EP1948976A1 - Hydrodynamic torque converter device for an automotive drive train - Google Patents

Abstract

The invention relates to a hydrodynamic torque converter device for an automotive drive train, comprising a torsional vibration damper and a converter torus which is configured by an impeller, a turbine wheel and a stator. The torsional vibration damper has a first energy accumulating device with one ore more first energy accumulators, and a second energy accumulating device with one ore more second energy accumulators, which is connected in series to the first energy accumulating device.

Description

 Hydrodynamic torque converter device for a motor vehicle

Antriebsstranq

The invention relates to a hydrodynamic torque converter device for a motor vehicle drive train, which has a torsional vibration damper and a transducer torus formed by a pump wheel, a turbine wheel and a stator.

A hydrodynamic torque converter device for a motor vehicle drive train is already known from FIG. 3 of DE 196 14 411 A1, which has a torsional vibration damper as well as a transducer torus formed by a pump wheel, a turbine wheel and a stator. The local torsional vibration damper has exactly one energy storage device which is arranged between an input part and an output part. The output member is rotatably connected to a hub, which in turn is rotatably coupled to a shaft. The input part is connected to the piston of a converter bridging clutch in such a way that, when the converter lockup clutch is closed, the energy storage device can be loaded by the converter housing via the input part. The input part is further coupled via a rivet connection with the outer turbine shell of the converter torus. This is such that the outer turbine shell in the region in which it limits the Torusinnere or Torusinnenraum having an outward manifestation, in which a rivet is arranged, the corresponding openings of the outer turbine shell and the input part a rotationally fixed connection generated between the input part of the outer turbine shell.

From DE 199 20 542 A1 a hydrodynamic torque converter device for a motor vehicle drive train is known, in which the torsional vibration damper has two energy storage devices. There, on the outside of the outer turbine shell in the region which delimits the torus interior, a driver part is welded, which is connected via a plug connection to the input part of an outer damper or an external energy storage device. The output part of this outer energy storage device is in turn coupled to the piston of a lockup clutch and at the same time forms the input part of the inner energy storage device whose output part is connected to a hub. Another hydrodynamic torque converter device for a motor vehicle drive train in which the torsional vibration damper has two energy storage devices is known from FIG. 1 of DE 103 58 901 A1. In the design there, the input part of the outer energy storage device is coupled to a converter bridging clutch. An intermediate part simultaneously forms the output part of the outer energy storage device and the input part of the inner energy storage device, which is connected via its output part with a hub. At this hub, an extension of the outer turbine shell is supported radially. On the outside of the outer turbine shell, in the area in which the outer turbine shell delimits the torus interior, a driver part is welded, which, on the other hand, is coupled to the intermediate part via a connecting means configured as a bolt connection.

The invention is based on the object of providing a torque converter with a torsional vibration damper and with one of a pump impeller, a turbine wheel and a stator torque converter device provided for a motor vehicle powertrain, which can be produced easily manufactured and the reliable relieve or compensate for rotational shocks an internal combustion engine allows.

According to the invention, in particular a hydrodynamic torque converter device according to claim 1 is proposed. Preferred developments are subject of the dependent claims.

In particular, a hydrodynamic torque converter device for a motor vehicle drive train is proposed which has a torsional vibration damper and a transducer torus formed by a pump wheel, a turbine wheel and a stator. It should be noted in this regard that in prior publications a device referred to herein as a "transducer torus" is sometimes referred to as a "hydrodynamic torque converter"; However, the term "hydrodynamic torque converter" is sometimes used in prior publications for devices comprising a torsional vibration damper, optionally a lockup clutch and a device formed by a impeller, a turbine wheel and a stator or - in the diction of the present disclosure - a transducer torus , Against this background, the terms "(hydrodynamic) torque converter device" and "converter torus" are used in the present disclosure for better distinctness. The torsional vibration damper has a first energy storage device with one or more Ren first energy storage and a second energy storage device with one or more second energy storage. The first energy storage device is connected in series with the second energy storage device, wherein between these two energy storage devices - also connected in series - a first component is provided. The transducer torus has-in particular in the usual form-a torus interior or a torus interior, which is designed in particular substantially torus-shaped or ring-shaped. An outer turbine shell forms a directly adjacent to the Torusinnere for the boundary wall section. The outer turbine shell is connected to the first component such that a load, such as in particular torque or force, from the outer 'turbine shell is transferable to the first component, wherein along the thus formed load transfer path, via which the load or the torque of the outer turbine shell is transferable to the first component, at least one connecting means is provided, by means of which - in particular adjoining - components for the torque or load transmission are interconnected. Such a connection means may be, for example, a rivet connection or a bolt connection or a screw connection or a welded connection or a plug connection or the like. It is provided that all connection means, by means of which along the load transfer path between the outer turbine shell and the first component - in particular adjacent - components are connected, are spaced from the immediately adjacent to the Torusinnere or Torusinnenraum for limiting its wall portion of the outer turbine shell.

In particular, it can be provided that turbine blades are provided, which are arranged in a conventional manner in the interior of the torus or Torusinnenraum. Advantageously, the addressed connecting means are arranged at a distance from the sections of the outer turbine shell, to which the turbine blades adjoin the outer turbine shell or are formed there.

It is provided in particular that the addressed load transfer path between the outer turbine shell and the first component is free of the first and the second energy storage device, so that a torque or a load along this load transfer path from the outer turbine shell to the first component is transferable, without that to be passed over or through one of the energy storage devices before the torque or the load reaches the first component. - A -

It may be provided, for example, that along the addressed load transfer path exactly one connecting means for connecting adjacent components of this load transfer path is provided. This can for example be such that the outer turbine shell, which is designed in particular in one piece, has an extension, which adjoins the wall portion which is provided for the delimitation of the Torusinneren, with the mentioned extension extends to the second component and there connected to this. However, it can also be provided that exactly two connection means are provided in the mentioned load transfer path. This can for example be such that an extension of the outer turbine shell adjoining the wall section of the turbine shell provided for delimiting the interior of the torus is provided, which is in particular integrally connected to the above-mentioned wall section or is made from one piece, and which has a Driver member, such as sheet metal or the like, is connected via a first connecting means. The addressed driver part can be connected via a second connecting means with the second component. It can also be provided in the mentioned load transfer path more than two connecting means.

It may be provided that - based on the circumferential direction of a rotation axis about which the torsional vibration damper is rotatable in an advantageous manner - the first energy storage device has a plurality of first, circumferentially distributed and spaced apart first energy storage and / or that the second energy storage device distributed a plurality of circumferentially or spaced second energy storage. The energy storage must not necessarily be located on an exact circumferential path. It can be provided that the first energy storage of the first energy storage device are each Bogenfedem and the second energy storage of the second energy storage device are each straight springs or straight compression springs. Advantageously, both the first energy store of the first energy storage device and the second energy store of the second energy storage device are each spiral springs.

In a preferred embodiment, the torque converter device further comprises a lockup clutch. It can be provided that the converter lockup clutch is connected on the input side to a converter housing and is coupled on the output side directly or via one or more intermediate components to a second component, so that when the converter lockup clutch is in a torque from the converter housing via the converter lockup clutch to the second component is transferable. The second component may, for example, the input part of the first energy be memory device. In a further preferred embodiment, it is provided that the second energy storage device - connected in series - is arranged between the first component and a third component. The third component may, for example, form a hub or be non-rotatably coupled to a hub. Such a hub, for example, with a shaft, such as transmission input shaft or the like, be rotatably coupled. Thus, it is particularly preferred that - in the following order - a second component, the first energy storage device, a first component, the second energy storage device and the third component are connected in series. It can be provided that the addressed series circuit consists exclusively of the mentioned components or that one or more parallel or intermediate components are provided.

According to a particularly advantageous embodiment, it is provided that the outer turbine shell is arranged pivotable or rotatable relative to the already mentioned hub. In particular, in such an embodiment can be provided that the outer turbine shell - preferably supported by a sleeve-shaped support portion - radially on the hub. This support can be such that essentially no torque can be transmitted from the outer turbine shell to the hub via the mentioned support. It is therefore provided in particular that a torque from the outer turbine shell to the hub substantially via the second energy storage device - but not via an additionally provided, in particular radial, support - can be transmitted from the outer turbine shell to the hub. It can be provided that an additional bearing device, such as plain bearing bush or roller bearing or the like, is provided between the mentioned support section and the hub.

The mentioned - in particular sleeve-shaped - support portion may be provided for example on an extension of the outer turbine shell or on a driver part or on a separate support member. As already mentioned, it is provided in a particularly preferred embodiment that the outer turbine shell or an extension of the outer turbine shell is connected by means of a driver part with the second component. It can be provided that by means of a first connecting means of the extension is connected to the driver part and by means of a second connecting means, the driver part is connected to the first component. It can also be provided, in particular, that the driver part has an extension on which the energy storage device of the first energy storage device is supported directly. In an advantageous embodiment, the driver part extends from one in the radially inner region of the outer tur- binenschale located portion or extension of the outer turbine shell to the second component. However, it can also be provided that the addressed driver part extends from a radially outer portion of the outer turbine shell to the second component. In a particularly preferred embodiment, it is provided that the driver part and / or the first component and / or the second component and / or the third component are formed as a metal sheet. In particular, in a design in which the second component and the driver part are each designed as a metal sheet, it is advantageously provided that the driver or driver plate has a greater wall thickness than the second component. According to a particularly preferred development, it is provided that the driver part-in particular with respect to the axis of rotation of the torsional vibration damper-has a greater mass moment of inertia than the second component. It can also be provided that the mass of the driver part is greater than that of the second component.

Furthermore, it can be provided that a relative Verdrehwinkelbegrenzung or Verdrehwinkelbegrenzung for the torsional vibration damper or for the first and / or second E nergiespeichereinrichtung is provided and in particular a Verdrehwinkelbegrenzung, which goes into a stop position before the energy storage of the first and / or second energy storage device go to block, provided that they are trained so that they can go to block. In particular, such a rotation angle limitation limits the maximum relative twist angle between the input part and the output part of the relevant energy storage device. In an advantageous embodiment, a rotation angle limitation is provided only for the second energy storage device, ie not for the first energy storage device; It can be provided that the first energy storage arc springs, and the second energy storage are straight (pressure) springs.

In a particularly preferable embodiment, it is provided that the driver part is connected via first connecting means with the outer turbine shell or an extension of the outer turbine shell and is rotatably connected, wherein the connecting means are provided in a region in which the extension or the outer turbine shell and / or the driver part is straight, and in a particularly preferable embodiment - with respect to the radial direction of the axis of rotation of the torsional vibration damper - in the radial direction - in particular in each case - straight.

In the following, embodiments of the invention will now be explained in more detail with reference to the figures. Showing: Fig. 1 shows a first embodiment of a hydrodynamic according to the invention

Torque converter device;

Fig. 2 shows a second embodiment of a hydrodynamic according to the invention

Torque converter device;

Fig. 3 shows a third embodiment of a hydrodynamic according to the invention

Torque converter device; and

Fig. 4 shows a fourth embodiment of a hydrodynamic according to the invention

Torque converter device.

FIGS. 1 to 4 show various embodiments of a hydrodynamic torque converter device 1 according to the invention.

The hydrodynamic torque converter device 1 is intended for a drive train of a motor vehicle or forms part of a motor vehicle drive train, which is schematically illustrated by the reference numeral 2. The hydrodynamic torque converter device 1 has a torsional vibration damper 10, a converter torus 12 formed by an impeller 20, a turbine wheel 24 and a stator 22, and a converter lock-up clutch 14.

The torsional vibration damper 10, the transducer torus 12 and the lockup clutch 14 are accommodated in a converter housing 16. The converter housing 16 is substantially non-rotatably connected to a drive shaft 18, which is for example the crankshaft or engine output shaft of an internal combustion engine.

The transducer torus 12 has - as mentioned - a pump or an impeller 20, a stator 22 and a turbine or a turbine wheel 24, which cooperate in a conventional manner. In a manner known per se, the transducer torus 12 has a transducer interior space or a torus interior 28, which is provided for receiving oil or for an oil flow. The turbine wheel 24 has an outer turbine shell 26, which forms a directly adjacent to the inner end of the torus 28 and provided for a boundary of the Torusinneren 28 wall portion 30. At the immediately adjacent to the torus interior 28 wall portion 30 is an extension 32 of the outer turbine closes nenschale 26 at. This extension 32 has a straight or annular shaped section 34. This straight or annular shaped portion 34 of the extension 32 may, for example, be such that it is substantially straight in the radial direction of the axis of rotation 36 of the torsional vibration damper 10 and, in particular as an annular portion, lies in a plane perpendicular to the axis of rotation 36 This spans.

The torsional vibration damper 10 has a first energy storage device 38 and a second energy storage device 40. The first energy storage device 38 and / or the second energy storage device 40 are in particular spring devices.

In the exemplary embodiments according to FIGS. 1 to 4, it is provided that the first energy storage device 38 has a first energy store 42, such as spiral springs or bow springs, arranged in a circumferential direction extending around the axis of rotation 36, in particular at a distance from one another. It can be provided that all the first energy storages 42 are designed identically. It can also be provided that differently designed first energy store 42 are provided.

The second energy storage device 40 has a plurality of, for example, each designed as a spiral spring or straight (pressure) spring, second energy storage 44. Here, in a preferred embodiment, a plurality of second energy storage 44 circumferentially - with respect to the circumferential direction of the rotation axis 36 - spaced from one another. It can be provided that the second energy storage 44 are each designed identically; different second energy storage 44 can also be designed differently.

According to the exemplary embodiments according to FIGS. 1 to 4, the second energy storage device 40-with respect to the radial direction of the axis of rotation 36 -is arranged radially within the first energy storage device 38. The first 38 and the second energy storage device 40 are connected in series. The torsional vibration damper 10 has a first component 46, which is arranged between the first 38 and the second energy storage device 40 or connected in series with these energy storage devices 38, 40. It is therefore provided in particular that - for example, with the converter lock-up clutch 14 closed - a torque from the first energy storage device 38 via the first component 46 to the second energy storage device 40 is transferable; The first component 46 may also be referred to as an intermediate part 46, which will also be done below. In the exemplary embodiments according to FIGS. 1 to 4, it is provided that the outer turbine shell 26 is connected to this intermediate part 46 such that a load, in particular torque and / or force, can be transmitted from the outer turbine shell 26 to the intermediate part 46 is.

Between the outer turbine shell 26 and the intermediate part 46 or in the load flow, in particular torque or force flow, between the outer turbine shell 26 and the intermediate part 46, a driver part 50 is provided. It can also be provided that the extension 32 also forms the intermediate part 46 and / or the driver part 50, or assumes its function. It can also be provided that the driver part 50 forms a first component or intermediate part, which is connected in series in the torque flow between the energy storage devices 38, 40. It is further provided that along the load transfer path 48, via which a load or a torque from the outer turbine shell 26 is transferable to the intermediate part 46, at least one connecting means 52, 56 and 54, 58 is provided. Such a connection means 52, 56 or 54, 58 may, for example, be a plug connection (see reference 58 in FIG. 4) or a riveted connection or bolt connection (see reference 56 in FIGS. 1 to 3 and 54 in FIG. or a welded joint (see reference numeral 52 in Figures 1 to 3) or the like. It should be noted that in Fig. 3 at the point where the welded joint 52 is given, in addition - to show an alternative design option - a rivet or bolt connection 54 is located. This should also clarify that the said connection means can also be designed differently or combined differently. By means of the corresponding connecting means 52, 54, 56, 58 are each adjacent components of the aforementioned load transfer path 48, via which the load from the outer turbine shell 26 to the intermediate part 46 is transferable, coupled together. Thus, in the designs according to FIGS. 1 to 3, the extension 32 of the outer turbine shell 26 is rotatably coupled to the driver part 50 in each case via a connection means 52 designed as a welded connection (which, according to FIG. 3, can alternatively be a rivet or bolt connection), and this driver part 50 rotatably coupled to the intermediate part 46 in each case via a connecting means 56 designed as a rivet or bolt connection. In the embodiment according to FIG. 4, the extension 32 of the outer turbine shell 26 is rotatably coupled to the driver part 50 via a connection means 54 designed as a rivet or bolt connection, and this driver part 50 to the intermediate part 46 in each case via a connection means 58 designed as a plug connection rotatably coupled. It is provided that all connection means 52, 54, 56, 58, by means of which along the load transfer path 48 between the outer turbine shell 26 and the intermediate part 46 adjacent components (such as extension 32 and driver part 50 and driver part 50 and intermediate part 46) are connected, are spaced from the immediately adjacent to the Torusinnere 28 wall portion 30 of the outer turbine shell 26. This allows - at least according to the embodiments - that the bandwidth of possible connecting means is increased. For example, it is possible to use not only thin-sheet or MAG or laser or spot welding as the welding method but, for example, also friction welding, which is not readily possible, for example, in the design according to FIG. 3 of DE 196 14 411 A1 , The use of bolted or riveted joints as connecting means can be realized more easily in the designs according to FIGS. 1 to 4 than in designs of the type shown in FIG. 3 of DE 196 14411 A1, so that when selecting suitable connecting means a wider range is available. In addition, the risk of production-related or thermally induced delay in the region of the turbine blades, which are provided in the interior of the torus 28 is reduced in the embodiments according to FIGS. 1 to 4 with respect to the design of FIG. 3 DE 196 14411 A1.

Connected in series with the first energy storage device 38, the second energy storage device 40 and the intermediate component 46 provided between these two energy storage devices 38, 40 are a second component 60 and a third component 62. The second component 60 forms an input part of the first energy storage device 38 and the third Component 62 forms an output part of the second energy storage device 40. A load or torque introduced from the second component 60 into the first energy storage device 38 can thus be transferred to the third component 62 via the intermediate part 46 and the second energy storage device 40 on the output side of this first energy storage device 38 ,

The third member 62 engages a hub 64 to form a rotationally fixed connection, which in turn is rotatably coupled to an output shaft 66 of the torque converter device 1, which is, for example, a transmission input shaft of an automotive transmission. The outer turbine shell 26 is supported radially on the hub 64 by means of a support section 68. The support portion 68, which is supported in particular radially on the hub 64, is designed substantially sleeve-shaped. It should be noted that the addressed radial support of the outer turbine shell 26 by means of the support section 68 is such that supporting forces acting thereon on the outer turbine shell 26 are not conducted via the first or second energy storage device 38, 40 from the support section 68 to the outer turbine shell 26. The support portion 68 is rotatable relative to the hub 64. It may be provided that between the hub 64 and the support portion 68, a slide bearing or a plain bearing or a rolling bearing or the like is provided for the radial support. Furthermore, appropriate bearings may be provided for axial support. The above-mentioned connection between the outer turbine shell 26 and the intermediate part 46 is such that a torque transmittable from the outer turbine shell 26 to the intermediate part 46 can be transmitted from the outer turbine shell 26 to this intermediate part 46 without along the corresponding load transfer path 48th one of the energy storage devices 38, 40 is provided. This torque transmission from the outer turbine shell 26 to the intermediate part 46 (via the load transmission path 48) can thus be effected in particular by means of a substantially rigid connection.

In the exemplary embodiments according to FIGS. 1 to 4, two connecting means are respectively provided along the load or force transmission path 48 between the outer turbine shell 26 and the intermediate part 46, namely a first connecting means 52 and 54 and a second connecting means 56 and 58. It should be noted that, relative to the circumferential direction of the axis of rotation 36, a plurality of first connecting means 52 and second connecting means 56 can be provided in the circumferential direction and / or preferably provided. In the context of this disclosure, however, the simplification is also referred to as "the first connection means" or "the second connection means", which strictly speaking means one or more first connection means or one or more second connection means. The first connecting means 52 or 54 connects - in particular rotationally fixed - the extension 32 with the driver part 50 and the second connecting means 56 and 58 connects - in particular rotationally fixed - the driver part 50 with the intermediate part 46. In these embodiments, it is provided that the first connecting means 52 and 54 - with respect to the radial direction of the axis 36 - is arranged radially within the second connecting means 56 and 58, respectively. Furthermore, it is provided in these exemplary embodiments that the first connection means 52 or 54 is arranged radially within the second energy storage device 40 or radially within the second energy storage 44 of the second energy storage device 40. The second connecting means 56 and 58 is there - with respect to the radial direction of the axis 36 - radially between the first energy storage device 38 and the second energy storage device 40 and the first energy storage 42 of the first energy storage device 38 and the second energy storage 44 of the second energy storage device 40 is arranged.

While in the embodiments according to FIGS. 1 to 3, the sleeve-like support region 68 is a radially inwardly located section of the driver part 50 with respect to the radial direction of the rotation axis 36, a separate support part 70 is provided in the design according to FIG In any case, based on the radial direction of the axis of rotation 36 - radially inside the sleeve-like support portion 68 is formed. The support member 70 is there rotatably connected to the extension 32 and the driver part 50. This rotationally fixed connection also takes place here by means of the connection means 54, wherein it should be noted that separate connection means can also be provided.

The converter lock-up clutch 14 is formed in the designs according to FIGS. 1 to 4 in each case as a multi-disc clutch and has a first disc carrier 72, of which first blades 74 are rotatably received, and a second disc carrier 76, of which second blades 78 are rotatably received. When the multi-plate clutch 14 is open, the first disk carrier 72 is relatively movable relative to the second disk carrier 76, in such a way that the first disk carrier 72 can be rotated relative to the second disk carrier 76. The second plate carrier 76 is here - with respect to the radial direction of the axis 36 - disposed radially within the first disc carrier 72, but this may be the other way round. The first plate carrier 72 is fixedly connected to the converter housing 16. For their operation, the multi-plate clutch 14 on a piston 80 which is arranged axially displaceable and for actuating the multi-plate clutch 14 - for example, hydraulically - can be acted upon. The piston 80 is fixed or rotatably connected to the second plate carrier 76, which may be effected for example by means of a welded connection. First 74 and second blades 78 alternate - seen in the longitudinal direction of the axis of rotation 36 - from. Upon actuation of the disk set 79 formed by the first 74 and second disks 78 by means of the piston 80, this disk set 79 is supported on the side of the disk set 79 opposite the piston 80 at a portion of the inside of the converter housing 16. Between adjacent lamellae 74, 78 and on both sides of the end of the disk set 79 friction linings 81 are provided, which are held for example on the fins 74 and / or 78. The friction linings 81, which are provided on the end side of the disk set 79, can also be held on one side and / or on the other side on the inside of the converter housing 16 or on the piston 80. In the exemplary embodiments according to FIGS. 1, 2 and 4, the piston 80 is formed integrally with the second component 60, that is to say the input part of the first energy storage device 38. In the embodiment of FIG. 3, the piston 80 is non-rotatably or fixedly connected to the second component 60 and the input part of the first energy storage device 38, wherein this fixed connection takes place here for example via a weld. In principle, the rotationally fixed connection can also be done in other ways; In the embodiments according to FIGS. 1, 2 and 4, in an alternative design, the piston 80 and the input part 60 of the first energy storage device 38 may also be formed as a separate, fixed part or part fixed to one another, for example via a weld or a rivet or bolt be. In the embodiment according to FIG. 3, another suitable connection between the piston 80 and the input part 60 may be provided for producing this (fixed or rotationally fixed) connection instead of the welded connection, such as bolt or rivet connection or plug connection, or it may be Alternatively, the piston 80 with the input part 60 may also be made in one piece from one part.

The piston 80 or the second component 60, the first component or the intermediate part 46, the third component 62 and the driver part 50 are each formed by sheets. In the design according to FIG. 4, the support part 70 can also be formed by a metal sheet. The second component 60 is in particular a flange. The first component 46 is in particular a flange. The third component 62 is in particular a flange.

In the embodiments according to FIGS. 1 to 3, the mass moment of inertia of the driver part 50 is greater than the mass moment of inertia of the piston 80 or of the input part 60 of the first energy storage device 38 or the unit of these parts 60, 80. In the exemplary embodiment according to FIG the Bleckdicke of the driver part 50 is greater than the Bleckdicke of the piston 80 and the input part 60 of the first energy storage device 38th

It should be noted that the vibration behavior in the design according to FIG. 4 is worse than in the designs according to FIGS. 1 to 3. In the design according to FIG. 2, the vibration behavior of the device 1 is particularly good.

For the first energy storage 42, a type of housing 82 is formed, which is at least partially, with respect to the radial direction and the axial direction of the axis of rotation 36. se on both sides axially and radially outside around the respective first energy storage 42 extends. In the embodiments according to FIGS. 1 to 3, this housing 82 is arranged on the driver part 50, whereas in the exemplary embodiment according to FIG. 4 it is arranged on the piston 80. In most applications, the above-mentioned rotationally fixed arrangement on the driver part 50 or on the outer turbine shell is advantageous under aspects of vibration technology, since in this way more mass moment of inertia is shifted to the secondary side of the first energy storage device 38.

In the exemplary embodiment according to FIG. 3, the first energy stores 42 can each be supported on the addressed housing 82 for friction reduction via a rolling element, such as balls or rollers, having means 84, which can also be referred to as roller skate. Although not shown in Figs. 1 and 2 and 4, such, rolling elements, such as balls or rollers having means 84 for supporting the first energy storage 42 and for reducing friction in the designs according to FIGS. 1 and 2 and 4 may be provided in a corresponding manner. According to FIGS. 1, 2 and 4, however, here instead a sliding shell or a sliding shoe 94 is provided instead of such a roller skate 84 for the low-friction support of the first energy store 42.

Furthermore, in the designs according to FIGS. 1 to 3 (in the design according to FIG. 4 this may be correspondingly) a second rotation angle limiting device 92 is provided for the second energy storage device 40, by means of which the maximum angle of rotation or relative rotation angle of the second energy storage device 40 or of the Input part of the second energy storage device 40 relative to the output part of the second energy storage device 40 is limited. This is so here that the maximum angle of rotation of the second energy storage device 40 is limited by means of this second Verdrehwinkelbegrenzungseinrichtung 92 such that prevents the second energy storage 44, which are in particular springs, go at a correspondingly high torque load on block. The second Verdrehwinkelbegrenzungseinrichtung 92 is - as shown in FIGS. 1 to 3 - for example, so that the driver part 50 and the intermediate part 46 via a bolt, which is in particular part of the connecting means 56, are rotatably connected, said bolt extending through a slot, which is provided in the output part of the second energy storage device 40 or in the third component 62. It may also - which is not shown in the figures - a first Verdrehwinkelbegrenzungseinrichtung be provided for the first energy storage device 38, by means of which the maximum angle of rotation of the first energy storage device 38 is limited such that an on-block walking the first, in particular as a spring designed, energy storage 42 is prevented. Insbesonde- If, as is advantageous, the case, the second energy storage 44 are straight (pressure) fedem and the first energy storage 42 bow springs, it can be provided that - as shown in Fig. 1 to 3 - only a second Verdrehwinkelbegrenzungseinrich - For the second energy storage device 40 is provided because in such designs in an on-block walking the risk of damage to bow springs is less than in straight springs, and an additional, first Verdrehwinkelbegrenzungseinrichtung would increase the number of components or manufacturing costs ,

In a particularly advantageous embodiment is provided in the embodiments according to FIGS. 1 to 4 that the angle of rotation of the first energy storage device 38 is limited to a maximum first angle of rotation and the angle of rotation of the second energy storage device 40 is limited to a maximum second angle of rotation, wherein the first energy storage device 38 reaches its maximum first twist angle when a first limit torque is applied to the first energy storage device 38 and the second energy storage device 40 reaches its maximum second twist angle when a second limit torque is applied to this second energy storage device 40, this first limit torque being less than this second limit torque is. This can be achieved in particular by an appropriate tuning of the two energy storage devices 38, 40 or the energy storage 42, 44 of the two energy storage devices 38, 40 - optionally or in particular with the first and / or second Verdrehwinkel- limiting device. It is provided that the first energy store 42 at the first limit torque go to block, so that the first energy storage device 38 reaches its maximum first twist angle, and is effected by means of a second Verdrehwin- kelbegrenzungseinrichtung for the second energy storage device 40 that the second energy storage device 40 at a second Limit torque reaches its maximum second angle of rotation, this maximum second angle of rotation is achieved when the second Verdrehwinkelbegrenzungseinrichtung reaches a stop position.

In this way, in particular a good vote for a partial load operation can be achieved.

It should be noted that the angle of rotation of the first energy storage device 38 and the second energy storage device 40 - and the same applies to the maximum first and maximum second twist angle - is strictly speaking the relative twist angle with respect to the circumferential direction of the axis of rotation 36 of the torsional vibration damper 10 which is given in relation to the unloaded rest position between the input side and the output side for torque transmission respectively directly to the relevant energy storage device 38 or 40 adjacent components. This angle of rotation, which is limited by the respective maximum first or second angle of rotation, in particular in the manner mentioned above, can change in particular in that the energy stores 42 and 44 of the respective energy storage device 38 or 40 absorb energy or deliver stored energy.

In the embodiments according to FIGS. 1 to 3, the piston 80 or the second component or the input part 60 of the first energy storage device 38 forms a plurality of circumferentially distributed tabs 86, each having a non-free end 88 and a free end 90 , and which are provided for the front-side, input-side load of a respective first energy storage unit 42. The non-free end 88 is - with respect to the radial direction of the axis of rotation 36 - arranged radially within the free end 90 of the respective tab 86.

In the exemplary embodiments according to FIGS. 1 to 4-based on the radial direction of the axis 36 of the torsional vibration damper 10 -the radial extent of the driver part 50 is greater than the average radial distance of the or the first energy store 42 from the second energy store or stores 44th

Bezuqszeϊchenliste

hydrodynamic torque converter device Automotive powertrain torsional vibration damper transducer torque converter lockup clutch converter housing drive shaft, such as engine output shaft of an internal combustion engine pump or impeller stator turbine external turbine shell torus internal wall portion of 26 extension to 30 of 26 straight section of 32 or annular section of 32 rotation axis of 10 first energy storage device second energy storage device first energy storage second energy storage first component of load transfer path driver part or welding connection between 32 and 50 in 48 connecting means or bolt or rivet connection between 32 and 50 in 48 connecting means or bolt or rivet connection between 50 and 46 in 48 connecting means or connector between 50 and 46 in 48 second component third component hub output shaft, transmission input shaft support portion Supporting member first rack of 14 first slat of 14 second rack of 14 slats of 14 slat pack of 14 pistons for the operation of 14 friction lining of 14 housing roller skate tab non-free end of 82 free end of 82 second Verdrehwinkelbegrenzungseinrichtung 92 of 40 Gleitschuh

Claims

claims

A hydrodynamic Drehmomentwandler- device for a motor vehicle powertrain (2) having a torsional vibration damper (10) and one of a pump impeller (20), a turbine wheel (24) and a stator (22) formed Wandlertorus (12), wherein the Torsional vibration damper (10) has a first energy storage device (38) which has one or more first energy stores (42), and a second energy storage device (40) which has one or more second energy stores (44) and which is connected to the first energy storage device (38). is connected in series, and wherein between this first (38) and said second energy storage device (40) is provided with these two energy storage devices (38, 40) connected in series first component (46), and wherein the turbine wheel (24) has an outer Turbine shell (26) having a directly to the Torusinnere (28) for a boundary of this Torusinneren (28) adjacent W and wherein the outer turbine shell (26) is connected to the first component (46) such that torque from the outer turbine shell (26) is transferable to the first component (46), and along which therewith at least one connection means (52, 54, 56, 58) is provided, by means of which, in particular adjoining, load transfer path (48), via which the torque from the outer turbine shell (26) can be transferred to the first component (46) Characterized in that all connecting means (52, 54, 56, 58), by means of which from the outer turbine shell (26) to the first component ( 46) extending load transfer section (48), in particular adjacent components (32, 50 or 50, 46) are connected, of the immediately adjacent to the Torusinnere (28) wall portion (30) of the outer T turbine shell (26) are spaced apart.

2. Torque converter device according to claim 1, characterized in that the torque converter device (1) has a second component (60) and a third component (62), wherein the first energy storage device (38) between the second component (60) and the first component (46) is arranged, and wherein the second energy storage device (40) between the first component (46) and the third component (62) is arranged so that a torque from the second component (60) via the first energy storage device ( 38) to the first component (46) and from this first component (46) via the second energy storage device (40) to the third component (62) is transferable.

3. torque converter device according to claim 2, characterized in that the third component (62) forms a hub (64) or with a hub (64), in particular rotationally fixed, is connected, and that the outer turbine shell (26) relative to the Hub (64) is pivotable and by means of a, in particular sleeve-shaped, support portion (68) radially on the hub (64) is supported.

4. torque converter device according to one of the preceding claims, characterized in that the torsional vibration damper (10) about an axis of rotation (36) is rotatable, wherein the first energy storage device (38) relative to the radial direction of this axis of rotation (36) radially outside of the second energy storage device (40) is arranged.

5. torque converter device according to one of the preceding claims, characterized in that the outer turbine shell (26) with the first component (46) by means of a driver part (50) is connected, wherein the outer turbine shell (26) or a directly to the wall portion (30) of the outer turbine shell (26), which adjoins directly to the provided for an oil flow Torusinnere (28) for limiting this Torusinneren (28), then extension (32) with this driver part (50) by means of a first connecting means ( 52, 54) is connected.

6. torque converter device according to claim 5, characterized in that the driver part (50) with the first component (46) by means of a second connecting means (52, 54, 56, 58) is connected.

The torque converter device according to any one of claims 5 and 6, characterized in that the first connection means (52, 54) is disposed radially inwardly of the second connection means (56, 58) with respect to the radial direction of the rotation axis (36) of the torsional vibration damper (10) is or is arranged radially with the second connecting means (56, 58) substantially at the same height.

8. torque converter device according to one of the preceding claims, characterized in that the first connecting means (52, 54) with respect to the radial direction of the axis of rotation (36) of the torsional vibration damper (10) radially within the second energy store (44) of the second Energy storage device (40) is arranged.

9. torque converter device according to one of claims 5 to 8, characterized in that the driver part (50) forms an extension which, relative to the radial direction de axis of rotation (36) of the torsional vibration damper (10) extends radially outward into a region, which is arranged radially outside the second connecting means (56, 58), and in that the first energy store (s) (42) of the first energy storage device (38) are supported on this extension of the driver part (50) such that a torque from the second component ( 60) via the first energy storage device (38) to the driver part (50) is transferable, said torque from the driver part (50) to the first component (46) is transferable.

10. Drehmomentwandler- device according to one of claims 1 to 8, characterized in that the driver part (50) relative to the radial direction of the axis of rotation (36) of the torsional vibration damper (10) completely radially within or the first energy storage (42) of the first Energy storage device (38) is arranged,

11. Drehmomentwandler- device according to one of claims 5 to 10, characterized in that the driver part (50) is in one piece.

12. Drehmomentwandler- device according to one of the preceding claims, characterized in that the torque converter device (1) has a Wandlerüberbrü- ckungskupplung (14).

13. Drehmomentwandler- device according to claim 12, characterized in that a converter housing (16) is provided and the lockup clutch (14) between said converter housing (16) and the second component (60) is arranged such that when the lock-up clutch (14) is closed a torque from the transducer housing (16) to the second component (60) and from this second component (60) via the first energy storage device (38) to the first component (46) is transferable, and that in fully open lock-up clutch (14) no Torque of the transducer housing (16) via the second component (60), the first energy storage device (38) to the first component (46) is transferable.

14. Torque converter device according to one of the preceding claims, characterized in that the second component (60) and the driver part (50) are each a sheet metal, wherein the sheet thickness of the driver part (50) is greater than the sheet thickness of the second component (60). is.

15. Torque converter device according to one of the preceding claims, characterized in that the mass moment of inertia of the driver part (50) is greater than the moment of inertia of the second component (60), in particular with respect to the axis of rotation 36 of the torsional vibration damper 10th