Vehicle Unit Fastening Subassembly and Modular System

Abstract

A vehicle unit fastening subassembly for vibratory fastening of a vehicle unit, in particular of a motor and/or transmission, to a vehicle structure of a motor vehicle, has at least one first carrier element on the unit side and a second carrier element on the vehicle side. The first carrier element and the second carrier element are connected to each other by a vibration damper, which is arranged at least in part in the first carrier element or in the second carrier element. The vibration damper is fluidically connected to a hydraulic unit by a flow channel, which is arranged adjacent to the vibration damper in a plan view of the vibration damper. A modular system is provided having a vibration damper and a hydraulic unit, wherein the vibration damper is usable either together with the hydraulic unit as a hydraulic vibration damper or without the hydraulic unit as a conventional bearing.

Claims

1.-11. (canceled)

12. A vehicle unit fastening subassembly for vibratory fastening of a vehicle unit in a vehicle structure of a motor vehicle, comprising: a unit-side first carrier element; a vehicle-side second carrier element; a vibration damper arranged at least partially in the first carrier element or in the second carrier element, wherein the first carrier element and the second carrier element are connected to each other by the vibration damper; a hydraulic unit; and a flow channel fluidically connecting the vibration damper to the hydraulic unit, wherein the hydraulic unit, when the vibration damper is viewed from above, is arranged adjacent the vibration damper.

13. The vehicle unit fastening subassembly according to claim 12, wherein the vibration damper comprises a bearing core and a suspension spring.

14. The vehicle unit fastening subassembly according to claim 13, wherein the suspension spring at least partially surrounds the bearing core.

15. The vehicle unit fastening subassembly according to claim 12, wherein the carrier element which receives the vibration damper has two adjacent recesses, the vibration damper and the hydraulic unit are received in an associated recess in each case, and the recesses are covered at least at one side by a cover which, together with the associated carrier element, forms at least a portion of the flow channel.

16. The vehicle unit fastening subassembly according to claim 12, wherein the vibration damper and the hydraulic unit are mounted together in a separate housing which is secured to one of the carrier elements.

17. The vehicle unit fastening subassembly according to claim 12, wherein the vibration damper is supported by a bearing ring on the carrier element or a separate housing.

18. The vehicle unit fastening subassembly according to claim 17, wherein the bearing ring forms at least a portion of the hydraulic unit.

19. The vehicle unit fastening subassembly according to claim 18, wherein the bearing ring forms at least a portion of a nozzle plate.

20. The vehicle unit fastening subassembly according to claim 12, wherein the flow channel extends in a substantially linear manner between the vibration damper and the hydraulic unit.

21. The vehicle unit fastening subassembly according to claim 12, wherein the flow channel has a step between the vibration damper and the hydraulic unit.

22. The vehicle unit fastening subassembly according to claim 13, wherein the bearing core is part of a stop system, wherein the bearing core can strike at least one of the two carrier elements.

23. The vehicle unit fastening subassembly according to claim 22, wherein the bearing core is cross-shaped or T-shaped when viewed as a longitudinal section.

24. A modular system, comprising: a vibration damper and a hydraulic unit, wherein the vibration damper is optionally used together with the hydraulic unit as a vehicle unit fastening subassembly, or without the hydraulic unit as a bearing for securing the vehicle unit to the vehicle structure.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] FIG. 1 is a sectioned illustration of a vehicle unit fastening subassembly according to an embodiment of the invention.

[0028] FIGS. 2 to 5 show in each case other embodiments of a vehicle unit fastening subassembly according to the invention.

[0029] FIGS. 6a to 6c show different vibration dampers of the vehicle unit fastening subassembly according to the invention.

[0030] FIG. 7 shows a vibration damper in a conventional bearing.

DETAILED DESCRIPTION OF THE DRAWINGS

[0031] FIG. 1 is a sectioned illustration of a vehicle unit fastening subassembly 10. The vehicle unit fastening subassembly 10 is suitable for securing a vehicle unit 11, in particular an engine and/or transmission, to a vehicle structure of a motor vehicle in a vibratory manner.

[0032] The vehicle unit fastening subassembly 10 comprises a unit-side carrier element 12 and a vehicle-side carrier element 14 and a vibration damper 16 which connects the two carrier elements 12, 14 to each other in terms of forces and at the same time damps relative movements.

[0033] The vibration damper 16 comprises a bearing core 18 and a suspension spring 20. The suspension spring 20 preferably comprises a resilient material. The vibration damper 16 can thereby become deformed during travel operation and can absorb the vibrations of the vehicle unit 11 during travel operation.

[0034] The unit-side carrier element 12 is, for example, a component of the vehicle unit 11, in particular a housing of the vehicle unit 11.

[0035] The vehicle-side carrier element 14 is, for example, an engine carrier or a transmission cross-member.

[0036] In the embodiments shown, the vibration damper 16 is partially supported in the vehicle-side carrier element 14, in particular the carrier element 14 is used as a receiving housing for the vibration damper 16. In principle, the vibration damper 16 may also be supported in the unit-side carrier element 12.

[0037] In addition to the vibration damper 16, when the vibration damper 16 is viewed from above, a hydraulic unit 22 is arranged. As can be seen in the Figures, a structural height in an axial direction is thereby reduced so that the fastening subassembly 10 can be readily installed in structural spaces with small spatial relationships in a vertical direction.

[0038] The vibration damper 16 and the hydraulic unit 22 are connected to each other in terms of flow by means of a flow channel 24 in which a hydraulic fluid is present. In the embodiment shown in FIG. 1, the flow channel 24 extends in a linear manner between the vibration damper 16 and the hydraulic unit.

[0039] The hydraulic unit 22 comprises a rolling bellows 26, a diaphragm 28 and a nozzle plate 30 which may be in one piece or several pieces. The rolling bellows 26 may become deformed in order to receive a hydraulic fluid which is displaced as a result of a movement of the vibration damper 16. Furthermore, the rolling bellows 26 seals the hydraulic unit 22 in the direction toward the carrier element 14.

[0040] As a result of a vibration damper 16 in combination with a hydraulic unit 22, a vehicle unit can be supported in a particularly advantageous manner. In this instance, the vibration damper takes on the support of the entire static weight of the vehicle unit 11 and, in combination with the hydraulic fluid, vibrations in the case of relative movements between the vehicle unit and a vehicle structure are damped in a particularly effective manner.

[0041] In order to support the vibration damper 16 and the hydraulic unit 22 in a reliable manner which is optimized in terms of structural space, recesses 32, 24 in the form of pockets which are freely constructed in geometric terms are provided in the carrier element 14, wherein the vibration damper 16 and the hydraulic unit 22 are arranged in each case in a recess 32, 34. In this instance, the recess 32 which receives the vibration damper 16 extends continuously in an axial direction through the carrier element 14. The recess 32 is stepped in order to support the vibration damper 16 in a non-releasable manner. In addition, the axial recess 32 enables the required freedom of movement in the axial direction, in the longitudinal direction and in the transverse direction of the vibration damper 16 when the vibration damper 16 is correctly mounted in the carrier element 14.

[0042] The vibration damper 16 protrudes, at least at a side directed toward the unit-side carrier element 12, out of the carrier element 14, in particular out of the recess 32. In particular, a securing portion 36 of the vibration damper 16 protrudes from the carrier element 14. The vibration damper 16 can thus be connected to the carrier element 12 in a simple manner, for example, by means of screws.

[0043] At a side facing away from the carrier element 12, the recesses 32, 34 are covered by a cover 38. The cover 38 may be secured to the carrier element 14 in a suitable manner, for example, by means of screwing, adhesive-bonding, fitting, locking or some other means.

[0044] The cover 38 forms together with the carrier element 14 the flow channel 24 and can further be used to secure the vibration damper 16 to the carrier element 14.

[0045] In order to be able to secure the vibration damper 16 to the carrier element 14 in a simple manner, a bearing ring 40 is provided. This ring 40 is connected to the vibration damper 16 by means of the suspension spring 20 which is in particular vulcanized on the bearing ring 40.

[0046] The bearing ring 40 can be secured to the carrier element 14 in an appropriate manner, for example, by means of screwing, adhesive-bonding, fitting or locking. In the embodiment shown, the bearing ring 40 is retained by the cover 38 by the bearing ring 40 being clamped between the cover 38 and the carrier element 14.

[0047] A hydraulic chamber 41 which is formed between the lower side of the vibration damper 16 and the cover 38 and in which the flow channel 24 opens is sealed via the bearing ring 40.

[0048] In order to limit a freedom of movement of a vehicle unit 11, a stop system 42 is provided. This is necessary so that the vehicle unit 11 does not strike adjacent components during travel operation.

[0049] In the embodiment shown, the bearing core 18 is part of the stop system 42, wherein the bearing core 18 can strike the carrier element 14. Such a stop system 42 has the advantage that no additional components are required to form the stop system 42. Consequently, the fastening subassembly 10 may be particularly cost-effective. Only a suitable geometry for the bearing core 18 has to be selected.

[0050] In FIG. 1, the bearing core 18 is cross-shaped when viewed as a longitudinal section. However, other suitable geometries are also conceivable. For example, the bearing core 18 may be T-shaped in section, as illustrated in FIG. 6b.

[0051] In order to seal the fastening subassembly 10, in particular the flow channel 24, in an outward direction, a seal 44 is arranged between the cover 38 and the bearing ring 40.

[0052] FIG. 2 is a sectioned illustration of another embodiment of a vehicle unit fastening subassembly 10 according to the invention.

[0053] In contrast to the embodiment shown in FIG. 1, the vibration damper 16 and the hydraulic unit 22 are not arranged directly in the carrier element 14, but are instead pre-assembled in a separate inner housing 46. The handling during assembly can thereby be simplified.

[0054] The housing 46 is constructed in a disk-like manner and has two recesses for receiving the vibration damper 16 and the hydraulic unit 22.

[0055] Furthermore, the housing 46 has a peripheral collar 52 which extends radially outward. This acts as a stop in order to mount the housing 46 in a defined position on the carrier element 14.

[0056] In addition, there is provided a radially inwardly protruding collar 54 which acts as a stop for the vibration damper 16 and the hydraulic unit 22. The vibration damper 16 and the hydraulic unit 22 can consequently be inserted in a simple manner into the housing 46.

[0057] The pre-assembled unit can again be secured by the cover 38 to the carrier element 14 and be inserted into one of the carrier elements.

[0058] FIG. 3 is a schematic sectioned illustration of another embodiment of a vehicle unit fastening subassembly 10 according to the invention. The vehicle unit fastening subassembly 10 is similar to the vehicle unit fastening subassembly 10 according to FIG. 1.

[0059] In the embodiment according to FIG. 3, however, the bearing ring 40 is covered at the contact faces 56, 58 thereof directed toward the carrier element 14 and the cover 38 at least partially by the material of the suspension spring 20. This has the advantage that an additional seal 44 can be dispensed with since the material of the suspension spring 20 which is arranged on the bearing ring 40 ensures adequate sealing.

[0060] Alternatively or additionally, the rolling bellows 26 may be formed at the same time by the material of the suspension spring 20 so that the rolling bellows 26 is integral with the suspension spring 20. This is illustrated in FIG. 3.

[0061] FIG. 4 is a schematic sectioned illustration of another embodiment of a vehicle unit fastening subassembly 10 according to the invention.

[0062] In contrast to the embodiments shown above, the flow channel 24 has between the vibration damper 16 and the hydraulic unit 22 a stop 60. The hydraulic unit 22 may thereby be subjected to flow from a different side in relation to the vibration damper 16.

[0063] In another embodiment which is not illustrated for the sake of clarity, the hydraulic unit 22 can in comparison with the hydraulic units shown in FIGS. 1 to 3 be arranged in an inclined manner, in particular tilted through 90°. In this manner, the vehicle unit fastening subassembly 10 may be adapted to different structural space situations.

[0064] FIG. 5 is a schematic sectioned illustration of another embodiment of a vehicle unit fastening subassembly 10 according to the invention.

[0065] In contrast to the embodiments shown above, the bearing ring 40 and the cover 38 are formed in such a manner that they together represent a nozzle plate 30 with a nozzle channel 48. In this instance, the bearing ring 40 forms a first portion and the cover 38 forms a second portion of the nozzle plate 30.

[0066] The nozzle plate 30 can thereby be integrated in already-provided components, whereby the vehicle unit fastening subassembly 10 can be constructed in a particularly cost-effective manner.

[0067] FIGS. 6a to 6c are schematically simplified sectioned illustrations of different possible forms of a vibration damper 16, in particular a bearing core 18 and a suspension spring 20.

[0068] The bearing cores 18 according to FIGS. 6a and 6c are cross-shaped in section whilst the bearing core 18 according to FIG. 5b is T-shaped. The suspension spring 20 is in each case arranged in an appropriate manner on the bearing core 18.

[0069] FIG. 7 shows the vibration damper 16 from FIG. 1 in a carrier, wherein the vibration damper 16 is mounted without a hydraulic unit 22. Without the hydraulic unit 22, the vibration damper 16 acts as a conventional bearing.

[0070] The vibration damper 16 can consequently be a component of a modular system and optionally be used together with the hydraulic unit 22 as a hydraulic vibration damper or without the hydraulic unit 22 as a conventional bearing.