DE102017215402A1 - Torsionsschwingungsdämpfer with at least one energy storage device - Google Patents

Abstract

A torsional vibration damper (1; 1a; 1b) is provided with at least one energy storage device (46) which has an input (36) connected to a coupling device (18) and an output (56) which is rotatable relative to the same against the action of at least one energy reservoir (45) 56a, 56b) and a rotational angle stop (42) delimiting the rotational guidance of the output (56; 56a; 56b) relative to the input (36). The torsional vibration damper (1; 1a; 1b) is further formed with a damper system (55,55b) having at least one damper mass support (49; 49b) for receiving at least one damper mass (74; 74b) movable relative thereto the absorber mass support (49; 49b) of the absorber system (55, 55b) acts as an output (56; 56a; 56b) of the energy storage device (46). The rotational angle stop (42) is provided at a position of the energy storage device (46) which is in the transmission direction of a torque transmitted from the coupling device (18) in front of the at least one energy store (45) of this energy storage device (46), so that one by the rotational angle stop (42) is ensured limitation of the Tilgermassenträger (49, 49b) via the at least one energy storage (45) supplied torque to a predetermined limit torque is ensured.

Description

The invention relates to a torsional vibration damper with at least one energy storage device, which has an input connected to a coupling device and a rotatable relative to the same against the action of at least one energy storage output and a rotation of the output relative to the input limiting rotational angle stop, and with a Tilgersystem, the at least one Tilgermassenträger has, which serves to receive at least one relative to the same movable absorber mass, wherein the absorber mass carrier of the absorber system is effective as an output of the energy storage device.

Such a torsional vibration damper is from the DE 10 2012 212 125 A1 known. This torsional vibration damper has two energy storage devices provided in series with one another, of which the energy storage device which is located on the drive side in the transmission direction of a torque transmitted by the coupling device is fastened with its input to a piston of the coupling device. The output of this at least one energy storage having energy storage device serves as Tilgermassenträger a Tilgersystems, and thus absorbs absorber masses relatively movable. The Tilgermassenträger is provided as well as the piston of the coupling device with recesses for receiving spacers, which are effective in conjunction with the recesses in each case as a rotational angle stop by limiting the Dreirlenkung the output relative to the input. The rotational angle stop is provided at a position of the energy storage device, which is located in the transmission direction of a torque transmitted by the coupling device behind the at least one energy storage. The torque load to be borne by the energy storage device of the energy storage device is limited to a predetermined limit torque by the rotational angle stop. In contrast, with regard to the load on the absorber mass carrier and thus of the absorber system at torques which exceed the predetermined limit torque, the rotational angle stop does not bring any advantage.

The absorber mass carrier has two Tilgermassenträgerelemente arranged with axial offset from each other, one of which is provided with a radial guide and with a drive for at least one energy storage of a second energy storage device, and therefore serves as an input of this second energy storage device. As the output of the second energy storage device, the turbine wheel is effective, which is connected to an output of the torsional vibration damper in the form of a non-rotatable with a transmission input shaft hub. The at least one energy store of the second energy storage device is arranged radially clearly outside the at least one energy store of the first energy storage device.

The invention has for its object to form a Torsionsschwingungsdämpfer with a Tilgersystem such that the Tilgermassenträger and thus the absorber system when initiating a delivered via a coupling device torque that exceeds a predetermined limit torque, are loaded only by a torque which does not exceed the predetermined limit torque ,

This object is achieved by a torsional vibration damper with at least one energy storage device which has an input connected to a coupling device and a rotatable relative to the same against the effect of at least one energy storage output and a rotation of the output relative to the input limiting rotational angle stop, and with a Tilgersystem having at least one Tilgermassenträger, which serves to receive at least one relative to the same movable absorber mass, wherein the absorber mass carrier of the absorber system is effective as an output of the energy storage device.

Of particular importance here is that the rotational angle stop is provided at a position of the energy storage device, which is in the transmission direction of a torque transmitted by the coupling device in front of the at least one energy storage of this energy storage device, so that caused by the rotational angle stop limiting the Tilgermassenträger on the at least an energy storage supplied torque is guaranteed to a predetermined limit torque.

By arranging the rotational angle stop at a position of the energy storage device, which is in the transmission direction of a torque transmitted by the coupling device before the at least one energy storage of this energy storage device, a coming from the coupling device torque is forwarded under deformation of the at least one energy storage in full to the Tilgermassenträger, as long as this torque does not exceed the predetermined limit torque. As soon as the torque coming from the clutch device reaches the value of the predetermined limit torque, the rotational angle stop comes into effect, by determining the relative movement between the input of the energy storage device and whose output, so terminated the Tilgermassenträger, and thereby limits the relative movement in total. If it then comes to a further increase in the torque coming from the coupling device, then the effect of the rotation angle stop continues, so that then only the predetermined torque limit corresponding part of the torque via the at least one energy storage to the output of the energy storage device and thus to the Tilgermassenträger is transmitted. Since the rotational angle stop does not permit a transmission of a torque exceeding the limit torque, the portion of the torque coming from the clutch device beyond the limit torque must be conducted along another transmission path, and is therefore conducted directly to the output of the energy storage device before the at least one energy store, and from there to a downforce. Due to the aforementioned positioning of the rotational angle stop relative to the at least one energy storage not only this energy storage is protected from an unduly high load, but equally the Tilgermassenträger, as this is also exposed in the transmission of torque only torques that do not exceed the predetermined limit torque. The rotational angle stop thus positioned is particularly important if, in addition to a torque supplied by an internal combustion engine and optionally by an electric machine, user-related torque peaks may also occur, for example during start-stop operations, recuperation processes or when sailing the corresponding motor vehicle with the internal combustion engine switched off.

In order for the angle stop to fulfill its function, it is structurally necessary for the output of the energy storage device in the transmission direction of a torque transmitted by the coupling device to be guided behind the absorber masses to the input of the energy storage device in order to attack there via the rotational angle stop at the input of the energy storage device.

With particular preference, the previously discussed energy storage device is associated with a further energy storage device. The first-mentioned energy storage device would then act on the further energy storage device on the aforementioned output, which may be, for example, a standing in rotation with a transmission input shaft hub.

If at least one further energy storage device is present, the output of the first-mentioned energy storage device and thus the absorber mass carrier would be effective as an input of the at least one further energy storage device. Since at least one further energy storage device is associated with the input of the at least one further energy storage device, an advantageous embodiment of this at least one further energy storage device is the input of this further energy storage device via at least one further rotation restricting the output relative to the input Tilt angle stop to the output.

With particular preference, the input of the further energy storage device is formed by two cover elements, of which at least one with axial offset, but with radial overlap, is arranged relative to the input of the first energy storage device, the inputs of both energy storage devices are provided with recesses for receiving in each case at least one spacer element, which together with the corresponding recesses in each case serves to form the angle of rotation stop.

An advantageous structural design of a rotational angle stop, here in particular the further rotational angle stop for the further energy storage device is present when the input of the further energy storage device is formed by two cover elements, of which at least one as well as the output of the further energy storage device with recesses for receiving in each case at least one Spacer are provided which serves together with the recesses to form the further rotational angle stop.

It is particularly advantageous if the further rotational angle stop is formed in the axial direction with a plurality of diameter steps, wherein cross-sectional transitions between the individual diameter steps form Axialanlageflächen for each adjacent components. The cross-sectional transitions therefore allow axial positioning of individual components relative to one another.

It is particularly advantageous if the at least one further energy storage device is provided radially inside the first energy storage device, while the input of the first energy storage device is guided into a radially outer region in which the at least one energy store of the first energy storage device is located. With such an arrangement of the two energy storage device relative to one another, centering and axial positioning of the first energy storage device via the further energy storage device can take place in a simple manner, and with advantage over the latter Downforce, while the first energy storage device is disposed at a position where it can develop a maximum damping effect due to sufficient space for relatively expansive energy storage.

The absorber system of the present torsional vibration damper may be formed either with an absorber mass carrier, which is provided with two absorber mass carrier elements arranged with axial offset relative to one another and spacers at a fixed distance from one another, or with an absorber mass carrier which has only a single absorber mass carrier element. In the former embodiment, the two Tilgermassenträgerelemente take the at least one absorber mass axially between them, and only one of Tilgermassenträgerelemente is firmly connected to at least one of the cover elements of the input of the other energy storage device, while in the other embodiment, the individual Tilgermassenträgerelement arranged axially between each other with axial offset Tilgermassen is provided, and is firmly connected by means of a connecting element with at least one of the cover elements of the input of the further energy storage device.

An advantageous embodiment of those energy storage device in which the rotational angle stop is provided at a position which is in the transmission direction of a torque transmitted from the coupling device before the at least one energy storage of this energy storage device, is present when an output of the coupling device rotatably connected to the input of the energy storage device is by the output of the coupling device and the input of the energy storage device are arranged with an axial offset to one another, which allows a recording of the output of the energy storage device in a predetermined common radial region axially between the output of the coupling device and the input of the energy storage device.

• 1 den Torsionsschwingungsdämpfer mit einem Tilgersystem, bei welchem der Tilgermassenträger über mit Axialabstand zueinander angeordnete Tilgermassenträger verfügt, die axial zwischen sich zumindest eine Tilgermasse aufnehmen, wobei der Torsionsschwingungsdämpfer in einem Gehäuse eines nasslaufenden Anfahrelementes in Form eines hydrodynamischen Drehmomentwandlers aufgenommen ist;
• 2 eine vergrößerte Herauszeichnung des Torsionsschwingungsdämpfers gemäß der 1;
• 3 eine Draufsicht auf den Torsionsschwingungsdämpfer der 2 gemäß der in 2 eingezeichneten Schnittlinie A - A;
• 4 wie 2, aber mit einem Tilgersystem, bei welchem der Tilgermassenträger lediglich ein einzelnes Tilgermassenträgerelement mit axial beidseitigen Tilgermassen aufweist.

The torsional vibration damper is shown below with reference to selected embodiments. It shows:

• 1 the torsional vibration damper with a Tilgersystem in which the Tilgermassenträger has spaced axially spaced Tilgermassenträger axially absorb at least one absorber mass between them, the Torsionsschwingungsdämpfer is accommodated in a housing of a wet-running starting element in the form of a hydrodynamic torque converter;
• 2 an enlarged drawing of the torsional vibration damper according to the 1 ;
• 3 a plan view of the torsional vibration damper of 2 according to the in 2 drawn section line A - A;
• 4 as 2 but with an absorber system in which the absorber mass carrier has only a single absorber mass carrier element with absorber masses on both sides.

In 1 is a torsional vibration damper 1a in a housing 2 a wet-running starting element 3 , which is designed as a hydrodynamic torque converter, added. The housing 2 has in the radially outer region on its inner side a toothing 4 on, in which a gearing 5 of drive-side coupling elements 6 intervene rotatably. The drive-side coupling elements 6 can under the action of a piston 7 with output side coupling elements 8th be brought into operative connection by means of a toothing 9 with a toothing 10 a gearing carrier 12 rotatably engaged. The piston 7 standing on a cabinet hub 13 of the housing 2 sealing centered, can in the extension direction of a central axis 15 axially displaced, and is as well as the coupling elements 6 and 8th as well as the gearing carrier 12 Part of a coupling device 18 ,

The piston 7 is used to engage the coupling device 18 in the direction of the coupling elements 6 and 8th displaces, and presses this, a frictional force between the coupling elements 6 and 8th generating against one in the teeth 4 of the housing 2 recessed retaining ring 19 as soon as in a first pressure room 20 that axially between a drive, not shown, such as an internal combustion engine, facing the drive side wall 21 and the piston 7 is provided, an overpressure relative to a second pressure chamber 22 is present, which is the opposite side of the piston 7 can apply. The supply of the pressure chambers 20 and 22 takes place, inter alia, in a manner not shown in detail via flow channels 23 and 24 in the housing hub 13 ,

The housing hub 13 serves to center a hub 25 of the torsional vibration damper 1a that as an output 26 serves, and rotationally fixed with a transmission input shaft, not shown.

An output side wall 28 of the housing 2 forms an impeller shown only schematically 30 of the wet-running starting element 3 that with a turbine wheel 31 interacts. Axial between the impeller 30 and the turbine wheel 31 is also just a schematic illustrated stator 32 shown on a likewise schematically illustrated freewheel 33 is centered.

The as part of the coupling device 18 effective gearing carrier 12 is just like a torsional vibration damper 1 in 2 out drawn.

As 2 shows in detail is the gearing carrier 12 and thus the coupling device 18 by means of spacers 35 with an entrance 36 of the torsional vibration damper 1 connected, with axial distance between the coupling device 18 and the entrance 36 , The spacers 35 are with an axial middle part 37 formed, which has a larger diameter than the axial end portions 38a . 38b , With this axial middle part 37 passes through the respective spacer 35 Recesses in two adjacent cover elements 39 . 40 , where these recesses 41 , as 3 clearly shows, extend in the circumferential direction further than this with respect to the diameter of the axial center part 37 of the respective spacer 35 would be required. The recesses 41 therefore grant the spacers 35 a relative displacement in the circumferential direction, so that also between the coupling device 18 and the entrance 36 of the torsional vibration damper 1 on the one hand and the two cover elements 39 . 40 on the other hand, a relative rotational displacement is possible. This Relativauslenkung can persist until the middle part 37 of the respective spacer 35 at one of the peripheral end edges 77 the respective recess 41 ( 3 ) comes into contact. The spacers 35 thus act together with the respective recesses 41 as a rotation angle stop 42 ,

The entrance 36 of the torsional vibration damper 1 engages, starting from its attachment point to the coupling device 18 , radially outward, and has a drive 44 for at least one energy store 45 a first energy storage device 46 , The at least one energy storage 45 On the other hand, it is supported on the circumference by a control system 47 from on a driven side Tilgermassenträgerelement 48 a Tilgermassenträgers 49 by means of a riveting 50 is attached. The output side absorber mass carrier element 48 continues to take by means of this riveting 50 a radial guide 51 for the at least one energy store 45 on.

The output side absorber mass carrier element 48 is to the formation of the Tilgermassenträgers 49 in its radially inner region via spacers 52 with a drive-side Tilgermassenträgerelement 53 connected by means of spacers 52 rotationally fixed and at a fixed axial distance to the output side Tilgermassenträgerelement 48 is held. Axial between the two Tilgermassenträgerelementen 48 and 53 are absorber masses 74 relatively movable relative to the Tilgermassenträgerelementen 48 and 53 and together with them form a system of extermination 55 ,

The drive-side Tilgermassenträgerelement 53 is radially inside the spacers 52 by means of further spacers 54 on the driven-side cover element 40 the already mentioned cover elements 39 . 40 attached. This output-side cover element 40 is by means of the other spacers 54 with the drive-side cover element 39 firmly connected. The two cover elements 39 . 40 are together with the Tilgermassenträger 49 as an exit 56 the first energy storage device 46 effective.

The two cover elements 39 . 40 serve as an entrance at the same time 57 a second energy storage device 58 , and therefore point into energy storage windows 59 that also in 3 are shown, at least one energy storage 60 on. The at least one energy storage 60 is supported in the circumferential direction with one end to a control 73 from, which by the peripheral end edges of the energy storage window 59 are formed, and with the circumferentially opposite end to a Absteuerung 61 of an exit 62 the second energy storage device 58 from. This exit 62 is by means of a riveting 63 at the as the output 26 of the torsional vibration damper 1 serving hub 25 attached.

The already mentioned further spacers 54 are with an axial middle part 65 formed, which has a larger diameter than the axial end portions 66a . 66b , With this axial middle part 65 passes through the respective spacer 4 Recesses in the two adjacent cover elements 39 . 40 , where these recesses 67 , as 3 clearly shows, extend in the circumferential direction further than this with respect to the diameter of the axial center part 65 of the respective spacer 54 would be required. The recesses 67 therefore grant the spacers 54 a Relativauslenkung in the circumferential direction, so that even between the two cover elements 39 . 40 on the one hand and the exit 62 on the other hand, a relative rotational displacement is possible. The spacers 54 thus act together with the respective recesses 67 as a rotation angle stop 68 ,

This in 1 shown turbine wheel 31 can, how 2 shows, alternatively, either on the output side Tilgermassenträgerelement 48 over the spacers 52 be attached, or at the hub 25 and thus at the output 26 about the riveting 63 ,

As 1 shows, the hub is supported 25 on the drive side on the housing hub 13 and on the output side via the output-side cover element 40 and the drive-side Tilgermassenträgerelement 53 via an axial bearing 70 at the freewheel 33 from.

The torsional vibration damper 1a of the 1 differs in two details from the in 2 shown torsional vibration damper 1 :

The drive-side cover element 39a ends according to 1 radially immediately outside of the at least one energy store 60 the second energy storage device 58 , so that only the output side cover element 40 axially between the gearing 12 and the entrance 36 the first energy storage device 46 attacks. Since the output side cover element 40 but in the same way the recess 41 for the passage of the spacer 38 , changes in the function of in 1 shown torsional vibration damper 1a in comparison to the torsional vibration damper 1 from Fig, 2 nothing.

The 1 indicates for the second energy storage device 58 spacer 54a which are axially multi-stage to the in 2 Spacers shown at this point 54 as well as the radially inside of these spacers 54 provided riveting 63 to replace. The axial multi-stage is provided by axially provided diameter steps 71 . 72 achieved, with cross-sectional transitions between the individual diameter steps 72 . 72 Axial contact surfaces for the two cover elements 39 . 40 form.

The in 4 illustrated torsional vibration damper 1b is basically the same as in 2 shown torsional vibration damper 1 , but has differences in the formation of the absorber system 55b on. Accordingly, the Tilgermassenträger has 49b only via a single Tilgermassenträgerelement 75 , the axial damper masses on both sides 74 relatively movable absorbs. This absorber mass carrier 49b is about the spacers 52b with a connection flange 76 connected, in turn, over the spacers 54b on the cover elements 39 and 40 and thus at the exit 56b the first energy storage device 46b or at the entrance 57b the second energy storage device 58b attacks.

The functioning of the torsional vibration damper 1 is subsequently using the 2 described:

One over the gearing carrier 12 the coupling device 18 Torque delivered is via the spacers 35 on the entrance 36 the first energy storage device 46 transfer. The entrance 36 relies on its control 44 at the adjacent end of the at least one energy store 45 under deformation of the same, since the at least one energy storage 45 with his from the drive 44 facing away from the other end at the Absteuerung 47 supports, and the Absteuerung on the output side Tilgermassenträgerelement 48 is fastened, the torque reaches the absorber mass member 48 and with it, because this is about the spacers 52 with the drive-side Tilgermassenträgerelement 53 is connected, also on this Tilgermassenträgerelement. As this Tilgermassenträgerelement 53 by means of the spacers 54 on the cover elements 39 and 40 Tailored, the torque is consequently on the cover elements 39 and 40 directed. So the torque is thus on the output 56 the first energy storage device 56 or, since this exit 56 at the same time the entrance 57 the second energy storage device 58 forms, at this entrance 57 at.

The torque is controlled by the activation direction 73 the energy storage window 59 to the adjacent end of the at least one energy storage 60 the second energy storage device 58 under deformation of the at least one energy store 60 transfer. Since the at least one energy storage 60 with his from the drive 73 facing away from the other end at the Absteuerung 61 supports, and the Absteuerung 61 at the exit 62 the second energy storage device 58 is provided, the torque passes due to the attachment of the output 62 the second energy storage device 58 at the hub 25 the downforce 26 to the downforce 26 , and from there to a transmission input shaft, not shown.

Are that about the gearing 12 the coupling device 18 supplied torsional vibrations or even shocks superimposed, they lead - depending on the effective direction of the torsional vibrations or shocks - to a temporary increase or reduction of the at least one energy storage 45 the first energy storage device 58 or at the at least one energy storage 60 the second energy storage device 58 applied torque. At the same time cause the torsional vibrations or shocks a deflection of the absorber masses 74 relative to the Tilgermassenträgerelementen 48 and 53 and thus the Tilgermassenträgers 49 at least essentially in the circumferential direction.

Is that about the gearing carrier 12 the coupling device 18 Delivered torque and / or the torque superimposed torsional vibrations or shocks so strong that the at least one energy storage 45 the first Energy storage device 46 would experience an oversized deformation, or even the individual turns of the energy storage 45 to get in contact with each other and thus would go to block, then to avoid damage to the at least one energy storage 45 that of the first energy storage device 46 assigned angle of rotation stop 42 effective. In which the at least one energy storage 45 the first energy storage device 46 associated angle stop 42 then becomes the axial center part 37 of the spacer 35 at the effective direction of the torque associated end edge 77 the recess 41 ( 3 ) come into contact. This will be the case when the introduced torque or the same superimposed torsional vibrations or shocks have reached a predetermined limit torque. If the introduced torque or the same superimposed torsional vibrations or shocks exceeds the predetermined limit torque, then that portion of this load which exceeds the predetermined limit torque is increased by the rotational angle stop 42 bypassing the at least one energy store 45 the first energy storage device 46 immediately on the exit 56 the first energy storage device 56 or, since this exit 56 at the same time the entrance 57 the second energy storage device 58 forms, at this entrance 57 transfer. The transmission takes place in the case of the comments 2 or 4 directly on both cover elements 39 and 40 , in the case of execution after 1 on the other hand, first on the cover element 40a to then use the spacers 54a also on the cover element 39a to get.

Since the Tilgermassenträger 49 as well as the at least one energy storage 45 the first energy storage device 46 in the transmission direction of the torque behind the rotational angle stop 42 is also on the Tilgermassenenträger 49 only a torque or the same superimposed torsional vibrations or shocks passed that do not exceed the predetermined limit torque. This also includes the Tilgermassenträgerelemente 48 and 53 and thus the Tilgermassenträger 49 through the angle of rotation stop 42 protected against excessive load. This also applies equally to an embodiment of the absorber mass carrier with only one absorber mass carrier element 75 as he is in 4 with the label 49b is shown. Of course, in both versions of the Tilgermassenträgers 49 or 49b also the absorber masses 74 or 74b before oversized Relativauslenkungen against the respective Tilgermassenträger 49 . 49 a or 49b, if the load exceeding the limit torque results mainly from torsional vibrations or shocks.

The over the Tilgermassenträger 49 transmitted, maximum torque corresponding to the torque passes as well as beyond the limit torque portion of one of the toothed carrier 12 the coupling device 18 delivered torque and / or the torque superimposed torsional vibrations or shocks on the cover elements 39 and 40 , and with it on the exit 56 the first energy storage device 56 or, since this exit 56 at the same time the entrance 57 the second energy storage device 58 forms, at this entrance 57 , If this torque and / or the torsional vibrations or shocks superimposed on this torque are so strong that the at least one energy store 60 the second energy storage device 58 would experience an oversized deformation, or even the individual turns of the energy storage 60 to get in contact with each other and thus would go to block, then to avoid damage to the at least one energy storage 60 that of the second energy storage device 58 assigned angle of rotation stop 68 effective. In which the at least one energy storage 60 the second energy storage device 58 associated angle stop 68 then becomes the axial center part 65 of the spacer 54 at the effective direction of the torque associated end edge 78 the corresponding recess 67 ( 3 ) come into contact. This will be the case when the introduced torque or the same superimposed torsional vibrations or shocks have reached a predetermined limit torque. If the introduced torque or the same superimposed torsional vibrations or shocks exceed the predetermined limit torque, then that portion of this load which exceeds the predetermined limit torque is increased by the rotational angle stop 68 bypassing the at least one energy store 60 the second energy storage device 58 immediately on the exit 62 the second energy storage device 58 or, since this exit 62 at the hub 25 the downforce 26 is attached to the output 26 of the torsional vibration damper 1 transfer.

This mode of operation is based on the in 2 shown torsional vibration damper 1 is described, but at the in 1 or 4 treated torsional vibration dampers 1a or 1b as well, and therefore will not be described again. The same components have therefore received the same reference numerals, but with different indices.

LIST OF REFERENCE NUMBERS

1

torsional vibration damper

2

casing

3

wet-running starting element

4

gearing

5

gearing

5

drive-side coupling elements

7

piston

8th

output side coupling elements

9

gearing

10

gearing

12

toothing carrier

13

housing hub

15

central axis

18

coupling device

19

retaining ring

20

first pressure chamber

21

drive-side wall

22

second pressure chamber

23

flow channels

24

flow channels

25

hub

26

output

28

output side wall

30

impeller

31

turbine

32

stator

33

freewheel

35

spacer

36

Input of the torsional vibration damper

37

axial middle part of the spacer

38

End areas of the spacer

39

drive-side cover element

40

output-side cover element

41

recesses

42

Rotation angle stop

44

control

45

energy storage

46

first energy storage device

47

Terminating

48

output side Tilgermassenträgerelement

49

Tilgermassenträger

50

clinch

51

radial guide

52

spacer

53

Drive-side Tilgermassenträgerelement

54

spacer

55

absorber system

56

Output of the first energy storage device

57

Input of the second energy storage device

58

second energy storage device

59

Energy storage window

60

energy storage

61

Terminating

62

output

63

clinch

65

Middle part of the other spacers

66

axial end portions of the other spacers

67

recesses

68

Rotation angle stop

70

axial bearing

71

Diameter step

72

Diameter step

73

Terminating

74

absorber masses

75

Tilgermassenträgerelement

76

Anbindungsflansch

77

circumferential end edge

78

circumferential end edge

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012212125 A1 [0002]

Claims (12)

A torsional vibration damper (1; 1a; 1b) having at least one energy storage device (46) connected via an input (36) to a coupling device (18) and an output (56; 56a) rotatable relative to the same against the action of at least one energy reservoir (45) 56b, 56b) relative to the input (36) limiting rotational angle stop (42) and with a Tilgersystem (55, 55b) having at least one Tilgermassenträger (49; 49b) the absorber mass carrier (49; 49b) of the absorber system (55, 55b) acting as an output (56; 56a; 56b) of the energy storage device (46) is operative to receive at least one absorber mass (74; 74b) movable relative thereto; characterized in that the rotational angle stop (42) is provided at a position of the energy storage device (46) which extends in the transmission direction of a of the coupling device (18) transmitted torque it is located in front of the at least one energy store (45) of this energy storage device (46), so that a limitation of the absorber mass carrier (49; 49b) is ensured via the at least one energy storage (45) supplied torque to a predetermined limit torque. Torsional vibration damper (1, 1a, 1b) according to Claim 1 characterized in that the output (56; 56a; 56b) of the energy storage device (46) in the transmission direction of a torque transmitted from the coupling device (18) behind the absorber masses (74; 74b) to the input (36) of the energy storage device (46) is guided to attack there via the rotational angle stop (42) at the input (36) of the energy storage device (46). Torsional vibration damper (1, 1a, 1b) according to Claim 1 or 2 , which has an output (26), characterized in that the Tilgermassenträger (49, 49b) with the output (26) is operatively connected at least in the circumferential direction. Torsional vibration damper (1, 1a, 1b) according to one of Claims 1 to 3 , which has an output (26), characterized in that the Tilgermassenträger (49, 49b) via at least one further energy storage device (58) on the output (26) engages. Torsional vibration damper (1, 1a, 1b) according to Claim 4 in which the output (56; 56a; 56b) of the first energy storage device (46) and thus the absorber mass carrier (49; 49b) acts as input (57; 57a; 57b) of the at least one further energy storage device (58), characterized in that at least one output (62) which is rotationally deflectable against the action of at least one energy store (60) is associated with this input (57; 57a; 57b) in rotationally fixed connection with the output (62) and which together with the input (57; 57a; 57b) of the at least one further energy storage device (58) has at least one further rotation angle stop (68; 68a; 68b) delimiting the rotational guidance of the output (62) relative to the input (57; 57a; 57b). Torsional vibration damper (1, 1a, 1b) according to Claim 5 characterized in that the input (57; 57a; 57b) of the further energy storage device (58) is formed by two cover elements (39, 40), of which at least one (40) with axial offset but with radial overlap relative to the input (36 the first energy storage device (46) is arranged, wherein the inputs (36; 57; 57a; 57b) of both energy storage devices (46, 58) are provided with recesses (41; 67) for receiving at least one spacer (35; which together with the corresponding recesses (41; 67) serves in each case for forming the rotational angle stop (42; 68; 68a; 68b). Torsional vibration damper (1, 1a, 1b) according to Claim 5 or 6 , characterized in that the input (57; 57a; 57b) of the further energy storage device (58) by two cover elements (39, 40) is formed, of which at least one as well as the output (62) of the further energy storage device (58) Recesses (67) for receiving in each case at least one spacer (54) are provided, which together with the recesses (67) for forming the further rotational angle stop (68; 68a; 68b) is used. Torsional vibration damper (1a) after Claim 7 , characterized in that the further rotational angle stop (68a) in the axial direction with a plurality of diameter steps (71, 72) is formed, wherein cross-sectional transitions between the individual diameter stages (71, 72) Axialanlageflächen for each adjacent components (39, 40). Torsional vibration damper (1, 1a, 1b) according to Claim 5 , characterized in that the at least one further energy storage device (58) is provided radially inside the first energy storage device (46; 46b), and that the input of the first energy storage device (46; 46b) is guided radially outward into a region in which the at least one energy store (45) of the first energy storage device (46; 46b) is located. Torsional vibration damper (1; 1a) after Claim 7 with a Tilgermassenträger (49), the two arranged with axial offset and by means of spacers (52) held at a fixed distance to each other Tilgermassenträgerelemente (48, 53) axially between them receive at least one absorber mass (74), characterized in that one of the Tilgermassenträgerelemente (48, 53) with at least one (40) of the Cover elements (39; 40) of the entrance; 57; 57a) of the further energy storage device (58) is firmly connected. Torsional vibration damper (1b) after Claim 7 , characterized in that the absorber mass support (49b) has only a single absorber mass support element (75) which is provided axially between Tilgermassen (74b) arranged with axial offset to each other, and by means of a connecting element (76) with at least one (40) of the cover elements ( 39, 40) of the input (57b) of the further energy storage device (58b) is firmly connected. Torsional vibration damper (1, 1a, 1b) according to Claim 1 or 2 in which a toothed carrier (12) of the coupling device (18) is non-rotatably connected to the input (36) of the energy storage device (46), characterized in that the toothing carrier (12) of the coupling device (18) and the input (36) of the energy storage device (46) are arranged with an axial offset to each other, in a predetermined common radial area receiving the output (56; 56a; 56b) of the energy storage device (46) axially between the toothing carrier (12) of the coupling device (18) and the input (36) the energy storage device (46) permits.

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