Source: https://patents.google.com/patent/DE102009042825B4/en
Timestamp: 2020-08-03 21:47:58
Document Index: 693821589

Matched Legal Cases: ['arts 3', 'arts 3', 'art 3', 'art 4', 'art 9', 'art 9', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13', 'art 18', 'art 18', 'art 18', 'art 18', 'art 21', 'art 21', 'art 3', 'art 18', 'art 21', 'art 18', 'art 13', 'art 13', 'arts 22', 'arts 22', 'art 9', 'arts 22', 'art 13', 'arts 22', 'arts 22', 'arts 22', 'arts 22', 'art 22', 'art 23', 'arts 22', 'arts 22', 'art 12', 'art 4', 'art 12', 'arts 22', 'art 12', 'arts 22']

DE102009042825B4 - Torque transfer device - Google Patents
DE102009042825B4
DE102009042825B4 DE102009042825.9A DE102009042825A DE102009042825B4 DE 102009042825 B4 DE102009042825 B4 DE 102009042825B4 DE 102009042825 A DE102009042825 A DE 102009042825A DE 102009042825 B4 DE102009042825 B4 DE 102009042825B4
pendulum masses
DE102009042825.9A
DE102009042825A1 (en
2008-10-30 Priority to DE102008054024.2 priority Critical
2008-10-30 Priority to DE102008054024 priority
2009-06-22 Priority to DE102009029724 priority
2009-06-22 Priority to DE102009029724.3 priority
2009-09-24 Application filed by Schaeffler Technologies AG and Co KG filed Critical Schaeffler Technologies AG and Co KG
2009-09-24 Priority to DE102009042825.9A priority patent/DE102009042825B4/en
2010-05-12 Publication of DE102009042825A1 publication Critical patent/DE102009042825A1/en
2016-09-15 Publication of DE102009042825B4 publication Critical patent/DE102009042825B4/en
2017-05-30 First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=42096598&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=DE102009042825(B4) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
238000005096 rolling process Methods 0.000 claims abstract description 35
F16F15/13114—Suppression of vibrations in rotating systems by making use of members moving with the system using elastic members or friction-damping members, e.g. between a rotating shaft and a gyratory mass mounted thereon the rotating system comprising two or more gyratory masses characterised by modifications for auxiliary purposes, e.g. provision of a timing mark
Torque transmission device (1, 1a, 1b, 1c, 1d) in a drive train of a motor vehicle with a torsional vibration damper (5) with two mutually against the action of at least one energy storage device (6, 6a, 7) limited rotatably mounted damper parts (3, 4, 4a) and a centrifugal pendulum (10, 10a, 10b, 10c) with a rotatably connected to one of the damper parts (4) arranged support member (13, 13a, 13), which distributed over the periphery and limited to this by means of rolling elements (30) relative to the Carrier part (13, 13a, 13b) receives pivotable pendulum masses (14, 14a, 14b), wherein the pendulum masses (14, 14a, 14b) are encapsulated at least radially outward, wherein radially outside the centrifugal force pendulum (10a) a the pendulum masses (14) cross-ring part (18 a) is provided, which is fixed to the not connected to the centrifugal force pendulum (10 a) damper part (3), wherein the annular part (18 a) in cross section angled to each other arranged Ringa (19a, 19b), one of which is attached to the primary damper part (3) or a component connected thereto and the other radially over the centrifugal pendulum (10a), wherein the centrifugal pendulum (10, 10a, 10b) axially adjacent to the at least one energy store (6, 7) is arranged.
The invention relates to a torque transmission device in a drive train of a motor vehicle according to one of claims 1 to 5.
Are known torque transmitting devices with a torsional vibration damper, for example in the form of a split flywheel with two mutually limited against the action of energy storage such as screws or bow springs limited rotatable damper parts such as flywheel masses with corresponding Beaufschlagungsbereichen for the energy storage. These torque transmission devices are supplemented by centrifugal pendulum pendulum, in which one of the damper parts, preferably the secondary damper part, has a flange part on which distributed over the circumference several, preferably two or four pendulum masses are limitedly received pivotably by means of rolling elements. The rolling elements in each case roll on a raceway of the flange and the pendulum mass, wherein preferably two circumferentially spaced rolling elements per pendulum mass are provided.
Such integrated in the torque transfer device centrifugal pendulum supports the torsional vibration damper in the damping of preferably by the connected to the primary damper part crankshaft internal combustion engine or registered from the output side torsional vibrations, the pendulum masses are pivoted by the registered torsional vibrations along the tracks and one due to the changed Oscillation angle of the pendulum masses against the flange cause a vibration damping effect. The design of the centrifugal pendulum can be done so that a speed-dependent vibration damping can be achieved.
Such centrifugal pendulums tend over lifetime to a changing eradication behavior, especially when due to corrosion of the components of the resonance range is changed and deteriorated. Furthermore, bursting centrifugal pendulums can damage the environment of the centrifugal pendulum. Furthermore, the pendulum masses can corrode during prolonged downtime of the motor vehicle on the flange or train against this increased friction.
As prior art, the citations DE 198 31 158 A1 . DE 199 51 577 A1 . DE 10 2008 005 138 A1 and DE 10 2004 011 830 A1 called.
It therefore results in the task of proposing a torque transmission device whose centrifugal pendulum can be operated safely and over life with the same quality.
The object is achieved in each case by a torque transmission device having the features of claims 1, 2, 3, 4 and 5.
The object is achieved by a torque transmission device in a drive train of a motor vehicle with a torsional vibration damper with two mutually against the action of at least one energy storage limited rotatably mounted damper parts and a centrifugal pendulum with a rotationally connected to one of the damper parts arranged carrier device, which distributed over the circumference and limited to several this accommodates by means of rolling elements relative to the support means pivotable pendulum masses, solved, wherein the pendulum masses are encapsulated at least radially outward. By encapsulating the pendulum masses at least radially outward creates a burst protection for the radially outer environment. Furthermore, the centrifugal pendulum and the prone to corrosion and pollution pendulum masses and their pivotal storage against radial outside penetrating pollution and dripping condensation are protected. A serving as a burst protection device and strainer measure that forms only a protection from the outside radially, can be taken in a particularly advantageous manner cost and as a simple measure for existing structures or constructions that will round off a proven concept. A fundamentally improved solution is the full encapsulation of the pendulum masses to the outside.
In an advantageous embodiment, the centrifugal pendulum may be axially adjacent to the at least one energy storage, for example, bow springs of a split flywheel. In this case, the carrier device is preferably firmly connected to the damper part, which contains the second as well as secondary flywheel mass. The support member for the pendulum masses may include loading areas such as arms for the at least one energy storage or axially adjacent to a flange containing the loading areas. Furthermore, in the case of a combination of the function of the secondary loading of the at least one energy store with the carrier part, the pendulum masses can be arranged radially inside the at least one energy store. Generally speaking, in this way, the centrifugal pendulum can be integrated with minimal axial space requirements and a reduced number of components in one of the damper parts.
The torque transmission device is preferably in a drive train with an internal combustion engine with a crankshaft and a subsequent transmission with one or more transmission input shafts connected, wherein a so-called primary damper part with the crankshaft of the internal combustion engine and a so-called secondary damper part with the transmission is connectable. Depending on the configuration of the following transmission, a hydrodynamic torque converter, a clutch unit with at least one dry or wet friction clutch or another clutch element integrated in the unit or attached during assembly of the drive train can be attached to the torque transmission device, which connects to the transmission input shaft (s) Gearbox produce.
In a simply configured embodiment of a torque transmission device according to the inventive idea, a pendulum masses cross-over metal ring is provided radially outside the centrifugal pendulum mass, which is attached to the non-connected to the centrifugal pendulum damper part. For example, in an arrangement of centrifugal pendulum on the secondary damper part of the sheet metal ring attached to the primary damper part as riveted or welded, which is designed as a primary flywheel and forms an annular space for receiving the at least one energy storage. In this case, the sheet-metal ring is preferably fastened to the region of the annular space facing the centrifugal pendulum pendulum. The sheet metal ring may have angled in cross-section to each other arranged annular projections, one of which is attached to the damper part such as annulus or a connected thereto component and the other radially overlaps the centrifugal pendulum.
An alternative embodiment of a torque transmission device which is particularly simple in this respect comprises a carrier device comprising a flange part which is connected to a damper part, preferably to the secondary damper part and carries the pendulum masses, a burst protection device being arranged on the outer circumference of the flange part. The burst protection device is formed by a firmly attached to the outer circumference of the flange part ring part. The ring member may be shrunk to the outer circumference, welded thereto or fastened in another way and forms on both sides of the flange portion arranged annular projections which engage over the pendulum masses axially and thus protect the radially outward environment at a burst of the centrifugal pendulum, for example forms a rupture of a pendulum mass. In particular, in order to avoid a large moment of inertia of the ring member may have over the circumference eruptions or recesses, which in their distance against each other ensure retention even small bursting parts, but reduce the radially outside of the moment of inertia particularly relevant, for the vibration damping of the centrifugal pendulum pendulum ineffective accumulation of material.
In a particularly advantageous embodiment of a torque transmission device, the pendulum masses are completely encapsulated. For this purpose, the support means may be formed of two mutually facing flange parts, which form by means of a respective annular and cup-shaped indentation at least a radially outer closed annular space in which the pendulum masses are housed. The flange parts are preferably made of sheet metal by means of a cold forming process, wherein the corresponding functional areas can be made essentially falling tool. It has proved to be particularly advantageous if the pendulum masses roll on rolling elements which are mounted axially in at least one of the two, preferably in both flange parts. In this way, a central flange, on which the pendulum masses are arranged on both sides, omitted. With an appropriate selection of the strength of the pendulum masses encapsulating the carrier part forming flange parts can be provided at least one of the weight of the central flange portion corresponding solution for the support member. The two flange parts are, for example, riveted radially on the outside and radially inwardly preferably received on the secondary damper part, such as a hub part or on the secondary flywheel.
The distributed over the circumference bearing areas for the rolling elements in the flange parts have raceways on which roll the rolling elements. To the pendulum masses complementary raceways are provided, on which roll the rolling elements and thus at a pivoting of the pendulum masses relative to the support member through the raceways a predetermined trajectory is formed for the pendulum masses. The rolling elements are preferably formed from rollers or bolts, which roll on substantially planar raceways. Alternatively, for example, balls can be used as rolling elements, wherein the raceways are adapted to the curved radius corresponding to each and roll a ball half in the raceways of the flange and a ball half in the raceways of the pendulum mass.
To achieve a completely closed annulus for the pendulum masses bearings such as bearing areas with the raceways can be stamped on the flange, wherein during embossing the bearing areas is avoided, so that the rolling elements are axially secured to the embossments and the other the annulus remains closed. To simplify the manufacturing process of the flange, the storage areas can also be put through, the resulting openings are covered by thin cover plates. The cover plates can be riveted by means provided on the flange rivets with the flange, conventional riveted by rivets, locked, caulked or otherwise secured.
The pendulum masses of the torque transmission device according to the invention may be solid or formed as composite units. For example, the pendulum masses of a mass body and two axially flanking support plates, in which the raceways are provided for the rolling elements, be formed. The carrier plates or at least the raceways of these are preferably hardened, the openings of the mass body are cut out further than the openings of the carrier parts carrying the raceways. Alternatively, the mass body may comprise the raceways and be flanked by cover plates, which are then correspondingly cut further than the cutouts for the raceways and may carry additional components such as spacers.
In the support means distributed over the circumference stop buffers may be provided for the circumferentially facing end faces of the pendulum masses, which are formed for example of rivets or bolts which protrude axially into the annulus and surrounded by a buffer layer of elastic material, such as rubber, rubber or the like could be.
To reduce the friction between the annular space forming inner walls of the flange and the pendulum masses axially effective axial spacers may be provided for example of plastic, which are arranged on the flange and / or on the pendulum masses. The mating surfaces on the inner surfaces of the flange parts or on the pendulum masses can be coated, for example with plastic, at least in the area in which the spacers drive over these surfaces during pivoting of the pendulum masses relative to the flange parts. Preferably, the spacers are connected to the pendulum masses. The substantially dense and encapsulated annulus allows a pollution-free operation of the centrifugal pendulum over the life of the torque transmitting device. Furthermore, the encapsulation forms a burst protection. In a preferred application, the centrifugal pendulum is operated in an air-filled annular space. In special applications, the annulus can be sealed liquid-tight, so that at least partially filled with lubricant operation of the centrifugal pendulum is made possible, so that a permanent lubrication of the rolling elements and raceways is secured. Furthermore, in the case of desired hydraulic damping of the pendulum masses, a higher proportion up to complete filling with lubricant or hydraulic fluid can be provided.
In an advantageous embodiment, in particular for a connection of the torque transmitting device to a clutch unit, the secondary damper part has two annular space for the pendulum masses forming flange, which are closed radially on the outside and radially extended arms for acting on the at least one energy storage. In this way, a fully encapsulated structure for a centrifugal pendulum can be proposed, which is integrated into a split flywheel with a primary and a secondary flywheel, the secondary flywheel having in a known manner a flange with Beaufschlagungsbereichen from radially inside at least apply an energy store.
Furthermore, an embodiment is advantageous in which the secondary damper part is connected to an input part of a clutch unit with at least one friction clutch, wherein the secondary damper part has a hub part on which the encapsulated centrifugal pendulum is arranged. The hub part in this case has a form-fitting device, for example, an internal toothing for the input part of the clutch unit, wherein the positive connection is formed during the final assembly of the drive train. In alternative embodiments, the torque transmission device can be designed as a unit with the clutch unit and mounted together.
The invention is based on the in the 1 to 9 illustrated embodiments explained in more detail.
1 a partial section through a torque transmission device with a radially outwardly disposed burst protection device,
2 a partial section through a torque transmitting device with respect to the torque transmission of the 1 slightly modified anti-burst device,
3 a partial section through a torque transfer device with fully encapsulated pendulum masses along a section line through rolling elements of the centrifugal pendulum,
4 a partial section through the torque transmission device of 3 along a section line through a stop buffer for the pendulum masses,
5 a partial section through the torque transmission device of 3 and 4 along a section line through a spacer,
6 a partial view of an open carrier part of the torque transmission device of 3 to 5 .
7 a partial view of a support part of the torque transmission device of 3 to 6 .
8th a partial section of a to the torque transmission device of 3 to 7 alternative embodiment of a torque transmission device with a modified support member and
9 a partial section through a torque transfer device with a built-in a flange for applying energy storage of the torsional vibration damper encapsulated centrifugal pendulum.
1 shows the torque transmitting device 1 on average, with only the top half around the axis of rotation 2 rotatable torque transmitting device 1 is shown. The torque transmitting device 1 is made of two mutually rotatable damper parts 3 . 4 formed as the flywheel masses to form a torsional vibration damper 5 like a split flywheel are formed. The damper parts 3 . 4 are contrary to the effect of energy storage 6 . 7 rotatable, the energy storage 6 . 7 are arranged on radially different diameters and cause a two-stage response of the split flywheel. The primary damper part 3 is as an input part of the torque transmitting device 1 trained and with the crankshaft 8th an internal combustion engine connected. The secondary damper part 4 has a hub part 9 on, which is the output part of the torque transmission device 1 forms and takes the centrifugal pendulum 10 rotatably by means of the rivet 11 on, at the same time the two-piece flange 12 for the output side admission of energy storage 6 . 7 with the hub part 9 connect.
The centrifugal pendulum 10 is by means of the carrier part 13 rotatably added to the rivets. The carrier part 13 takes against this along non-illustrated raceways limited pivoting pendulum masses 14 on, on both sides of the carrier part 13 are arranged. For determining the pivoting path of the pendulum masses 14 opposite the carrier part 13 A rolling element, not shown, rolls in a raceway of a pendulum mass at a given angle of oscillation 14 and a complementary track of the support member, preferably two tracks per pendulum mass 14 are provided and two axially opposite pendulum masses 14 are interconnected and each having common rolling elements. Two to six of these units are over the circumference of the carrier part 13 distributed. Viewed in the circumferential direction between the pendulum masses 14 are stop buffers 15 provided at the same time in the form of rivets, the compound of the axially opposite pendulum masses 14 can take over and a buffer disk 16 have, at the peripheral abutment surfaces of cutouts in the carrier part 13 strikes at angles of oscillation, which are smaller than the stop areas of the rolling elements in the raceways, so that they do not hit and thus the raceways and the rolling elements are protected.
To the destruction of the pendulum masses 14 surrounding areas in the event of bursting of the pendulum masses 14 To prevent is on the outer circumference of the support member 13 a burst protection device 17 provided by the ring part 18 is formed. The ring part 18 forms two radially extending ring approaches 19 out, the outbreaks distributed over the circumference 20 have, so that the mass of the ring part 18 is reduced. The outbreaks 20 are designed so that they are not passable for all components with possibly damaging kinetic energy. In particular, the area of the eruptions is smaller than the smallest parts affected by rupture, for example the rolling elements.
The 2 shows a partial section through one of the torque transmitting device 1 of the 1 similar torque transfer device 1a , In contrast to this is the burst protection device 17a through a ring part 18a formed, with the disc part 21 is welded and the centrifugal pendulum 10a radially overlaps externally. The disc part 21 is doing to the formation of the annulus 3a for receiving the energy storage 6 with the damper part 3 connected. The ring part 18a has two viewed in cross section to each other angled as arranged at right angles ring approaches 19a . 19b on, with the ring approach 19a on the disc part 21 attached and the ring neck 19b the centrifugal pendulum 10a radially overlaps externally. Due to the arrangement of preferably designed as a sheet metal ring ring part 18a becomes the carrier part 13a relieved of a mass accumulation.
3 shows a partial section through the torque transmitting device 1b , their centrifugal pendulum 10b completely encapsulated. This is the carrier part 13b of the centrifugal pendulum 10b out two flange parts 22 . 23 formed, which has an annular indentation 24 have and facing each other mounted an annular space 25 , in each of which individual pendulum masses 14a are distributed over the circumference, form. The flange parts 22 . 23 are radially externally interconnected as riveted or welded and radially inward by means of the rivet 11 at the hub part 9 added.
The pendulum masses 14a are designed in several parts and have a central mass body 26 on, the two sides of two cover plates 27 flanked. In the mass body 26 are cutouts 28 each with a career 29 provided on which rolling elements 30 roll off. To the raceways 29 complementary raceways 31 are in the flange parts 22 . 23 formed, which is the storage of pendulum masses 14a on the support part 13b take. These are the flange parts 22 . 23 embossings 32 provided, which are not put through, so that the flange parts 22 . 23 despite formation of bearings with the raceways 31 stay closed. At the same time form the embossments 32 an axial stop for the rolling elements 30 ,
4 shows a partial section with through the torque transmission device 1b of the 3 with one through a stop buffer 33 guided cutting line. The stop buffers 33 are distributed in the circumferential direction and each offset from the rolling elements 30 ( 3 ) arranged. Here are the two flange parts 22 . 23 through the rivet-shaped bump stop 33 axially connected together. In the area of the stop surfaces of the end faces 34 the cover sheets 27 is at the stop buffers 33 a buffer disk 35 provided for example of plastic or rubber.
5 shows a further partial section through the torque transmitting device 1b of the 3 and 4 along a through a spacer 36 guided cutting line. The spacers 36 are about the pendulum masses 14a distributed and attached to the cover plates, for example with these locked, snapped or riveted. The spacers 36 can be made of plastic or metal. Im by the pendulum masses 14a predetermined pivoting range and contact area of the spacers 36 on the inner surfaces of the flange parts 22 . 23 are coatings 37 made of plastic or other coating material. The cover sheets 27 are with the mass body 26 by means of the continuous rivet 38 connected.
6 shows a section of the centrifugal pendulum 10b of the 3 to 5 in view. Shown is the centrifugal pendulum 10b without the flange part 22 ( 3 ). in the flange part 23 are distributed over the circumference four pendulum masses 14a arranged out of the mass body 26 and the cover sheets 27 are formed. Mass body and cover plates 27 are by means of the rivet 38 riveted together. On the cover plates 27 are spacers 36 arranged; each on coatings 37 on the inner surfaces of the flange parts 22 . 23 ( 22 , please refer 5 ) slide. Between the pendulum masses 14a are the stop buffers 33 arranged, by means of which the swing angle of the pendulum masses 14a is limited by the end faces 34 the cover sheets 27 attacks.
In the mass bodies 26 are cutouts 28 with raceways 29 introduced, on which the rolling elements 30 roll off. Out 7 that a section of the flange 23 in view, are the markings 32 It can be seen that the complementary raceways 31 for the rolling elements 30 ( 6 ) contain. The unimpressed embossments contained simultaneously axial support surfaces 39 for the rolling elements 30 ( 6 ).
8th shows one of the torque transmitting device 1b of the 3 to 7 similar torque transmitting device 1c in partial section. In contrast to this, instead of the markings 32 ( 6 ) cutouts 40 with the raceways 31 for the rolling elements 30 intended. To the annulus 25 for the pendulum masses 14a Nevertheless, seal on the outsides of the flange 22a . 23a preferably annular, the cutouts 40 covering cover sheets 41 Made of thin material provided with the flange parts 22a . 23a connected, for example, riveted.
9 shows the torque transmitting device 1d in partial section. In contrast to the torque transfer devices of the preceding figures, the fully enclosed centrifugal pendulum 10c directly into the flange part 12a of the secondary damper part 4a for charging the energy storage 6a integrated. For this purpose, the flange part 12a two radially outer flange parts 22b . 23b on, with the flange part 12a rotatably connected and the annulus 25a for the pendulum masses 14b form. The flange parts 22b . 23b are radial to arms 42 extended to each other by means of riveting 43 are connected and the secondary loading areas for the energy storage 6a form. In this way, the pendulum masses 14b radially inside the energy storage 6a be arranged axially across, whereby axial space is saved.
Drehmomentübertragunhseinrichtung
Anschlagpuff
buffer Scheib
Torque transmission device ( 1 . 1a . 1b . 1c . 1d ) in a drive train of a motor vehicle with a torsional vibration damper ( 5 ) with two counteracting each other the action of at least one energy store ( 6 . 6a . 7 ) limited rotatably mounted damper parts ( 3 . 4 . 4a ) and a centrifugal pendulum ( 10 . 10a . 10b . 10c ) with one with one of the damper parts ( 4 ) rotationally connected arranged carrier part ( 13 . 13a . 13 ) distributed over the circumference and limited to this by means of rolling elements ( 30 ) opposite the carrier part ( 13 . 13a . 13b ) pivotable pendulum masses ( 14 . 14a . 14b ), whereby the pendulum masses ( 14 . 14a . 14b ) are encapsulated at least radially outward, wherein radially outside of the centrifugal pendulum ( 10a ) the pendulum masses ( 14 ) cross-ring part ( 18a ), which is not connected to the centrifugal pendulum ( 10a ) connected damper part ( 3 ), wherein the ring part ( 18a ) in cross-section angled ring approaches arranged ( 19a . 19b ), one of which on the primary damper part ( 3 ) or a component connected thereto and the other the centrifugal pendulum ( 10a ) radially overlaps, wherein the centrifugal pendulum ( 10 . 10a . 10b ) axially adjacent to the at least one energy store ( 6 . 7 ) is arranged.
Torque transmission device ( 1 . 1a . 1b . 1c . 1d ) in a drive train of a motor vehicle with a torsional vibration damper ( 5 ) with two against each other against the action of at least one energy store ( 6 . 6a . 7 ) limited rotatably mounted damper parts ( 3 . 4 . 4a ) and a centrifugal pendulum ( 10 . 10a . 10b . 10c ) with one with one of the damper parts ( 4 ) rotationally connected arranged carrier part ( 13 . 13a . 13 ) distributed over the circumference and limited to this by means of rolling elements ( 30 ) opposite the carrier part ( 13 . 13a . 13b ) pivotable pendulum masses ( 14 . 14a . 14b ), whereby the pendulum masses ( 14 . 14a . 14b ) are encapsulated at least radially outward, the centrifugal pendulum ( 10c ) in one of the damper parts ( 4a ), wherein the secondary damper part ( 4a ) an annulus ( 25a ) for the pendulum masses ( 14b ) forming flange parts ( 22b . 23b ), which are closed radially on the outside and radially expanded arms ( 42 ) for acting on the at least one energy store ( 6a ) exhibit.
Torque transmission device ( 1 . 1a . 1b . 1c . 1d ) in a drive train of a motor vehicle with a torsional vibration damper ( 5 ) with two counteracting each other the action of at least one energy store ( 6 . 6a . 7 ) limited rotatably mounted damper parts ( 3 . 4 . 4a ) and a centrifugal pendulum ( 10 . 10a . 10b . 10c ) with one with one of the damper parts ( 4 ) rotationally connected arranged carrier part ( 13 . 13a . 13 ) distributed over the circumference and limited to this by means of rolling elements ( 30 ) opposite the carrier part ( 13 . 13a . 13b ) pivotable pendulum masses ( 14 . 14a . 14b ), whereby the pendulum masses ( 14 . 14a . 14b ) are encapsulated at least radially outward, wherein the carrier part ( 13 ) from a with a damper part ( 4 ), the pendulum masses ( 14 ) carrying flange part is formed, wherein a burst protection device ( 17 ) on the outer circumference of the carrier part ( 13 ), wherein the burst protection device ( 17 ) by a on the outer circumference of the support member ( 13 ) firmly attached ring part ( 18 ) is formed.
Torque transmission device ( 1 . 1a . 1b . 1c . 1d ) in a drive train of a motor vehicle with a torsional vibration damper ( 5 ) with two counteracting each other the action of at least one energy store ( 6 . 6a . 7 ) limited rotatably mounted damper parts ( 3 . 4 . 4a ) and a centrifugal pendulum ( 10 . 10a . 10b . 10c ) with one with one of the damper parts ( 4 ) rotationally connected arranged carrier part ( 13 . 13a . 13 ) distributed over the circumference and limited to this by means of rolling elements ( 30 ) opposite the carrier part ( 13 . 13a . 13b ) pivotable pendulum masses ( 14 . 14a . 14b ), whereby the pendulum masses ( 14 . 14a . 14b ) are encapsulated at least radially outward, wherein the carrier part ( 13a . 13b ) of two facing flange parts ( 22 . 22a . 23 . 23a ) is formed, which by means of a respective annular indentation ( 24 ) an at least radially outer closed annular space ( 25 ) in which the pendulum masses ( 14a ), the pendulum masses ( 14a ) on rolling elements ( 30 ) roll axially in at least one of the two flange parts ( 22 . 22a . 23 . 23a ), bearing points for the bearing of the rolling elements ( 30 ) in the at least one flange part ( 22a . 23a ) and the resulting openings through cover plates ( 41 ) are covered.
Torque transmission device ( 1 . 1a . 1b . 1c . 1d ) in a drive train of a motor vehicle with a torsional vibration damper ( 5 ) with two counteracting each other the action of at least one energy store ( 6 . 6a . 7 ) limited rotatably mounted damper parts ( 3 . 4 . 4a ) and a centrifugal pendulum ( 10 . 10a . 10b . 10c ) with one with one of the damper parts ( 4 ) rotationally connected arranged carrier part ( 13 . 13a . 13 ) distributed over the circumference and limited to this by means of rolling elements ( 30 ) opposite the carrier part ( 13 . 13a . 13b ) pivotable pendulum masses ( 14 . 14a . 14b ), whereby the pendulum masses ( 14 . 14a . 14b ) are encapsulated at least radially outward, the pendulum masses ( 14a ) from a mass body ( 26 ) and two axially flanking cover plates ( 27 ), wherein mass bodies ( 26 ) and cover sheets ( 27 ) are riveted together.
Torque transmission device ( 1 . 1a . 1b . 1c ) according to one of claims 3 to 5, characterized in that the centrifugal pendulum ( 10 . 10a . 10b ) axially adjacent to the at least one energy store ( 6 . 7 ) is arranged.
Torque transmission device ( 1b . 1c ) according to one of claims 1, 3, 4 or 5, characterized in that in the carrier part ( 13a . 13b ) Bump stops distributed over the circumference ( 33 ) for the circumferentially facing end faces ( 34 ) of the pendulum masses ( 14a ) are provided.
Torque transmission device ( 1b . 1c ) according to claim 4, characterized in that between the pendulum masses ( 14a ) and the insides of the flange parts ( 22 . 22a . 23 . 23a ) axial spacers ( 36 ) are provided of plastic.
DE102009042825.9A 2008-10-30 2009-09-24 Torque transfer device Active DE102009042825B4 (en)
DE102008054024.2 2008-10-30
DE102008054024 2008-10-30
DE102009029724 2009-06-22
DE102009029724.3 2009-06-22
DE102009042825.9A DE102009042825B4 (en) 2008-10-30 2009-09-24 Torque transfer device
DE102009042825A1 DE102009042825A1 (en) 2010-05-12
DE102009042825B4 true DE102009042825B4 (en) 2016-09-15
ID=42096598
DE102009042825.9A Active DE102009042825B4 (en) 2008-10-30 2009-09-24 Torque transfer device
DE (1) DE102009042825B4 (en)
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2017-06-01 R026 Opposition filed against patent
2018-11-20 R006 Appeal filed
2018-11-28 R008 Case pending at federal patent court