阅读说明：本技术 扭振减振器 (Torsional vibration damper ) 是由 M·黑斯勒 A·鲁施 P·克伦佩尔 Y·施特鲁布 L·索瑞特 于 2019-03-18 设计创作，主要内容包括：设置一种扭振减振器、尤其摆式减振器,其具有：用于导入扭矩的输入部件(12)；与所述输入部件(12)运动耦合的、尤其构型为摆的两个中间元件(16),其中,所述中间元件(16)在线性运动中能够朝向彼此和/或远离彼此运动；作用在所述中间元件(16)上的、尤其构型为压力弹簧的至少一个储能元件(18)；与所述中间元件(16)运动耦合且能够相对于所述中间元件(16)扭转的输出部件(22),用于导出被减振的扭矩；和设置在所述输出部件(22)与所述中间元件(16)之间的、尤其弹性和/或柔韧的至少一个补偿部件(28),用于消除所述中间元件(16)相对于所述输出部件(22)的轴向间隙。通过所述补偿部件(28),自发的且不可预测的摩擦效应能够被持续的并且在设计所述扭振减振器(10)的振动特性时所考虑的带有摩擦的减振代替,从而能够在机动车的驱动系(36)中实现良好的扭振减振。(A torsional vibration damper, in particular a pendulum vibration damper, is provided, comprising: an input member (12) for introducing torque; two intermediate elements (16), in particular in the form of a pendulum, which are kinematically coupled to the input part (12), wherein the intermediate elements (16) are movable in a linear movement toward and/or away from each other; at least one energy storage element (18), in particular in the form of a compression spring, acting on the intermediate element (16); an output part (22) which is coupled in terms of movement to the intermediate element (16) and can be rotated relative to the intermediate element (16) in order to derive a damped torque; and at least one compensating part (28), in particular elastic and/or flexible, arranged between the output part (22) and the intermediate element (16) for eliminating axial play of the intermediate element (16) relative to the output part (22). By means of the compensating element (28), spontaneous and unpredictable frictional effects can be replaced by a continuous and frictional damping which is taken into account when designing the vibration behavior of the torsional vibration damper (10), so that a good torsional vibration damping can be achieved in the drive train (36) of the motor vehicle.)

1. A torsional vibration damper, in particular a pendulum vibration damper, having:

an input member (12) for introducing torque;

two intermediate elements (16), in particular in the form of a pendulum, which are kinematically coupled to the input part (12), wherein the intermediate elements (16) are movable in a linear movement toward and/or away from each other;

at least one energy storage element (18), in particular in the form of a compression spring, acting on the intermediate element (16);

an output part (22) which is coupled in terms of movement to the intermediate element (16) and can be rotated relative to the intermediate element (16) in order to derive a damped torque; and

at least one compensating part (28), which is arranged between the output part (22) and the intermediate element (16), is in particular elastic and/or flexible, in order to eliminate an axial play of the intermediate element (16) relative to the output part (22).

2. The torsional vibration damper as claimed in claim 1, characterized in that the output part (22) has a first output disk (24) and a second output disk (26) which is coupled torsionally fixed to the first output disk (24), wherein the intermediate element (16) is arranged in the axial direction between the first output disk (24) and the second output disk (26), wherein the at least one compensation part (28) is arranged in the axial direction between the first output disk (24) and the intermediate element (16) and/or between the intermediate element (16) and the second output disk (26).

3. The torsional vibration damper as claimed in claim 1 or 2, characterized in that the compensating element (28) is configured as a pretensioned spring, in particular as a disk spring or as a corrugated plate.

4. The torsional vibration damper as claimed in any of claims 1 to 3, characterized in that the compensating part (28) is secured in a rotationally fixed manner to the output part (22).

5. The torsional vibration damper as claimed in any of claims 1 to 4, characterized in that the compensation component (28) acts indirectly on the intermediate element (16) or on the output component (22) via a friction element (30).

6. The torsional vibration damper according to one of claims 1 to 5, characterized in that the intermediate element (16) is provided with a friction element (30) at least on the axial side directed toward the compensation component (22), wherein in particular the intermediate element (16) is largely enclosed by the friction element (30).

7. The torsional vibration damper as claimed in claim 6, characterized in that the friction element (30) is configured as a, in particular, two-part sleeve for covering the intermediate element (16) over a large area, wherein, in particular, the friction element (30) covers, in particular substantially completely covers, the axial sides of the intermediate element (16).

8. The torsional vibration damper as claimed in claim 6 or 7, characterized in that the friction element (30) is elastically and/or flexibly configured in the axial direction for the purpose of configuring the compensation component (28).

9. The torsional vibration damper according to one of claims 1 to 8, characterized in that the compensating part (28) is supported on the one hand on the intermediate element (16) and on the other hand both on the output element (22) and on the input element (12), wherein in particular the input element (12) has a first input disk and a second input disk coupled thereto in a rotationally fixed manner, wherein the intermediate element (16) is arranged in the axial direction between the first input disk and the second input disk (26).

10. The torsional vibration damper according to any of claims 1 to 9, characterized in that the intermediate element (16) is coupled with the input member (12) by means of a first cam gear (14) such that a relative rotation of the input member (12) with respect to the intermediate element (16) can be converted into a linear movement of the intermediate elements (16) towards and/or away from each other, wherein the output member (22) is coupled with the intermediate element (16) by means of a second cam gear (20) such that a relative linear movement of the intermediate elements (16) with respect to each other can be converted into a rotational movement of the output member (22) with respect to the intermediate element (16).

Technical Field

The invention relates to a torsional vibration damper, by means of which torsional vibrations in the drive train of a motor vehicle can be damped.

Background

A torsional vibration damper configured as a pendulum vibration damper is known from DE 102015211899 a1, in which, when the input part is twisted by means of a first cam gear, mutually opposite intermediate elements configured as pendulums are linearly displaced relative to one another in order to compress and/or relax a pressure spring acting on the intermediate elements, wherein the spring force of the pressure spring is supported on the output part by means of a second cam gear acting on the intermediate elements in order to derive the damped torque.

There is a continuing need for good damping of torsional vibrations in the drive train of a motor vehicle.

Disclosure of Invention

The object of the present invention is to provide measures which make it possible to achieve good torsional vibration damping in the drive train of a motor vehicle.

According to the invention, this object is achieved by a torsional vibration damper having the features of claim 1. Preferred configurations of the invention, which can each represent an aspect of the invention individually or in combination, are described in the dependent claims and in the following description.

According to the invention, a torsional vibration damper, in particular a pendulum damper, is provided, comprising: an input member for introducing torque; two intermediate elements, in particular in the form of a pendulum, which are coupled to the input part in a kinematic manner, wherein the intermediate elements are movable in a linear movement toward one another and/or away from one another; at least one energy storage element, in particular in the form of a compression spring, acting on the intermediate element; an output part which is coupled in motion with the intermediate element and can rotate relative to the intermediate element, and is used for deriving the damped torque; and at least one compensating part, in particular elastic and/or flexible, arranged between the output part and the intermediate element for eliminating axial play of the intermediate element relative to the output part.

The intermediate element is embodied so as to be linearly movable in a radial plane of the torsional vibration damper. Due to this movability, it is in principle possible that the intermediate element may tilt, for example in case of sudden occurrence of forces, in case of gaps and/or installation tolerances. In the tilted position, the intermediate element can come to rest against and slide along a component, in particular an output part, which is arranged next to the intermediate element in the axial direction. This leads to friction which adversely affects the movement of the intermediate element and the output part, which also occurs spontaneously and in advance unpredictably. However, an axial play of the intermediate element, in particular with respect to the output part, can be eliminated by the at least one compensating part. As a result, tilting with unpredictable, frictional braking effects on the intermediate element and/or on the output part can be avoided.

However, due to the relative movement of the intermediate element with respect to the output part, a sliding contact with friction caused by the compensating part cannot be avoided. However, the following recognition is fully utilized here: the energy storage element, which is in particular embodied as a compression spring, together with the intermediate element and the coupled input and output parts, forms a vibrating mass-spring system, which generally operates supercritical. In particular, when starting a motor vehicle in whose drive train a torsional vibration damper in the form of a pendulum damper is provided, it may happen that the torsional vibration damper must be operated through its resonant rotational speed. Due to the frictional sliding contact caused by the compensating element, an intentional frictional damping can be provided, which enables the resonance-induced starting of the torsional oscillation to be damped in the torsional vibration damper, as a result of which a good torsional vibration damping can be achieved in the drive train of the motor vehicle. The inevitable damping with friction caused by the compensating member therefore has even a positive effect: unnecessary torsional vibration caused by resonance can be avoided. However, such a damping, which is usually rather weak, with friction does not occur spontaneously and unpredictably, but rather continuously and programmatically, so that it can be taken into account when designing the vibration behavior of the torsional vibration damper. This prevents transient, spontaneous and unanticipated detuning of the oscillation behavior of the torsional vibration damper. By means of the compensating element, the spontaneous and unpredictable frictional effects can be replaced by the damping with friction, which is continuous and is taken into account when designing the vibration behavior of the torsional vibration damper, so that a good torsional vibration damping can be achieved in the drive train of the motor vehicle.

In particular, the output part has a first output disk and a second output disk coupled to the first output disk in a rotationally fixed manner, wherein the intermediate element is arranged in the axial direction between the first output disk and the second output disk, wherein the at least one compensating part is arranged in the axial direction between the first output disk and the intermediate element and/or between the intermediate element and the second output disk. In this way, a compensating part can be provided on each of the two axial sides of the respective intermediate element, which compensating part provides a damping with friction when the respective intermediate element is moved relative to the two output disks. The compensating means arranged on both axial sides of the intermediate element can thereby center the intermediate element between the first output disk and the second output disk, in particular with the same spacing from the respective output disk, so that even if the intermediate element is inclined out of the radial plane of the torsional vibration damper, an unpredictable abutment of the intermediate element on the output part can be avoided.

Preferably, the compensating element is in the form of a prestressed spring, in particular a disk spring or a corrugated plate. The compensating part can thereby be supported indirectly or directly on the intermediate element on one axial side and indirectly or directly on the output part on the other axial side in order to eliminate axial play of the intermediate element. In this case, the internal friction of the compensating element can be minimized. Furthermore, the compensating part can have a very small axial extension, so that the compensating part can be constructed substantially space-neutral with respect to the mounting space, without the axial extension of the torsional vibration damper being increased significantly. If the compensating part is formed as a disk spring, it is possible for the compensating part to be formed circumferentially in the circumferential direction and to be able to act on the two intermediate elements. When the compensating member is configured as a corrugated plate, it is possible for the compensating member configured as a corrugated plate to extend in the circumferential direction only to the extent required for the respective intermediate element to be axially supported on the output member. In this way, a compensation element in the form of a corrugated plate can be provided for each intermediate element, which compensation element extends in the circumferential direction only over a limited angular range, in particular substantially tangentially.

Particularly preferably, the compensation element is secured in a rotationally fixed manner to the output element. The compensating part is thereby fixed in a defined constant nominal radius to the output part in such a way that it can be twisted in the circumferential direction relative to the intermediate element. As a result, the compensating element need not participate in a linear relative movement in the radial plane of the torsional vibration damper, as a result of which the compensating element can be configured substantially rotationally symmetrically. Thereby avoiding unnecessary imbalances.

In particular, the compensating part acts indirectly on the intermediate element or the output part via the friction element. A defined, desired damping with friction can be provided by the friction properties, in particular the friction coefficient, of the friction element, in particular in the form of a friction ring. In this case, it is not necessary to provide the compensating element with a defined friction characteristic. Since only low damping with friction is generally required, the friction element can in particular provide a comparatively low coefficient of friction, so that the friction element can be designed more precisely as a slip ring.

Preferably, the intermediate element is provided with a friction element at least on the axial side directed toward the compensation part, wherein in particular the intermediate element is largely enclosed by the friction element. The friction element can be configured, for example, as a coating or as a jacket or sleeve. This makes it easy to fix the friction element with the intermediate element. Damping with friction can be achieved by compensating for the sliding of the component on the friction element.

In particular, the friction element is preferably configured as a, in particular, two-part sleeve for covering the intermediate element over a large area, wherein, in particular, the friction element covers, in particular substantially completely covers, the axial side of the intermediate element. In particular, when the intermediate element together with the friction element performs a linear relative movement in the radial plane of the torsional vibration damper with respect to the compensation part and the compensation part together with the output part performs a relative movement in the circumferential direction with respect to the intermediate element, a larger area can be generated by the superimposed relative movement, in which the compensation part can act on the intermediate element, in particular with spring force. By covering the intermediate part with a friction element over a large area, the same friction can be achieved at almost any relative position.

In particular, the friction element is elastically and/or flexibly configured in the axial direction for the purpose of forming the compensating part. The elastic flexibility of the friction element makes it possible to compensate for the axial play of the intermediate element and thus to form the compensating part itself. At the same time, the elastically compressed friction element can provide a spring force with which the friction element is pressed against the output part and provides friction for damping with friction.

Preferably, the compensating part is supported on the one hand on the intermediate element and on the other hand both on the output element and on the input element, wherein in particular the input element has a first input disk and a second input disk coupled to the first input disk in a rotationally fixed manner, wherein the intermediate element is arranged between the first input disk and the second input disk in the axial direction. The output part and the input part can have different extensions in the radial direction. Thus, for example, it is possible for the output part to be arranged with its output disk radially on the inside and for the input part to overlap the output disk with its input disk radially on the outside. In this way, both the input part and the output part can act on the intermediate element in order to produce the desired kinematic coupling, which is achieved in particular by the interposed cam gear, with a conversion between the rotary motion of the input part and of the output part and the linear motion of the intermediate element. This enables the intermediate element to be supported in the axial direction on the output part in a first (in particular inner) radial range and on the input part in a second (in particular outer) radial range. In this case, the compensating part can be supported axially not only in the first radius range but also in the second radius range, as a result of which tilting of the intermediate element can also be avoided better. In particular, the compensation element is preferably formed by a friction element of the intermediate element which is elastically and/or flexibly formed in the axial direction.

Particularly preferably, the intermediate element is coupled to the input part by means of a first cam mechanism such that a relative rotation of the input part relative to the intermediate element can be converted into a linear movement of the intermediate element towards and/or away from each other, wherein the output part is coupled to the intermediate element by means of a second cam mechanism such that a relative linear movement of the intermediate element relative to each other can be converted into a rotational movement of the output part relative to the intermediate element. In particular, the kinematic coupling of the input part to the intermediate element and/or of the output part to the intermediate element can be achieved by a cam gear which can be configured as shown in DE 102015211899 a1, the content of which is hereby incorporated as part of the present invention.

The invention also relates to a clutch disk for a friction clutch which can be arranged in a drive train of a motor vehicle, having a torsional vibration damper for damping torsional vibrations, which can be constructed and expanded in the manner described above. For example, a friction lining can be fastened to the input part of the torsional vibration damper, which friction lining can be pressed in a friction-locking manner between a pressure plate and a counter-pressure plate of the friction clutch in order to transmit a torque to the clutch disk. By means of the compensating element in the torsional vibration damper, the spontaneous and unpredictable frictional effects can be replaced by a damping with friction which is continuous and which is taken into account when designing the vibration behavior of the torsional vibration damper, so that a good torsional vibration damping can be achieved in the drive train of the motor vehicle.

The invention also relates to a friction clutch for establishing and/or interrupting a torque transmission in a drive train of a motor vehicle, having: a counterplate for introducing a torque originating in particular from a drive shaft of a motor vehicle engine; a clutch disk for the purpose of dissipating torque, in particular to a transmission input shaft of a motor vehicle transmission, which clutch disk can be designed and expanded in the manner described above; and a pressure plate which can be axially displaced relative to the counter plate for frictionally pressing the clutch disk between the counter plate and the pressure plate. By means of the compensating element in the torsional vibration damper, the spontaneous and unpredictable frictional effects can be replaced by a damping with friction which is continuous and which is taken into account when designing the vibration behavior of the torsional vibration damper, so that a good torsional vibration damping can be achieved in the drive train of the motor vehicle.

The invention also relates to a drive train of a motor vehicle, in particular of an electrically drivable motor vehicle, having a flywheel which can be driven by an internal combustion engine and/or an electric motor, and having a torsional vibration damper for damping torsional vibrations, which is connected indirectly or directly to the flywheel and which can be constructed and expanded in the manner described above, wherein the torsional vibration damper is connected, in particular directly or indirectly, to a transmission input shaft of a motor vehicle transmission. By means of the compensating element in the torsional vibration damper, the spontaneous and unpredictable frictional effects can be replaced by a damping with friction which is continuous and which is taken into account when designing the vibration behavior of the torsional vibration damper, so that a good torsional vibration damping can be achieved in the drive train of the motor vehicle.

Drawings

The invention is exemplarily described below according to preferred embodiments with reference to the drawings, wherein the features shown below are capable of presenting one aspect of the invention both individually and in combination, respectively. The figures show:

FIG. 1: a schematic top view of a torsional vibration damper,

FIG. 2: a schematic cross-sectional view of the torsional vibration damper in figure 1 along section a-a,

FIG. 3: a schematic cross-sectional view of an alternative embodiment of the torsional vibration damper in figure 1 along section a-a,

FIG. 4: a schematic perspective view of the compensating member,

FIG. 5: a schematic cross-sectional view of a component of the drive train, an

FIG. 6: schematic cross-sectional view of a friction clutch.

Detailed Description

The torsional vibration damper 10 shown in fig. 1 and 2, which is in the form of a pendulum damper, has an input part 12 which is composed of two outer input disks and which can be, for example, parts of a clutch disk 48 of a friction clutch 42 in a drive train 36 of a motor vehicle. For example, a friction lining of the clutch disk 48 can be arranged on the radially outer edge of the input part 12, through which a torque generated by the motor vehicle engine can be introduced. The input part 12 is coupled via a first cam mechanism 14 to two intermediate elements 16, each of which is in the form of a pendulum. In order to form the first cam gear 14, the input part 12 and the intermediate element 16 can have a suitably configured straight and/or curved track or ramp on which pulleys, rolling bodies or other coupling elements can be guided. Between the two intermediate elements 16, two energy storage elements 18, which extend parallel to one another and are in the form of compression springs, are arranged. When a relative rotation of the input member 12 relative to the intermediate element 16 is caused by torsional vibrations, the relative rotation of the input member 12 can be converted by means of the first cam gear 14 into a linear relative displacement of the intermediate elements 16 towards or away from each other, which is associated with a compression or relaxation of the energy storing element 16. The intermediate element 16 is coupled to an output member 22 via a second cam gear arrangement 20 of substantially similar configuration to the first cam gear arrangement 14. When the intermediate element 16 moves linearly, the linear movement of the intermediate element 16 can be converted into a relative rotation of the output part 22 relative to the intermediate element 16 by means of the second cam gear 20. The output part 22 has a first output disc 24 and a second output disc 26, between which the intermediate element 16 is arranged. The output part 22 can be connected in a rotationally fixed manner to a hub, which has, for example, an internal toothing, in order to be able to form a toothed segment together with a transmission input shaft 40 of a motor vehicle transmission.

The axial play between the intermediate element 16 and the output part 22 can be eliminated by a compensating part 28, which is prestressed in the axial direction, between the intermediate element 16 and the first output disk 24 and/or between the intermediate element 16 and the second output disk 26, as a result of which tilting of the intermediate element 16 out of the radial plane of the torsional vibration damper 10 can be avoided. In this case, the output member 22 can additionally be pressed against the intermediate member 16 by means of a spring force supported on the output member 22 and exert a frictional force. Thus, relative movement of the intermediate element 16 with respect to the output member 22 can be used to provide intentional, frictional damping. In order to adjust the defined friction characteristics, a friction element 30 is provided between the intermediate element 16 and the first output disk 24 on the one hand and the intermediate element 16 and the second output disk 26 on the other hand.

For example, the friction element 30 is coupled to the output part 22, possibly in a rotationally fixed manner, via the interposed output part 22, so that a damping with friction can be achieved by a relative rotation of the output part 22 together with the friction linings 30 on the intermediate element 16 and/or on the compensating part 28. The compensating element 28 can be coupled to the intermediate element 16 or to the output element 22 in a movement-proof manner. Instead, the friction element 30 is coupled to the intermediate element 16, possibly in a movement-proof manner, via the intermediate connected output part 22, so that a damping with friction can be achieved by a relative rotation of the intermediate element 16 together with the friction lining 30 on the output part 22 and/or on the compensation part 28. The compensating element 28 can be coupled to the intermediate element 16 or to the output element 22 in a movement-proof manner. In the embodiment shown in fig. 2, the compensating part 28 is arranged only on one axial side of the intermediate element 16, whereby the intermediate element 16 is supported on the output part 22 on the other axial side without the compensating part 28 connected in between by means of the friction element 30 connected in between. On the axial side of the intermediate element 16 facing the compensating part 28, the compensating part 28 is arranged between the intermediate part 16 and a friction lining 30 supported on the output part 22. However, it is also possible for the compensating part 28 to be supported directly on the output part 22 and to be pressed against the intermediate element 16 by means of the friction linings 30. The friction element 30 is configured, for example, as a separate disc-shaped member. Since the input disk of the input part 12 overlaps the output disks 24, 26 of the output part 22 radially on the outside, the intermediate element 16 can also be supported axially on the input part 12 radially on the outside in a frictionally-loaded manner by means of the friction element 30 and/or the compensating part 28 connected in between.

In the exemplary embodiment of the torsional vibration damper 10 shown in fig. 3, the friction element 30 is configured as a sleeve, which encloses the intermediate element 16 and for this purpose surrounds the intermediate element 16, for example, radially on the inside, in contrast to the exemplary embodiment of the torsional vibration damper 10 shown in fig. 2. Additionally, the friction elements 30 are elastically and/or flexibly configured in the axial direction, so that the friction elements 30, which are clamped at least slightly between the output disks 24, 26, can also eliminate the axial play of the intermediate elements and thus at the same time form the output part 22. In contrast to the exemplary embodiment of torsional vibration damper 10 shown in fig. 2, friction element 30 and compensating part 28 are not formed as separate components from one another, but as a common, one-piece component.

If the compensating element 28 is configured as a separate component with respect to the friction element 30, the compensating element 28 can be configured, for example, as a disk spring which is closed in the circumferential direction. Alternatively, as shown in fig. 4, the compensating element 28 can be configured as a corrugated plate which is arranged as a corrugated plate only in a limited angular range, for example in a substantially tangential orientation. By means of the corrugated shape, the compensating part 28 can have, for example, two first contact surfaces 34 pointing towards the intermediate element 16 and three second contact surfaces 34 pointing towards the output part 22.

A drive train 36, which is partially shown in fig. 5, of a motor vehicle that can be electrically driven, in particular a hybrid motor vehicle, has a flywheel 38, via which the torque generated in the electric machine can be introduced and transmitted to a transmission input shaft 40 of a motor vehicle transmission. A torsional vibration damper 10, which can be constructed and expanded in the manner described above, is arranged in the torque flow between the flywheel 38 and the transmission input shaft 40.

The friction clutch 42 shown in fig. 6 for the drive train 36 of the motor vehicle has a counter plate 44, which can be connected indirectly or directly to the drive shaft of the motor vehicle engine, via which the torque generated by the motor vehicle engine can be introduced. A clutch disk 48 connected to the transmission input shaft 40 in a rotationally fixed manner can be pressed in a friction-locked manner by means of a pressure plate 46 that can be displaced axially relative to the counter-pressure plate 44. The clutch disk 48 has a torsional vibration damper 10 which functions as a disk damper and can be constructed and expanded in the manner described above.

List of reference numerals

10 torsional vibration damper

12 input unit

14 first cam gear

16 intermediate element

18 energy storage element

20 second cam gear

22 output member

24 first output tray

26 second output tray

28 compensating part

30 Friction element

32 first contact surface

34 second contact surface

36 drive train

38 flywheel

40 transmission input shaft

42 friction clutch

44 pairs of pressing plates

46 extrusion plate

48 clutch disc