DE19640754A1 - Radiation-welded bond to join bodywork panel to rolled strip - Google Patents

Abstract

The radiation-welded bond has the joint gap of the rolled strip (1) positioned in the preset connection zone of the bodywork panel (3). In this position, it is welded by radiation welding to the rolled strip in the region of the joint gap (2). The rolled strip should preferably be closed by welding at the same time. An edge part of the bodywork panel which is to be connected to the rolled strip may be laid against a zone reinforced by deformation before being welded to it. The joint gap may be formed by a flush abutment, which is covered by the bodywork panel.

Description

The invention relates to a composite of a body panel with a rolling profile the preamble of claim 1 and a method for its production.

It is known that the joining of sheets with one-piece flangeless hollow profiles, for example by rolling, hydroforming or extrusion are difficult with the usual joining processes in body construction. With CO₂ seam welding, a lot of heat is introduced into the components, which leads to Default. Spot welding and punch rivets cannot be used because these procedures require access to the joint from both sides. Roll profiles must be closed before connecting sheet metal to one To prevent or minimize delay.

Furthermore, it is known that with beam welding, in which the melting of the Materials of the sheet metal parts to be joined together along the joining gap the introduced thermal energy of a beam of high energy density is effected unilaterally welded, non-penetrating hidden seams for aesthetically exposed components or body areas can be produced. But also for load-bearing bodies Components, laser and electron beam welding are increasingly used puts.

The beam welding of thin sheets has compared to the resistance spot welding a number of advantages. These are due to the high energy density of the laser or Given electron beam, which has a high welding speed at a relatively low Heat input allowed, so that only a small delay and limited property tensions occur. Alloys of a different type can be joined together. The components produced can be further shaped. The continuous weld leads to a higher stiffness and strength of the component, especially when vibrating Stress. However, the use of beam welding requires - in the  As a rule, flanges that require additional material and have been specially prepared - one increased positioning accuracy and, associated with this, a sophisticated clamping technology as well as a special joint preparation to make it very strong in the joint area to be able to comply with reduced tolerances, which is the application of beam welding enable in the first place.

The object of the invention is a beam-welded composite of a body to create component with a rolling profile, taking into account the above Aspects can be produced with reduced effort and reduced weight.

The task is carried out with a composite of a body sheet with a rolling profile the preamble of claim 1 solved in that the joining gap of Roll profile is placed in the area of its circumference in which the body panel to be connected flangeless, in a particularly advantageous manner, that by the same beam welding connection with the rolling profile at the same time Roll profile itself is closed with. This saves weight on the composite by dispensing with flanges on the rolling profile that are turned outwards for welding of the body panel.

A particularly advantageous arrangement provides that the joint gap of the rolling profile through a butt joint is formed and that a single beam weld is placed is that both the connection of the body panel with the rolling profile and the Closure of the roll profile is effected.

But also the joining arrangement according to claim 3 or 4 is advantageous, according to which the Ver Binding the body panel to the rolling profile by means of a weld seam on both Sides of the butt joint is effected. This arrangement is characterized by a increased strength and reliability.

The joint gap of the rolling profile can also be formed by an overlap joint. The Body panel can then be on or between the overlapping ends of the roll profiles and be connected to both ends by a beam weld seam, whereby the rolling profile is also closed. When arranging the body sheet between the ends can have an advantageous tensioning effect, that the predetermined gap between the overlapping ends is smaller than that Is the thickness of the body panel.  

The measure according to claim 6 serves the increased requirements for Positioning accuracy in beam welding, the formation of a stop step or a bead as a positioning means for the body panel at a predetermined End of the roll profile represents an excellent variant, since this positioning means on can be easily introduced into the rolling profile during the rolling process.

The measure according to claim 8 enables the detection of a in a simple manner predetermined weld seam course and thus serves to control the beam welding device. As an alternative to this feature, one for a sensor system recognizable other orientation aid arranged on the rolling profile a light / dark contrast.

The feature contained in claim 9 advantageously serves to escape the Zinc gases when connecting galvanized body panels in rolled profiles.

The invention is explained below using exemplary embodiments. In the the accompanying drawing shows schematically:

Fig. 1 shows the arrangement of a body panel on a roll profile for an inventive laser-welded composite blunt joining shock,

FIG. 1a to 1c laser welds of this composite,

Fig. 1d shows a top view of the laser weld joint according to Fig. 1c,

Fig. 2 shows the arrangement of a body panel on a roll profile with the lap joint of an inventive laser-welded composite,

FIGS. 2a and 2b laser welds for this composite,

Fig. 2c shows a modified embodiment for the embodiment shown in Fig. 2 variant

Fig. 3 shows a further arrangement variant of a body panel on a rolling profile with lap joint and

Fig. 3a the associated laser weld joint.

In the exemplary embodiment shown in FIG. 1 of a laser-welded composite of a body panel with a rolling profile according to the invention, the rolling profile 1 has a joining gap 2 formed by a butt joint, which is covered by a body component 3 to be closed. At the left end of the rolling profile 1 according to the drawing, a bead 4 is arranged at a distance and parallel to the joining gap 2, which bead serves as a stop for the body panel 3 and as a positioning means for the laser welding arrangement. The connection of the body panel 3 to the rolling profile is provided by a single laser weld 5 or by two laser welds 6 and 7 . The latter are formed on both sides of the joint gap, as shown in Fig. 1b. These laser welding seams 6 and 7 are shown in FIGS. 1c and 1d as stitched seams with the stitching 6 a and 7 a.

In the embodiments of a laser-welded composite shown in FIGS . 1a to 1d, the body panel 3 is welded to the rolling profile 1 without flanges, the latter being closed directly ( FIG. 1a) or indirectly ( FIGS. 1b to 1d) by the laser welding connection. The joining gap 2 is formed on the rolling profile 1 by appropriate precautions in its manufacturing process in the predetermined connection area of the checker sheet 3 .

In the embodiment shown in FIG. 2, the rolling profile 1 has a joint gap 8 formed by an overlap joint, which is formed in the predetermined connection area of the body panel 3 on the upper right edge of the rolling profile 1 as shown in the drawing. At the overlapping end of the roll profile 1 is a parallel to the edge of the roll profile 1 and thus also parallel to the joining gap 8 aligned bead 9 is arranged, which serves as a stop for the body panel 3 and thus as a positioning means for the laser welding arrangement. The body panel 3 is arranged on the lap joint and thus above the joint gap 8 . FIGS. 2a and 2b show that the body sheet 3 in this arrangement ver by a single laser weld seam 5 with the rolling profile 1 is connected, through which the rolled profile 1 is also closed. In the embodiment according to FIG. 2b, the weld seam is formed on the edge of the body panel 3 resting on the bead 9 .

The embodiment shown in FIG. 2c shows for the rolling profile 1 a beam welding seam 5 a arranged at a distance from the connection of the body panel 3 . The hollow profile produced in this way is flangeless and takes up an edge region 3 a of the check sheet 3 on a corner region 1 a stiffened by deformation. This creates a very dimensionally stable bond.

Alternatively, the body panel in the embodiment according to FIG. 3 and 3a disposed between the forming the lap joint ends of the rolling profile 1, wherein the overlapping end having an opening formed to the interior of the roll profile bead 10 as positioning means for the body panel 3. The design is advantageous with regard to the clamping arrangement for the welding process.

The manufacture of such a laser-welded composite begins with the manufacture of a rolling profile 1 in a rolling process in which the sheet-like starting material is cut in several sections from an axis aligned parallel to the direction of advance to the predetermined profile. This creates a profile with an unclosed joint gap, the position of which in the profile can be predetermined by appropriate precautions on the rolling tools. The joining gap is now formed according to the invention in the predetermined connection area of the body panel as a butt joint or overlap joint of the two free profile ends. The roll profile produced in this way, with the joint gap formed in the intended arrangement area of the body panel, is fixed together with the body panel by suitable tensioning means, such that the body panel covers the joint gap or is arranged between the overlapping ends of the roll profile in the event of an overlap joint, and then Both components are laser welded together, at the same time closing the joint gap of the roll profile.

Claims (12)

1. beam-welded composite of a body panel with a rolling profile, in which the rolling profile has a joining gap, characterized in that the joining gap ( 2 ; 8 ) of the rolling profile ( 1 ) is positioned in the predetermined connection region of the body panel ( 3 ), and that the body panel ( 3 ) in the area of the joint gap ( 2 ; 8 ) with the rolling profile ( 1 ) without a flange by means of beam welding ( 5 ; 6 ; 7 ). 2. Beam-welded composite according to claim 1, characterized in that at the same time the rolling profile ( 1 ) is closed by the beam welding ( 5 , 6 , 7 ) carried out to produce the flangeless connection. 3. beam welded composite according to claim 1 or 2, characterized in that one with the rolling profile ( 1 ) to be connected to the edge portion ( 3 a) of the body panel ( 3 ) on a stiffened area by deformation ( 1 a) for beam welding. 4. beam welded composite according to claim 2, characterized in that the joining gap ( 2 ) is formed by a blunt butt and the body panel ( 3 ) is arranged to cover this, and that a single beam weld seam ( 5 ) is placed so that by this at the same time the connection of the body panel ( 3 ) with the rolling profile ( 1 ) and the closing of the rolling profile ( 1 ) is effected. 5. beam welded composite according to claim 2, characterized in that the joint gap ( 2 ) is formed by a butt joint and the body panel ( 3 ) is arranged to cover this, and that on both sides of the joint gap ( 2 ) a beam weld ( 6 , 7th ) is placed. 6. beam welded composite according to claim 5, characterized in that the two beam welds ( 6 , 7 ) are formed as quilting seams with staggered steps ( 6 a, 7 a). 7. beam welded composite according to claim 2, characterized in that the joining gap (8) is formed by an overlap joint, that the body panel (3) is arranged on or between the overlapping ends of the rolling section (1), and that the connection of Body sheet metal ( 3 ) with the rolling profile ( 1 ) and the closing thereof is effected by a single beam weld seam ( 5 ). 8. beam-welded composite according to one of the preceding claims, characterized in that the rolling profile ( 1 ) has at least one positioning means for the body panel ( 3 ). 9. beam-welded composite according to claim 8, characterized in that as a positioning means at a predetermined end of the rolling profile ( 1 ) for joining gap ( 2 ; 8 ) parallel stop step or bead ( 4 , 9 , 10 ) is arranged. 10. Beam-welded composite according to one of the preceding claims, characterized in that at a distance from the joining gap at a predetermined end of the rolling profile ( 1 ) is arranged a sensor-detectable step oriented parallel to the joining gap ( 2 ; 8 ), to which the beam welding seam ( 5 ; 6 , 7 ) runs parallel. 11. Beam-welded composite according to one of the preceding claims, characterized in that the rolling profile ( 1 ) has a corrugation or an equivalent surface structure in the region of the arrangement of the body sheet ( 3 ) to form degassing channels. 12. A method for producing a beam-welded composite according to claim 1 or claim 1 and one or more of the following claims, characterized in that a rolling profile ( 1 ) with a joining gap ( 2 ; 8 ) is produced in a rolling process, the joining gap ( 2 ; 8 ) formed by a butt joint or an overlap joint and its position on the rolling profile ( 1 ) is predetermined by the predetermined arrangement area of a body panel to be connected ( 3 ), and that the body panel ( 3 ) in its arrangement position on the rolling profile ( 1 ) is locked by suitable clamping means, and that the body panel ( 3 ) and the rolling profile ( 1 ) are then flangelessly connected to one another by beam welding, the rolling profile ( 1 ) being closed at the same time.