Subassembly for the mounting of a headlight

A deformable subassembly (1) for mounting of headlight in the region of a recess (5) in a wing (4) of a motor vehicle has a sealing channel body (6) connected to the wing (4) in the region of a joint with a motor vehicle bonnet. A headlight cup (3) for mounting the headlight is connected on one side to the sealing channel body (6) spaced from the wing (4). A lower side of the headlight cup (3) is connected to a bracket body (7) that is connected to a supporting structure (8) of the motor vehicle. The sealing channel body (6), headlight cup (3) and/or the bracket body (7) are configured to deform in the event of an impact with a pedestrian so that the risk of injury to the pedestrian is reduced.

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority under 35 USC 119 to German Patent Application No. 10 2008 026996.4 filed on Jun. 5, 2008, the entire disclosure of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a subassembly for mounting a headlight in the region of a recess in a wing of a motor vehicle. The subassembly has a deformation body.

2. Description of the Related Art

EP 1 577 610 A1 discloses a subassembly for the mounting a headlight of a motor vehicle. The subassembly has a headlight housing, a support body for the headlight housing and a deformation body connected fixedly to the support body. The support body is attached to the vehicle frame by a fastening device. The deformation body protrudes in the direction of illumination of the headlight over the headlight housing and is offset laterally with respect thereto. An impact against the headlight subassembly, in particular the impact of a pedestrian, is absorbed efficiently and gently.

A disadvantage of the known subassembly is that the deformation takes place exclusively in the region of the separate deformation body. Other parts of the subassembly cannot contribute to a relevant extent to absorbing an impact on the subassembly, in particular an impact of a pedestrian.

It is an object of the invention to provide a subassembly for mounting a headlight that provides enhanced deformation in the region of the wing and headlight of the vehicle in response to an impact of a pedestrian for reducing the risk of injury to the pedestrian.

SUMMARY OF THE INVENTION

The invention relates to a subassembly for mounting a headlight in a wing at a region of a joint with a motor vehicle bonnet that is connected to a sealing channel body. The subassembly also includes a headlight cup for mounting the headlight. The headlight cup is connected on one side to the sealing channel body and on a part of the sealing channel body spaced from the wing. Additionally, the headlight cup is connected on its lower side to a bracket body that is connected to a supporting structure of the motor vehicle. The construction unit formed by the sealing channel body, the headlight cup and the bracket body forms the deformation body.

The headlight cup is configured to be deformed in the event of an impact and also is mounted in a manner that it is suitable for deformation.

The sealing channel body preferably forms a deformation region of the deformation body. For example, the sealing channel body may be an angled strip, and preferably is a strip angled at a substantially right angle. The limbs of the angled strip preferably are connected to the wing and to the headlight cup, and a deformable indentation preferably is formed between the limbs. The deformation of the sealing channel body results primarily from the deformability of the indentation between the two limbs of the sealing channel body in the event of an application of force that has a predominant force component from above, such as the force generated by impact of a pedestrian. The force of the impact exerted on the wing is transmitted from the wing to the sealing channel body and causes the sealing channel body to deform in the region of its indentation. A certain degree of deformability also is provided in the region of the limbs, which can bend under the action of the force acting on the wing. The limb of the sealing channel body that is connected to the wing preferably has cutouts between the connecting region of the limb to the wing. The cutouts are open toward the free edge of the limb. The open cutouts enable the limb of the sealing channel body to buckle in the event of an impact force acting on the wing. Thus, the sealing channel body can be deformed particularly effectively in this region.

The limbs of the sealing channel body preferably are connected to the wing and the headlight cup by clinch connections. This connecting technique contains a multiple advantages. Better energy absorption by means of deformation can be ensured by adapting the clinching point spacings. The open cutouts of the sealing channel body preferably are positioned between clinching point arrangements. The cutouts at these positions achieve local weakening of the sealing channel body and hence provide a greater deformation distance in the event of an impact of a pedestrian, in particular an impact of a pedestrian's head. Finally, the connection of the sealing channel body with wing and/or headlight cup permits precise alignment of the headlight cup with respect to the wing during assembly. Therefore the headlight can be mounted in the headlight cup and aligned precisely with respect to the recess in the wing with a minimum expenditure of time. The headlight mounted on the headlight cup can be aligned precisely so that the headlight ends flush with the wing toward the visible outer side.

The headlight cup preferably has a receiving plate for the headlight. The receiving plate is connected to the wing, and a reinforcing component is connected to the receiving plate and to the sealing channel body. The reinforcing component defines a deformation region of the deformation body in addition to the above-described deformation region formed by the sealing channel body. The reinforcing component preferably is a frame part that has an outer periphery and one or more large openings inwardly from the outer periphery. Thus, the headlight cup preferably has a two-part design formed by the receiving plate and the reinforcing component. The headlight cup will deform in the region of the frame-shaped reinforcing component during an impact of a pedestrian while the relatively stiff receiving plate permits a precise mounting of the headlight. The reinforcing component is deformed substantially in the plane defined by the outer peripheral parts of the frame.

The reinforcing component preferably has a reinforcing component limb that is connected to the sealing channel body by clinch connections. Also the transition between the limb of the reinforcing component and other parts of the reinforcing component will deform in a specific manner in the event of application of a deformation force. The design of the sealing channel body with the limb facing the headlight cup and the design of the reinforcing component of the headlight cup with the limb that bears against the limb of the sealing channel body limits the connection of sealing channel body and headlight cup to the two limbs. The connection produced by clinching is particularly advantageous. Also, the spaces between the clinching point in this region are adapted to ensure optimum energy absorption by means of deformation.

A further deformation region of the deformation body preferably is formed in the bracket body between the supporting structure of the motor vehicle and the headlight cup, and particularly in the receiving plate of the headlight cup. The bracket body preferably has two bracket sections arranged at an angle to each other, and most preferably at a right angle to each other. A deformation region of the deformation body is formed by weakening the bracket body in the connecting region of the two bracket sections. The weakening is represented, for example, as a constriction of the bracket body in the connecting region of the two bracket sections. The bracket sections constitute separate components that are connected by clinch connections. Thus, the headlight cup and the headlight are positioned exactly by a defined arrangement of the bracket sections with respect to each other and by clinching the bracket sections in position.

The wing, the sealing channel body, the headlight cup and/or the bracket body preferably consist of sheet metal, in particular aluminum sheet. Aluminum sheet is best suitable for clinching sheet-metal parts, in particular deformed sheet-metal parts, to each other.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A subassembly in accordance with the invention for mounting a headlight is identified by the numeral1inFIGS. 1 to 3. The headlight includes headlight glass2, which is illustrated by dashed lines to show the outer contour thereof. The subassembly1has a headlight cup3for mounting the headlight, a wing4with a recess5that is matched to the cross-sectional shape of the headlight glass2, a sealing channel body6that is connected to the wing4, and a bracket body7that is connected to a lower part of the headlight cup3. The wing4is at the front left or right part of the motor vehicle and extends generally from the left or right wheel house to the area of the bonnet B or hood/trunk lid. The sealing channel body6extends along the side of the wing4closer to the center line of the motor vehicle. The bracket body7is connected to a supporting structure8of the motor vehicle, in the present case of a passenger vehicle. The supporting structure8extends generally in the longitudinal direction of the vehicle and is disposed lower than the sealing channel body6. The bracket body7is bolted to the supporting structure8.

The headlight cup3, the wing4, the sealing channel body6and the bracket body7are formed from aluminum sheet, and hence are best suitable for connection to one another by clinching.

The headlight cup3is of two-part design and comprises a receiving plate9and a frame10that are connected to each other by clinching. The headlight is positioned on and fastened to the receiving plate9. The frame10defines a reinforcing component with an outer periphery and one or more large openings inward of the outer periphery. The receiving plate9is substantially horizontal and the frame10is substantially vertical in the fitted position of the subassembly1. The upper peripheral part of the frame10facing away from the receiving plate9is connected by clinching to the wing5adjacent to the wheel house of the vehicle, as shown inFIG. 2.

The upper end of the frame10is not connected directly to the wing4, but rather to the sealing channel body6which, in turn, is connected to the wing4. As shown inFIG. 4, the sealing channel body6is a strip that is formed at a right angle with first and second limbs11and13. The first limb11of the sealing channel body6is clinched in an overlapping arrangement to a downwardly angled limb12of the wing4. The wing limb12bounds a joint between the wing4and a vehicle bonnet (not shown). The second limb13of the sealing channel body6is clinched in an overlapping arrangement to a limb14of the frame10. The wing limb12is arranged substantially vertically, and the frame limb14is arranged substantially horizontally. The clinching of the sealing channel body6to the wing4and the frame10of the headlight cup3enables the headlight cup3to be aligned vertically and laterally precisely with respect to the wing4and to be clinched in the position set.

An indentation15is formed between the first and second limbs11and13of the sealing channel body6. The indentation15ensures deformation between the limbs11and13of the sealing channel body6in the event of an impact of a pedestrian in the region of the wing4and the headlight glass2.FIG. 1illustrates a spherical test body16that impacts on the wing4in the region of the wing4and the headlight glass2and symbolizes the head of an impacting pedestrian.FIG. 1illustrates that the sheet metal of the wing4bulges in the region adjacent to the sealing channel body6under the action of the test body16.

Energy can be absorbed by deformation in the connecting region of the first limb11of the sealing channel body6to the limb12of the wing4by adapting the distances between the clinching points17, as illustrated inFIGS. 5 and 6. These figures also clarify that further deformation distance is available to the pedestrian local weakening of the first limb11of the sealing channel body6by cutouts19that open toward the free edge18of the limb11. The cutouts19can be curved as in the embodiment ofFIG. 5or rectangular as in the embodiment ofFIG. 6.

The two-part design of the headlight cup3with the frame10results in a further deformation region because the large interior openings of the frame10permit the frame10to be deformed by bending or buckling in the event of an impact.

The bracket body7has two bracket sections20and21that are arranged at a right angle to each other and connected to each other by clinching. Thus, the two bracket sections20and21can be aligned precisely with one another before clinching to achieve precise alignment of both the horizontal bracket section20and the headlight cup3. The bracket section20also is clinched to the headlight cup3, and specifically to the receiving plate9thereof. The two bracket sections20and21have a weakening constriction22in their connecting region. The constriction22defines a further deformation region in the subassembly1by permitting the angular position of the two bracket sections20and21to change to an acute angle in the event of an impact.

The subassembly1therefore has plural components with individual deforming distances in the event of an impact of a pedestrian. More particularly, the wing4, the sealing channel body6, the headlight cup3in the region of the frame10thereof, and the bracket body7in the region of the constriction22all can be deformed.