阅读说明：本技术 具有扭矩限制器的扭振减振器 (Torsional vibration damper with torque limiter ) 是由 马丁·黑斯勒 阿兰·鲁施 洛朗·塞里奥特 于 2018-05-04 设计创作，主要内容包括：本发明涉及一种具有扭矩限制器的扭振减振器(10),尤其用于机动车的动力传动系内的离合器盘,其具有能围绕转动轴线(12)转动地支承的输入部件(14)和相对于输入部件(14)能围绕转动轴线(12)抵抗弹簧装置(16)的作用有限地转动地设置的输出部件(18),其中在输入部件(14)和输出部件(18)之间设置有至少两个传递力矩的中间元件(20),所述中间元件在输入部件(14)和输出部件(18)相对转动时借助于凸轮传动机构(22)径向移动,其中通过凸轮传动机构(22)的设计方案和/或弹簧装置(16)的构成方案,在输入部件和输出部件之间相对转动时形成驱动力矩关于转动角的扭转特性曲线(32),扭转特性曲线具有减振器级(34)和邻接于减振器级(34)的末级(36),其中减振器级(34)说明驱动力矩关于转动角的减振器性能,并且末级(36)包括驱动力矩关于转动角的扭矩极限。(The invention relates to a torsional vibration damper (10) with a torque limiter, in particular for a clutch disk in a drive train of a motor vehicle, having an input part (14) which is mounted so as to be rotatable about a rotational axis (12) and having an output part (18) which is arranged so as to be rotatable about the rotational axis (12) relative to the input part (14) to a limited extent against the action of a spring device (16), wherein at least two torque-transmitting intermediate elements (20) are arranged between the input part (14) and the output part (18) and are radially displaceable by means of a cam mechanism (22) during the relative rotation of the input part (14) and the output part (18), wherein a torsional characteristic curve (32) of the drive torque is formed during the relative rotation between the input part and the output part with respect to the rotational angle by means of the design of the cam mechanism (22) and/or the design of the spring device (16), the torsional characteristic curve has a damper stage (34) and an end stage (36) adjoining the damper stage (34), wherein the damper stage (34) specifies a damper behavior of the drive torque with respect to the pivot angle, and the end stage (36) comprises a torque limit of the drive torque with respect to the pivot angle.)

1. A torsional vibration damper (10) with a torque limiter, in particular for a clutch disk in a drive train of a motor vehicle, having an input part (14) which is mounted rotatably about a rotational axis (12) and an output part (18) which is arranged rotatably about the rotational axis (12) relative to the input part (14) in a limited manner about the rotational axis (12) counter to the action of a spring device (16), wherein the torsional vibration damper has a torque limiter, wherein the output part (18) is connected to the input part (14) in a rotationally fixed manner about the

At least two torque-transmitting intermediate elements (20) are arranged between the input part (14) and the output part (18), which are radially displaced by means of a cam mechanism (22) when the input part (14) and the output part (18) rotate relative to one another, wherein

By means of the design of the cam mechanism (22) and/or the design of the spring device (16), a torsional characteristic curve (32) of the drive torque over the pivot angle is formed during the relative rotation between the input part and the output part, said torsional characteristic curve having a damper stage (34) and an end stage (36) adjoining the damper stage (34), wherein the damper stage (34) specifies the damper behavior of the drive torque over the pivot angle, and the end stage (36) comprises a torque limit of the drive torque over the pivot angle.

2. The torsional vibration damper as claimed in claim 1, characterized in that the torsional characteristic curve (32) of the final stage (36) comprises a decreasing, constant and/or slightly increasing moment curve with respect to the angle of rotation.

3. The torsional vibration damper according to claim 1 or 2, characterized in that the cam drive is formed in each case by a radially acting ramp device (26), wherein the ramp devices (26) in the pulling direction and in the pushing direction have in each case two mutually adjoining, mutually different profiles (28).

4. The torsional vibration damper as claimed in claim 3, characterized in that the profiles (28) adjoining one another have a linear, convex and/or concave design and/or are formed in a free shape.

5. The torsional vibration damper as claimed in claim 3 or 4, characterized in that a triggering moment is formed at the transition (40) between the profiles (28) of the ramp device (26) adjoining one another in the pulling direction and/or pushing direction.

6. The torsional vibration damper as claimed in any of claims 3 to 5, characterized in that rolling bodies (30) are provided between mutually complementary contours (28) of the ramp device (26) of the cam gear (22).

7. The torsional vibration damper as claimed in any of claims 3 to 6, characterized in that the profiles (28) of the ramp device (26) in the pulling direction and in the pushing direction are constructed differently from one another.

8. A clutch disc for arrangement in a drive train of a motor vehicle, having a torsional vibration damper (10) according to one of the preceding claims.

9. A flywheel having a clutch disk according to claim 8, with a torsional vibration damper, wherein an input part of the torsional vibration damper is connected to the flywheel in a rotationally fixed and/or rotationally fixed manner.

Technical Field

The invention relates to a torsional vibration damper with a torque limiter, in particular for a clutch disk in a drive train of a motor vehicle.

The invention further relates to a clutch disk for arrangement in a drive train of a motor vehicle, having a torsional vibration damper according to the invention.

The invention further relates to a flywheel having a clutch disk with a torsional vibration damper according to the invention.

Background

Torsional vibration dampers are generally known and are usually arranged between the crankshaft of an internal combustion engine and the drive shaft of a motor vehicle. The crankshaft is excited by periodic disturbances by the stroke of the internal combustion engine. In order to prevent disturbances from being transmitted to the drivetrain, torsional vibration dampers are provided which shift disturbing resonances occurring in different operating situations into a rotational speed range which is as low as possible below the operating rotational speed. The resonance remaining in the operating speed range can be damped by the integrated friction device.

In order to protect the drive train against excessive torques in the event of a shock, torsional vibration dampers are designed in some applications with overload clutches, which are typically designed as serial friction clutches, which slip when a certain torque is exceeded and absorb the energy of the shock.

A device for absorbing torque fluctuations is known, for example, from EP1602854a 2. The device is arranged between the crankshaft of the engine and the input shaft on the driven side. The crankshaft is connected with the flywheel, and a damping unit is arranged on the crankshaft and provided with a friction lining. The input shaft has a pair of drive disks, a disk driven between the drive disks, and a spring damper. The damping unit acts between the drive disks by means of friction linings and the spring damper exerts a spring force on the friction linings, wherein the friction linings can slip when they absorb at least one predetermined torque magnitude, thereby limiting the torque or absorbing an impact.

The accuracy with which the desired activation torque of the torque limiter can be set is limited by the contact pressure of the spring damper and the rigidity of the component accommodating the spring damper.

Furthermore, a torsional vibration damper is known from DE102015211899a1, which has an input part arranged about a rotational axis and an output part which is rotatable relative to the input part about the rotational axis to a limited extent against the action of a spring device. The conversion of the relative vibrations within the torsional vibration damper into an axial actuation of the spring device is based solely on the free movement between the components with rolling contact. The torsional vibration damper allows, given the performance of the spring arrangement, different torsional characteristic curves to be plotted by the change in the transformation, which torsional characteristic curves each utilize the entire capacity of the energy store. However, the triggering of the torque limiter is not described.

There is a general need for improving torsional vibration dampers having a torque limiter in order to be able to adjust the triggering torque precisely. There is also a general need to reduce the manufacturing costs and simplify the construction of a torsional vibration damper with a torque limiter.

Disclosure of Invention

The object of the invention is to provide a torsional vibration damper with a torque limiter, the triggering torque of which can be adjusted in a simple manner. It is also an object to specify a torsional vibration damper with a torque limiter which can have a reduced installation space and reduced production costs.

This object is achieved according to the invention by a torsional vibration damper with a torque limiter having the features of claim 1, by a clutch disk having the features of claim 8 and by a flywheel having a clutch disk having a torsional vibration damper according to the invention having the features of claim 9. Preferred embodiments of the invention are given in the dependent claims and in the following description, which respectively, individually or in combination, can show aspects of the invention. All combinations and individual combinations between the features of the torsional vibration damper, the features of the clutch disk and the features of the flywheel with the clutch disk can be used together. Furthermore, it is also correspondingly proposed and possible to combine the individual features or a plurality of features of the torsional vibration damper, the clutch disk and the flywheel having the clutch disk as desired.

According to the invention, a torsional vibration damper with a torque limiter, in particular for a clutch disk in a drive train of a motor vehicle, having an input part which is mounted so as to be rotatable about a rotational axis and having an output part which is arranged so as to be limitedly rotatable about the rotational axis relative to the input part against the action of a spring device, wherein at least two torque-transmitting intermediate elements are arranged between the input part and the output part, which intermediate elements are radially displaced by means of a cam mechanism during a relative rotation of the input part and the output part, wherein a torsional characteristic curve of the drive torque with respect to the rotational angle is formed during the relative rotation between the input part and the output part by means of a design of the cam mechanism and/or a design of the spring device, which torsional characteristic curve has a damper stage and a final stage which adjoins the damper stage, wherein the damper stage describes a damper behavior of the drive torque with respect to the pivot angle, and the final stage comprises a torque limit of the drive torque with respect to the pivot angle.

Aspects of the invention are therefore: the torsional vibration damper with the torque limiter has an input part which is rotatably supported about a rotational axis and an output part which is arranged in a rotationally limited manner about the rotational axis relative to the input part against the action of a spring device. The input element can preferably be operatively connected to a flywheel arranged on a drive shaft of the motor vehicle. In particular, the input element can preferably be fixedly connected to the flywheel. The drive shaft can preferably be a crankshaft. The output part is preferably coupled or fixedly connected to a drive shaft of a motor vehicle transmission. At least two torque-transmitting intermediate elements are arranged between the input part and the output part, said intermediate elements being designed to be radially displaced by means of a cam mechanism when the input part and the output part are rotated relative to each other. During the relative rotation between the input part and the output part, a torsional characteristic of the drive torque over the rotation angle is formed by the design of the cam mechanism and/or the design of the spring device. The torsional characteristic curve has a damper stage and an end stage adjoining the damper stage, the damper stage specifying a damper behavior of the drive torque with respect to the pivot angle, and the end stage including a torque limit of the drive torque with respect to the pivot angle. In other words, due to the design of the cam mechanism and/or the design of the spring device, a torque transmission is achieved in the damper stage with respect to the rotation angle in relation to the torsional characteristic curve during the relative rotation between the input part and the output part. The final stage is started by reaching the trigger torque, i.e. a predefined threshold value, wherein the torque transmission is limited when the angle of rotation increases, whereby preferably shocks can be absorbed. The torque-transmitting triggering torque can thus be precisely determined by the design of the cam mechanism and/or the design of the spring device. Furthermore, the installation space can be reduced, since the torque limitation is preferably realized by the design of the cam mechanism. Thereby also reducing the manufacturing cost.

A preferred embodiment of the invention consists in: the final torsional characteristic curve comprises a decreasing, constant and/or slightly increasing moment curve with respect to the angle of rotation. The cam mechanism thus has a transition after the trigger torque has been reached, i.e. when the final stage is reached, so that, during further rotation between the input part and the output part and during further compression of the spring device, an increase in the transmitted drive torque can be reduced and/or avoided. The transmitted torque is preferably designed to be returned, constantly maintained and/or slightly increased with respect to the angle of rotation of the final stage, in each case as follows: the energy of the impact can be absorbed in the spring elements of the torsional vibration damper. In the slightly elevated torque curve, the torque rise is preferably less than 50% of the maximum torque rise in the damper stage.

In an advantageous embodiment of the invention, it is provided that: the cam mechanism is formed in each case by a radially acting ramp device, wherein the ramp devices in the pulling direction and in the pushing direction have in each case two mutually adjacent contours which differ from one another. This means that the ramp, starting from the neutral position, has two mutually adjacent, mutually different profiles in the pulling direction and in the pushing direction, respectively. The switching of the cam mechanism can therefore preferably be formed by the design of the ramp device of the cam mechanism.

In this respect, an advantageous embodiment of the invention consists in: the contours adjoining one another have a linear, convex and/or concave design and/or are formed in a free form. Preferably, the first contour can have a concave design in the pulling direction and the second contour adjoining the first contour can have a straight design. It is likewise conceivable for the first contour and the second contour to have a straight-line design, the slope of the straight-line first contour differing from the slope of the straight-line second contour.

According to a preferred embodiment of the invention, provision is made for: the transition between the profiles of the ramp device that adjoin one another in the pulling direction and/or pushing direction forms and/or defines a triggering moment. In this way, the triggering torque can be determined precisely via the transitions between the contours. The configuration of the second contour thus enables the switching of the cam mechanism to be determined such that the final torsional characteristic curve has a constant and/or slightly increasing torque curve with respect to the angle of rotation after the triggering torque is reached or exceeded.

In a preferred embodiment of the invention, it is provided that: rolling bodies are arranged between mutually complementary contours of the ramp device of the cam gear. The rolling bodies are preferably designed as free-rolling, roller-shaped rolling elements which, for axial locking, can preferably have an at least partially circumferential annular edge at the respective end. In this way, the relative rotation between the input part and the output part can be converted into a movement of the intermediate element, preferably via the contour of the ramp device in the cam mechanism, by means of a corresponding freely rolling roller body arranged in the cam mechanism between two complementary contours, whereby the spring elements can be actuated in parallel and purely axially, for the same pulling and pushing loads. The torque required for the movement is first transmitted from the input part to the intermediate element via the corresponding contour and rolling bodies of the ramp device and subsequently from the intermediate element to the output part via the corresponding contour and rolling bodies.

In principle, the profile of the ramp device in the pulling direction and the pushing direction can be designed identically. A preferred embodiment of the invention consists in: the profiles of the ramp device in the pulling direction and the pushing direction are configured differently from one another. In this way, different torsional characteristic curves in the pulling direction and in the pushing direction can be generated.

The invention further relates to a clutch disk for arrangement in a drive train of a motor vehicle, having a torsional vibration damper according to the invention, which has a torque limiter.

The clutch disk is preferably arranged between a drive shaft, preferably a crankshaft, of a motor vehicle and a drive shaft of a motor vehicle transmission. In particular, the clutch disk is preferably arranged between a flywheel, which is arranged on the crankshaft, and a drive shaft of a motor vehicle transmission.

In a preferred embodiment of the invention, it is provided that: the input part of the torsional vibration damper is connected to the flywheel in a rotationally fixed manner. The rotationally fixed connection between the input part and the flywheel can preferably be produced by screwing and/or riveting. However, it is also conceivable: the rotationally fixed connection between the input part and the flywheel can be produced in other ways and methods. The output part is preferably coupled in a rotationally fixed manner to a driveshaft of a motor vehicle transmission. In the case of a relative rotation between the input element and the output element, in particular in the case of a crash, i.e. a large collision with a rotational speed difference between the crankshaft and the driveshaft of the motor vehicle transmission, the input element does not slip, as is usual in slip clutches. At least two torque-transmitting intermediate elements are arranged between the input part and the output part, said intermediate elements being designed to be radially displaced by means of a cam mechanism when the input part and the output part are rotated relative to each other. During the relative rotation between the input part and the output part, a torsional characteristic of the drive torque over the rotation angle is formed by the design of the cam mechanism and/or the design of the spring device. The torsional characteristic curve has a damper stage and an end stage adjoining the damper stage, the damper stage specifying a damper behavior of the drive torque with respect to the pivot angle, and the end stage including a torque limit of the drive torque with respect to the pivot angle. In other words, due to the design of the cam mechanism and/or the design of the spring device, a torque transmission is achieved in the damper stage with respect to the rotation angle in relation to the torsional characteristic curve during the relative rotation between the input part and the output part. The final stage is started by reaching the trigger torque, i.e. a predefined threshold value, wherein the torque transmission is limited when the rotation angle increases, whereby shocks can be absorbed. The torque-transmitting triggering torque can thus be precisely determined by the design of the cam mechanism and/or the design of the spring device.

The invention further relates to a flywheel having a clutch disk with a torsional vibration damper according to the invention, wherein an input part of the torsional vibration damper can be connected to the flywheel in a rotationally fixed manner and/or to the flywheel in a rotationally fixed manner. In this way, the clutch disk is not coupled as a slip clutch with the flywheel. Via the rotationally fixed connection of the input part to the flywheel, there is preferably a rotationally fixed connection that is non-positive. The rotationally fixed connection can preferably be a screw connection and/or a rivet connection. However, other connection possibilities are also conceivable, via which a rotationally fixed connection between the flywheel and the input part can be produced.

Drawings

The invention is explained in a schematic manner in the following according to preferred embodiments with reference to the drawing, wherein the features shown below are able to show aspects of the invention both individually and in combination. The figures show:

figure 1 shows a schematic view of a torsional vibration damper with a torque limiter according to a preferred embodiment of the invention,

figure 2 shows a schematic view of a cam gear mechanism according to a preferred embodiment of the invention,

figure 3 shows an implementation of the torsion characteristic with a final stage according to a preferred embodiment of the invention,

figure 4 shows another embodiment of the torsion characteristic with the final stage according to a preferred embodiment of the invention,

fig. 5 shows a further embodiment of a torsional characteristic curve with a final stage according to a preferred embodiment of the invention.

Detailed Description

Fig. 1 shows a schematic illustration of a torsional vibration damper 10 with a torque limiter. The torsional vibration damper 10 comprises an input part 14 which is mounted so as to be rotatable about a rotational axis 12 and an output part 18 which is arranged so as to be limitedly rotatable about the rotational axis 12 relative to the input part 14 against the action of a spring device 16. Two torque-transmitting intermediate elements 20 are arranged between the input part 14 and the output part 18, which are each coupled to the input part 14 and the output part 18 via a cam mechanism 22 and are formed so as to be radially displaceable when the input part 14 and the output part 18 rotate relative to one another. Between the intermediate elements 20, a spring device 16 is provided, which comprises at least two spring elements 24 or energy stores arranged at a distance from one another.

The input part 14 is thus coupled to the output part 18 via the intermediate elements 20, two cam gears 22 being formed between the input part 14 and the respective intermediate elements 20, and the output part being coupled to the respective intermediate elements 20 via the cam gears 22. The respective cam mechanism 22 is of identical design, the cam mechanism 22 between the input part 14 and the intermediate element 20 being illustrated in schematic detail and in detail in fig. 2.

The cam mechanism 22 is formed by ramp devices 26 formed on the input part 14 and on the intermediate element 20, which ramp devices 26 are arranged complementary to one another, wherein the respective ramp device 26 has two mutually adjacent, mutually different profiles 28, namely a first profile 28a and a second profile 28b, in the pulling direction and in the pushing direction, and between the ramp devices 26 rolling elements 30 in the form of roller-shaped rolling elements are provided.

In principle, the contours 28 adjoining one another can have a linear, convex, concave design or be formed in a free form. In the present exemplary embodiment, the first contour 28a and the second contour 28b adjoining one another each have a design with straight lines having respectively different slopes.

During the relative rotation between the input part 14 and the output part 18, a torsional characteristic curve 32 of the drive torque over the angle of rotation is formed by the design of the cam mechanism 22 and the design of the spring device 16, as can be seen in fig. 3 to 5. The torsional characteristic 32 has a damper stage 34 and an end stage 36 adjoining the damper stage 34, the damper stage 34 specifying a damper behavior of the drive torque with respect to the pivot angle, and the end stage 36 including a torque limit of the drive torque with respect to the pivot angle. In other words, due to the design of the cam mechanism 22, in particular the design of the contour 28 of the ramp device 26 of the cam mechanism 22 and the design of the spring device 16, a torque transmission is achieved in the damper stage 34 with respect to the angle of rotation in relation to the torsional characteristic curve 32 during the relative rotation between the input part 14 and the output part 18. The final stage is started by reaching the triggering moment 38, wherein the torque transmission is limited when the rotation angle increases, whereby preferably shocks can be absorbed.

The profiles 28 of the ramp device 26, in particular the transition 40 between the first profile 28a and the second profile 28b, which adjoin one another in the pulling direction and/or pushing direction, preferably define a triggering moment. The torque-transmitting activation torque 38 can therefore be precisely determined by the design of the cam mechanism 22.

Fig. 3 to 5 show diagrams of various torsional characteristic curves 32 in which a torque or a drive torque is shown with respect to the angle of rotation of the input member 14 relative to the output member 18. The torsional characteristic 32 is effective in the thrust direction and the traction direction and has two damping stages 34 and a single final stage 36 adjoining the damping stages 34 as the angle of rotation increases. The design of the pushing and pulling steps of the torsion characteristic curve is achieved by the design of the ramp device 26, in particular of the contour 28, and the design of the spring device 16.

The damping stage 34 has a first, softer spring stage and a second, harder spring stage. After reaching the threshold value of the drive torque, i.e. the trigger torque 38 and the predefined pivot angle, no further or significant torque increase takes place in the final stage 36. The cam mechanism thus has a transition after reaching the trigger torque 38, i.e. during the transition into the final stage 36, so that the torque transmitted does not increase further during further rotation and further compression of the spring device 16. The transmitted torque returns with respect to the angle of rotation of final stage 36, which is shown in final stage 36 by the falling curve of torsion curve 32.

Fig. 4 shows a further torsional characteristic 32. In contrast to the torsional response curve 32 shown in fig. 3, the curve in the final stage 36 is constant.

Fig. 5 shows a further torsional characteristic 32. In contrast to the torsional characteristic curve 32 shown in fig. 3, the curve of the torsional characteristic curve 32 in the final stage 36 has a torque curve that rises slightly with respect to the angle of rotation. In the slightly increased torque curve, the torque increase is less than 50% of the maximum torque increase in the damping stage 34.

The torque or drive torque thus transmitted is therefore designed to be returned, constantly maintained and/or slightly increased in relation to the angle of rotation of the final stage 36, in each case as follows: the energy of the impact can be absorbed in the spring elements 16 of the torsional vibration damper 10.

List of reference numerals

10 torsional vibration damper

12 axis of rotation

14 input unit

16 spring device

18 output member

20 intermediate element

22 cam transmission mechanism

24 spring element

26 ramp device

28 profile

28a first profile

28b second profile

30 rolling element

32 torsion characteristic curve

34 damper stage

36 last stage

38 triggering moment

40 transition part