DE4432082A1 - Safety bumper for cars, - Google Patents

Abstract

The first of two energy absorbent media used, is reversibly deformable and has a first compressive modulus. The second is deformable with a larger modulus. At 50% and 10% compression, the ratio of its moduli is 1.5 at the greatest. The first medium absorbs a first impact energy by compression at least for a time, while the second medium is compressed by no more than 10%. Its deformable volume is dimensioned to absorb no more than 60% of a second impact energy. The first medium is foam with a ratio of moduli between 2 and 3, at 50% and 10% compression. Its modulus is smaller, near 50% compression. Its volume is so dimensioned, that it absorbs a first impact energy, by no more than 50% compression, at least for a time, whereas the second foam is compressed by no more than 10%. A variety of foams may be used, such as polypropylene, polystyrene, and polyurethane foams in suitable half-hard, and EA or 'energy-absorbing' modified grades may be used.

Description

The present invention relates to a novel bumper based on energy absorbent foams, in particular for the equipment of strength vehicles.

Flexible energy absorbing foams have already been used to avoid Damage to the motor vehicle at low impact speeds of less than 4 km / h used. Such foams should on the one hand be sufficient have a pronounced compressive stress hysteresis effect on the one hand To ensure sufficient energy absorption, but on the other hand after a Compression due to an obstacle impacting its original shape take again and a sufficient compression hardness for a new impact preserve. The upsetting stress hysteresis effect must therefore not be too great being shaped.

Bumpers come for higher impact speeds of 8 or up to 18 km / h constructions for use in which the energy absorption by irreversible Deformation of the cross members and side members of the vehicle chassis, or for this purpose seen parts of it. However, this requires considerable repair effort after an impact.

According to the invention, it is now proposed for energy absorption in the area a brittle energy absorbing foam at the higher speed use, which is irreversibly deformed in the event of an impact, the Replacement, however, requires a significantly reduced repair effort. Of the Foam is made with a reversibly deformable shock absorbing agent  combined, the reversibly deformable agent bumps with impact speed in the lower speed range.

The present invention accordingly relates to a bumper based containing energy absorbing foams

• - first energy absorbing reversibly deformable means of a first Compression hardness, and
• - Second energy absorbing deformable agent consisting of foam with a second larger compression hardness with a ratio of compression harden at 50% compression and at 10% compression of at most 1.5.

Preferably, the first means should at least have an impact energy under compression can absorb temporarily, the foam layer not more than 10% is compressed. The first impact energy can impact one Motor vehicle on a wall at a speed of 3 to 5 km / h correspond.

The deformable volume of the foam of the second agent should preferably be such that a second impact energy while compressing the Foam is absorbed by no more than 60%. The second Impact energy of a motor vehicle colliding with a wall Correspond to speeds of 8 to 18 km / h.

In principle, all means known per se are the first deformable means Shock absorption suitable such. B. hydraulic damper, semi-elastic Damping modules, etc.

Preferably, the first deformable agent is a foam with a Ratio of compression hardness at 50% compression and at 10% compression of 2 to 3 used, the compression hardness of this first foam compared to the second foam (second deformable agent) at least in the area the compression is up to 50% smaller.  

The deformable volume of the first foam (first deformable means) dimensioned so that a first impact energy under compression of this first foam at least temporarily absorbed by no more than 50% can be, with the second foam compressed by no more than 10% becomes.

Any foams can be used as foams for the first and second deformable agents Foams that meet the above conditions are used. The absolute compression hardness of the foams only determines what is required deformable foam volume. For example, the compression hardness of the first Foam with a compression of 50% at 120 to 250 kPa and the Compression hardness of the second foam at 50% compression at 150 to 400 kPa lie.

To select the foams suitable according to the invention, the quasi-static measured compression hardness are used as the influence of the Deformation rate on the compression hardness in the here for discussion standing area is small.

Polypropylene, polystyrene or others are suitable for the first foam thermoplastic foams, especially semi-rigid polyurethane foams as described in the Handbook of Polyurethanes.

Foams suitable for the second deformable agent are rigid polyurethane foams, rigid polyisocyanurate foams or polyiso containing polyurethane rigid cyanurate foams that are used as EA foams (EA = energy absorbing) Have found their way into technology, such as B. in US-A 4 866 102 and US-A 5 232 957.

The invention is explained below with reference to the accompanying figures.

The reference symbols in the figures denote in detail:

A the or the side members of a motor vehicle chassis
B the cross member of a motor vehicle chassis
D the bumper trim
I the first deformable agent
II the second deformable agent.

Fig. 1 shows schematically the structure of a bumper according to the invention with a mechanical damping module I and a foam II, which are arranged between the cross member B of the motor vehicle chassis and the bumper trim D.

Fig. 2 shows an alternative embodiment of the invention, are used in the first deformable means hydraulic shock absorbers I. In the event of a frontal impact, the impact energy is first transferred from the bumper trim D via the foam II and the cross member B to the hydraulic bumper I.

The hydraulic bumpers I are designed so that they have an impact energy absorb an impact at a speed of at least 4 km / h can. Due to the compression hardness of the foam II, this is not yet deformed to absorb energy. At higher impact speeds, too the foam II deformed. According to the invention, this is dimensioned so that that an impact energy that corresponds to an impact of at least 8 km / h, can be absorbed without the longitudinal beams A being destroyed.

Fig. 3 to 5 show preferred embodiments of the inventions, in which used as a first deformable means is a foam I.

Fig. 6, the compression / voltage (Stauchhärte-) shows two characteristic according to the invention suitable foams I and II. The values were determined at a compression speed of 500 mm / min (quasi-statically).

Fig. 7 shows the delay characteristic

of a bumper according to the invention, in which a foam I according to FIG. 6 with a dimension of 50 × 200 × 150 mm³ and a foam II according to FIG. 6 with a dimension of 200 × 200 × 1500 mm³ were used. The deceleration is shown depending on the deceleration distance for the impact of a mass of 1t at different speeds. The arrows indicate the deceleration distance in the event of an impact at 1 m / s (3.6 km / h) or 4 m / s (14.4 km / h).

Claims (5)

1. Containing bumpers based on energy-absorbing foams

• - first energy absorbing reversibly deformable means of a first compression hardness, and
• - second energy absorbing deformable means consisting of foam with a second greater compression hardness with a ratio of compression hardness at 50% compression and at 10% compression of at most 1.5.

2. The bumper of claim 1, wherein the first means a first impact energy can absorb at least temporarily under compression, the Foam (second deformable agent) by no more than 10% is compressed. 3. A bumper according to claim 1 or 2, wherein the deformable volume of Foam is dimensioned so that a second impact energy under compression of the foam cannot be absorbed by more than 60%. 4. Bumper according to one of claims 1 to 3, wherein the first means Foam with a ratio of compression hardness at 50% compression and at 10% compression is from 2 to 3, and the compression hardness in comparison to the second foam (second deformable agent) at least in The range of compression is up to 50% smaller. 5. The bumper of claim 4, wherein the volume of the first foam is so dimensioned that a first impact energy while compressing this first Foam absorbed by no more than 50% at least temporarily the second foam by no more than 10% is compressed.