EP2470386A1

EP2470386A1 - Bearing mechanism for a transverse leaf spring, mountable in the area of a vehicle axle

Info

Publication number: EP2470386A1
Application number: EP10741964A
Authority: EP
Inventors: Gabriele Fruhmann; Jens Heimann; Volker Wagner
Original assignee: ZF Friedrichshafen AG
Current assignee: ZF Friedrichshafen AG
Priority date: 2009-08-26
Filing date: 2010-08-11
Publication date: 2012-07-04
Also published as: US20120146308A1; CN102481819A; WO2011023547A1; CN102481819B; DE102009028899A1; BR112012004040A2; US8444162B2

Abstract

A bearing mechanism (4) for a transverse leaf spring is described. Said bearing mechanism (4) can be mounted in the area of a vehicle axle and comprises an outer bearing shell device (30) and insertion devices (9, 10), at least some areas of which are embraced by the outer bearing shell device (30) and each of which includes at least two layer elements (9A, 9B and 10A, 10B) having a different rigidity. In the assembled state, the insertion devices (9, 10) are arranged between the outer bearing shell device (30) and the transverse leaf spring (1). According to the invention, the outer bearing shell device (30) comprises a monolithic bearing ring element (31), and the insertion devices (9, 10) can be effectively connected at least in a form-locking manner to the bearing ring element (31) and the transverse leaf spring (1) by means of clamping elements (35, 36).

Description

Laαervorrichtunα for a transverse leaf spring in the area

a Fahrzeuαachse a vehicle is mounted

The invention relates to a bearing device for a transverse leaf spring, which is mountable in the region of a vehicle axle of a vehicle, according to the closer defined in the preamble of claim 1. Art.

A wheel suspension for a motor vehicle with a transverse leaf spring arranged transversely to the motor vehicle is known from EP 1 645 445 B1. The transverse leaf spring has a central region and two mutually opposite end regions, wherein the transverse leaf spring is connected in the middle region via two central bearings with a vehicle body and in the end regions via end bearings with wheel carriers in operative connection.

The central warehouse are each formed with two outer bearing shells which can be connected to one another and with insertion devices gripped by the outer bearing shells. The insertion devices each comprise two layer elements with different rigidity, wherein the insertion devices are arranged in the assembled state respectively between the bearing outer shells and the transverse leaf spring.

The in the assembled state of the transverse leaf spring facing and executed with higher rigidity layer elements of the insertion devices are bolted together in the vehicle longitudinal direction respectively before and after the transverse leaf spring, whereby the insertion devices are independent of the bearing outer shells on the transverse leaf spring preassembled. Furthermore, pretensioning forces in the area of the insertion devices can be precisely adjusted via the screw connections. The bearing outer shells are firmly connected to each other via a separate screw connection and abut each other in the region of a parting plane. Disadvantageously, the above-described leaf spring suspension is characterized in particular in the central warehouse both by a high space requirement and by an undesirably high production costs, since the screwed together layer elements of the insertion means for receiving the Verschraubungsbereiche and for transmitting the biasing forces massively and are provided with a threaded recess. In addition, the central warehouse on a high number of parts, whereby the space requirement and also the production costs are further increased.

A transverse leaf spring produced from a fiber-plastic composite material and a bearing device of a transverse leaf spring mountable in the region of a vehicle axle of a motor vehicle is known from US Pat

WO 2008/125076 A1. On the one hand to be able to exclude axial movements of the transverse leaf spring in the installed state on a vehicle and on the other hand to provide an undamaged structure of the transverse leaf spring available, the transverse leaf spring is formed in the region of a central mounting portion perpendicular to its longitudinal axis with at least one constriction, in which a force introduction element of Bearing device is positively and non-positively used. The constriction is formed in the region of a surface of the transverse leaf spring whose surface normal in the assembled state of the transverse leaf spring in a vehicle is oriented substantially horizontally.

A disadvantage, however, is that the bearing device consists of rigid bearing elements that prevent movement of the transverse leaf spring in the clamped storage area and thus affect an overall behavior of the spring system and the overall spring effect to an undesirable extent.

The present invention is therefore based on the object to provide a storage device of a mountable in the region of a vehicle axle of a vehicle transverse leaf spring available, which is simple and inexpensive to produce, is characterized by a low space requirement and in the area of which movement of a transverse leaf spring is ensured in a circumference necessary for an operation of the transverse leaf spring.

According to the invention this object is achieved with a storage device having the features of claim 1.

The bearing device according to the invention for a transverse leaf spring, which can be mounted in the region of a vehicle axle of a vehicle, is designed with a bearing outer shell device and with insertion devices gripped at least in certain areas by the bearing outer shell device. The insertion devices each have at least two layer elements with different rigidity, wherein the insertion devices are arranged in the assembled state respectively between the bearing outer shell means and the transverse leaf spring.

According to the invention the bearing outer shell means comprises a one-piece bearing ring element and the insertion means are at least frictionally engageable by clamping elements with the bearing ring member and the transverse leaf spring in operative connection.

The storage device according to the invention is designed to be space-saving compared to known from the prior art storage devices, since this is only in the region of the bearing ring element with a vehicle body or a vehicle body connected to the subframe to assemble. The fixed connection between the bearing device and the transverse leaf spring is produced by means of the clamping elements interacting with the insertion devices in the assembled state, by means of which the pretensioning force to be applied to the insertion devices is made available.

Since no additional screw devices are provided in the region of the insertion devices, the layer elements are compared to off known in the art solutions with small dimensions executable and cheaper to produce, for example, no threads are cut into the layer elements.

In addition, by the executed with different stiffness layer elements of the insertion means required for the operation of the transverse leaf spring rotational movement of the transverse leaf spring in the bearing device at the same time sufficiently high bearing stiffness, which at gleichseitigem and mutual compression in the range of wheels of the two sides of the vehicle different spring rates available are.

Furthermore, via the transverse leaf spring also Radführungsfunktionen be adjusted by the different stiffnesses of the layer elements available, as a bearing stiffness in the vehicle transverse direction, for example, is correspondingly high adjustable and a displacement of the transverse leaf spring in the vehicle transverse direction in a simple manner is avoidable.

In addition, a bearing stiffness of the bearing device according to the invention in the vehicle vertical direction with the sufficient for a sufficient frictional connection between the bearing device and the transverse leaf spring is sufficiently adjustable. This offers in a simple way the possibility to avoid an undesired and a rigid body corresponding displacement or movement of the transverse leaf spring in the region of the bearing device with mutual deflection. With a correspondingly high bearing stiffness of the bearing device according to the invention in the vehicle vertical direction, a targeted deformation of the transverse leaf spring in the form of a so-called S-shock, due to which results in a higher mutual spring rate compared to a simultaneous compression without corresponding S-stroke in the transverse leaf spring. By means of the bearing outer shell device embodied with a closed and one-piece bearing ring element, the prestressing force is easily adjustable in the region of the bearing devices, which decreases to a lesser extent due to setting operations and the like, unlike a screwing applied biasing force, which is provided for connecting two separate bearing outer shells , In addition, a good power flow is ensured by the closed bearing ring element. In contrast to the two-part Lageraußenschalenausführungen a relative displacement between the two bearing outer shells is prevented by the closed ring shape of the bearing ring element in a simple manner.

In an advantageous development of the storage device according to the invention, the clamping elements are formed with at least one wedge-shaped region which can be arranged in each case between the insertion devices and the transverse leaf spring and / or between the insertion devices and the bearing ring element. Thus, the required for the operation of the bearing device biasing force is independent of manufacturing tolerances in the field of storage device and in the transverse leaf spring in a simple manner during assembly adjustable because any existing manufacturing tolerances by varying the Einschiebweges the clamping elements between the insertion devices and the transverse leaf spring and / or between the insertion devices and the bearing ring element are compensated.

In an easy to install and characterized by a simple structural design embodiment of the bearing device according to the invention at least a portion of the clamping elements for generating a tensioning element side biasing force on the insertion means and the transverse leaf spring with the bearing ring element can be brought into operative connection and the biasing force on a shoulder of the bearing ring element supportable.

Another easy-to-install embodiment of the bearing device according to the invention is in the region of the bearing ring element with connector trained training areas over which the bearing ring element vehicle mounting on site is determined.

An assembly of the storage device according to the invention is further simplified in a further embodiment of the storage device according to the invention that the bearing ring element in the assembled state in a vehicle body facing contact area is formed with a vehicle body-side centering corresponding centering. During assembly, the bearing ring element or the bearing device can be aligned and positioned via the centering area relative to the vehicle body or the auxiliary frame fixed therewith without further aids, thus ensuring that the bearing device is required or required for the correct functioning of the transverse leaf spring. arranged position is arranged.

The clamping elements are held in a space-saving and structurally simple development of the bearing device according to the invention via a connectable to the bearing ring member plate in a biasing force generating position.

An alternative and cost-effective embodiment of the bearing device according to the invention comprises a locking ring which can be connected to the bearing ring element and by means of which the tensioning elements can each be retained in a position producing the preload force.

In order to prevent an undesired automatic release of the clamping elements after assembly of the bearing device according to the invention in a structurally simple manner and / or to reduce relative movements between the clamping elements and the adjacent components to a minimum, a friction coefficient in defined surface areas of the clamping elements in another advantageous embodiment of the inventive Storage device higher than in other surface areas of the clamping elements.

In order to ensure the most uniform possible initiation of the biasing force generated by the clamping elements in the insertion devices, the clamping elements in a further advantageous embodiment of the storage device according to the invention between the formed with the higher stiffness layer elements of the insertion devices of the transverse leaf spring and / or between the bearing ring element and with the arranged higher rigidity formed layer elements of the insertion devices.

In order to transmit the forces and moments acting on the operation of a vehicle from the lower stiffness bearing elements with the lowest possible surface pressure in the area between the insertion devices and the transverse leaf spring, between the layer elements of the insertion means and the transverse leaf spring is preferably at least one semi-cylindrical preferably running insert arranged the insertion means which are formed with a higher stiffness than the lower stiffness running layer elements.

The term at least approximately semi-cylindrical running inserts are presently subsumed all volumetric structures, which are formed at least with at least approximately circular segment-like base surfaces which are spaced from each other. There is the possibility that the arch connecting the chordal ends of the base is circular or elliptical. In further developments, the tendon is straight or curved, preferably convex. In the region of the transitions between the chord and the arc of the base can be provided depending on the particular application, edges or corresponding rounding. In order that damage to the transverse leaf spring in the region of the bearing device can be avoided during the operation of a vehicle, the inserts of the insertion devices can be formed with a rubber-elastic protective layer in contact areas facing at least in the assembled state of the transverse leaf spring. In a further advantageous embodiment of the bearing device according to the invention, the layer elements formed with a higher rigidity are alternatively provided with a rubber-elastic protective layer at least in some regions, at least in the end regions.

In a marked by a good application of force embodiment of the storage device according to the invention, the clamping elements between the transverse leaf spring and the inserts can be arranged.

In order to be able to initiate forces and moments acting on the insertion device without relative movement between the insertion devices and the transverse leaf spring in the transverse leaf spring, at least one of the insertion devices in a bearing surface facing contact surface is executed in a further advantageous embodiment of the storage device according to the invention with at least one receiving device in which engages a region of the transverse leaf spring in the assembled state of the insertion devices. Thus, the bearing device according to the invention in addition to the force produced by the screw means frictional connection is also positively connected to the transverse leaf spring, wherein the positive connection between the bearing device and the transverse leaf spring is preferably designed such that due to the positive connection in the transverse leaf spring smallest possible additional stresses arise that the operation of the Can interfere with transverse leaf spring to undesirable extent and reduce the life of the transverse leaf spring.

Additionally or alternatively, a positive connection between the bearing device and the transverse leaf spring in further advantageous embodiments of Inventive bearing device produced by the transverse leaf spring in the region of one of the bearing surface for one of the insertion device is formed with a recess into which the insertion device engages positively.

The engaging in the insertion region of the transverse leaf spring is preferably provided in the region of the recess of the transverse leaf spring, whereby a course of fibers of a transverse leaf spring preferably made of composite deviates only slightly from a required for the operation of the transverse leaf spring course in the region of the bearing device.

In a further advantageous embodiment of the storage device according to the invention formed with lower rigidity layer elements overlap the transverse leaf spring with stop areas in the assembled state in the vehicle longitudinal direction and vehicle vertical direction respectively at least partially, to position the multi-part insertion means during assembly relative to the transverse leaf spring in a simple manner and on the other to be able to provide a soft support of the transverse leaf spring in the vehicle longitudinal direction in the area of the bearing outer shells in a structurally simple manner.

The abutment regions can be embodied in abutment regions facing the transverse leaf spring and / or in the abutment regions facing the bearing outer shells with projections and / or recesses oriented at least approximately in the vehicle longitudinal direction in order to achieve different bearing stiffnesses over the displacement of the transverse leaf spring in the region of the bearing device according to the invention the acting in the vehicle longitudinal direction as a bearing stops abutment areas with respect to a vehicle front side in front of and behind the transverse leaf spring can be designed differently to represent correspondingly different bearing characteristics can. Further advantages and advantageous embodiments of the subject invention emerge from the claims and the embodiments described below with reference to the drawing, wherein in the description of the various embodiments in favor of clarity for construction and functionally identical components, the same reference numerals are used.

Both the features specified in the subclaims and the features specified in the following exemplary embodiments of the bearing device according to the invention are suitable in each case alone or in any desired combination with each other to further develop the object according to the invention. The respective feature combinations represent no limitation with respect to the development of the subject matter according to the invention, but essentially have only an exemplary character.

It shows:

Figure 1 is a highly schematic representation of a transverse leaf spring with two outer guide bearings and two arranged in the central region of the transverse leaf spring storage devices according to the invention.

2 shows a three-dimensional partial representation of the transverse leaf spring with a first embodiment of the bearing device according to the invention, which is arranged in a middle region of the transverse leaf spring;

FIG. 3 shows the bearing device according to FIG. 2 in a longitudinal sectional view along a longitudinal sectional plane E3 which is shown in greater detail in FIG. 2 and extends in the vehicle vertical and vehicle transverse directions; FIG. 4 shows a representation corresponding to FIG. 2 of a second embodiment of the bearing device according to the invention;

FIG. 5 shows a representation corresponding to FIG. 3 of the bearing device according to FIG. 4 in a longitudinal sectional view along a longitudinal sectional plane E5 shown in more detail in FIG. 4, which is oriented both in the vehicle vertical direction and in the vehicle transverse direction;

6 shows a representation corresponding to FIG. 2 of a third embodiment of the bearing device according to the invention;

FIG. 7 shows a longitudinal sectional view corresponding to FIG. 3 of the bearing device according to FIG. 6 along a longitudinal sectional plane E7, which is shown in greater detail in FIG. 6 and extends both in the vehicle vertical direction and in the vehicle transverse direction;

8 shows a representation corresponding to FIG. 2 of a further exemplary embodiment of the bearing device according to the invention;

9 is a longitudinal sectional view, corresponding to FIG. 3, of the bearing device according to FIG. 8 along a sectional plane E9 extending in the vertical direction of the vehicle and the vehicle transverse direction;

FIG. 10 shows a representation corresponding to FIG. 2 of a fifth exemplary embodiment of the bearing device according to the invention;

1 is a representation corresponding to FIG. 3 of the bearing device according to FIG. 10 along a sectional plane E1 1 extending in the vehicle's vertical and vehicle transverse directions; 12a is a schematic enlarged partial detail view of a defined surface area of a clamping element of the storage device according to the invention;

FIG. 12b is a simplified side view of the surface area shown in FIG. 12a; FIG.

FIGS. 13 to 21 each show a partial view of different embodiments of the transverse leaf spring in a mounting region of the bearing device according to the invention.

In Fig. 1 a highly schematic representation of a transverse leaf spring 1 is shown, which is mountable in the region of a vehicle axle of a vehicle. The transverse leaf spring 1 is in their wheels of the vehicle axle facing end portions 1 A, 1 B in outer bearings 2, 3 or guide bearings, which are in the present case designed as a so-called bearing shoes, mounted and connected to wheel carriers of the vehicle axle.

In central areas of the transverse leaf spring 1, this is operatively connected via bearing devices 4, 5 acting as a central bearing directly to a vehicle body or to a subframe, which in turn is connected to the vehicle body, and is mounted thereon. The storage devices 4 and 5 are arranged symmetrically to the center of the transverse leaf spring 1 and connect them in the manner described below with the vehicle body of the vehicle, with rotations of the transverse leaf spring 1 in the area of the storage devices 4 and 5 with equal and mutual suspensions to the extent required are possible so that on the transverse leaf spring 1 at an equilateral and mutual compression in the areas 1 A and 1 B different spring rates are available. The storage devices 4 and 5 have a high bearing stiffness in the vehicle transverse direction or in the y-direction and deform only slightly in the y-direction during operation of a running with the transverse leaf spring 1 and the storage facilities 4 and 5 vehicle, in addition to the above-described suspension functionality To be able to take over wheel management tasks. The high bearing stiffness in the y-direction also offers the possibility to avoid a total displacement of the transverse leaf spring 1 in the vehicle transverse direction or in the y-direction in a simple manner.

Thus, the respectively required between the storage devices 4 and 5 and the transverse leaf spring 1 for the proper functionality of the transverse leaf spring 1 frictional connection can be produced, the two storage devices 4 and 5 are also executed in the vehicle vertical direction or in the z-direction with a correspondingly high bearing stiffness. In addition, it is achieved by the high bearing stiffness of the storage devices 4 and 5 in the vehicle vertical direction that the transverse leaf spring 1 with mutual deflection of the end portions 1 A and 1 B does not have the displacement of a rigid body in the storage devices 4 and 5. The transverse leaf spring 1 is selectively deformed according to a so-called S-stroke in a mutual deflection and provides a correspondingly higher mutual spring rate available.

Fig. 2 shows a three-dimensional partial representation of the transverse leaf spring 1, which is designed as a bar-like spring element. The transverse leaf spring 1 is connected to the wheels of a vehicle axle of the vehicle via the two bearing devices 4, 5 with a vehicle body not illustrated in detail in the drawing and via the two end bearing devices 2, 3 and mounted in the end regions 1 A, 1 B. The so-called four-point bearing allows in the region of the transverse leaf spring 1 to provide both a lifting suspension and a roll suspension available, which conventional suspension springs and known from practice stabilizer devices are not provided. With appropriate design of the storage devices 4 and 5 and the Endbereichslagerungen 2 and 3 are on the transverse leaf spring 1 ne- ben the latter suspension functions also Radführungsfunktionen available. The presented spring system offers a high cost-saving potential with appropriate choice of material for the production of the transverse leaf spring 1, for example fiber composite materials, also the possibility of weight reduction in the range of a vehicle axle.

A longitudinal sectional view of the bearing device 4 along a sectional plane E3 shown graphically in more detail in FIG. 2 is shown in FIG. 3, the sectional plane E3 extending in the vehicle vertical direction z and in the vehicle transverse direction y and corresponding to a so-called yz cutting plane.

The storage devices 4 and 5 basically have the same structure, which is why in the following description, essentially only the bearing device 4 is discussed in more detail.

The bearing device 4 has a bearing outer shell device 30 with a one-piece bearing ring element 31, which is formed as a closed metal part. This high forces and moments between the transverse leaf spring 1 and the vehicle body or a subframe are transferable with low space requirement. The bearing ring element 31 is connectable to the vehicle body side in the region of screws 33A, 33B via two connecting devices 32A, 32B arranged on the upper side of the bearing ring element 31 with respect to the vehicle vertical axis z and presently designed as straps, and can be fixedly connected to the vehicle body or a subframe coupled thereto , Alternatively, however, it is also possible to set the bearing device 4 on the vehicle body side via other suitable fastening measures.

Between the tabs 33 A, 33 B, the bearing ring element is designed with a centering region 34 which cooperates in the assembled state of the bearing device 4 with a vehicle body-side centering region and the Alignment of the bearing device 4 relative to the vehicle body in vehicle longitudinal and transverse vehicle direction x and y is used. In the present case, the centering region 34 is designed as an elevation on the outside of the bearing ring element 31, which extends in the vehicle transverse direction x and has a rounded contour and lifts off in the vehicle vertical direction z, which engages in a corresponding vehicle body-side recess.

The transverse leaf spring 1 is completely surrounded by the bearing ring element 31, wherein in each case between one with respect to the vehicle vertical direction z positioned upper side of the transverse leaf spring 1 and the underside of the transverse leaf spring 1 each insertion means 9, 10 and an upper wedge-shaped clamping element 35 and a lower clamping element 36 are arranged , The clamping elements 35 and 36 are respectively inserted between the bearing ring member 31 and the insertion means 9 and 10, respectively, to provide a vertical bias of the arranged between the bearing ring member 31 and the transverse leaf spring 1 insertion means 9 and 10, and depending on the particular application made of metal, fiber composite or pure plastic materials.

The upper clamping element 35 is screwed to the bearing ring element 31 in the region of bores 37A, 37B, while the lower clamping element 36 is screwed to the bearing ring element 31 in the region of bores 38A, 38B. Alternatively, however, it is also possible to connect the clamping elements 35, 36 in each case only via a screw connection with the bearing ring element 31 or to provide other suitable types of connection.

The biasing force generated by the clamping elements 35 and 36 as a function of the insertion path of the clamping elements 35 and 36 in the bearing ring element 31 is supported in the region of a shoulder 40 of the bearing ring element 31. In the present exemplary embodiment, the clamping elements 35 and 36 are each designed as separate components. In further advantageous embodiments, to simplify a mounting, it is possible to connect the clamping elements with laterally the transverse leaf spring 1 encompassing thin webs, whereby the clamping elements are designed as easily pushed onto the transverse leaf spring or mountable hollow ring body. The clamping elements are then designed to be elastically deformable in the region of the webs in order to be able to compensate for strains and compressions in the area of the webs caused by component tolerances and the like during application of the bearing pre-tensioning force.

In the present case, the insertion devices 9 and 10 comprise two layer elements 9A, 9B or 10A, 10B and are additionally formed in each case with a substantially semi-cylindrical insert part 9D or 10D. The layer elements 9A and 10A of the insertion devices 9 and 10 are in this case made of rubber-elastic material which is applied during vulcanization respectively on the sheet metal elements produced 9B and 10B and the present also made of metal inserts 9D and 10D or respectively the layer elements 9B and 10B and the inserts 9D and 10D at least partially surrounds.

The inserts 9D and 10D are also made of plastic, fiber composites, natural materials such as wood, stone and the like, as well as various metal materials.

The sheet members 9B and 10B and the inserts 9D and 10D are respectively made higher in rigidity than the sheet members 9A and 10A, respectively. Due to the stiffer configuration of the inserts 9D and 10D, the life of the bearing device 4 is increased and the bearing stiffness of the bearing device 4 in the vehicle longitudinal direction x, in the vehicle transverse direction y and in the vehicle vertical direction z are higher than for storage devices without inserts representable. As an alternative to the above-described embodiment, however, it is also possible to carry out the insertion devices 9 and 10 without the layer elements 9B and 10B which are designed with higher rigidity.

Are the inserts 9D and 10D formed in the transverse leaf spring 1 facing contact surfaces with a rubber-elastic protective layer, a surface 11 of the transverse leaf spring 1 is sufficiently protected against damage, in particular under oscillating load, which can affect the life of the transverse leaf spring to an undesirable extent.

In addition, the penetration of fine dirt particles between the inserts 9D and 10D and the transverse leaf spring 1 on the protective layer can be prevented. It is also conceivable that the inserts 9D and 10D are glued to avoid the entry of dirt particles with the surface 1 1 of the transverse leaf spring 1, which may be provided both in the embodiment with and without protective layer.

Furthermore, manufacturing tolerances in the region of the positive connection between the bearing device 4 and the transverse leaf spring 1 can be compensated by means of a protective layer, preferably embodied as vulcanization layer of the inserts 9D and 10D, and a coefficient of friction between the inserts 9D and 10D and transverse leaf spring 1 by a suitable material selection and a corresponding surface finish Protective layer can be increased.

Depending on the respective application, so-called thrust plates can be inserted into the layer elements 9A and 10A in order to be able to provide the rotational stiffness around the bearing axis, which corresponds to the vehicle longitudinal axis x, in a suitable ratio to the vertical rigidity. Due to the additional thrust plates relatively small torsional stiffnesses are adjustable even with high vertical stiffness. The insertion devices 9 and 10 are in the bearing surfaces 1 1A and 1 1 B of the transverse leaf spring 1 facing contact surfaces 9E and 1 OE each with at least one receiving device 9F or 1 OF executed in each of which a region 1 C and 1 D of the transverse leaf spring. 1 in the assembled state of the insertion devices 9 and 10 positively engages. In addition, the transverse leaf spring 1 in vehicle vertical direction z in the region of the bearing surfaces 1 1 A and 1 1 B respectively for the insertion devices 9 and 10 recesses 1 1 C, 1 1 D, in which the insertion devices 9 and 10 via the correspondingly shaped inserts 9D and 1 OD interlocking to engage in the operation of a vehicle, a relative movement of the transverse leaf spring 1 in the vehicle transverse direction y relative to the vehicle body in addition to the frictional connection with the bearing device 1 via an additional positive connection between the transverse leaf spring 1 and the bearing device 4 in a structurally simple manner avoid.

The recesses 1 1 C and 1 1 D or the contours of the recesses 1 1 C and 1 1 D are designed such that in the contact region of the bearing device 4 on the transverse leaf spring 1 in operation as uniform as possible stress distribution, which is a life of the transverse leaf spring. 1 favorably influenced. The contour of the recesses 1 1 C and 1 1 D corresponds in each case substantially to a special cosinusoidal depression in the y-direction, whereby a uniform distribution of stress in the storage area of the transverse leaf spring 1 is achieved.

The transverse leaf spring 1 is executed in the region of its surface 1 1 at least in the contact area with the bearing devices 4 and 5 with a special surface coating or surface treatment in order to increase the hardness of the surface 1 1 of the transverse leaf spring 1 with respect to the remaining surface 11 and Region of the positive connection between the transverse leaf spring 1 and the storage devices 4 and 5 to provide a larger coefficient of friction to increase the connection forces compared to the untreated state. In addition, there is a special surface coating or Surface treatment of the surface 1 1 of the transverse leaf spring 1, the possibility that a manufacturing process for the production of the areas 1 C and 1 D of the transverse leaf spring 1, for example, the demolding operation of the transverse leaf spring 1 from the tool, facilitated or simplified.

As surface coating, for example, an adhesive layer, a lacquer layer, a plastic material as well as a plastic layer made with nanoparticles are conceivable. During a surface treatment, the surface 11 of the transverse leaf spring 1 is pretreated, for example, with a liquid which increases the adhesion property of the surface, and subsequently the hardness or coefficient of friction-increasing particles are applied to the surface of the transverse leaf spring in the area mentioned, for example by vapor deposition.

The pivot point of the two insertion devices 9 and 10 is in the assembled state of the storage devices 4 and 5 substantially on the neutral fiber 14 of the transverse leaf spring 1, whereby deformations in the region of the insertion devices 9 and 10 are advantageously substantially equal. The preferably transverse in the vehicle transverse direction cosinusoidal recesses 1 1 C and 11 D of the transverse leaf spring 1 are provided for the positive connection of the bearing device 4 with the transverse leaf spring 1, wherein the cosinusoidal configuration or the cosinusoidal transition between the surface 1 1 of the transverse leaf spring 1 outside of the recesses C and 1 1 D and the bearing surfaces 1 1 A and 1 1 B in the region of the recesses 11 C and 1 1 D ensures the smoothest possible transition in the course of the individual fibers of the transverse leaf spring 1 produced in this case from composite material. The smooth transition in the fiber flow of the transverse leaf spring 1 prevents in a simple manner an impairment of the life of the transverse leaf spring. 1

FIGS. 4 to 12 b show further advantageous exemplary embodiments of the bearing device 4 according to the invention, which essentially only partially extend from the first embodiment illustrated in FIGS. 2 and 3. In the following description relating to FIGS. 4 to 12 b, essentially only the differences are discussed and reference is made to the description of FIGS. 2 and 3 with regard to the further mode of operation of the bearing device 4. The clamping elements of the embodiments of the bearing device 4 shown below are each in one or more parts executable depending on the particular application in the manner described above.

In the embodiment shown in Fig. 4, the required to illustrate the desired bearing functionality of the bearing device 4 biasing force on hollow cylindrical and segmentally designed clamping elements 35 A, 35 B and 36 A, 36 B is provided, wherein the biasing force of the bearing device 4 via a with the bearing ring member 31 preferably firmly connectable plate 39 is produced via a screw connection.

In the assembled state of the cover plate 39, the clamping elements 35 B and 36 B are increasingly inserted between the bearing ring member 31 and the insertion devices 9 and 10. The biasing force generated by the clamping elements 35B and 36B is introduced via the insertion devices 9 and 10 in the clamping elements 35A and 36A and supported in the region of the shoulder 40 and the transverse leaf spring 1.

As an alternative to the above-described screw connection, the cover plate 39 can also be connected to the bearing ring element to the desired extent depending on the respective application case via other suitable types of connection, such as riveting, flanging or the like.

In the illustrated in Fig. 4 and Fig. 5 second embodiment of the bearing device 4 is in the area between the inserts 9D and 10D and the transverse leaf spring 1 no additional positive connection as in the stock proviso direction 4 of FIG. 2 and FIG. 3 is provided. This also applies to the further exemplary embodiments of the bearing device 4 illustrated in FIGS. 6 to 12b. It is, of course, at the discretion of the person skilled in the art, the further exemplary embodiments of the bearing device 4 illustrated in the drawing also with a form-locking connection in the region between the insertion devices 9 and 10 and the transverse leaf spring 1 execute.

In the third exemplary embodiment of the bearing device 4 illustrated in FIGS. 6 and 7, the clamping elements 35A, 35B and 36A, 36B are held in their pretensioning force by means of a retaining ring 42 arranged in a groove 41 of the bearing ring element 31. In contrast to the second embodiment of the bearing device 4, the clamping elements 35A, 35B and 36A, 36B overlap in the vehicle transverse direction y and in the vehicle vertical direction in order to ensure a particularly good power transmission between the vehicle body and the transverse leaf spring 1 can.

In Fig. 8 and Fig. 9, a fourth embodiment of the bearing device 4 is shown, in which the clamping elements 35 and 36 are respectively positioned between further sheet elements 9C and 10C and the surface 1 1 of the transverse leaf spring 1, the metal, fiber composite or pure Plastic materials can be produced and represent separate components in the present case, wherein the further layer elements 9C and 10C are also integrally executable. The further layer elements 9C and 10C are designed with higher rigidity than the rubber-elastic layer elements 9A and 10A and are arranged between the rubber-elastic layer elements 9A and 10A and the tension elements 35, 36. The wedge-shaped clamping elements 35 and 36 of the bearing device 4 according to FIG. 8 and FIG. 9 extend over the entire bearing width between the further layer elements 9C and 10C and the transverse leaf spring 1.

The additional layer elements 9C and 10C provide in a simple way the possibility of the biasing force of the clamping elements 35 and 36 as evenly as possible in the rubber-elastic layer elements 9A and 1 OA in particular during tilting movements of the transverse leaf spring 1 in the region of the storage device 4 to initiate. Furthermore, the further layer elements 9C and 10C can in turn be connected to the layer elements 9A and 10A by vulcanization depending on the application and offer in a simple manner the possibility that the rubber-elastic layer elements 9A and 1OA are not separated from the bearings during assembly of the bearing device 4 Clamping elements 35 and 36 are damaged.

The clamping elements 35 and 36 are in turn held on the retaining ring 42 in its biasing position. In order to avoid an undesired automatic loosening of the clamping elements 35 and 36 after assembly of the bearing device 4, the clamping elements in the surface 1 1 of the transverse leaf spring 1 associated surface areas 35C, 36C performed with a friction coefficient increasing surface coating. Alternatively, it is also possible, the surface 1 1 of the transverse leaf spring 1 in the contact area with the clamping elements 35 and 36 with a friction coefficient-increasing coating or a particular surface profile shown for example in Fig. 12a and Fig. 12b, which the loosening of the clamping elements 35 and 36 prevents execution.

A fifth embodiment of the bearing device 4 is shown in FIG. 10 and FIG. 11, in which the bearing device 4 has a similar construction to the bearing device 4 according to FIG. 8 and FIG. 9, however, in a symmetrical design. The biasing force is respectively generated again via wedge-shaped clamping elements 35A, 35B and 36A, 36B, which are arranged between the surface of the transverse leaf spring 1 and the further layer elements 9C and 10C and the rubber-elastic layer elements 9A and 10A.

The further layer elements 9C and 10C are equipped with substantially planar center regions and angle end regions 9C1, 9C2, 10C1, 10C2 adapted in each case to the slopes of the clamping elements 35A, 35B and 36A, 36B. leads, wherein the ply elements 9A and 1 OA are respectively adapted in their contact area on the further layer elements 9C and 1 OC to the shape of the layer elements 9C and 1 OC. On its side facing away from the transverse leaf spring 1, the rubber-elastic layer elements 9 A and 1 OA are applied directly to the bearing ring element 31.

Fig. 12a and Fig. 12b show a preferred embodiment of the O- berfläche 11 of the transverse leaf spring 1 according to FIG. 8 and FIG. 10 in the contact region of the clamping elements 35 and 36 or 35 A, 35 B and 36 A, 36 B, by means of a slipping back the clamping elements after assembly from its biasing position is prevented in a structurally simple manner. In Fig. 12a, the mounting direction of the clamping elements is shown graphically by the arrow. Since the sawtooth-like fish scale profile allows the clamping elements to be guided over the surface 11 of the transverse leaf spring in the mounting direction, assembly of the bearing device 4 is not hindered by the surface profile of the transverse leaf spring 1. After assembly, a slipping back of the clamping elements by means of tips 43 is effectively prevented.

FIGS. 13 to 21 show various embodiments of the regions of the transverse leaf spring 1 producing the positive connection between the transverse leaf spring 1 and the bearing device 4. The embodiments illustrated in FIGS. 13 to 21 each differ only in partial regions, for which reason in the following description in each case only the differences between the individual embodiments will be discussed and with respect to the further functionality of the recesses reference is made to the description of FIG. 13.

FIGS. 13 to 21 show various embodiments of the regions of the transverse leaf spring 1 producing the positive connection between the transverse leaf spring 1 and the bearing device 4. The embodiments shown in FIGS. 13 to 21 each differ only in partial regions, for which reason in the following description only on the differences will be discussed between the individual embodiments and reference is made to the description of FIG. 13 with respect to the further functionality of the recesses.

In the embodiment shown in FIG. 13, the transverse leaf spring 1 is compressed more intensively in the vehicle vertical direction or in the z direction and is formed with the same width as in the remaining cross-sectional area of the transverse leaf spring 1. As a result, in the compressed region or in the region of the recesses 1 1 C and 1 1 D of the transverse leaf spring 1 is an increased fiber content. Due to the recesses 1 1 C and 1 1 D acting in the region of the bearing device 4 increased lateral forces safely from the transverse leaf spring 1 in the storage device 4 can be introduced. The transition between the recesses 1 1 C and 1 1 D and the adjoining surface 1 1 of the transverse leaf spring 1 is designed in this case over a cosine contour with tangential inlets and outflows voltage-optimized so that in the region of the recesses 1 1 C and 1 1 D. only slight voltage overshoots occur during operation.

The areas 1 C and 1 D of the transverse leaf spring 1 essentially take over only the task of centering the bearing device 4 in the longitudinal and transverse directions on the transverse leaf spring 1, while the areas 1 C and 1 D at the force transmission between the bearing device 4 and the transverse leaf spring 1 only in small extent or not at all. The shapes of the regions 1 C and 1 D are each performed with smooth transitions to the recesses 1 1 C and 1 1 D, wherein in the areas 1 C and 1 D substantially resin during the production of the transverse leaf spring occurs. Due to this procedure, an abrupt fiber deflection in the cross section of the transverse leaf spring 1 is avoided.

In the embodiment of the transverse leaf spring 1 shown in FIG. 14, the regions 1 C and 1 D are designed with less gentle transitions to the recesses 1 1 C and 1 1 D and essentially have an at least approximately semi-cylindrical outer shape. The semi-cylindrical outer shape offers in comparison to the shape shown in Fig. 13 of the areas 1 C and 1 D a simplified manufacturability of the tool, which is used to produce the transverse leaf spring 1. The regions 1 C and 1 D of the embodiment of the transverse leaf spring 1 illustrated in FIG. 14 in turn essentially only take over the centering of the bearing device 4 in the longitudinal and transverse directions on the transverse leaf spring 1 and are only at the power transmission between the bearing device 4 and the transverse leaf spring 1 slightly or not at all involved. The shapes of the regions 1 C and 1 D are in turn such that the fibers of the transverse leaf spring 1 have no significant deflection and that a strength of the transverse leaf spring 1 of the strength of transverse leaf springs, which are executed without the areas 1 C and 1 D.

In the embodiment of the regions 1 C and 1 D shown in FIG. 15, these are configured with two noses arranged in the region of the outsides of the transverse leaf spring and approximately at least approximately frustoconical, via which the centering of the bearing device 4 is realized on the transverse leaf spring 1. The regions 1 C and 1 D are in turn substantially resin accumulations in order to avoid abrupt deflections of the fibers in the region of the recesses or the regions 1 C and 1 D.

The regions 1 C and 1 D are formed in the further embodiment of the transverse leaf spring 1 according to FIG. 16 as disposed in the region of the outer sides of the transverse leaf spring 1 lugs 1 C1 to 1 C4, wherein the transitions between the recesses 1 1 C, 1 1 D and the noses 1 C1 to 1 C4 is again designed to optimize the voltage. In the embodiment of the transverse leaf spring 1 according to FIG. 17, the regions 1 C and 1 D are shown with lugs 1 C1 and 1 C2 arranged in the middle region of the transverse leaf spring 1.

The illustrated in Fig. 18 further embodiment of the transverse leaf spring 1 is in the region of the recesses 1 1 C and 1 1 D of the transverse leaf spring 1 in the compressed state of the transverse leaf spring 1 in the vehicle transverse direction erstre- creasing and alternately arranged ribs 100A to 100E and grooves 200A to 200D, which is based on the function of the regions 1C and 1D. The number of ribs 100A to 100E is selected depending on the width of the transverse leaf spring 1 and the depth of the grooves 200A to 200D, and the side ribs 100A and 100E may be omitted as needed. In the region of the grooves 200A to 200D, the fiber portion of the transverse leaf spring is compressed or partially relocated on the ribs 100A to 100E, wherein the transitions between the ribs 100A to 100E and the grooves 200A to 200D and between the remaining surface 1 1 of the transverse leaf spring 1 voltage optimized are designed to produce only small voltage peaks in the transitions. The depth of the grooves 200A and 200D varies in the vehicle transverse direction as well as in the vehicle longitudinal direction and has in a central region substantially each at its maximum and in the vehicle transverse direction opposite edge regions in each case its minimum.

The illustrated in Fig. 19 embodiment of the transverse leaf spring 1 is formed with recesses 1 1 C and 1 1 D, each having a rotated cosine contour and are respectively embossed in the surface 1 1 of the transverse leaf spring 1. The recesses 1 1 C and 1 1 D are in the assembled state of the transverse leaf spring 1 in the vehicle longitudinal direction x each of between an upper side

1 1 1 and a bottom 1 12 and side surfaces 1 13, 1 14 of the transverse leaf spring 1 formed edge regions 1 15 and 1 16 of the top 1 1 1 and the bottom

1 12 limited, in the region of which the thickness of the transverse leaf spring 1 preferably substantially corresponds to the thickness outside the recesses 1 1 C and 1 1 D. By this contour in turn arises only a slight increase in voltage in the transition between the bearing point of the transverse leaf spring 1 and the rest of the bearing surface surrounding the surface 1 1 of the transverse leaf spring 1. The width of the transverse leaf spring 1 remains substantially the same, whereby in the region of the recesses 1 1 C and the first 1 D in the transverse leaf spring cross section in each case an increased fiber content is present. Through these recesses 1 1 C and 1 1 D, each representing a recess, increased transverse and longitudinal forces of the bearing device 4 can be well introduced into the transverse leaf spring 1. About the recesses 11 C and 1 1 D, the insertion devices 9, 10 are centered during assembly of the storage device 4 both in the vehicle longitudinal direction and vehicle transverse direction on the transverse leaf spring 1.

Depending on the respective application, other suitable rotationally symmetrical shapes, such as a truncated cone, a hemisphere or the like, with each rounded transitions to the remaining surface 1 1 of the transverse leaf spring 1 for the design of the recesses of the transverse leaf spring vorsehbar.

In the embodiment of the transverse leaf spring 1 according to FIG. 20, the recesses 11 C and 1 1 D of the transverse leaf spring 1 with a rounded rectangular shape, which has a pillow-like shape, embossed in the transverse leaf spring. The contour can be produced for example by two orthogonally superimposed cosine contours, which ensures only a slight increase in voltage in the region between the bearing point of the bearing device 4 of a transverse leaf spring 1 and the remaining surface 1 1 of the transverse leaf spring 1. In principle, it is possible to perform the transverse leaf spring in the recesses 1 1 C and 1 1 D with the same width as in the rest of the transverse leaf spring 1, whereby in the region of the recesses 1 1 C and 1 1 D in the transverse leaf spring cross-section an increased fiber content is present , The recesses 1 1 C and 1 1 D are in the assembled state of the transverse leaf spring 1 in the vehicle longitudinal direction x each of between a top 1 1 1 and a bottom 1 12 and side surfaces 1 13, 1 14 of the transverse leaf spring 1 formed edge regions 1 15 and 1 16 of Limited top side 1 1 1 and the bottom 1 12, in the region of which the thickness of the transverse leaf spring 1 preferably substantially corresponds to the thickness outside of the recesses 1 1 C and 1 1 D. The illustrated in Fig. 21 embodiment of the transverse leaf spring 1 has in each case in the region of the recesses 1 1 C and 1 1 D a over the entire width of the transverse leaf spring 1 extending portion 1 C and 1 D, wherein the transverse leaf spring 1 in vehicle vertical direction or compressed in the z-direction during manufacture. This in turn leads to an increased fiber content in the contact area of the bearing device 4. The regions 1 C and 1 D is again essentially based on the functionality of the centering of the bearing device 4 in the longitudinal direction on the transverse leaf spring 1. If the regions 1 C and 1 D, starting from a central region of the transverse leaf spring 1 in the vehicle longitudinal direction respectively in the direction of the outer sides of the transverse leaf spring 1 slightly rising, a centering of the bearing device 4 in the transverse direction on the transverse leaf spring 1 is possible.

Basically, it is also possible, the recesses 1 1 C and 1 1 D of the embodiments shown in Fig. 13 to Fig. 18 and Fig. 21 in the assembled state of the transverse leaf spring 1 in the vehicle longitudinal direction x respectively between an upper side 1 1 1 and a bottom 1 12 and side surfaces 1 13, 1 14 of the transverse leaf spring 1 formed edge regions 1 15 and 1 16 of the top 1 1 1 and the bottom 1 12 to limit, in the area of the thickness of the transverse leaf spring 1 is preferably substantially the thickness outside the recesses C and 1 1 D corresponds.

In general, the above-described inventive subject matter or offer the various embodiments of the subject invention the ability to support in the operation of a vehicle in the region of a transverse leaf spring attacking forces and moments without piercing the transverse leaf spring in the desired extent in the field of vehicle body. In addition, this requirement is ensured even without the introduction of a foreign part in the transverse leaf spring. This means that forces and moments can be transferred from central bearings to a transverse leaf spring again, without the durability of a transverse leaf spring through holes for screwing or riveting or other strong deflections of the fibers is negatively affected.

The storage devices according to the invention are designed with the respectively required high rigidity and the surface of a transverse leaf spring is not injured by the appropriately executed storage devices during operation. In addition, as low as possible stresses occur in the area of the surface of a transverse leaf spring, whereby the transverse leaf spring is not damaged by the bearing device even with changing load. Relative movements in the area between the surface of the transverse leaf spring and the bearing devices or the central warehouse are avoided in a structurally simple and space-saving manner. The inventive bearing design also offers a structurally simple way the possibility that the torsion axis in the vehicle longitudinal direction or in the x-direction intersects with the neutral fiber of the transverse leaf spring and is parallel to an xy plane. An exact positioning of the bearing device on the transverse leaf spring in both the x and y directions is also ensured, whereby a functionality of a transverse leaf spring with high precision is available.

If necessary, the storage device according to the invention also offers the possibility to attach the transverse leaf spring directly to the vehicle body or without isolation of a subframe relative to the vehicle body on the subframe.

The bearing device according to the invention can also be integrated without complex design measures into different wheel suspension configurations, which are formed with a transverse leaf spring and similar fiber composite components.

The upper half and the lower half of the bearing device 4, which are in relation to the vehicle's vertical axis, can be both symmetrical and with a low degree of asymmetry, depending on the respective application be executed, with Lagerunsymmetrien the bearing device 4 are specifically used to vote the bearing stiffness in the different directions.

REFERENCE CHARACTERS

QuerblattfederA, 1 B end

C, 1 D area

C1 to 1 C4 nose

, 3 outer bearing

, 5 storage device

insertion device

A layer element

B layer element

C layer element

C1. 9C2 angle end area

D insert

D1 recess

E contact surface

F recording device

0 insertion device

0A layer element

0B layer element

0C layer element

0C1, 10C2 angle end range

0D insert

0D1 recess

0E contact surface

0F recording device

1 surface of the transverse leaf spring 1 A, 1 1 B bearing surface

1 C, 11 D recess of the transverse leaf spring4 neutral fiber

0 Lagerau ßenschaleneinrichtung 31 bearing ring element

32A, 32B tab

33A, 33B bore

34 centering area

35 upper clamping element

35A, 35B clamping element

36 lower clamping element

36A, 36B clamping element

37A, 37B bore

38A, 38B bore

39 plate

40 shoulder

41 groove

42 circlip

43 tips

100A to 100E rib

1 1 1 Top side of the transverse leaf spring

1 12 underside of the transverse leaf spring

1 13, 1 14 side surface of the transverse leaf spring

1 15, 1 16 edge area of the transverse leaf spring

200A to 200D groove

E3 to E10 cutting plane

X vehicle longitudinal direction y vehicle transverse direction

Z vehicle vertical direction

Claims

claims

1. bearing device (4, 5) for a transverse leaf spring (1) which can be mounted in the region of a vehicle axle of a vehicle, with a bearing outer shell device (30) and with at least partially encompassed by the bearing outer shell device (30) insertion means (9, 10) , each having at least two layer elements (9A, 9B, 9C and 1 OA, 1 OB, 10C) with different stiffness, wherein the insertion means (9, 10) in the assembled state respectively between the bearing outer shell means (30) and the transverse leaf spring (1) are arranged, characterized in that the bearing outer shell means (30) comprises a one-piece bearing ring element (31) and the insertion means (9, 10) via clamping elements (35, 36, 35A, 35B, 36A, 36B) at least frictionally with the bearing ring element ( 31) and the transverse leaf spring (1) can be brought into operative connection.

2. A bearing device according to claim 1, characterized in that the clamping elements (35, 36; 35A, 35B, 36A, 36B) are formed with at least one at least approximately wedge-shaped region which in each case between the insertion devices (9, 10) and the transverse leaf spring ( 1) and / or between the insertion devices (9, 10) and the bearing ring element (31) can be arranged.

3. Bearing device according to claim 1 or 2, characterized in that in each case at least a part of the clamping elements (35, 36) for generating a clamping element-side biasing force on the insertion means (9, 10) and the transverse leaf spring (1) with the bearing ring element (31) in Active connection can be brought and the biasing force on a shoulder (40) of the bearing ring element (31) can be supported.

4. Storage device according to one of claims 1 to 3, characterized in that the bearing ring element (31) via connecting regions (32A. 32B) vehicle body side is fixed.

5. Bearing device according to one of claims 1 to 4, characterized in that the bearing ring element (31) in the assembled state in a vehicle body-facing bearing region is formed with a vehicle with a body-side centering region (34) corresponding centering.

6. Bearing device according to one of claims 1 to 5, characterized in that the clamping elements (35A, 35B, 36A, 36B) are held by a with the bearing ring member (31) connectable plate (39) in a position generating the biasing force.

7. Bearing device according to one of claims 1 to 5, characterized in that the clamping elements (35A, 35B, 36A, 36B) via a with the bearing ring member (31) connectable securing ring (42) are held in a position generating the biasing force.

8. A bearing device according to A, characterized in that a coefficient of friction in defined surface areas of the clamping elements is higher than in other surface regions of the clamping elements (35, 36).

9. Bearing device according to one of claims 1 to 8, characterized in that the clamping elements (35, 36, 35A, 35B, 36A, 36B) between the higher stiffness formed layer elements (9B, 9C, 10B, 10C) of the insertion devices ( 9, 10) and the transverse leaf spring (1) and / or between the bearing ring element (31) and the layer elements (9B, 9C, 10B, 10C) formed with the higher rigidity of the insertion devices (9, 10) can be arranged.

10. Bearing device according to one of claims 1 to 9, characterized in that between the sheet elements (9A, 9B, 10A, 10B) and the transverse leaf spring (1) each have a preferably at least approximately semi-cylindrical running insert (9D, 10D) is arranged, the with higher rigidity Speed are formed as the running with less rigidity layer elements (9A, 1 OA).

1 1. A bearing device according to claim 10, characterized in that the inserts (9D, 10D) in the assembled state, at least in the transverse leaf spring (1) facing plant areas are each formed with a rubber-elastic protective layer.

12. Bearing device according to one of claims 1 to 1 1, characterized in that at least the lower stiffness formed with layer elements have recesses.

13. Bearing device according to one of claims 1 to 12, characterized in that the layer elements formed with higher rigidity at least in the end regions at least partially have a rubber-elastic protective layer.

14. Bearing device according to one of claims 1 to 13, characterized in that at least one of the insertion means (9, 10) in a bearing surface (1 1 A, 1 1 B) of the transverse leaf spring (1) facing bearing surface (9E, 10E) each with at least one receiving device (9F, 10F) is executed, in which a region (1 1 C, 1 1 D) of the transverse leaf spring (1) in the assembled state of the insertion devices (9, 10) engages.

15. Bearing device according to one of claims 1 to 14, characterized in that the lower stiffness formed layer elements (9A, 10A) the transverse leaf spring (1) with stop regions (18A, 19B) in the assembled state in the vehicle longitudinal direction (x) and in the vehicle vertical direction ( z) in each case overlap at least regionally, wherein the stop regions (18A to 19B) in the transverse leaf spring (1) facing contact areas and / or in the bearing outer shells (6, 7) facing contact areas preferably at least approximately in the vehicle longitudinal direction (x) oriented projections and / or recesses are executed.