EP3810957A1

EP3810957A1 - Torsional vibration damping assembly

Info

Publication number: EP3810957A1
Application number: EP19734009.4A
Authority: EP
Inventors: Michael Traut; Thomas Weigand
Original assignee: ZF Friedrichshafen AG
Current assignee: ZF Friedrichshafen AG
Priority date: 2018-06-25
Filing date: 2019-06-19
Publication date: 2021-04-28
Also published as: DE102018210292A1; WO2020002112A1

Abstract

A torsional vibration damping assembly, more particularly a tuned mass damper, comprises a deflection mass support (12) which can be rotated about an axis of rotation (A) and a plurality of deflection masses (22) which are arranged one after another in the circumferential direction and are supported on the deflection mass support (12) such that they can be deflected from a basic relative position in relation to the deflection mass support, wherein, on deflection from the basic relative position, the radial position of the deflection masses (22) in relation to the axis of rotation (A) changes, wherein each deflection mass (22) is supported by means of at least two coupling formations (29) on the deflection mass support (12) such that said deflection mass can be deflected starting from the basic relative position in both circumferential directions, wherein at least one stop formation (52) is provided in association with each deflection mass (22), wherein at least one stop formation (52) comprises a non-curved first stop surface that is fixed in relation to the deflection mass support (12) and in association with each first stop surface a non-curved first stop counter-surface (92, 92') is provided on a deflection mass (22), and wherein, when a first stop counter-surface (92, 92') impinges on a first stop surface (60, 60', 86, 86'), a movement direction vector of the deflection mass (22) on the first stop counter-surface (92, 92') and a surface normal of the first stop surface are at an angle to each other of at most 5°.

Description

Drehschwinqunqsdämpfunqsanordnung

The present invention relates to a torsional vibration damping arrangement, which che used in the drive train of a vehicle as a so-called absorber who can to counteract the occurrence of torsional vibrations.

Such a torsional vibration damping arrangement, for example known from DE 10 201 1 086 436 A1, comprises a deflection mass carrier which can be rotated about an axis of rotation and a plurality of deflection masses carried successively in the circumferential direction on the deflection mass carrier from a basic relative position with respect to the sem deflectable masses Basic relative position, the radial position of the deflection masses with respect to the axis of rotation changes, in particular in such a way that a respective deflection mass moves radially inwards or the radial distance of a center of gravity of a respective deflection mass is shifted radially inwards. Each deflection mass is guided by means of at least two coupling formations on the Auslenkungsmas sträger starting from the basic relative position in both circumferential directions, wherein at least one stop formation is provided in association with each deflection mass.

It is the object of the present invention to provide a torsional vibration damping arrangement, in particular a tiger, for the drive train of a vehicle, in which an improved damping functionality can be achieved with a compact structure.

According to the invention, this object is achieved by a torsional vibration damping arrangement, in particular an absorber, comprising a deflection mass carrier that can be rotated about an axis of rotation and a plurality of circumferentially following one another on the deflection mass carrier from a basic relative position with respect to this deflection masses that are deflectably carried, with deflection from the Basic relative position, the radial position of the deflection masses with respect to the axis of rotation changes, each deflection mass starting from the by means of at least two coupling formations on the deflection mass carrier Basic relative position is supported deflectable in both circumferential directions, with at least one stop formation being provided in association with each deflection mass, at least one stop formation comprising an uncurved first stop surface which is fixed with respect to the deflection mass carrier and in association with each first stop surface at a deflection mass curved first stop counter surface is provided, and wherein when striking a first stop counter surface on a first stop surface, a direction of motion vector of the deflection mass on the first stop counter surface and a surface normal of the first stop surface have an angle of at most 5 ° to each other.

Since in the torsional vibration damping arrangement constructed according to the invention, a deflection mass strikes a stop surface of a stop formation substantially perpendicularly and because of the fact that the surfaces of the deflection mass or the stop formation coming into contact with each other at the time of impact, there is essentially no loss of friction resulting Relative movement of the contacting surfaces parallel to the contact area. On the one hand, this avoids the occurrence of wear, on the other hand, a detuning of the vibration system caused by such friction effects is avoided.

A particularly advantageous embodiment is one in which when the first stop counter surface is struck on the first stop surface, the direction of movement vector of the deflection mass on the first stop counter surface and the surface normal to the first stop surface are oriented parallel to one another.

In order to be able to bring about a stop effect with one and the same first stop counter surface in both deflection end positions of a deflection mass, it is proposed that at least one, preferably each stop formation comprises an uncurved second stop surface which is fixed with respect to the deflection mass carrier, the at least in a first end deflection position a first stop counter surface is in contact with the first stop surface of a stop formation and in a second deflection end position in contact with the is the second stop surface of this stop formation, and that when the at least one first stop counter surface is attached to a second stop surface, a movement direction vector of the deflection mass on the first stop counter surface and a surface normal of the second stop surface have an angle of at most 5 ° to one another, preferably the movement direction vector of Deflection mass on the first stop counter surface and the surface normal of the second stop surface are oriented parallel to each other.

An excessively strong stop can be avoided with optimized use of installation space in that, in the basic relative position, each deflection mass has a basic minimum distance from each associated stop formation, and that in at least one deflection mass when deflected from the basic relative position in at least one circumferential direction, a minimum distance to at least one of these associated stop formation in a deflection path area of at least 80% of a maximum deflection path based on the basic relative position in the area of

0.5 M _G <M <1, 5 M _G, said _G M of the basic minimum distance and M is the minimum distance.

For this purpose, it can preferably be provided that the deflection path corresponding to a deflection state is represented starting from the basic relative position by an angle related to the axis of rotation between a position of a center of gravity of a deflection mass in the basic relative position and a position of the center of gravity in the deflection state.

In order to be able to use the effect of a minimum distance that remains essentially constant over the largest part of the deflection path as efficiently as possible, it is proposed that at least two stop formations are provided in association with at least one, preferably each deflection mass, and that when deflection from the basic relative position in at least one circumferential direction the minimum distance to each stop formation in the deflection path area from at least 80% of the maximum deflection path based on the basic relative position in the range of

0.5 M _G <M <1, 5 M _G is located, and / or that the minimum distance when deflected from the base relative position in each circumferential direction tung to at least one, each stop formation is preferably in the Auslenkungswegbereich of at least 80% of the maximum deflection path based on the basic relative position in the range of

0.5 M _G <M <1, M 5 _g.

In a structurally simple to implement, at least one stop formation can be provided on a deflection mass carrier by providing at least one first stop surface of at least one stop format on at least one stop element carried on the deflection mass carrier.

The first stop surfaces of two stop formations can be provided on at least one stop element.

Furthermore, the at least one first stop surface and the at least one second stop surface can be provided on at least one stop formation for a simple construction on at least one stop element.

A defined contact of a stop element on a deflection mass carrier with simultaneous provision of an axial support functionality for a deflection mass can be achieved in that at least one stop element comprises a plate-like stop element body, wherein at least one first stop surface projection is provided on at least one axial side of the stop element body. For improved interaction with a deflection mass, it is proposed that a stop surface projection providing at least one first stop surface is provided on at least one stop element body on both axial sides.

For the integration of a stop element in a torsional vibration damping arrangement, the deflection mass carrier can comprise a carrier disk, wherein at least one stop surface projection recess penetrated by a stop surface projection of the stop element is provided in the carrier disc in association with at least one stop element, the stop elements body of the at least one stop element on a first Axial side of the carrier disc is arranged and a stop surface projection of the stop element passes through a stop surface projection recess and protrudes axially beyond the carrier disc on a second axial side of the carrier disc.

Excessive weakening of a deflection mass carrier provided with a carrier disk can be avoided in that at least one, preferably each, stop surface projection penetrating a stop surface projection recess comprises a plurality of projection segments, and that the stop surface projection receiving the stop surface projection has recess segments in association with the projection segments.

In order to be able to provide a symmetrical mass distribution of a deflection mass with respect to a deflection mass carrier in the axial direction, the deflection mass carrier can comprise a carrier disc, and at least one, preferably each deflection mass, can comprise a deflection mass range on each axial side of the carrier disc.

With such a configuration of a deflection mass with a deflection mass regions arranged on both sides of a carrier, at least one, preferably each, stop element in association with at least one deflection Kungsmassenbereich include at least one deflection mass at least a first stop surface providing stop surface projection. Particularly advantageous is an embodiment in which at least one, preferably each stop element in association with the two deflection mass areas of two deflection masses each comprises a stop surface projection providing a first stop surface.

In a simple and inexpensive to manufacture, but nevertheless stable and reliable structure, at least one, preferably each, impact element can be constructed with plastic material.

In order to avoid an excessively hard stop and associated noises when a respective stop formation takes effect, it is proposed that at least one, preferably each stop element, at least one, preferably each stop surface is formed on an elastic, preferably constructed with rubber material, stop cover.

The present invention is described in detail below with reference to the accompanying figures. It shows:

1 shows an axial view of a torsional vibration damping arrangement with two deflection masses carried on a deflection mass carrier;

2 shows a perspective view of a stop element;

3 shows a further perspective view of the stop element;

4 shows the stop element viewed from another side;

5 shows an axial view of a deflection mass carrier;

6 shows the torsional vibration damping arrangement of FIG. 1, viewed from the side thereof; 7 shows a view corresponding to FIG. 1 of the torsional vibration damping arrangement with deflection masses arranged in a deflection end position;

FIG. 8 is a view corresponding to FIG. 6 of the torsional vibration damping arrangement with deflection masses arranged in the deflection end position; FIG.

Fig. 9 shows the detail IX in Fig. 7 enlarged.

In the figures, a so-called speed-adaptive damper in the drive train of a vehicle, for example integrated in a dual-mass flywheel, is shown as a replaceable torsional vibration damping arrangement. The torsional vibration damping arrangement 10 comprises a deflection mass carrier 12 which is designed as a substantially flat carrier disc 14. With an angular distance of about 180 °, radially outward-reaching support projections 16, 18 are provided on the carrier disk 14, on which the damper springs of two damper spring units of a dual-mass flywheel or another

Support vibration system.

In the central area of the generally designed with a ring-like structure and also shown in Fig. 5 in axial view deflection mass carrier 12, a hub disc 20 is arranged and fixed to four circumferential areas, for example, each by a plurality of rivet bolts on the carrier disk 14 of the deflection mass carrier 12.

The torsional vibration damping arrangement 10 further comprises two deflection masses 22 carried on the deflection mass carrier 12, preferably identical to one another. Each of the two deflection masses 22 comprises a disc-like deflection mass range 28 and 30 on each axial side of the carrier disc 14 Rivet bolts 32 are firmly connected to one another and thus embrace the carrier disk 14 in a U-shaped manner from the outside. In its two circumferential end regions 24, 26, the deflection masses 22 are each supported by a coupling formation 29 on the deflection mass carrier 12 or the carrier disk 14 thereof. Each such coupling formation 29 comprises in each of the two deflection mass regions 28, 30 of a respective deflection mass 22 an opening 34. The opening 34 provides on its side facing the central region of the deflection mass carrier 12 a guideway 36 with an approximately radially inner apex region 38. It should be pointed out that, in the embodiment shown, the approximately radially inward apex region 38 of a respective guideway 36 identifies that area of the guideway 36 which is central to one of the two steering masses 22 and also by a rotational axis A of the torsional vibration damping arrangement 10 the center transverse line Li running therethrough, which in the example shown also runs centrally through the two support projections 16, 18, has a minimal distance.

In association with each such pair of openings 34 in the Auslenkungsmas sen regions 28, 30 of a respective deflection mass 22, an opening 40 is provided in the carrier disc 14. Each such opening 40 provides a guideway 42 with an apex region 44 positioned essentially radially on the outside or at a maximum distance from the center transverse line L-i already mentioned.

For coupling the deflection masses 22 to the carrier disk 14, each coupling formation 29 further comprises a roller-shaped guide pin 46. With its central area, this can move along a guide track 42 and can move with its two end areas located in the axial direction and engaging in the openings 34 move along the guideways 36 in the openings 34.

Due to the mutually opposing curvatures or apex areas of the openings 34 and 40 of a respective coupling formation 29, when the centrifugal force loading of the deflection masses 22 occurs during rotation operation, the guide bolts 46 become in the apex areas 38 and 44 of the guideways 36 and 42 interacting therewith position. This means that the the deflection masses 22 opposite with respect to the center transverse line Li will assume a state of maximum distance from one another. This state of maximum distance between the two deflection masses 22 also means a state in which a respective center of mass MS of the deflection masses 22 is at a maximum distance from the axis of rotation A.

If rotational rotational irregularities occur in the rotational operation of such a torsional vibration damping arrangement 10, which are noticeable in the form of circumferential accelerations of the deflection mass carrier 12 coupled, for example, to a drive shaft, for example a crankshaft of an internal combustion engine, the deflection masses 22 become from their basic relative position with respect to the deflection mass carrier 12. in which they have the maximum distance to each other or to the axis of rotation A, deflected in the circumferential direction. The guide bolts 46 move, starting from the apex regions 38 and 44, along the guide tracks 36, 42 and thereby force the peripheral end regions 24, 26 of the two deflection masses 22 towards one another, which in turn means that the deflection masses 22 with their center of gravity MS are shifted radially inwards and take up energy in the fleeing potential. The deflection masses 22 thus provide a vibration system which is designed to build up a counter-vibration when torsional vibrations occur in a drive train and thus counteract the stimulating vibrations. Since the centrifugal forces acting on the deflection masses 22 depend on the rotational speed, the natural frequency of this vibration system also depends on the rotational speed, so that such torsional vibration damping arrangements 10 generally also act or are referred to as speed-adaptive absorbers.

In order to provide a movement stop for the deflection masses 22 when a respective deflection end position is reached, stop elements 48 described in detail below with reference to FIGS. 2 to 4 are provided on the carrier disk 14 of the deflection mass carrier 12. Each stop element 48 of this type comprises a plate-like stop element body 50. This serves as an axial sliding surface around an axial steel-steel contact of the deflection masses 22 to prevent deflection mass carrier 12, reduce friction and wear and tear and improve the impact acoustics.

Each stop element 48 also has two stop formations 52, 54, each stop element 48 being supported on the carrier disk 14 in such a way that it can interact with a respective circumferential end region 24 or 26 of a deflection mass 22 or the two deflection mass regions 28, 30 of the same.

The stop formation 52 provided on such a stop element 48 or the stop element body 50 thereof comprises a stop surface projection 56 protruding from the plate-like body 50. On the stop surface projection 56 of the stop element 48, which is basically provided as a plastic component, there is a stop element 48 with an elastic material, for example rubber material or other elastomer material. trained stop cover 58 provided. On the stop cover 58, two first stop surfaces 60, 60 'of the stop formation 52 are provided. Furthermore, a second stop surface 62 is provided, which is separated from the first stop surface 60 by an apex region 63 of the stop over train. While the first stop surface 60 and the second stop surface 62 are, for example, approximately at the same level, that is, they continue in a line, the first stop surface 60 'is offset. Each of the first stop surfaces 60, 60 'and the second stop surface 62 are not curved.

On the other axial side of the stop element body 50, a stop surface projection, generally designated 64, of the second stop formation 54 provided on the stop element 48 is provided. The stop surface projection 64 in the illustrated embodiment includes a total of four projection segments 66, 68, 70, 72, which recess segments 74, 76, 78, 80 of a disc 14 provided in the carrier, correspondingly segmented stop surface pre jump recess 82 are assigned. When the stop element 48 is attached to the carrier disk 14, the projection segments 66, 68, 70, 72, the recess segments 74, 76, 78, 80 of the stop surface projection recess 82 are positioned so that they have a length range 84 within the element body 50 adjoining the plate-like stop element 50 the recess Segments 74, 76, 78, 80 lie and protrude from the support plate 14 with the adjoining section 85, which carries an impact coating 85.

Also provided on each of the projection segments 66, 68, 70, 72 stop cover 85 is made of elastic material, such as. B. rubber material or other elastomeric material. Corresponding to the first and second stop surfaces 60, 60 ', 62 of the stop formation 52, first stop surfaces 86, 86' are provided on the projection segments 70, 72 of the stop formation 54 and a second stop surface 88 of the stop formation 54 is provided on the projection segment 66 , On the projection segment 68, in correspondence to the apex region 63 of the stop formation 52, an apex region 90 is formed on the part of the stop cover 85 provided there. 1, the deflection mass region 28 of a respective deflection mass 22 interacts with the stop formation 52 of the total of four stop elements 14 carried on the carrier disk 14, the deflection mass regions 30 of the deflection masses 22 act with the stop formations 54 of the four stop elements 48 together.

At the circumferential end regions of the deflection masses 22 and the deflection mass regions 28, 30, respective first stop counter surfaces 92, 92 'are provided. Like the various stop surfaces 60, 60 ', 62, 86, 86', 88, the first stop counter-surfaces 92, 92 'are non-curved. When positioning the deflection masses 22 in their basic relative position with respect to the deflection mass carrier 12 and accordingly positioning the guide bolts 46 in the apex regions 38, 44 of the guide tracks 36, 42, the deflection masses 22 are positioned with respect to the stop elements 48 interacting with them so that the first stop counter surfaces 92 of the deflection mass areas 28, 30 are each positioned at a short distance above an apex area 63, 90 of the respective stop formations 52, 54. In the event of rotational irregularities and corresponding acceleration of the deflection masses 22 with respect to the deflection mass carrier 12 in the circumferential direction, the deflection masses 22 shift in the circumferential direction and come into a deflection end position, for example, as shown in FIGS. In this Auslenkungsendpo position act in the peripheral end regions 24 of the deflection masses 22 there provided first stop counter surfaces 92, 92 'together with the first stop surfaces 60, 60' and 86, 86 'of the stop formations 52, 54 at the stop elements 48 together. In particular, a respective first stop counter surface 92 comes into contact with a respective first stop surface 60, 86, while a respective first stop counter surface 92 'comes into contact with a respective first stop surface 60', 86 '. In the other circumferential end regions 26, a respective first stop counter surface 92 comes into contact with a respective second stop surface 62 or 88 of the stop formations 52, 54.

When deflection in the opposite circumferential direction, this interaction of the first stop counter-surfaces 92, 92 'is reversed, so that now the first stop counter-surfaces 92, 92' provided on the peripheral end regions 26 with first stop surfaces 60, 60 'and 86, 86 'of the stop formations 52, 54 of the total of four stop elements 48 cooperate and the first stop counter surfaces 92 provided on the circumferential end areas 24 cooperate with second stop surfaces 62 and 88 of the stop formations 52, 54 to provide a stop function.

As already stated above, the first and second stop surfaces 60, 60 ', 86, 86', 62, 88 and first stop counter surfaces 92, 92 'which come into contact with one another to provide a stop function are uncurved. Furthermore, the first and second stop surfaces 60, 60 ', 86, 86', 62, 88 are oriented such that when a respective peripheral end region 24 or 26 approaches the provided first stop counter-surfaces 92, 92 'at the time of occurrence of a mutual contact have a direction of movement illustrated by a movement direction vector V shown in FIG. 9, which is approximately parallel to a surface normal N of the various first and second stop surfaces 60, 60 ', 86, 86', 62, 88. This means that at the time a respective circumferential end region 24, 26 strikes a stop element 48, there is no movement direction component which represents a relative movement parallel to the surfaces which come into contact with one another. Small deviations from such an exactly orthogonal stop function in an angular range of approximately 10 °, represented by the angle W in FIG. 9, that is to say a deviation from each Direction of about 5 °, can still be interpreted in the sense of the present invention as a substantially vertical impact without significant movement direction component parallel to the surfaces in contact with one another.

Since the first stop counter surfaces 92, 92 'with each stop surface with which they cooperate to provide the stop function in the sense described above, that is to say with every first stop surface 60, 60', 86, 86 'and every second stop surface 62, 68, in Such interaction, there is essentially no relative movement of the components in contact with one another in the area of the surfaces in contact. This avoids friction losses and detuning caused by friction in the vibration system comprising the respective deflection masses 22. Also, by avoiding friction effects, wear occurring in the area of the various stop formations 52, 54 is minimized.

In order to provide, in addition to the impact produced by the elasticity of the stop covers 58 and 85, a further, step-acting stop function, the same second stop counter surfaces 94 are provided in the peripheral end regions 24, 26 of the deflection masses 22 and the deflection mass regions 28, 30 , 7 and 8 that these second stop counter surfaces 94 are always effective through cooperation with a respective apex region 63 or 90 when the first stop counter surfaces 92, 92 ', which are provided on the same circumferential end, are effective. Interact with the first stop surfaces 60, 60 'and 86, 86' of a respective stop element 48. Does the first stop counter surface 92 act with a second stop surface 62 or

88 of a stop element together, the associated second stop counter surface is ineffective. The second stop counter surfaces 94 are positioned on the deflection mass areas 28, 30 such that when a contact occurs between the first stop counter surfaces 92, 92 'and the first stop surfaces 60, 60' and 86, 86 ', respectively there is a slight distance to the respective apex area 63 or 90. Only when the stop cover 58 or 85 of the stop formations 52, 54 on the respective first stop surfaces 60, 60 'or 86, 86 'is slightly compressed, the second stop mating surfaces 94 also come into contact with the apex regions 63, 90.

The deflection masses 22 are in their circumferential end regions 24, 26 also so designed that in the basic relative position with respect to the deflection mass carrier, each time a minimal distance between a deflection mass 22 or a deflection mass region 28, 30 and a stop element 48 interacting therewith in the region a first stop counter surface 92 positioned above a respective apex region 63, 90 is present. Moves a respective deflection mass 22 with respect to the deflection mass carrier 12, so initially each deflection mass 22 with respect to the stop formations 52, 54 cooperating with it remains in such a position that the minimum distance between deflection mass 22 and stop formation 52, 54 is in the region of the ground - Relative position existing basic minimum distance is, preferably no greater than +/- 50% to this. This state preferably remains over a deflection path range of at least 80%, starting from the basic relative position in the direction of a respective deflection end position. Only at the end of a respective deflection movement, the deflection masses 22 with their circumferential end regions 24, 26 then approach the associated stop formations 52 and 54 in order to interact with them in the manner described above in the form of an essentially orthogonal stop , In this way, an optimal use of space is guaranteed. On the other hand, it is avoided that the deflection masses initially move excessively far away from the assigned stop formations and then strike very massively against them.

In order to provide additional strength or support for the stop elements 48 when a stop occurs, as can be seen in FIG. 1, the hub disk 20 can be shaped such that it extends radially outwards and on the carrier disk 14 fixed attachment areas 96 engages between two different deflection masses 22 associated stop elements 48 and supports them towards each other. The hub disc 20 can also be designed in such a way that it slightly supports the stop elements 48 supported by this engages, so that an axial movement of the stop elements 48 in the direction away from the carrier disk 14 is prevented and these are thus firmly held in the area of a respective stop surface projection 56 between the carrier disk 14 and the hub 20.

Bezuaszeichen torsional vibration damping arrangement deflection mass carrier

carrier disc

support projection

hub disc

deflection mass

Peripheral end area

Auslenkungsmassenbereich

coupling formation

Auslenkungsmassenbereich

rivet bolts

opening

guideway

apex region

opening

guideway

apex region

guide pins

stop element

Stoppers body

stop formation

Stop surface projection

stop coating

first stop surface

'' first stop surface

second stop surface

apex region

Stop surface projection Projection segment projection segment

protrusion segment

cut segment

Stop area position recess length range

stop coating

first stop surface

'' first stop surface

second stop surface

apex region

first stop counter surface

'' first stop counter surface

second stop counter surface fastening area

Claims

claims

1. Torsional vibration damping arrangement, in particular damper, comprising a deflection mass carrier (12) rotatable about an axis of rotation (A) and a plurality of successive circumferentially on the deflection mass carrier (12) from a basic relative position with respect to this deflection supported deflection masses (22), where the deflection from the basic relative position changes the radial position of the deflection masses (22) with respect to the axis of rotation (A), with each de deflection mass (22) using at least two coupling formations (29) on the deflection mass carrier (12) starting from the basic relative position in is deflectably supported in both circumferential directions, with at least one stop formation (52, 54) being provided in association with each deflection mass (22), at least one stop formation (52, 54) having a non-curved first stop surface (12) which is fixed with respect to the Auslenkungsmas carrier (12) 60, 60 ', 86, 86') and assigned to each first answer Contact surface (60, 60 ', 86, 86') on a deflection mass (22) an uncurved first stop counter surface (92, 92 ') is provided, and when a first stop counter surface (92, 92') is attached to one a first stop surface (60, 60 ', 86, 86'), a direction of movement vector (V) of the deflection mass (22) on the first stop counter surface (92, 92 ') and a surface normal (N) of the first stop surface (60, 60', 86, 86 ') have an angle of at most 5 ° to one another.

2. torsional vibration damping arrangement according to claim 1, characterized in that when striking the first stop counter surface (92, 92 ') on the first stop surface (60, 60', 86, 86 ') of the direction of motion vector (V) of the deflection mass (22nd ) on the first stop counter surface (92, 92 ') and the surfaces normal (N) of the first stop surface (60, 60', 86, 86 ') are oriented parallel to one another.

3. torsional vibration damping arrangement according to claim 1 or 2, characterized in that at least one, preferably each stop formation (52, 54) comprises a fixed with respect to the deflection mass carrier (12), non-curved second stop surface (62, 88), in a first Auslenkungsendpositi on the at least one first stop counter surface (92) in contact with the first attachment striking surface (60, 86) of a stop formation (52, 54) and in a second steering end position in contact with the second stop surface (62, 88) of this stop formation (52, 54), and that when striking the at least one first stop - Counter surface (92) on a second stop surface (62, 88) a movement direction vector (V) of the deflection mass (22) on the first stop counter surface (92) and a surface normal (N) of the second stop surface (62, 88) at an angle of maximum 5 ° to each other, preferably the movement direction vector (V) of the deflection mass (22) on the first stop counter surface (92) and the surface normal (N) of the second stop surface (62, 88) are oriented parallel to one another.

4. Torsional vibration damping arrangement according to one of the preceding claims, characterized in that in the basic relative position each deflection mass (22) has a basic minimum distance to each stop formation (52, 54) associated therewith, and that at least one deflection mass (22) in the event of deflection from the basic relative position in at least one circumferential direction, a minimum distance from at least one stop formation (52,

54) in a deflection path area of at least 80% of a maximum deflection path based on the basic relative position in the area of

5. Torsional vibration damping arrangement according to claim 4, characterized in that the deflection path corresponding to a deflection state is represented starting from the basic relative position by an angle related to the axis of rotation (A) between a position of a center of gravity (MS) and a deflection mass (22). in the basic relative position and a position of the center of gravity (MS) in the deflection state.

6. torsional vibration damping arrangement according to claim 4 or 5, characterized in that in association with at least one, preferably each Auslen- tion mass (22) at least two stop formations (52, 54) are provided, and that when deflection from the basic relative position in at least one circumferential direction, the minimum distance to each stop formation (52, 54) in the deflection path range of at least 80% of the maximum deflection path based on the basic relative position in the range of

0.5 M _G <M <1, 5 M _G is located, and / or that the minimum distance when deflected from the base relative position in each circumferential direction tung to at least one, preferably each stop formation (52, 54) in the Auslenkungswegbereich of at least 80 % of the maximum displacement based on the basic relative position in the range of

0.5 M _G <M <1, M 5 _g.

7. torsional vibration damping arrangement according to one of the preceding claims, characterized in that on at least one of the deflection mass carrier (12) carried stop element (48) at least one first stop surface (60, 60 ', 86, 86') of at least one stop formation (52 , 54) is provided.

8. torsional vibration damping arrangement according to claim 7, characterized in that the first stop surfaces (60, 60 ', 86, 86') of two stop formations (52, 54) are provided on at least one stop element (48).

9. torsional vibration damping arrangement according to claim 3 and claim 7 or 8, characterized in that on at least one stop element (48) we least a first stop surface (60, 60 ', 86, 86') and the at least one second stop surface (62, 88 ) at least one stop formation (52, 54) are provided.

10. torsional vibration damping arrangement according to one of claims 7 to 9, characterized in that at least one stop element (48) comprises a plattenar term stop element body (50), with at least one axial side of the stop element body (50) at least a first stop surface (60, 60 ' , 86, 86 ') providing stop surface projection (56, 64) is provided.

1 1. Torsional vibration damping arrangement according to claim 10, characterized in that at least one stop element body (50) on both axial sides has at least one first stop surface (60, 60 ', 86, 86') providing stop surface projection (56, 64).

12. Torsional vibration damping arrangement according to claim 10 or 1 1, characterized in that the deflection mass carrier (12) comprises a carrier disc (14), wherein in the carrier disc (14) in association with at least one stop element (48) at least one of a stop surface projection (64) of the stop element (48) penetrated stop surface projection recess (82) is provided, the stop element body (50) of the at least one stop element (48) being arranged on a first axial side of the carrier disk (14) and a stop surface projection (64) of the Stop element (48) penetrates a stop surface projection (82) and on a second axial side of the carrier disc (14) projects axially beyond the carrier disc (14).

13. Torsional vibration damping arrangement according to claim 12, characterized in that at least one, preferably each stop surface projection (64) passing through a stop surface projection recess (82) comprises a plurality of projection segments (66, 68, 70, 72), and that the projection surfaces project ( 64) receiving stop surface projection recess (82) in association with the projection segments (66, 68, 70, 72) has recess segments (74, 76, 78, 80).

14. Torsional vibration damping arrangement according to one of the preceding claims, characterized in that the deflection mass carrier (12) comprises a carrier disc (14) and that at least one, preferably each deflection mass (22) on each axial side of the carrier disk (14) comprises a deflection mass region (28, 30).

15. Torsional vibration damping arrangement according to claim 7 and claim 14, characterized in that at least one, preferably each stop element (48) in association with at least one deflection mass region (28, 30) at least one deflection mass has at least one first stop surface (60, 60 ', 86 , 86 ') providing stop surface projection (56, 64).

16. Torsional vibration damping arrangement according to claim 7 and claim 14 or according to claim 15, characterized in that at least one, preferably each of the stop element (48) in association with the two deflection mass ranges (28, 30) two deflection masses (22) each have a first stop surface che (60, 60 ', 86, 86') providing stop surface projection (56, 64).

17. Torsional vibration damping arrangement according to one of claims 8 to 16, characterized in that at least one, preferably each stop element (48) is constructed with plastic material.

18. Torsional vibration damping arrangement according to one of claims 8 to 17, characterized in that in at least one, preferably each stop element (48) at least one, preferably each stop surface (60, 60 ', 86, 86',

62, 88) on an elastic, preferably constructed with rubber material, impact coating (58, 85) is formed.