AXLE CARRIER OF A HYBRID CONSTRUCTION MODE

Abstract

The present invention relates to an axle carrier 1 and to a method for the production of the axle carrier 1. The axle carrier 1 has an upper shell 2 from an aluminum die-casting and a lower shell 3 from a fiber composite material. On a ribbed structure of the lower shell 3, an upper end 14 of the reinforcing ribs 9 is preferably configured so as to be widened such that the bearing face between the reinforcing rib 9 and the upper shell 2 is enlarged and, on account thereof, the strength of the axle carrier 1 produced is increased.

Claims

1. Axle carrier (1) for a motor vehicle, produced as a hybrid component from an upper shell (2) from an aluminum alloy and from a lower shell (3) from a fiber composite material, wherein the lower shell (3) has reinforcing ribs (9) projecting in relation thereto, which at least in regions are disposed in a cavity (21) that is formed between the upper shell (3) and the lower shell (2), characterized in that the upper shell (2) is produced as a casting, in particular a die-casting, and/or in that the reinforcing ribs (9) at the upper end 14 thereof, in the region of bearing on the upper shell (2), are configured so as to be widened.

2. Axle carrier (1) according to claim 1, characterized in that the upper shell (3) is configured as a component that is U-shaped in the cross section, the upper shell (3) in particular having longitudinal supports and transverse supports (18, 19), wherein the longitudinal supports and transverse supports (18, 19) are in each case configured so as to be U-shaped in the cross section.

3. Axle carrier (1) according to either of claims 1 and 2, characterized in that the lower shell (3) is configured so as to be planar, wherein tubes or cable ducts for routing connector lines are preferably provided in the lower shell (3).

4. Axle carrier (1) according to one of claims 1 to 3, characterized in that attachments to a motor vehicle body are configured from the fiber composite material of the lower shell (3), and/or in that attachments of suspension components are configured on the upper shell (2), wherein said attachments are conjointly cast in the casting.

5. Axle carrier (1) according to one of claims 1 to 4, characterized in that the reinforcing ribs (9) are configured from a fiber composite material and are integrally configured on the lower shell (3), or in that the reinforcing ribs (9) are coupled to the lower shell (3).

6. Axle carrier (1) according to one of claims 1 to 5, characterized in that the lower shell (3) is joined to the upper shell (2) in a materially integral manner by adhesive bonding, wherein the plastics of the fiber composite material are used as the adhesive, and/or a separate adhesive is used and optionally an additional form-fitting coupling is performed.

7. Axle carrier (1) according to one of claims 1 to 6, characterized in that the upper shell (2), so as to be oriented toward an internal side (13), has undercuts and/or clearances (16), the lower shell (3) and/or the reinforcing ribs (9) by way of the plastics engaging in a form-fitting manner in the clearances (16) and/or undercuts from behind.

8. Axle carrier (1) according to claim 1, characterized in that at least one sleeve (11) is disposed in a cavity (21) between the upper shell (2) and the lower shell (3) in such a manner that, when being coupled to a motor vehicle body, the upper shell (2) is pressed onto the motor vehicle body by means of the sleeve (11).

9. Axle carrier (1) according to claim 8, characterized in that a cover, in particular a washer (24) which at least partially covers the lower shell (3) is disposed on the external side (25) of the lower shell (3) so as to be in direct contact with the sleeve (11).

10. Method for the production of an axle carrier (1) having the features of at least claim 1, wherein the lower shell (3) is produced from a fiber composite material by injection molding or impact extruding, and the upper shell (2) is produced by casting, characterized in that the reinforcing ribs (9) that project in relation to the lower shell (3) at an upper end are not cured and/or are heated and, when the lower shell (3) is being pressed onto the upper shell (2), are widened in such a manner that a larger bearing face and/or coupling face of the respective reinforcing rib is configured on the internal side (13) of the upper shell (2), and/or in that plastics material of the reinforcing rib (9) is pressed into a clearance (16) and/or an undercut of the upper shell (2) and configures a form-fitting undercut.

11. Method according to claim 10, characterized in that the lower shell (3) and the reinforcing ribs (9) are produced separately and are subsequently intercoupled, the reinforcing ribs (9) being in particular injected into the upper shell (2) and being coupled to the lower shell (3) by a materially integral coupling, preferably plastics welding, or in that the reinforcing ribs (9) are produced by injection molding and are adhesively bonded into the upper shell (2) and are coupled to the lower shell (3) in a materially integral manner, in particular by plastics welding.

Description

[0034] The invention will be explained in more detail hereunder by means of exemplary embodiments that are illustrated in schematic drawings, in which:

[0035] FIG. 1 shows an axle carrier according to the invention in the assembly;

[0036] FIG. 2 shows a longitudinal sectional view according to B-B from FIG. 1;

[0037] FIGS. 3a) and b) show a reinforcing rib in a sectional view;

[0038] FIGS. 4a) and b) show an upper end of a reinforcing rib;

[0039] FIG. 5 shows a cross-sectional view according to A-A from FIG. 1; and

[0040] FIG. 6 shows a sectional view through the axle carrier having the sleeve.

[0041] The same reference signs are used for the same or similar components in the figures, even when a repetition of the description is omitted for reasons of simplification.

[0042] FIG. 1 shows an embodiment of an axle carrier 1 according to the invention in the assembly. The axle carrier 1 comprises an upper shell 2, a lower shell 3, and a ribbed structure having reinforcing ribs 9 for stiffening the upper shell 2. The reinforcing ribs 9 in FIG. 1 can be seen only through the opening 8 as said reinforcing ribs 9 are otherwise completely inside the cavity 21 of the axle carrier 1. The upper shell 2 in this exemplary embodiment is produced as an injected-molded component from an aluminum alloy. The lower shell 3 is composed of a fiber-reinforced plastics, wherein the fiber reinforcement preferably includes both long fibers as well as short fibers. The reinforcing ribs 9 are configured conjointly with the lower shell 3 so as to be integral thereto, and are composed of a short fiber-reinforced plastics. The fibers herein have a length of up to ten centimeters.

[0043] Furthermore, two attachment towers 4, 5 are attached to the upper shell 2. Said attachment towers 4, 5 serve for attaching the axle carrier 1 to the vehicle body. Stiffening portions 6, 7 which protrude into the attachment towers 4, 5 are optionally configured from the lower shell 3. The lower shell 3 per se is configured as a planar face without clearances, and closes the upper shell 2 across the entire area from below. The stiffening portions 6, 7 are angled upward, so as to point toward the upper shell 2, in relation to the planar plane of the lower shell 3, the former in turn closing off the attachment towers 4, 5. The attachment towers 4, 5 are produced as separate components and are connected in a materially integral manner to the upper shell 2. Said attachment towers 4, 5 form particularly designed attachment locations for other suspension parts and to this end are provided with attachment sleeves 11. Other attachment locations 10 for other suspension parts such as, for example, a stabilizer or a control arm, are likewise provided partially with attachment sleeves 11 for reinforcement.

[0044] The bearing 12 represents a further particularly configured attachment location. Said bearing 12 serves for attaching a torque support of the engine block and thus for supporting the torques of the engine block.

[0045] On account of the upper shell 2 being produced according to the invention from aluminum casting, the attachment towers 4, 5 can be integrally configured in a materially integral manner. The various attachment locations 10 and/or attachment sleeves 11 can likewise be conjointly cast in the aluminum casting. The upper shell can have mutually dissimilar wall thicknesses which in particular correspond to the predefined strength.

[0046] FIG. 2 shows a longitudinal section according to the section line B-B of FIG. 1. The reinforcing ribs 9 which in particular bear at least partially on an internal side 13 of the upper shell 2 can be readily seen. An upper end 14 of the reinforcing ribs herein is widened according to the invention, in particular according to the principle of a mushroom head. This is illustrated on the left side in relation to the image plane. This is shown in a detailed illustration in FIGS. 3a) and b). An upper end 14 of the reinforcing rib 9 is first heated, as illustrated by thermal rays 15. The heat can be applied by means of hot air, for example. The reinforcing rib 9 is thereupon pressed onto the internal side 13 of the upper shell 2. The upper end widens according to the principle of a mushroom head. A larger bearing face is thus provided but a materially integral connection is also generated at the same time. The reinforcing ribs 9 can have mutually dissimilar wall thicknesses W3, W4. The upper shell 2 can also have mutually dissimilar wall thicknesses W1, W2.

[0047] Alternatively however, according to FIGS. 4a) and b) it is also possible for the upper end of the reinforcing rib 9 to be provided with a V-shaped gap 17 or wedge, respectively, and to likewise fuse here by way of thermal rays 15 by hot air, for example. On account thereof, V-shaped splitting of the upper end 14 of the reinforcing rib 9 is supported when the latter is being pressed on, as is illustrated in FIG. 4b).

[0048] It is furthermore illustrated in FIG. 2, on the right side in relation to the image plane, that the upper end 14 of the respective reinforcing rib 9 penetrates a clearance 16 of the upper shell 2 and in particular configures an undercut in the manner of a mushroom head. An additional form-fitting coupling is provided on account thereof.

[0049] According to the cross-section of the section line A-A illustrated in FIG. 5, transverse supports 18, 19 are furthermore illustrated on the axle carrier 1. The upper shell 2 in the respective cross section has a U-shaped or hat-shaped configuration, respectively. Laterally projecting flanges 20, such that a hat-shaped configuration is configured, for example, can in this instance be coupled to the lower shell 3 in a materially integral manner, for example by adhesive bonding.

[0050] A sleeve which is disposed in a cavity between the lower shell 3 and the upper shell 2 is furthermore illustrated in FIG. 6. The sleeve bears on the internal side 13 of the upper shell 2 in form-fitting manner. A body screw 23 that penetrates the sleeve 11 is engaged from below by a disc or washer 24, respectively. The washer 24 bears on the sleeve 11 and by way of the force F presses the screw directly onto the upper shell 2. The washer 24 at the same time covers an external side 25 of the lower shell 3 such that any migrating or creeping of the fiber composite material of the lower shell 3 is avoided to the largest extent possible and does not have any effect on the strength of the screw connection established between the axle carrier 1 and the motor vehicle body.

LIST OF REFERENCE SKINS

[0051] 1Axle carrier [0052] 2Upper shell [0053] 3Lower shell [0054] 4Attachment tower [0055] 5Attachment tower [0056] 6Stiffening portion [0057] 7Stiffening portion [0058] 8Opening [0059] 9Reinforcing ribs [0060] 10Attachment location [0061] 11Attachment sleeve [0062] 12Bearing [0063] 13Internal side (to 2) [0064] 14Upper end (to 9) [0065] 15Thermal rays [0066] 16Clearance [0067] 17Gap [0068] 18Transverse support (to 2) [0069] 19Transverse support (to 2) [0070] 20Flange (to 2) [0071] 21Cavity [0072] 22Internal side (to 3) [0073] 23Body screw [0074] 24Washer [0075] 25External side (to 3) [0076] FForce [0077] W1Wall thickness [0078] W2Wall thickness [0079] W3Wall thickness [0080] W4Wall thickness