided with receiving sections or suchlike, each of which is in active connection via an articulation lever or a push-rod with the associated lever element. Thus, depending on the rotational direction of the actuator, one or the other transmission brake can be actuated. For example, the pivot axle of each lever element can be fixed to the housing at the end remote from the toothed segment disk, on which the end of the transmission brake made as a band brake fixed to the housing is also held, such that the moving end of the band brake can be fixed for example to the respective lever element between the two ends. However, other designs are also conceivable.

[16] Regardless of the particular design of the synchronizing elements and also of the actuator in the actuating assembly according to the invention, it can preferably be provided that each synchronizing element is associated with a gearwheel having the highest transmission ratio of the respective part- transmission. However, other possible arrangements are also conceivable. For example, the actuator can be arranged essentially axis-parallel to, or even perpendicularly to the countershafts of the dual-clutch transmission. Here too, other possible arrangements are conceivable.

[17] To achieve a particularly great structural space advantage in the dual- clutch transmission, it can be provided that each synchronizing element is arranged concentrically with the respective control gear on one of the countershafts. Thus, the synchronizing elements can be accommodated in the same axial space, so that a structure with radial nesting one inside the other is possible.

[18] The actuator provided for actuating the two synchronizing elements can be, for example, an electric motor in the form of a rotary or linear motor. It is also possible to use an electromagnet or a cylinder-piston unit as the actuator.

[19] As synchronizing elements, for example at least one transmission brake and/or a clutch can be associated with each part-transmission. As transmission brakes, for example band brakes, disk brakes and/or cone brakes can be provided. When a transmission brake is used, the necessary brake drum, brake disk or break cone can be made integrally with the associated fixed or loose wheel. For the transmission brake, other designs too are conceivable.

[20] As a clutch, for example a cone clutch, a disk clutch or suchlike can be provided. The shifting elements or shifting devices for gear selection can preferably be actuated from the shaft outward, by so-termed internal actuators. The shifting elements themselves can be claws or suchlike. Other shifting elements can also be used.

[21]
[22] Below, the invention is explained in more detail with reference to the drawings, which show:

[23] Fig. 1: Perspective partial view of a first design variant of an actuating assembly, with one actuator for actuating the synchronizing elements of both part-transmissions;

[24] Fig. 2: Perspective partial view of the first design variant with an altemative arrangement of the actuator;

[25] Fig. 3: Perspective partial view of a second design variant of the actuating assembly, with the actuator having only one transmission element for actuating the synchronizing elements of both part-transmissions;

[26] Fig. 4: Another perspective partial view of the second design variant;

[27] Fig. 5: Detailed perspective view of the synchronizing elements according to Fig. 3 and 4, made as band brakes; and

[28] Fig. 6: Schematic representation of the principle of a dual-clutch transmission with possible fitting locations of the synchronizing elements on the two part-transmissions.

[29]
[30] Figs.1 to 6 show various embodiment variants of an actuating assembly according to the invention for actuating synchronizing elements in a centrally synchronized dual-clutch transmission with a first part-transmission 6 and a second part-transmission 7, a synchronizing element being respectively associated with each of the part-transmissions 6, 7. Regardless of the specific design of the dual-clutch transmission, in the actuating assembly according to the invention it is provided that the two synchronizing elements of the part- transmissions 6, 7 can be actuated by means of a common actuator 1. Thus, the actuator 1 constitutes a 'combi-actuator", which can selectively actuate the transmission
synchronizing elements of the part-transmissions 6, 7 connected in parallel.

[31] Regardless of the specific design variant, the actuating assembly comprises as the actuator 1, designed as an electric motor 2, which drives an output shaft 3. As synchronizing elements transmission brakes in the form of band brakes 4, 5 are provided^ the band brake 4 being associated with the first part-transmission 6 and the band brake 5 with the second part-transmission 7. The actuating assembly is designed in such manner that depending on the respective direction of movement of the actuator 1 away from its null position, the band brake 4 of the first part-transmission 6 or the band brake 5 of the second part-transmission 7 is actuated.

[32] Figs. 1 and 2 show a first, possible embodiment variant of the actuating assembly according to the invention on the centrally synchronized dual-clutch transmission. In this first design variant, to transmit rotational movement of the electric motor 2 or its output shaft 3 to the respective band brakes 4, 5, two mechanical transmission elements are provided between the electric motor 2 and the band brakes 4, 5. Each transmission element comprises a lever element 8, 8', each of these being in active connection, via a push-rod 9, 9', with a toothed segment disk 10 driven by the output shaft 3 of the electric motor 2. The splined output shaft 3 of the electric motor 2 engages with teeth 11 of the toothed segment disk 10, and the rotational axle 12 of the toothed segment disk 10 is provided with receiving sections 13, 14 which, respectively, are in active connection via the push-rods 9, 9", with the ends of the respective lever elements 8, 8' pointing toward them. The end of each lever element 8, 8' facing away from the respective push-rod 9, 9' is mounted fixed on the housing as a pivot axis 15, 15'. The end of the respective lever element 8, 8' forming the pivot axis 15, 15' serves at the same time to receive the end of the respective band brake 4, 5 fixed to the housing. In each case the movable end or the end that can be acted upon to actuate the band brake 4, 5 is held on the respective lever element 8, 8' between the two ends. Thus, the associated band brake 4, 5 can be activated or tightened, or released or relaxed by pivoting the appropriate lever element 8, 8'.

[33] In the first design variant shown in Fig. 1, the electric motor 2 is arranged approximately perpendicularly to the two countershafts w_v1, w_v2 and the transmission input shafts w_k1, w_k2 of the two part-transmissions 6, 7 of the dual-clutch transmission indicated as an example. The teeth 11 of the toothed segment disk 10 are provided radially on the outside of the circumference of the toothed segment disk 10.

[34] In an alternative arrangement of the electric motor 2 shown in Fig. 2, the electric motor 2 is arranged approximately parallel or at a predetermined acute angle to the two countershafts w_v1, w_v2 and the transmission input shafts w_k1, w_k2 of the two part-transmissions 6, 7 of the dual-clutch transmission. In this version the teeth 11 of the tooth segment disk 10 are provided on the surface thereof.

[35] Regardless of the specific arrangement of the actuator 1, in the first embodiment variant the receiving sections 13, 14 can be arranged approximately at an angle of 180® relative to one another on the circumference of the rotational axle of the toothed segment disk 10. Other angles too are conceivable.

[36] Regardless of the specific design of the first embodiment variant shown in Figs. 1 and 2, by selecting the rotational direction of the output shaft 3 of the electric motor 2 the toothed segment disk 10 is rotated to the left or to the right. Rotation of the toothed segment disk 10 actuates one or other of the push-rods 9, 9' in order to pivot the associated lever element 8, 8' around its pivot axis 15, 15' so that the associated movable end of the band brake 4, 5 moves with it, whereby the associated band brake 4, 5 is tightened or activated. Thus, depending on the rotational direction of the output shaft 3 of the electric motor 2, one or other of the band brakes 4, 5 can be actuated.

[37] Figs. 3 to 5 show views of a second possible embodiment variant, the same components being given the same indexes as in the first embodiment variant. In the second embodiment variant, to transmit the movement direction of the electric motor 2 to the band brakes 4, 5 only one transmission element is provided. As the transmission element a dual-eccentric shaft 20 is provided, whose eccentrics 16, 17 are respectively connected to the movable ends of the respective band 4, 5. The ends of the band brakes 4, 5 fixed to the housing are attached to a bearing bolt 18 which is held with its ends in holding bushes of a supporting unit 19. The dual-eccentric shaft 20 is mounted so that it can rotate in the supporting unit 19.

[38] The two eccentrics 16, 17 of the dual-eccentric shaft 20 are arranged one behind the other in the axial direction, and offset relative to one another by an angle of approximately 180° in the circumferential direction. Other angles too are possible. The end of the dual-eccentric shaft 20 remote from the band brakes 4, 5 is in active connection with the output shaft 3 of the electric motor 2 in a manner not illustrated in detail.

[39] From Fig. 5 in particular it can be seen that when the output shaft 3 of the electric motor 2 and hence the dual-eccentric shaft 20 is rotated to the right, the band brake 4 is released by the corresponding movement of the eccentric 16 and the band brake 5 is tightened by the corresponding movement of the eccentric 17. When the output shaft 3 of the electric motor 2 and hence the dual-eccentric shaft 20 rotates to the left, the band brakes 4, 5 oppositely are actuated.

[40] Fig. 6 shows a schematic representation of the principle of a possible dual- clutch transmission, indicating the fitting location of the synchronizing elements on the two part-transmissions 6, 7. This representation shows that in each case the synchronizing elements are associated with the gearwheel of the highest gear of the part-transmission 6, 7 concerned. in the manner described above, the synchronizing elements are actuated by the schematically indicated actuator 1. The arrows extending from the actuator 1 indicate the respective fitting locations of the synchronizing elements and are intended schematically to represent the transmission elements. Besides the various transmission ratio steps of the transmission, the transmission input shaft w_k1 associated with the first part- transmission 6, which is associated with the clutch K1, and the transmission input shaft w_k2 associated with the second part-transmission 7, which is associated with the clutch K2, and the drive output shaft w_ab are shown.

[41] Regardless of whether the band brakes 4, 5 are actuated by the lever elements 8, 8' or by the dual-eccentric shaft 20, during actuation on the run-in side of the braise band a self-reinforcing effect takes place and a smaller braking force is therefore needed, so that the band brakes 4, 5 are more sensitive to frictional coefficient. When the actuation takes place on the run-out side of the brake band there is no self-reinforcement, so higher braking forces are needed and the band brakes 4, 5 are then less sensitive to frictional coefficient. Consequently, better adjustment of the braking force can take place if necessary. Regardless of the particular embodiment variant concerned, a suitable friction lining is fixed to the brake band of each band brake 4, 5. Regardless of the mode of actuation, a restoring element can be provided between the actuating device and the band brakes 4, 5 in order to ensure a clearance at the brake band. As the restoring element, for example a restoring spring or suchlike can be used. Other adjustment elements too can be used.

Indexes

1 Actuator

2 Electric motor

3 Output shaft

4 Band brake

5 Band brake

6 First part-transmission

7 Second part-transmission

8, 8' Lever element

9,9' Push-rod

10 Toothed segment disk

11 Gearteeth

12 Rotation axle of the toothed segment disk

13 Receiving section

14 Receiving section

15,15' Pivot axis of the lever element

16 Eccentric

17 Eccentric

18 Bearing bolt

19 Supporting unit

20 Dual-eccentric shaft

w_K1 First transmission input shaft

w_K2 Second transmission input shaft

w_v1 First countershaft

w_v2 Second countershaft

K1 Clutch

K2 Clutch

w_ab Drive output shaft

Claims

1. Actuating assembly for the actuation of synchronizing means of a centrally synchronized dual-clutch transmission with at least a first part- transmission (6) and a second part-transmission (7), such that a synchronizing element is associated with each part-transmission (6, 7), characterized in that at least the synchronizing elements of the two part-transmissions can be actuated by a common actuator (1).

2. Actuating assembly according to Claim 1, characterized In that depending on the respective movement direction of the actuator (1) away from its null position, the synchronizing element of the first part-transmission (6) or the synchronizing element of the second part-transmission (7) can be actuated.

3. Actuating assembly according to Claim 2, characterized in that to transmit the movement of the actuator (1) to the synchronizing elements, at least one transmission element is provided between the actuator (1) and the respective synchronizing element concerned.

4. Actuating assembly according to Claim 3, characterized in that as the transmission element a dual-eccentric shaft (20) is provided, whose eccentrics (16, 17) are respectively connected in each case to a movable end of the synchronizing elements made as band brakes (4, 5).

5. Actuating assembly according to any of the preceding claims, characterized in that as the transmission element a lever element (8, 8') is associated with each synchronizing element, and the two lever elements (8, 8') can in each case be actuated via a push-rod (9, 9') by a toothed segment disk (10) driven by the actuator (1).

6. Actuating assembly according to Claim 5, characterized In that a splined output shaft (3) of an actuator (1) in the form of an electric motor (2) engages with teeth (11) of the toothed segment disk (10), and the rotational axle (12) of the toothed segment disk (10) is provided with receiving sections (13, 14) which, respectively, are in active connection via the push-rods (9, 9') with the associated lever elements (8, 8').

7. Actuating assembly according to Claim 6, characterized in that the pivoting axles (15, 15') of the respective lever elements (8, 8') are fixed to the housing at the end remote from the toothed segment disk 10.

8. Actuating assembly according to Claim 7, characterized in that the end, fixed to the housing, of the synchronizing element made as a band brake (4, 5) is held at the other end of each lever element (8, 8'), such that the movable end of the band brake (4, 5) is attached to the respective lever element (8, 8') between the two ends.

9. Actuating assembly according to any of the preceding claims, characterized in that the synchronizing elements are in each case associated with a gearwheel of the respective part-transmission (6, 7) with the highest transmission ratio.

10. Actuating assembly according to any of Claims 6 to 9, characterized in that the actuator (1) is arranged essentially axis-parallel or perpendicularly to the countershafts (w_v1, w_v2) and the transmission input shafts (w_k1, w_k2) of the part-transmissions (6, 7).

11. Actuating assembly according to any of the preceding claims, characterized in that each synchronizing element is arranged concentrically with the respective internal shifting means on one of the countershafts (w_v1, w_v2).

12. Actuating assembly according to any of the preceding claims, characterized in that as the actuator (1), an electric motor (2), an electromagnet and/or a cylinder-piston unit is provided.

13. Actuating assembly according to Claim 12, characterized in that the
electric motor (2) is a rotary or a linear motor.

14. Actuating assembly according to any of the preceding claims, characterized in that as the synchronizing element, each part-transmission (6, 7) is associated with a respective transmission brake and/or a clutch.

15. Actuating assembly according to Claim 14, characterized in that as the transmission brake, a band brake (4, 5), disk brake and/or cone brake is provided.

16. Actuating assembly according to Claims 14 or 15, characterized in that as the clutch, a cone clutch and/or a disk clutch is provided.