DE19858903B4 - Reinforcing element for a hollow body, in particular for a vehicle body spar, method for introducing such a reinforcing element into a hollow body and vehicle body with such a reinforced body spar - Google Patents

Abstract

Reinforcing element for a hollow body, in particular for a vehicle body spar, which is composed of a carrier (2) and an associated foamable mass (5), wherein the reinforcing element (1) in the hollow body (20) can be introduced, and the mass (5) is arranged on the carrier (2) and is present in such an amount that the foamed mass (5) is able to keep the carrier (2) in the hollow body, characterized in that the carrier (2) and / or the foamable Mass (5) has at least partially an outer contour adapted to the inner contour of the hollow body (20), in which a positional fixation of the reinforcing element (1) within the hollow body (20) is achieved when the reinforcing element (1) is inserted into the hollow body (20) even when not foamed ) he follows.

Description

The invention relates to a reinforcing element for a hollow body, in particular for a vehicle body spar, a method for introducing such a reinforcing element into a hollow body and to a vehicle body with such a reinforced body spar.

The body of a vehicle should be as light as possible and still have sufficient rigidity z. B. to be able to achieve good driving dynamics values. The driving behavior of a vehicle is namely not insignificant z. B. determined by a sufficient torsional rigidity of the body. In addition, certain areas of the body, eg. As the parts that form the passenger compartment, be so resistant that in accidents for the occupants a sufficiently large survival space remains. Particularly critical here is the area of the B-pillar and its connection to the upper and lower side rail. Various proposals have already been made in order to prevent intrusion of the sidewall into the passenger compartment with simple means in the event of a side collision.

So will in the DE 197 10 894 A1 proposed to provide the side skirts with transverse walls that stiffen this scotch. In this way, good results can be achieved. The assembly is complicated.

Furthermore, it is proposed u. a. the side rails and the B-pillar, which usually consist of two half-shells welded together at their flange-like edges, are to be provided with a further intermediate wall which lies between the connecting flanges and is welded thereto. The disadvantage here is that a significant increase in weight is recorded by the additional wall. In addition, welding of three layers is extremely critical, especially when it comes to galvanized sheets.

It is also proposed ( DE 40 16 730 C2 ) To insert pipes in the spars. Again, there is the problem of weight gain. In addition, it means some effort to fix these tubes in the bars. For this purpose, separate blocks must be provided so that a high effort must be operated for the installation of the pipes.

Furthermore, z. B. in the DE 195 46 352 A1 proposed to completely fill the spars of the vehicle with aluminum foam. Although this foam is relatively light, yet contributes, since large areas must be filled, not inconsiderable to the weight of the vehicle. In addition, it is difficult to clearly portion and control the amount of foam. It should therefore not be easy to prevent it from foaming bulges of the body spars comes and closing of vacant openings for fasteners.

The compromise solution currently being used by vehicle manufacturers for an acceptable cost-benefit ratio is to provide additional stiffening sheets. However, in this solution, a significant increase in weight of the vehicle body must be taken into account.

From the DE 196 48 164 A1 a reinforcing element according to the preamble of claim 1 is known. The carrier of the reinforcing element is designed as a load-bearing structural component of the body and therefore has to be laboriously attached to this.

From the DE 298 12 841 U1 is a flexible reinforcing element is known, which can also be inserted through curves in a hollow body to be positioned in hard to reach areas of the hollow body. Spacers may be provided on the carrier, through which a centering of the reinforcing element takes place within the hollow body. However, these spacers must allow a displacement and rotation of the reinforcing element in order not to hinder the insertion of the reinforcing element.

From the JP 07-117728 A For example, a reinforcing member having a carrier and a foamable mass mounted thereon is known. The foamable mass in this case has a sticky surface, via which the reinforcing element can be fastened in non-foamed state on the inner wall of the hollow body.

The invention is thus based on the object to represent a reinforcing element for a hollow body, which can be manufactured inexpensively, is easy to use, is as light as possible and a significant contribution to the stiffening or reinforcement z. B. is able to afford a vehicle body.

It is therefore proposed a reinforcing element, which is composed of a carrier and an associated foamable mass, wherein the reinforcing element is introduced into the hollow body and wherein the mass is arranged on the carrier and in such an amount that the foamed mass in the Able to hold the carrier in the hollow body. Furthermore, the carrier and / or the foamable mass at least partially an adapted to the inner contour of the hollow body outer contour, takes place in the non-foamed state, a positional fixation of the reinforcing element within the hollow body when introduced into the hollow body reinforcing element.

The invention thus presents itself as a clever combination of a pipe reinforcement and the reinforcement by foaming. The particular advantage is that on the one hand no complicated assembly steps are necessary to fix the tube in the hollow body positive and non-positive, and on the other hand only small areas, namely the space between the carrier and the hollow body is filled by a foam, which in particular keeps the material costs low.

The foam not only has the task to position the carrier in the hollow body, but rather contributes to the reinforcement of the hollow body itself. The effects are more pronounced the larger the sections of the gap which are filled with foamed material. Therefore, at least one or more sections of the gap should be completely foamed. The result is optimal, at least with regard to a particularly good stiffening, when almost the entire gap is filled.

Furthermore, it has been found that the carrier by no means must be solid in order to achieve good stiffening values, but can even be executed hollow, z. B. as a pipe. The tube in the outer diameter needs to be only slightly smaller than the hollow body to be stiffened, so that only a relatively small gap remains. This has the consequence that only little aufzuschäumende mass needs to be used and the weight increase is low.

The pipe itself is made of a metal sheet. It has been shown that plastic pipes, z. B. made of polyamide, partly as good results, if not better. This results in the advantage that such plastic pipes are inexpensive to manufacture, almost arbitrarily shaped and thus the shape of the hollow body can be adjusted. It is also conceivable to manufacture the tubes from extruded profiles, preferably from extruded aluminum profiles.

With little effort, the reinforcing effect can be improved by the pipe with bulkheads, z. B. is provided with intersecting reinforcing plates. A reinforcing effect is already achieved when distributed on the inside of the tube on the circumference several inwardly directed longitudinal webs.

The foamable mass is attached to the carrier and provided with a contour corresponding to the inner contour of the hollow body at least in individual points. In this way it is achieved that the carrier with the not yet foamed mass only has to be inserted into the hollow body, so that he assumes there a predefined position. It then no further aids must be used to fix the carrier with the not yet foamed mass in the hollow body until the foaming takes place. But also the carrier can be provided with outer elements which protrude through the mass and come into contact with the inner wall of the spar, so as to allow a positioning. Since at this stage only in individual points a contacting of the foamable mass with the inner wall of the hollow body, there remains a sufficiently large gap between the mass and the inside of the spar, so that z. As agents that are introduced for rust protection or to prepare a paint in the hollow body, can get to all points of the hollow body. Otherwise, the contour of the mass to be foamed will orient itself to the amount necessary to fill the gap. The local quantity is adapted to the variation of the gap width.

Organic materials which swell and harden under the influence of temperature to form a structural foam have proven useful as the composition to be foamed. This is an expandable synthetic rubber, in particular an epoxy-based solid composition treated with an amino compound to which various modifiers, especially ethylene-based copolymers, are added. The material also contains a compound that releases nitrogen when heated.

This material is solid enough in the ground state to z. B. to be handled by a robot without a change in shape occurs. It is also easy to work with and can in a simple way with the carrier z. B. be connected by gluing.

The material has the property of foaming and hardening when exposed to heat (about 150 ° C). The result is a foam with closed cells, in which the released nitrogen is. This makes it possible, in particular in the field of bodywork, to use the following method in order to provide a hollow body or a body spar with such a reinforcing element.

Body spars are usually made from two half-shells. The method consists of the material to be foamed coated carrier in the insert a half shell, which results in a positional fixation by the selected outer contour of the mass to be foamed. Then the spar is closed by the other shell and the two shells welded together. The fixation ensures that the spar can be moved freely, without the reinforcing element in the spar shifts or twisted.

The beam prepared in this way becomes part of a vehicle body, which, once fully assembled, is dip-coated. To dry and cure the coating, the body is placed in an oven. The prevailing temperature causes the material to foam and, as explained above, fills the space between the support and spar in the desired mass. The hardened foam forms a resistant sheath of the carrier. This results in an intimate connection between the carrier and the spar, which is now stiffened both by the carrier fixed by the foam and by the foam itself.

One possible application of such reinforcing elements is the stiffening of the roof rail of a vehicle in the node to the B-pillar. The reinforcing element is introduced into the roof rail above the B-pillar as described above, wherein the ends of the reinforcing element, as it is slightly longer than the width of the B-beam, protrude into the closed areas of the roof rail. A foamed reinforcing element placed there shows the result that the penetration depth of the B-pillar is reduced in standardized side impact tests compared to a non-stiffened spar.

In principle, all areas of the body can be stiffened, which are formed by a hollow body, such. As the side skirts, the B-pillar and the side members, which in particular must be secured against lateral load, and all spars, where there is a tendency to invade or buckle under load of any kind. It would also be conceivable to reinforce in this way the recessed in the doors reinforcing bars themselves.

In the following, the invention will be explained in more detail with reference to an embodiment and an application example. Show this

1 a reinforcing element in perspective view,

2 a vehicle body with such reinforcing elements and

3 a section through the roof rail of a vehicle body with a not yet foamed reinforcing element.

First, on the 1 Referenced. The reinforcing element 1 consists of a tube 2 used as a carrier for a foamable mass 5 acts. The pipe 2 is by means of two in the interior of the tube arranged crosswise and extending in the longitudinal direction reinforcing plates 3 . 3 ' strengthened. The one sheet 3 ' is slightly longer than the other, so that its end area acts as a grip tongue, the z. B. a robot gun during assembly can be taken.

The pipe 2 and the reinforcing sheets 3 . 3 ' can be made of a thin sheet metal, but also versions in plastic, z. B. polyamide are conceivable.

The pipe 2 is over its entire circumference and its entire length with a foamable mass 5 cases. This is a material or a material composition that foams or under the action of heat and forms a relatively light but stable structural foam. But even the unfoamed mass 5 has sufficient strength, so that the reinforcing element 1 can be handled easily.

The outer contour of the mass 5 has roughly the shape of a dumbbell. The two thickenings 6 . 6 ' at the ends of the pipe 2 , each with a plurality of recesses distributed on the circumference 7 are provided, serve to the reinforcing element 1 z. B. to position in a vehicle body spar. That is, after the reinforcing element 1 has been introduced into the spar, it should be immovable there, so that it undergoes no change in position in the spar during further assembly of the vehicle body. Therefore, the thickening correspond 6 . 6 ' the inner contour of the spar.

With the recesses 7 is achieved, inter alia, that the contacts of the recesses 7 limited surveys 7 ' with the inner wall of the spar are as small as possible. In addition, the recesses effect 7 in that means for cleaning the spar of grease residues and for interior preservation can reach all points of the spar. The dumbbell presentation is only an example.

Otherwise, the distribution corresponds to the mass 5 around the pipe 2 the amount required in each case to the possibly varying in size gap between pipe 2 and Holm fill in locally. In addition, a certain amount of the foamed material should be able to penetrate into any existing side rails in order to optimally reinforce the knot formed by the spar and side spar. These are two humps 8th . 8th' provided that partially engage in the non-foamed state in the side rail and thus contribute to the fixation of the reinforcing element in the spar.

In addition, in the lateral surface of the reinforcing element 1 several depressions 9 provided, the holes in the spar for fasteners opposite each other. As a result, less foamable mass is available at the corresponding points, so that the holes remain free after foaming and fastening clips can be used without difficulty.

As already explained, such a reinforcing element 1 inserted in the half shell of the spar. Subsequently, the spar is closed by the other half-shell, wherein the two shells are welded together. The foaming and curing takes place in an oven into which the body, after being in a coating dip, is brought to cure and dry the coating. At the temperature of approx. 150-180 ° C prevailing in the oven, the selected material foams up in such a way that the space between the pipe and the bar is completely filled.

2 shows a typical vehicle body 10 with a front end 11 in which normally a drive motor is housed, a passenger compartment 12 and a rear car 13 with a trunk. The passenger compartment 12 includes a bottom plate 14 as well as two side walls 15 . 15 ' each made up of a side sill 16 , an A-pillar 17 , a B-pillar 18 and a C-pillar 19 consist. In the transition to the roof of the vehicle each extending a roof spar 20 ,

In standardized side impact tests it has been shown that in particular the transition of the B-pillar 18 in the roof rail 20 is critical. The use of the reinforcing element described above at this point produces the necessary rigidity, whereby a buckling of the knot is prevented. This is achieved in particular by the fact that the reinforcing element 1 with its two ends in the closed areas of the roof rail 20 engages, and the amount of the foamable material is selected so that not only the said gap is filled, but a part of the foamed mass in the B-pillar 18 penetrates, so that the knot is stiffened very well overall.

Other uses are indicated in the drawing anyway. Thus, such a reinforcing element 1 also at other places of the roof rail 20 , in the B-pillar 18 , the A-pillar 17 or in the C-pillar 19 be used. Basically, all parts of the body that form cavities and that should be stiffened in one way or another are possible job sites.

3 shows an example in a sectional view of the arrangement of a reinforcing element 1 in the roof rail of a vehicle body. The cut was made transversely to the longitudinal axis of the spar in the region of one of the thickenings 6 . 6 ' , It can be seen first that the sectional contour of the reinforcing element is adapted to the cross-sectional shape of the roof rail. The surveys 7 ' Contact the inner wall of the roof spar, thus ensuring that the tube can not turn in the spar. The humps 8th . 8th' ensure the position assurance in the axial direction. The 3 should in particular make it clear that the reinforcing element 1 can be used in different cavities by adaptation to the given shape.

Not shown is an embodiment in which the tube is made of plastic and on the outer wall has a plurality of webs whose position and height are dimensioned so that they cause the pre-positioning in the spar. This has the advantage that the distribution of the mass around the carrier only needs to be designed in view of a good foaming of the gap. The reinforcement of the tube is made by some longitudinal ribs or ribs on the inside of the tube, which extend approximately to the center of the tube. The cross section of the tube is adapted to the cross section of the spar and z. B. for use in the roof rail above the B-pillar polygonal, the connecting surfaces between the corner straight lines are designed to be partly concave and partly convex.

Claims (12)

Reinforcing element for a hollow body, in particular for a vehicle body spar, consisting of a carrier ( 2 ) and an associated foamable mass ( 5 ), wherein the reinforcing element ( 1 ) in the hollow body ( 20 ), and the mass ( 5 ) on the carrier ( 2 ) and is present in such an amount that the foamed mass ( 5 ) is capable of carrying the carrier ( 2 ) in the hollow body, characterized in that the carrier ( 2 ) and / or the foamable mass ( 5 ) at least partially a to the inner contour of the hollow body ( 20 ) has adapted outer contour through which in the hollow body ( 20 ) introduced reinforcing element ( 1 ) already in non-foamed state a positional fixation of the reinforcing element ( 1 ) within the hollow body ( 20 ) he follows. Reinforcing element according to claim 1, characterized in that the foamable Dimensions ( 5 ) surrounds the carrier and is present in an amount that allows the gap between the carrier ( 2 ) and the hollow body ( 20 ) at least in one or more sections almost or completely filled. Reinforcement element according to claim 2, characterized in that the foamable mass ( 5 ) is present in an amount which allows the gap between the carrier ( 2 ) and the hollow body ( 20 ) completely. Reinforcement element according to one of the preceding claims, characterized in that the support ( 2 ) is made hollow. Reinforcement element according to claim 4, characterized in that the support is a tube ( 2 ), on whose outer surface the foamable mass ( 5 ) is attached. Reinforcement element according to claim 5, characterized in that the support ( 2 ) is made of plastic. Reinforcement element according to claim 5, characterized in that the support ( 2 ) inside with reinforcing walls ( 3 . 3 ' ) is provided. Reinforcing element according to one of the preceding claims, characterized in that the foamable mass ( 5 ) on the outside of the carrier ( 2 ) and such an outer contour ( 6 . 6 ' ) that the not yet foamed mass ( 5 ) at least in some points on the inside of the hollow body ( 20 ), or that the carrier ( 2 ) is designed so that in some points on the inside of the hollow body ( 20 ) is present. Reinforcing element according to claim 8, characterized in that the mass ( 5 ) has such an outer contour that only to the extent a contact with the inner surface of the hollow body ( 20 ) is that a continuous path between the reinforcing element ( 1 ) and the hollow body ( 20 ) remains. Method for applying a reinforcing element ( 1 ) according to one of the preceding claims in a clam shell hollow body ( 20 ) consisting of at least the following steps: - inserting the reinforcing element ( 1 ) in a half-shell of the hollow body ( 20 ) such that a positional fixation of the reinforcing element ( 1 ), - closing the hollow body ( 20 ) with the other half-shell, - connecting the two half-shells and - placing in an oven at a temperature at which the mass ( 5 ) foams and hardens. Method according to Claim 10, characterized in that - after the two half-shells have been joined together, the hollow body ( 20 ) is immersed in a coating bath, - that then the coating is cured in an oven, - and that the parameters of the foamable composition ( 5 ) are chosen so that this foams at the necessary for the curing and drying of the coating temperature. Vehicle body with a roof spar ( 20 ) and a B-pillar ( 18 ) and with a reinforcing element ( 1 ) according to one of claims 1 to 9, characterized in that the reinforcing element ( 1 ) in the roof rail ( 20 ) of the body ( 10 ), the carrier being a tube ( 2 ) and approximately in the middle of the B-pillar ( 18 ) and in the closed sections of the roof rail ( 20 ) on both sides of the B-pillar ( 18 ) is introduced.

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