EP3390129A1 - Engine mount pendulum support device - Google Patents

Abstract

The invention relates to an engine mount pendulum support device (10, 110, 210, 310) for supporting an engine relative to a body of a motor vehicle. The engine mount pendulum support device (10, 110, 210, 310) comprises a first securing region (12) for securing the engine mount pendulum support device (10, 110, 210, 310) on the body, said securing region comprising a first securing surface (50) for contacting the body, a second securing region (14) for securing the engine mount pendulum support device (10, 110, 210, 310) on the body, said securing region comprising a second securing surface (54) for contacting the body, and a third securing region (16) for securing the engine on the engine mount pendulum support device (10, 110, 210, 310), wherein the first securing region (12) and the second securing region (14) are elastically connected to the third securing region (16) via a first elastic mount (18) and via a second elastic mount (20). The first securing region (12) and the second securing region (14) are rigidly connected together by a connection element (56).

Description

 Motor bearing pendulum support device

The invention relates to an engine mount pendulum support device for supporting an engine relative to a body of a vehicle. The engine mount pendulum support apparatus includes a first attachment portion, a second attachment portion, and a third attachment portion. The first and second attachment areas are each for attachment of the engine mount pendulum support device to the body. The third mounting portion is provided for mounting the motor to the engine mount pendulum support device.

Engine mounts are used to support an engine relative to the body of the vehicle. For this purpose, the motor bearings are equipped with elastic bearings, which absorb the vibrations of the engine elastic and thus can isolate them. The elastic bearings are usually designed so that they can absorb the vibrations of the engine effectively in one direction only; Often this is in the direction of the engine's gravity. Movements of the engine perpendicular to this vibration receiving direction, be it vibrations or induced due to the inertia of the engine, can only be absorbed by the elastic bearing poorly. Therefore, some engine mounts are provided with a pendulum support, which absorb the torques occurring while driving. The pendulum support represents a further connection between the engine and the body.

JP 2005 075 223 A and JP 2005 075 157 A show engine mounts with pendulum supports, in which the pendulum support is not fixed at a distance from the attachment of the elastic bearing to the body, but is designed such that it is in the same position of the body as the elastic Bearing is attached. The object of the invention is to provide an engine mount pendulum support device which allows reliable support of the engine while easy installation.

The object is achieved by the motor bearing pendulum support device according to claim 1.

Claims 2 to 10 describe preferred embodiments of the motor bearing pendulum support device according to the invention.

The invention relates to an engine mount pendulum support device for supporting an engine relative to a body of a motor vehicle. The engine mount pendulum support apparatus includes a first attachment portion, a second attachment portion, a third attachment portion, a first elastic bearing, and a second elastic bearing. The first attachment area serves to attach the engine mount pendulum support device to the body and includes a first attachment surface for engagement with the body. The second attachment portion serves to secure the engine mount pendulum support device to the body and includes a second attachment surface for engagement with the body. The third attachment area serves to secure the motor to the engine mount pendulum support device. The second attachment surface is offset from a plane defined by the first attachment surface. The first attachment portion and the second attachment portion are connected to the third attachment portion via a first elastic bearing configured to receive vibrations in a first direction and a second elastic bearing adapted to receive vibrations in a second direction perpendicular to the first direction Direction is formed, elastically connected to each other. The first attachment region and the second attachment region are firmly connected to one another by a connecting element.

The engine mount pendulum support device supports the engine, in particular elastically, against the body of the motor vehicle. The motor bearing pendulum support device according to the invention causes isolation of the vibrations of the engine relative to the body. Furthermore, the kicking forces are absorbed. The weight of the engine preferably corresponds to the first direction.

The engine mount pendulum support device is attached to the body of the vehicle by the first attachment portion. Preferably, the first attachment region for attachment of the engine mount pendulum support device is provided on a longitudinal member of the body. The first attachment region can be realized for example by a flange. Furthermore, it is possible for the first fastening area to be realized by two or more flanges spaced apart from one another. The attachment to the body can be done by means of screws or bolts. The first attachment region may be formed in one piece or in several parts.

The surface by means of which the first attachment region is in contact with the body is referred to as the first attachment surface. The first attachment surface is preferably the surface along which force is transferred from the first attachment region to the body. The first attachment surface is arranged in particular perpendicular to the first direction.

Components which are provided for fastening the first fastening region between the first fastening region and the body are considered in the context of this invention as belonging to the first fastening region. Thus, the first attachment surface is in particular always arranged directly on the body and is determined by this. The first attachment portion is preferably formed on the first attachment surface as the body at the location of the attachment.

The first attachment surface is designed in particular as a straight plane, for example, when the body in the region of the attachment of the motor bearing pendulum support device has a flat surface. However, it is also possible that the first attachment surface is curved. Furthermore, the first fastening surface can be composed of a plurality of partial surfaces, for example if the first fastening region has a plurality of fastening points spaced apart from one another. For the second fastening region, the considerations made with regard to the first fastening region apply analogously. In particular, the second fastening region is not arranged at the same location of the body as the first fastening region, for example not at the longitudinal member, like the first fastening region. The second attachment portion may be attached to a wheel arch of the vehicle. The second attachment surface is arranged in particular perpendicular to the second direction.

However, the second attachment portion is spaced from the first attachment portion. In this case, the second attachment surface is arranged offset to a plane which is defined by the first attachment surface. In particular, the second attachment surface is arranged offset to the first attachment surface in the first direction and / or in the second direction and / or in a third direction, which is perpendicular to the first direction and the second direction.

Here, the attachment of the second attachment portion to the body is such as to serve to support the engine mount pendulum support device in a lateral direction, that is, to stabilize the attachment of the engine mount pendulum support device to the first attachment surface. In particular, acting on the motor bearing Pendelstützen- device by means of the second mounting portion forces acting parallel to the plane of the first mounting surface to be supported. For the first attachment area absorbs in particular the forces which act perpendicular to the first attachment surface. The second attachment region therefore serves for the lateral support of the first attachment region.

It should be noted that the first elastic bearing can also receive forces in the second direction, but it is particularly adapted to receive forces along the first direction. Similarly, the second elastic bearing is configured to receive forces particularly well along the second direction, however, it may also receive forces along the first direction.

The third attachment region is in particular designed such that the engine of the vehicle can be attached to it. The third attachment area For example, it may be configured as known from the prior art for engine mounts.

The first attachment portion and the third attachment portion are elastically connected to each other via the first elastic bearing. The combination of the first attachment region, the third attachment region and the first elastic bearing can be constructed, for example, like an engine mount known from the prior art. In particular, the arrangement of the first mounting portion, third mounting portion and first elastic bearing for supporting the motor on the body, so that the first elastic bearing supports the weight of the engine and generated by the engine vibrations. In particular, the first elastic bearing is designed to isolate vibrations of the engine.

The second attachment portion is connected to the third attachment portion via a second elastic bearing. The arrangement of the second attachment region, the third attachment region and the second elastic bearing can be realized, for example, by a pendulum support bearing known from the prior art. In particular, this arrangement serves for the lateral support of the arrangement of the third attachment area, the first elastic bearing and the first attachment area; It is thus intended to support a tilting of the third attachment region relative to the first attachment region from the first direction.

In particular, the second elastic bearing can elastically absorb vibrations or movements of the motor in the second direction and in particular isolate vibrations or movements of the motor in the second direction.

The first attachment area and the second attachment area are rigidly connected via the connection element, so that the first attachment area can not move with respect to the second attachment area. Moreover, the distance between the first attachment portion and the second attachment portion is fixed via the connection member. In particular, the connecting element is selected such that, when the first fastening region bears against the body, the second fastening region is also at a different location the body rests. Thus, with correct positioning of the first attachment region on the body, the second attachment region is also suitably arranged on the body.

The connecting element may be a separate element from the first fastening area and the second fastening area, preferably being firmly connected to one another for producing the motor bearing pendulum support device, for example by screwing or welding. Alternatively, the first attachment portion, the second attachment portion and the connection member may be integrally formed with each other, for example, these components are manufactured in one piece.

Advantage of the motor bearing pendulum support device according to the invention is that it is supported in the second direction. The support is particularly effective because the second attachment area is offset from the first attachment area. Thus, in comparison to the device described in JP 2005 075 223 A in particular, improved support can be achieved, as a result of which the force acting on the first fastening surface can be reduced. This can be avoided on the body acting local overloading. In particular, in a misuse of the vehicle in which rotating masses store kinetic energy and release it abruptly (cavalier start), the deflection of the motor can be supported particularly well.

The engine mount pendulum support device further has the advantage of easy installation in the vehicle, since the second attachment portion is fixed with respect to the first attachment portion, whereby a quick installation can be realized.

Advantageously, the first attachment surface to the second attachment surface an angle not equal to 0 °, in particular 90 ° include.

Since the second attachment portion is provided for receiving forces in the second direction which is perpendicular to the first direction, this engagement can be particularly successful when the second attachment surface is disposed at an angle to the first attachment surface. Especially if the second Mounting surface is perpendicular to the first mounting surface, that is, when the power input through the second mounting portion is parallel to the second direction, there is a particularly good transmission of the engine-derived forces on the body.

It is advantageous that the first elastic bearing is arranged between the first fastening region and the third fastening region and / or that the second elastic bearing is arranged between the second fastening region and the third fastening region.

Thus, the third attachment area is movably arranged by means of the first elastic bearing with respect to the first attachment area. This is achieved in a particularly simple manner when the first elastic bearing is arranged between the first fastening region and the third fastening region, wherein in particular the first elastic bearing is provided in the first direction between the first fastening region and the third fastening region.

The third attachment region is arranged to be movable relative to the second attachment region. In order to be able to accomplish a particularly good power transmission from the third attachment region to the second attachment region, the second elastic bearing is arranged between these regions. The second elastic bearing may be disposed in the second direction or in the third direction between the second attachment portion and the third attachment portion.

Advantageously, the first elastic bearing may comprise an engine mount, in particular a hydraulic bearing, a rectangular engine mount or a rubber-metal engine mount, and / or the second elastic mount may comprise a pendulum support bearing.

The first elastic bearing and the second elastic bearing may be constructed by one or more elastic bearings, respectively. However, it is preferred that the first elastic bearing is realized only by a motor bearing and the second elastic bearing by a pendulum support bearing. The design of the engine mount and the pendulum support bearing can be as it is known from the prior art. Advantageously, the pendulum support bearing has a first pendulum support sleeve mounted on the second attachment portion, a second pendulum support sleeve mounted on the third attachment portion, and a pendulum support connecting the first pendulum support sleeve to the second pendulum support sleeve.

The pendulum support has in particular at both ends of a fork, which surrounds the first pendulum support sleeve and the second pendulum support sleeve. Between the ends of the fork of the pendulum support rods are provided, which are connected via an elastic material in each case with the first pendulum support sleeve and the second pendulum support sleeve. In this way, the power transmission from the third attachment area to the second attachment area can take place. The rod can be vulcanized into the elastomeric material of the first pendulum bushing and the second pendulum bush, so that the pendulum support can be fastened to the respective rod.

Alternatively, the first and second pendulum support bushing may be attached to the pendulum support. At the third and second attachment area then preferably the forks are attached, to which the rod is attached.

Advantageously, the second fastening region can be provided directly on the first pendulum support bushing, in particular on a side surface of the first pendulum support bushing.

For example, a side surface of the first pendulum support bushing forms the second attachment surface. Alternatively, one or more flanges may be provided directly on the first pendulum support bush, forming the second attachment region. The direct arrangement of the second mounting portion on the first pendulum support bushing represents a particularly simple realization of the motor bearing pendulum support device.

Alternatively, the second attachment portion may be spaced from the first pendulum support sleeve. The connection between the first pendulum support bushing and the second fastening region can be realized for example by a bridging element. For example, it is possible that the second attachment portion, the bridging member and the first pendulum support sleeve are integrally formed; For example, these components can be made in one piece.

It is advantageous that the second pendulum support bushing is provided on a boom of the third attachment region, wherein preferably the second pendulum support bushing is offset from the first elastic bearing by the boom in a third direction, which is perpendicular from the first direction and the second direction.

The provision of a cantilever for attaching the second pendulum support bush thereto allows optimum force absorption of the second direction force to be generated from the third attachment portion to the second attachment portion. This is advantageous, for example, when the second fastening region and the third fastening region are arranged along the third direction, and the arm arranges the second pendulum support sleeve with respect to the second fastening region in the second direction. In particular, with the aid of the jib, the pendulum support is arranged such that it extends in the direction of the second direction. Thus, an improved power transmission from the third attachment area to the second attachment area can be made possible.

Advantageously, the second pendulum support bush can be arranged in the first direction offset from the first elastic bearing, in particular above.

In particular, the center of the second pendulum support sleeve coincides with an axial centerline of the first elastic bearing. In this embodiment, a tilting of the first elastic bearing from the first direction can be particularly well absorbed by the pendulum support, since the second elastic bearing is far removed from a tipping point of the second bearing. The lever of the second elastic bearing is particularly large in this embodiment. In addition, this embodiment has the advantage that it is particularly space-saving in the second and third directions. It is advantageous that an axial direction of the first pendulum support bush and / or the second pendulum support bush coincides with the first direction.

The axial direction of the first and / or second pendulum support sleeve is in particular coincident with the rod for attachment to the pendulum support. The axial direction is in particular perpendicular to a radial direction of the first and / or second pendulum support bushing. This configuration allows a deflection of the third attachment portion from the first direction to be particularly well received by the second elastic bearing, since the arrangement of the rod in the first and / or second pendulum support sleeve extends in the axial direction, so that an elastic receptacle in its radial direction is provided.

Advantageously, the first fastening region and / or the second fastening region and / or the third fastening region and / or the connecting element can be produced from steel, aluminum, magnesium or plastic.

Moreover, the invention relates to a motor vehicle having a body and a motor, wherein the motor is fixed to the body via the above-described engine mount pendulum support device.

Preferred embodiments of the invention are shown schematically in the accompanying drawings. Show:

1 is a perspective view of a motor bearing Pendelstützen-

Device according to a first embodiment;

FIG. 2 is a cross-sectional view of the engine mount pendulum support device of FIG. 1 along the plane I; FIG.

3 is a perspective view of an engine mount pendulum support

Device according to a second embodiment;

4 is a cross-sectional view through the engine bearing pendulum support

Device according to Figure 3 along the plane I; 5 is a perspective view of an engine mount pendulum support

Device according to a third embodiment;

FIG. 6 is a cross-sectional view of the engine mount pendulum support device of FIG. 5 along the plane I; FIG.

7 is a cross-sectional view of an engine mount pendulum support device according to a fourth embodiment; and

FIG. 8 is a cross-sectional view of the engine mount pendulum support device of FIG. 7, which is perpendicular to the view of FIG. 7.

An engine mount pendulum support apparatus 10 according to a first embodiment as shown in FIGS. 1 and 2 includes a first attachment portion 12, a second attachment portion 14, a third attachment portion 16, a first elastic bearing 18, and a second elastic bearing 20 ,

The first elastic bearing 18 is formed as a hydrobox bearing and damps vibrations of an unillustrated motor in a first direction Z. The first elastic bearing 18 is disposed between the first mounting portion 12 and the third mounting portion 16 so that the weight of the motor is applied to the third mounting portion 16 is transmitted and from there via the first elastic bearing 18 on the first mounting portion 12 on a side member, not shown in the figures, of a body of a vehicle. The first elastic bearing 18 in the form of the hydrobox bearing comprises in known manner a hydro-bearing core 22, rubber walls 24, which define a working chamber 26 via a nozzle-membrane system 28. A compensation chamber 30 is separated from the working chamber 26 via the nozzle-membrane system 28.

The second elastic bearing 20 is a pendulum support bearing 32 which includes a first pendulum support sleeve 34, a second pendulum support sleeve 36, and a pendulum support 38. The first pendulum support sleeve 34 is formed integrally with the second attachment portion 14. The second pendulum support sleeve 36 is formed integrally with the third attachment portion 16. The pendulum support 38 has at both ends a fork 40 which is releasably connected to a rod 42. The rod 42 is vulcanized into an elastomeric body 44 in the first pendulum support sleeve 34 and the second pendulum support sleeve 36. Thus, the rods 42 are resiliently disposed opposite the first pendulum support sleeve 34 and the second pendulum support sleeve 36. The rods 42 extend along the first direction Z.

The second pendulum support sleeve 36 is connected to the third attachment portion 16 at one end of a boom 46. The second pendulum support sleeve 36, the boom 46 and the third attachment portion 16 are formed integrally with each other. The boom 46 extends in a third direction Y.

The first mounting portion 12 has two flanges 48 by means of which the motor bearing pendulum support device 10 can be fastened to the body by screws. The flanges 48 are spaced apart in the second direction X and define a first attachment surface 50. The first attachment surface 50 extends in the plane defined by the second direction X and the third direction Y. The first attachment surface 50 is flat.

The second fastening region 14 has two openings 54, by means of which the second fastening region 14 can be fastened to another location of the body. The second attachment portion 14 defines a second attachment surface 54 that extends in a plane that is spanned by the first direction Z and the second direction X. The first attachment surface 50 encloses an angle of 90 ° with the second attachment surface 54. Moreover, the second attachment surface 54 is arranged offset from the first attachment surface 50 in the first direction Z, in the second direction X, and in the third direction Y.

The second fastening region 14 and the first fastening region 12 are rigidly connected to one another by a connecting element 56. In the illustrated embodiment, the first attachment portion 12, the second attachment portion 14, and the connecting member 56 are integrally formed as a casting. The third attachment portion 16 is formed as a support arm for attachment to a motor, as is known in the art.

The first attachment portion 12, the second attachment portion 14, the third attachment portion 16 and the connecting member 56 are made of steel, aluminum, magnesium or plastic.

The operation of the engine mount pendulum support device 10 according to FIGS. 1 and 2 will be described below. The engine of the vehicle is mounted on the third attachment portion 16. As a result, the motor 16 is mounted on the longitudinal member of the body via the first elastic bearing 18 and the first attachment portion 12. Vibrations of the engine in the first direction Z are absorbed by the first elastic bearing 18, whereby a decoupling of the longitudinal member from the engine takes place.

Movements of the motor in the second direction X, which cause the third attachment region to tip over from the first direction Z, are transmitted to the second attachment region 14 by the second elastic bearing 20. Thus, lateral support of the third attachment portion 16 is performed by the second attachment portion 14, so that forces in the second direction X and the third direction Y can be supported by the second attachment portion 14. As a result, the forces in the second direction X and the third direction Y act less strongly on the first attachment region 12.

By the boom 46, the second pendulum support sleeve 36 is positioned such that the pendulum support 38 extends in the second direction X, so that the second elastic bearing 20 can accommodate movements of the motor in the second direction X very well.

Hereinafter, a second embodiment of the engine mount Pendelstützen- device 1 10 of FIG. 3 and 4 will be explained. Features and components that correspond to the engine mount pendulum support device 10 according to the first embodiment of Figs. 1 and 2 are given the same reference numerals. Thus, in the following, only differences between the engine mounts Pendulum support device 10 and the engine mount pendulum support device 1 10 described.

The first elastic bearing 18 is formed in this embodiment as a round hydraulic bearing. In addition, the first attachment portion 12 and the third attachment portion 16 have a different shape. In addition to the lateral support by the second mounting portion 14, a side support 58 is provided to support the engine mount pendulum support bearing 1 10 additionally in the third direction Y.

The sectional view of Fig. 4 is in particular a section transverse to the direction of travel, wherein the first elastic bearing 18 has a transverse soft spring, the bearing core 60 is connected via the first mounting portion 12 with the longitudinal member of the body of the vehicle. A boom 46 stabilizes the first attachment portion 12 by the support member 40 with a wheel arch of the vehicle against lateral tilting.

The first elastic bearing 18 has the bearing core 60, which is provided with stop regions 62 made of rubber for movement restrictions in all spatial directions. Tensile and transverse movements along the second direction X and the third direction Y are supported against a bearing housing 64 formed as part of the third attachment portion 16. High pressure loads act on the first mounting region 12 from the bearing housing 64 via profiled rubber geometries.

High drive torques act, on the one hand, from the bearing core 60 on the bearing housing 64 and, coordinated therewith, via the pendulum support bearing 32 on the second fastening region 14, which is screwed to the body. The power transmission is distributed to the first mounting portion 12 and second mounting portion 14 and the pendulum support bearing 32 to the body. This can be avoided on the body acting local overloading.

A third embodiment of an engine mount pendulum support device 210 will be described with reference to FIGS. 5 and 6 described. Components and features associated with the engine mount pendulum support device 10 according to the first embodiment of Figs. 1 and 2 are identical, are provided with the same reference numerals. In the following, therefore, only the differences between the engine mount pendulum support device 210 shown in FIGS. 5 and 6 and the engine mount pendulum support device 10 of FIG. 1 and 2 described.

The first elastic bearing 18 is, as in the embodiment of the motor bearing pendulum support device 1 10 of FIGS. 3 and 4, configured as a hydraulic bearing.

The second elastic bearing 20 is disposed in a first direction Z above the first elastic bearing 18 and not, as in the motor bearing pendulum support device 10 shown in FIGS. 1 and 2, in a third direction Y offset from the first elastic bearing 18th The second elastic bearing 20 has a pendulum support bearing 232 which has a pendulum support 238. The pendulum support 238 has the first pendulum support sleeve 234 and the second pendulum support sleeve 236. The rods 42 are each in turn vulcanized into the elastomeric bodies 44 of the first pendulum support sleeve 234 and the second pendulum support sleeve 236. In contrast to the embodiments shown so far, the forks 240 are not provided on the pendulum support 238 but on the second attachment region 14 and on the third attachment region 16. The forks 240 are each formed integrally with the second attachment region 14 and the third attachment region 16.

The second attachment portion 14, unlike the previously shown embodiments of the engine mount pendulum support device 10, 110, is not directly provided on the first pendulum support sleeve 34, but has an intermediate bridging member 260. The bridging element 260, the fork 240, the connecting element 56, the second fastening region 14 and the first fastening region 12 are formed in one piece.

The embodiment of the engine mount pendulum support device 210 shown in FIGS. 5 and 6 can particularly well accomplish the dumping of the third attachment region 16 from the first direction Z, since the second elastic mount 20, in particular the second pendulum support bush 236, is far from a pivot point of the first first elastic bearing 18 in the first direction Z is spaced. Thus, in the engine mount pendulum support device 10, the lever is for lateral movement. Chen support of the third mounting portion 16 compared to the engine mount pendulum support devices 10, 1 10 improved. At the same time, the engine mount pendulum support device 210 is particularly narrow in extent in the third direction Y.

Another embodiment of an engine mount pendulum support device 310 will now be described with reference to FIGS. 7 and 8. This is consistent with the engine mount pendulum support device 210 of FIGS. 5 and 6. The engine mount pendulum support device 310 differs from the engine mount pendulum support device 210 in that the first bearing 18 is provided by a rubber-metal engine mount in the embodiment shown in FIGS. 7 and 8, not as shown in FIGS. 6 and 7 , through a hydraulic bearing. Otherwise, the engine mount pendulum support device 310 mates with the engine mount pendulum support device 210.

LIST OF REFERENCE NUMBERS

Engine Bearing Pendulum Support Device First Mounting Area

second attachment area

third mounting area

first elastic bearing

second elastic bearing

Hydro bearing core

rubber wall

working chamber

Nozzle membrane system

compensation chamber

Hinged column bearing

first pendulum support bush

second pendulum support bush

Stabilizer

fork

Rod

elastomer body

boom

flange

first attachment surface

opening

second attachment surface

connecting element

side support

bearing core

stop area

bearing housing

Engine Bearing Pendulum Support Device Engine Bearing Pendulum Support Device 232 pendulum support bearings

234 first pendulum support bush

 236 second pendulum support bush

 238 pendulum support

 240 fork

 260 bridging element

 310 Engine Bearing Pendulum Support Device

X second direction

 Y third direction

 Z first direction

Claims

claims

1 . Motor bearing pendulum support device for supporting an engine relative to a body of a motor vehicle, comprising

 a first attachment portion (12) for attaching the engine mount pendulum support device (10, 110, 210, 310) to the body comprising a first attachment surface (50) for engagement with the body;

 a second attachment portion (14) for attaching the engine mount pendulum support device (10, 110, 210, 310) to the body comprising a second attachment surface (54) for engagement with the body;

 a third mounting portion (16) for mounting the motor to the engine mount pendulum support device (10, 110, 210, 310),

 wherein the second attachment surface (54) is staggered to a plane defined by the first attachment surface (50),

 wherein the first attachment portion (12) and the second attachment portion (14) are connected to the third attachment portion (16) via a first elastic bearing (18) adapted to receive vibrations in a first direction (Z) and a second elastic portion Bearing (20) which is formed for receiving vibrations in a direction perpendicular to the first direction (Z) second direction (X) are elastically connected to each other, and

 wherein the first attachment portion (12) and the second attachment portion (14) are fixedly connected to each other by a connector (56).

2. Motor bearing pendulum support device according to claim 1, characterized in that the first (50) to the second mounting surface (54) forms an angle not equal to 0 °.

3. Motor bearing pendulum support device according to claim 1 or 2, characterized in that the first elastic bearing (18) between the first mounting portion (12) and the third mounting portion (16) is arranged and / or that the second elastic bearing (20) is arranged between the second fastening region (14) and the third fastening region (16).

4. Motor bearing pendulum support device according to one of the preceding claims, characterized in that the first elastic bearing (18) comprises an engine mount, in particular a hydraulic bearing, a rectangular engine mount or a rubber-metal engine mount, and / or that the second elastic Bearing (20) comprises a pendulum support bearing (32, 232).

5. Motor bearing pendulum support device according to claim 4, characterized in that the pendulum support bearing (32) has a first pendulum support bushing (34) which is attached to the second attachment portion (14), a second pendulum support bush (36), which at the third attachment portion (16) and a pendulum support (38) connecting the first pendulum support sleeve (34) to the second pendulum support sleeve (36).

6. Motor bearing pendulum support device according to claim 5, characterized in that the second fastening region (14) directly to the first pendulum support bushing (34), in particular on a side surface of the first pendulum support bushing (34), is provided.

7. Motor bearing pendulum support device according to claim 5 or 6, characterized in that the second pendulum support bushing (36) on a boom (46) of the third mounting portion (16) is provided, wherein preferably the second pendulum support sleeve (36) by the boom ( 46) is offset from the first elastic bearing (18) in a third direction (Y) which is perpendicular from the first direction (Z) and the second direction (X).

8. Motor bearing pendulum support device according to claim 5 or 6, characterized in that the second pendulum support sleeve (36) in the first direction of the first elastic bearing (18) offset, in particular above, is arranged.

9. Motor bearing pendulum support device according to one of claims 5 to 8, characterized in that an axial direction of the first pendulum support sleeve (34) and / or the second pendulum support bushing (36) with the first direction (Z) matches.

10. Motor bearing pendulum support device according to one of the preceding claims, characterized in that the first fastening region (12) and / or the second fastening region (14) and / or the third fastening region (16) and / or the connecting element (56) Steel, aluminum, magnesium or plastic is made.