WO1999015365A1 - Bumper, and the fabrication thereof - Google Patents

Abstract

The present invention relates to a structural beam or bumper and the fabrication thereof. The structural beam or bumper, especially for a vehicle, comprises an elongated profile which upon collision is adapted for absorbing collision energy and forces. The bumper is prepared from a complete and hollow blank (B) and is further provided with different cross sections along its more or less arched extension, the bumper has an unchanged, compressed or folded cross section (3) at the areas of each of the terminal portions and a substantially unchanged basic cross sections (4) at each side of its centre (5). At its centre (5) the bumper is provided with an outwardly pressed cross section relative to said basic cross section whereby at least one part of the interior section of the structural beam or bumper is divided by at least one protrusion or one dividing wall (1d), whereby the interior section of said beam in this part comprises at least two chambers. In the reforming of the bumper the dividing wall transmits forces in a manner that simplifies the process. In crash situations, the dividing wall will reduce the risk of buckling and prematurely cross section collapse, while more elastic and plastic energy can be absorbed.

Description

BUMPER, AND THE FABRICATION THEREOF

Field of the invention

The present invention relates to an improved structural beam, or bumper especially for a vehicle, comprising an elongated profile which upon collision is adapted for absorbing collision energy and forces, the bumper being prepared from a complete and hollow blank and being further provided with different cross sections along its more or less arched section.

The invention also relates to a method for fabrication of such a structural beam or bumper.

Prior art

The applicants own patent application WO 97/27082 discloses a structural beam or bumper prepared from a complete and hollow blank being provided with different cross sections along its more or less arched extension. The bumper has a compressed or folded cross section at the areas of each of the terminal portions while the cross sections at each side of its centre are substantially unchanged. The centre of the bumper is provided with an outwardly pressed cross section. The manipulated cross section of the bumper contributes to an improved bumper with very good flexing characteristics. Meanwhile, bumpers of this type involving one single chamber will often require the use of quite comprehensive forming operations to achieve the desired shape of the bumper. Further, single chamber beams may be prone to buckling under high loads.

The present invention involves substantial improvements of such a structural beam or bumper and the fabrication thereof. Background of the invention

The motive of the present invention is the task of providing an improved bumper which combines the protection of a vehicle and persons in the vehicle upon collision. In addition, it is a further motive of the invention to provide an improved method for the fabrication of such a bumper.

The invention has for one of its objective to provide a bumper which excels in high torsional stiffness, combined with great bending softness.

A further objective of the invention is to provide a bumper rendering the possibility for rational and sturdy attachment to the frame of the vehicle.

An object of the invention is also to provide an elastic and relatively slender structural beam or bumper which in relation to previously known profile based, closed bumpers, may absorb more elastic and plastic bending energy in relation to quantity of used material.

Further, the invention relates to a method which renders a more rational and simplified production of profile based, closed bumpers where the method at the same time being specifically favourable for high rate forming in a production line.

Brief disclosure of the invention

These and other objects are achieved in a bumper of the type as stated in the preamble, which according to the preamble relates to a structural beam or bumper, especially for a vehicle, comprising an elongated profile which upon collision is adapted for absorbing collision energy and forces, the bumper being prepared from a complete and hollow blank and being further provided with different cross sections along its more or less arched extension, the bumper has an unchanged or compressed or folded cross section at the areas of each of the terminal portions and substantially unchanged basic cross sections at each side of its centre, where the bumper at its centre is provided with an outwardly pressed cross section relative to said basic cross section, and where the bumper has one outer wall portion and one inner wall portion. The bumper is characterised in that at least one part of the interior section of the structural beam or bumper is divided by at least one protrusion or one dividing wall, whereby the interior section of said beam comprises at least two chambers.

In accordance with the claimed bumper there is achieved favourable cross sections along the length of the bumper that sustain very good elasticity properties. Further, according to the invention, the manipulated cross section of the claimed bumper may be formed by a simplified forming operation.

A specific embodiment of such a bumper may involve that the cross section at the centre comprises an outer wall portion having larger height than that of the inner wall portion, slanted yoke portions interconnecting said outer wall portion and said inner wall portion, at least one dividing wall extending substantially perpendicularly from said inner wall portion and where the outer wall portion has a concave exterior face, that said cross section at each side of the centre comprises a less concave, flat or convex outer wall portion, an arched inner wall portion, as well as yoke portions extending substantially perpendicularly from said outer wall portion, and where the dividing wall extends substantially perpendicularly from said inner wall portion, and where the outer wall portion has substantially the same, or a little bit larger height as said intermediate cross section and where the inner wall portion is of lesser height, and that said cross section at the terminal portions has an outer wall portion having larger height as said intermediate cross section and an inner wall portion having larger height than the height of the inner wall portion at the centre, and further having intermediate arched, sharp cornered or wavy yoke portions.

Further, it is appropriate that this type of bumper comprises a closed cross section having an inner wall portion with a relatively large wall thickness compared to the dividing wall and the yoke portions, and where the outer wall portion is provided with relatively large wall thickness in its upper and lower parts, compared to the dividing wall and the yoke portions. Advantageously, the transitions of thickness in the walls of the cross sections of the bumper are smooth.

Further, it is to be understood that the outer wall portion can be substantially straight, or be provided with a more or less contoured shape. Further, appropriately, the terminal portions may be so prepared that the merge into attachment portions which are provided with individual grid, alternatively net parallel surfaces against associated side beam for attachment thereto.

Further, it is to be understood that the bumper may be prepared substantially symmetrically about a central plane extending in the longitudinal direction of the car, and be proved with an outer mantle of plastic material.

The method for fabrication of a such a structural beam or bumper comprises the use of various forming operations as the beam or bumper being prepared from a complete hollow blank where the interior of the blank is divided by at least one protrusion or one dividing wall, at least in the centre portion of the blank, whereby the dividing wall transmits forces between the outer- and the inner wall of the beam as the blank is processed to an outwardly pressed cross section in this portion. In other words, the dividing wall transmits forces in an advantageous manner in the forming operation of the bumper. In crash situations, the dividing wall will be an effective contribution to improve the energy absorbing properties of the bumper.

In one embodiment of the method, the processing of the blank takes place in a first stretching or pressing to a main shape, especially a vaguely arched shape in the longitudinal direction of the blank, whereafter the profile at the same time or in a subsequent processing operation is processed at the centre portion and compressed at the terminal portions. Preferably, the sections at each side of the centre remains unprocessed.

Advantageously, as a blank there is used an extruded profile having a closed cross section, said inner wall portion and the ends of the outer wall portion having relatively larger wall thickness than the wall thickness of the intermediate yoke portions and the dividing wall, and where the transitions of thickness in the walls of the cross sections of the bumper may be smooth. The enlarged front or outer walls are in particular advantageous in the forming operations of the blank, as these enlarged wall sections can be clamped under the forming operations and thereby improving the ability to manipulate the cross section of the blank to the desired form. Appropriately the bumper is manufactured by outer processing, said outer processing taking place by means of mechanical tools. Alternatively, hydroforming can be used.

Further advantages and specific features of the present invention will appear from the following description taken in connection with the attached drawings, as well as from the appended patent claims.

Brief disclosure of the drawings

Fig. 1 is a perspective view of a blank with reformed cross-sections,

Fig. 2 shows a schematic view as seen from above of a symmetrical half of a structural beam, especially a bumper beam according to the invention,

Fig. 3, 4, 5 are cross sections taken along the lines Ill-Ill, IV-IV, as well as V-V, respectively according to Fig. 2,

Fig. 6 shows a schematic distribution of forces when reforming the blank in the portion according to Fig. 3,

Fig 7 shows a schematic distribution of forces when reforming the blank in the portion according to Fig. 5,

Fig. 8 shows in an embodiment a cross section of a structural beam provided with two dividing walls,

Fig. 9 is a diagram that displays the ability of absorbing elastic energy in a beam according to the invention in comparison to a prior art beam.

Detailed description of embodiments

Figure 1 shows in a perspective view, a blank B with reformed cross-sections. The blank has an outer wall portion 1a and an inner wall portion 1b. In its centre portion 5, the blank is processed to a shape where the distance between the outer and inner wall portions is at a maximum along the length of the blank. Further the blank is compressed or folded in the portions 3. At the portions 4 between the centre portion 5 and said portions 3, together with the outermost ends of the blank, the original shape of the profile is substantially maintained. This shape comprises a flat or contoured outer wall portion 1a, an arched inner wall portion 1b, as well as yoke portions 1c extending substantially perpendicularly from said outer wall portion 1a. A dividing wall 1d extends substantially perpendicularly from said inner wall portion 1b, dividing the interior section of the blank into two chambers 1e and 1f. After forming, the blank may be further processed (not shown). Such processing may comprise cutting to obtain proper length, drilling or punching of holes, etc.

Figure 2 shows a schematic view as seen from above of a symmetrical half of a structural beam, especially a bumper beam according to the invention.

Figures 3, 4, and 5 represents cross sections taken along the lines Ill-Ill, IV-IV as well as V-V respectively, illustrated in Fig. 2. These cross sections corresponds respectively to the portions 3, 4, and 5 of the blank.

The beam or bumper rail as shown in Figures 2-5, is illustrated in its finished processed form, and is as such adapted for absorbing collision energy and forces when used in a car, it being preferably as a bumper, but also as a supporting beam in the overall structure of the car.

The bumper 1 is made from a complete and hollow extruded blank (B) which is manufactured from an extrudable material, for example aluminium, or any other materials or alloys having corresponding extrudable and strength-related properties. The blank has in its initial form a basic cross section 4 which is specifically illustrated in Fig. 4, and which comprises an outer wall portion 4a being flat or contoured, an arched inner wall portion (4b), as well as yoke portions (4c) extending substantially perpendicularly from said outer wall portion (4a), and where the dividing wall (4d) extends substantially perpendicularly from said inner wall portion (4b).

This basic cross section 4 is on both sides of the centre, see IV-IV in Fig. 2 and Fig. 4, according to the present invention maintained so to say unchanged, whereas at the centre portion itself, see V-V in Fig. 2 and Fig. 5, the basic cross section has been given an outwardly pressed cross section 5, whereas in the areas of the terminal portions, here at section Ill-Ill in Fig. 2, see also Fig 3, the basic cross section 4 has been compressed or folded to a further cross section 4, which is different from the basic cross section, alternatively has not been processed.

In other words, the bumper rail 1 is manufactured on the basis of a basic cross section on each side of the centre, and an outwardly pressed cross section at the centre in relation to said basic cross section, as well as a compressed or folded cross section in the areas of each of the terminal portions, alternatively unprocessed at the terminal portions.

It is to be understood that the transition between the basic cross section 4 and the centre cross section 5 and said terminal cross section 3, respectively, is gradual and smooth, and can, of course, be varied within large ranges.

Further, it is to be understood that the outer wall portion can deviate from the wall portion 4a as illustrated here, namely by being substantial straight, or be designed with a more or less contoured shape.

In the embodiment which is specifically illustrated in Figures 2-5, the cross section 5 at the centre, see specifically Fig. 5, is pressed out to a cross section where the concavity of the outer wall portion 5a has augmented. The inner wall portion 5b is straight and has substantially the same height h5 as the inner wall portion 4b of the intermediate cross section 4. At the same time there are provided substantially inclined yoke portions 5c between said straight inner wall portion 5b and said outer wall portion.

The cross section 3 at the terminal portions, see specifically Fig. 3, is in this embodiment compressed or folded to comprise a substantial straight outer wall portion 3a having substantially the same height H3 as the outer wall portion 4a for said intermediate cross section 4, see Fig. 4, as well as an inner wall portion 3b which is here folded out to a larger height h3 than said outer wall portion 3a, and then with intermediate arched or wavy yoke portions 3c. Alternatively the terminal portions are unprocessed. In the embodiment illustrated in Figures 2-5, the starting point is a cross section 4, see Fig. 4, which constitutes a closed cross section, the outer wall portion 4a at its ends 4a', 4a" and the inner wall portion 4b being provided with or comprising portions having a larger wall thickness than the wall thickness of the intermediate yoke portions 4c and the dividing wall 4d.

The Figures 6 and 7 shows a schematic distribution of forces as a blank is reformed.

Figure 6 shows the forming of a blank at its terminal portions, to obtain the cross section as shown in Fig. 3. The blank is compressed or folded by forces at the inner wall portion 3b, while these forces are opposed by forces at each end 3a', 3a" at the ends of the outer wall portion 3a.

Figure 7 shows the forming of the blank at its centre portion, see Fig. 5. Here the blank is attached or clamped at the ends 5a', 5a" of the outer wall portion 5a, while a force is applied at the centre of surface 5a, whereby the dividing wall 5d transmits forces between the outer- and the inner wall 5a, 5b of the beam as the blank is processed to an outwardly pressed cross section in this portion.

Figure 8 shows an alternative cross section of the blank in the outwardly pressed section. The blank is made out of a profile having two dividing walls 9d', 9d", dividing the interior section of the blank into three chambers 9e, 9f, and 9g. The area of the enlarged end portions 9a", 9a" of the outer wall 9a are preferably in sum of same magnitude as the area of the inner wall portion 9b.

In accordance with the claimed bumper, by having as a starting point a basic cross section which is more or less kept unchanged on each side of the centre, at the same time as the centre portion is processed to an outwardly pressed cross section at the centre and a compressed or folded cross section at the side portions or terminal portions, where the cross section comprises at least one dividing wall possible to achieve a specifically favourable resilient effect upon collision at velocities up to 4 km/h, and at velocities above 4 km/h will devise favourable collision qualities. The overall profile will be able to absorb more energy compared with corresponding bumper rails. Additionally, there is, by this form of profile rail, secured a very favourable torsional stiffness, since the hollow chamber profile is maintained and the bumper blank can be processed on the basis on continuous working blank.

It is to be understood that the profile or bumper rail can be made substantially symmetrical about a centre plane running in the longitudinal direction of the vehicle, and beyond this be provided with an outer mantle of plastic material.

If the structural beam according to the invention is to be used as a structural element in the vehicle as such, this symmetrical design can appropriately be alleviated.

Appropriately, the terminal portions may merge into attachment portions where said attachment portions being provided with a net parallel surface against side beams of the vehicle.

It is to be understood that the processing of the blank can take place by a first stretching to the basic shape, especially an arched shape in the longitudinal direction of the blank, whereafter the profile is simultaneously processed at the centre portion and the terminal portions.

Alternatively, said processing may be performed by means of hydroforming (not shown).

In Figure 9 the ability of absorbing elastic energy in a beam according to the invention in comparison to a prior art beam is displayed. The curves are established by measuring the displacement D of a beam supported at its terminal portions f1, f2, under the influence of a force F acting in the central portion of the beam.

The comparative diagram shows that the present invention beam is able to absorb more elastic and plastic energy than the prior art bumper.

This due to the beam being substantially less prone to buckling in the front wall and collapse of the cross section under bending loads.

Claims

Claims

1. Structural beam or bumper (1), especially for a vehicle, comprising an elongated profile which upon collision is adapted for absorbing collision energy and forces,

,- the bumper being prepared from a complete and hollow blank (B) and being further provided with different cross sections along its more or less arched extension, the bumper has unchanged, compressed or folded cross section (3) at the areas of each of the terminal portions and substantially unchanged basic cross sections (4) at each side of its centre (5), where the bumper at its centre is _f. provided with an outwardly pressed cross section relative to said basic cross section, and where the bumper has one outer wall portion (a) and one inner wall portion (b), characterised in that at least one part of the interior section of the structural beam or bumper is ₅ divided by at least one protrusion or one dividing wall (d), whereby the interior section of said beam in this part comprises at least two chambers.

2. Structural beam according to claim 1, characterised in that ₀ the dividing wall (d) is arranged between and interconnects the outer wall portion

(a) and the inner wall portion (b) of the beam.

3. Structural beam according to claim 1 , characterised in that ₅ the dividing wall divides the interior of the beam in two substantial equal sections.

4. Structural beam according to claim 1 , characterised in that ₀ the inner wall portion (b) have a relatively large wall thickness compared to the dividing wall (d).

5. Structural beam according to claim 1 , c h a r a c t e r i s e d i n that the outer wall portion is provided with relatively large wall thickness in its upper and lower parts (4a", 4a'), compared to the dividing wall (4d).

6. Structural beam according to any preceding claim, c h a r a c t e r i s e d i n that the cross section at the centre (V-V, 5) comprises an outer wall portion (5a) having larger height (H5) than that (h5) of the inner wall portion (5b), slanted yoke portions (5c) interconnecting said outer wall portion and said inner wall portion, at least one dividing wall (5d) extending substantially perpendicularly from said inner wall portion and where the outer wall portion has a concave exterior face, that said cross section (IV-IV, 4) at each side of the centre comprises a flat or contoured outer wall portion (4a), an arched inner wall portion (4b), as well as yoke portions (4c) extending substantially perpendicularly from said outer wall portion (4a), and where the dividing wall (4d) extends substantially perpendicularly from said inner wall portion (4b), and where the outer wall portion (4a) has substantially the same, or a little bit larger height (H4) as said intermediate cross section (V-V, 5) and where the inner wall portion (4b) is of lesser height (h4), and that said cross section (Ill-Ill, 3) at the terminal portions has an outer wall portion (3a) having larger height (H3) as said intermediate cross section (V-V, 5) and an inner wall portion (3b) having larger height (h3) than the height (h4) of the inner wall portion at the centre, and further having intermediate arched or wavy yoke portions (3c), alternatively the terminal portions or parts thereof, are unchanged.

7. Structural beam according to any preceding claim, c h a r a c t e r i s e d i n that at least one part of the interior section of the structural beam or bumper is divided by two protrusions or dividing walls (d), whereby the interior section of said beam in this part comprises least three chambers.

8. Method for fabrication of a structural beam or bumper as defined in claims 1 - 7 from a complete hollow blank (B), involving the use of various forming operations, c h a ra cte ri s e d i n that the beam or bumper being prepared from a complete hollow blank where the interior of the blank is divided by at least one protrusion or one dividing wall (d), at least in the centre portion (5) of the blank, whereby the dividing wall (5d) transmits forces between the outer- (5a) and the inner wall (5b) of the beam as the blank is processed to an outwardly pressed cross section in this portion.

9. Method according to claim 8, characterised in that the processing of the blank (B) takes place in a first stretching or pressing to a main shape, especially a vaguely arched shape in the longitudinal direction of the blank, whereafter the profile at the same time or in a subsequent processing operation is processed at the centre portion (5) and the terminal portions (3).

10. Method according to claim 8, characterised in that as a blank (B) there is used an extruded profile having a closed cross section, said inner wall portion (8b) and the ends (8a", 8a') of the outer wall portion having relatively larger wall thickness than the wall thickness of the intermediate yoke portions (8c) and the dividing wall (8d).