EP1830003A1 - Impact damper with segment boards - Google Patents

Abstract

The lock supports (2) have an outer sleeve (4) and a lock section (5) that are connectable to one another. The lock section may be connectable with the outer sleeve via a snap connection (1). The outer sleeve has an upper (4a) and a lower section (4b) that are connected together via a shaped linkage (7). The upper section of the outer sleeve may be slidably connected with the lower section in the direction of a rotary axis (R).

Description

The invention relates to impact absorbers for damping the impact of a vehicle against an obstacle and / or the returning of vehicles to the road, with a plurality of plastically deformable damping elements, which are provided with segment plates.

Generic impact absorbers are known from the prior art. At the damper construction off DE 20 2004 011 701 plastically deformable damping elements are arranged in rows next to one another so that the entire damper construction forms the shape of a V. The individual damping elements are secured by means of a prestressed connecting cable. In the case of an impacting vehicle, the damping elements are deformed by a predetermined deformation characteristics by intermediate pieces and are supported in the rear end region against a fortified support from.

Another generic impact absorber is from the US Pat. No. 6,863,467 known. In this damper construction, two rows of elastically deformable, different-sized damping elements are arranged, which are connected to a frame structure so that the impact damper has the shape of a V. The individual damping elements are provided on the outside with baffle-deflecting plates and on the inside with compression elements. In the rear of the crash cushion, a support is arranged.

Although the from the DE 20 2004 011 701 known generic impact absorbers for cars has excellent performance, in order to work well for heavy vehicles, the wall thicknesses of the damping elements in relation to be large. Also, the risk of denting in an impact and thereby uncontrolled subsequent movement of a larger vehicle over a wide speed range to avoid. Since the damping elements have to be replaced after they have been hit by a vehicle, high costs are incurred per damping element with a large wall thickness, relatively speaking.

The from the US Pat. No. 6,863,467 known crash cushion is equipped with elastic damping elements. By elastic damping elements impacting vehicles are thrown back uncontrollably. The energy accumulating in the elastic element during compression changes abruptly at a certain point, depending on the damper characteristic, into a countermovement which throws the impacting vehicle away from the impact damper. A reinforcing, hard deflector skin attached to the outside of the damper element enhances the effect of the deflection. A second deflector skin is optionally mounted and stands from the damping element in the direction of the road at a very specific angle, so that it can collapse in the event of an impact and thereby absorb energy. The disadvantage here is that although energy can be absorbed, the impact angle of the vehicle is unknown, and thus an optimal effect is not predictable. Furthermore, these protruding Ablenkhäute entail the risk to penetrate into the vehicle, if this, for example, in a preceding spin not from the direction of travel, but laterally impacts, or even in this spinning rotates so that the protruding Ablenkhäute from behind and can not follow their originally intended Umklappbewegung. In the event of a frontal collision, the frame arranged between the damper rows is used to move in the direction of travel, but the elastic characteristic of the damper elements is the same, so that the vehicle is almost certainly deflected from one side to the other from a certain point of compression, and is thrown uncontrollably from the impact damper.

The invention has for its object to decelerate vehicles in a cost-effective manner both from the front, as well as sideways, controlled to protect against an obstacle and / or returned controlled in the longitudinal direction to the lane.

This object is achieved in a generic crash cushion in that at least one damping element at least one segment plate is secured to at least a portion of a pipe wall, through which the damping element can absorb greater loads.

In this way advantageously an improved impact energy absorption can be achieved and a buckling can be avoided when driving on side.

Advantageously, a segment plate is arranged in each case a damping element. In this way, the damping element changes its deformation characteristics in such a way that it can absorb larger loads and amounts of energy. The segment plate is thereby mounted in the damping element so that it is advantageously positioned on the traffic-facing outer side in the interior of the damping element. The convex outer shape of the segment plate is exactly adapted to the concave inner contour of the damping element.

Seen in the direction of travel, the segment plates are advantageously mounted in the rear region of the damping elements, so that they represent a continuation of the externally mounted side plates and thus the power flow in the event of an impact from the side, so from the side plates on the damping element in the interior of the damping element on the Segment plates runs. In this way, a thrust transfer is achieved with which the overall system of the crash cushion can absorb greater loads, so that vehicles in the road usual weight classes safely deflected, braked and returned to the road. In this case, the damping elements are plastically deformed and in addition, according to the invention, the segment plates are plastically deformed. The possibilities of energy absorption are thereby advantageously expanded and there is obtained a characteristic deformation pattern of the segment plates more resilient damping elements and thus of the impact absorber.

The extension of the segment plates along the inner arc of the damping elements advantageously extends beyond the point of the subsequent, arranged on the outside of the damping element Schubstegs, so that in case of an impact of the power flow and the shear transfer of a segment plate to the nearest slide bar and thus the next damping element is transmitted.

Furthermore, it is advantageous if the segment plates overlap in their extension counter to the direction of travel with the externally mounted side plates so that the power flow and the shear transfer in the event of an impact from the outside, so initiated by the side plates and by the damping elements on the segment plates be transmitted.

According to the invention, the segment plates with the damping elements and the side plates are advantageously connected, preferably riveted, screwed or welded. In this way, the entire construction, in particular the sides is clearly stabilized and allows the transmission of forces in the event of a side impact, without the possibility to absorb impact energy from the front is permanently impaired. Due to the simple handling of the type of fastening, the segment plates can also be retrofitted to existing impact absorbers of this type.

Furthermore, it is advantageous if the segment plates not all have the same height, but, seen in the direction of travel, z. B. from front to back are getting bigger. The segment plates can either be mounted on all the damping elements, front to rear, or be omitted in the front seen from the direction of travel front damping elements to allow for a larger and faster deformation of the front damping elements in the event of a frontal impact. It is particularly advantageous according to the invention, the segment plates in each successive Damping elements in their size to increase progressively increasing, which is not ruled out that partially equally large segment plates are arranged in directly successive damping elements. In this way, the entire crash cushion from the front to the rear is constantly more resilient and offers the impacting vehicle a growing resistance. As a result, vehicles that do not impinge laterally on the impact damper in the foremost area, continue in the direction of travel by the then larger impact in the impact area segment panels, and thus resulting greater resistance, practical without delay in a uniform manner.

Particularly advantageous in a frontal collision, but also in a side impact, is the arrangement of the segment plates, the side plates and the push bars. The Wandund push bars have the same attachment point to the respective, seen in the direction of travel, previously lying damping element and are based in this point by the wall of a damping element on a segment plate from. By attaching a segment plate, a punctiform or line-like indentation in the damping element, in the event of an impact, can be avoided at this position.

According to the invention, the segment plates are advantageously arranged flush with the lower edge of the damping elements. Positioned in this way, all damper elements that have a segmented plate attached can accommodate greater loads down to the lower limit and provide increased protection over the entire length of the impact damper for impacting vehicles whose center of gravity is that of a standard passenger car.

The invention will be explained in more detail with reference to an embodiment shown in the figures.

The drawings show:

• 1 is a plan view of an impact absorber according to the invention with damping elements, segment plates, side plates and push bars,
• 2 shows a perspective view of the impact absorber according to the invention from FIG. 1 with damping elements, segment plates, side plates and the positions and points at which they are connected to one another,
• 3 is a side view of a further embodiment of an impact absorber according to the invention with damping elements, segment plates, side plates and the bottom,
• Fig. 4a and Fig. 4b are plan views of an embodiment of further damping elements with execution form dependent two, or four segment plates.

An impact absorber, generally designated 1, consists of a multiplicity of plastically deformable damping elements 2. The damping elements 2 are arranged essentially one behind the other in the direction of travel and / or next to one another in the impact absorber 1.

In Fig. 1, a double-row impact absorber 1 with five damping elements 2 per row and a single projecting, positioned centrally to the rows, damping element 2 is shown. This preceding one, and the first two subsequent damper elements 2, are arranged in a triangular formation, if one were to connect their center point. A head side shield 30 wraps around the preceding damping element 2 and the two subsequent damping elements 2 arranged next to each other on the outside until, seen in the direction of travel 6, to just above the apex of the subsequent damping elements 2, so that these three front damping elements are connected to form a unit.

According to the invention in the illustrated embodiment in the interior 8 of a damping element 2, on the respective traffic-facing outer side 4 of the series of damping elements 2 each have a segment plate 5 is arranged. Each segment plate 5 is connected to its associated damping element 2 at least two connection points 9, preferably riveted, screwed or welded. On the other hand, seen in the direction of travel 6, in the rear region of the damping element 2 between the contact point 20 to the following damping element 2 and an attachment point 11 of a below explained in more detail Schubstegs 7 on the damping element 2. The segment plate 5 projects in each case forward and rear beyond the connection points 9 addition. By this simple connection type segment panels can be retrofitted to existing generic impact absorbers and thus their deformation characteristics are influenced so that larger Strain, especially from the side, can be recorded.

The segment plates 5 supplement the damping elements 2 and allow the impact damper 1 to absorb a higher impact energy. Furthermore, a denting is prevented by a laterally impacting vehicle, as seen through the segment plates 5, the gap between the individual damping elements 2 and the rear area, seen in the direction of travel 6, after completion of the side plates 3 of the damping elements 2. Impacting vehicles are not thrown back uncontrollably on the road, but influenced in their direction of travel so that they controlled by the resistance of the crash cushion 1 along the longitudinal axis of the crash cushion 1 and ultimately back in the direction of travel 6 are performed.

The damping elements 2 arranged one behind the other have a circular cross-section 12 and can each contact each other along their adjacent generatrix. Laterally of the "points of contact" push bars 7 are mounted so that the impact damper 1 deformed in the event of an impact along the longitudinal axis, corresponding to the pressure specification of the push ribs 7. Between each two damping elements 2 each two push ribs 7 are arranged. The push ribs 7 allow an advantageous deformation characteristic along the longitudinal axis of the crash cushion.

The side shields 3 each extend from one seen in the direction of travel 6, front damping element 2, from a common front attachment point 11 with the outside slide 7, substantially tangentially to the lateral surface of a subsequent damping element 2 and slightly beyond. It follows at the same time that a force applied to the side plate 3 thrust force via the connection 9 in the subsequent damping element 2 via the respective segment plate 5 in runs.

There are both on the outside 4, as well as on the inside 10 of the crash cushion 1 side shields 3 are arranged. Thus, two side shields 3 each connect two damping elements 2. The side shields 3 on the outer sides 4 facing the roadway are designed with greater wall thickness to counteract the loads occurring from the outside, than those on the inside 10 of the impact absorber.

In the embodiment according to Figure 1, only the further damping elements 2 are equipped after the head assembly with a segment plate 5, although the head damping elements may be provided with such a segment plate 5.

In Fig. 2, the crash cushion 1 is shown in a perspective manner. The connection 9 of the side plates 3 on the damping elements 2 takes place on the outside at at least five positions. It can be riveted, screwed or welded. The segment plates 5 are fastened at the same connection points 9, with smaller segment plates 5 in the front region of the crash cushion 1 at three attachment points 9, with larger segment plates 5 with four or five attachment points 9. The segment plates 5 have different heights and have at their lower edge to the lower edge 14 of Damping element 2 a distance.

In Fig. 3, the crash cushion 1 is shown in a side view. The side plates 3 are dimensioned equal in height from front to back the same size.

The tubular damping elements 2 are with their tube axis at right angles to the bottom 13. The segment plates 5 close in this embodiment with the lower edge 14 of the damping elements 2 flush. The lower edge 14 of the damping elements is not in contact with the ground 13. In this way, the crash cushion 1 can be extended in this area.

FIGS. 4 a and 4 b show a further embodiment of arrangements of segment plates 5 in a damping element 2. By two in the direction of travel 6, the rear portion of the damping element 2 symmetrically arranged segment plates 5, each individual damping element 2 absorb more deformation energy and thus the performance of the crash cushion can be further increased. By attaching four symmetrical segment plates 5 within a damping element 2, this effect can be even further enhanced. Thus, different stiffnesses, damping and deformation characteristics can be set for the impact damper 1, so that even applications with larger impact energies can be implied by higher speeds and / or larger masses.

Claims (16)

Impact damper (1) for damping the impact of a vehicle in front of an obstacle, comprising - A plurality of arranged in series, tubular, plastically deformable damping elements (2), characterized in that - At least one of the damping elements (2) at least one segment plate (5), is attached to at least a portion of the pipe wall, through which the damping element (2) can absorb greater loads. Impact damper (1) according to claim 1, characterized in that in each case a segment plate (5) is assigned in each case to a damping element (2). Impact damper (1) according to claim 1 or 2, characterized in that the segment plates (5) are arranged at least on the traffic-facing outer side (4) of the damping element (2). Impact damper (1) according to one of the preceding claims, characterized in that the segment plates (5) seen from the direction of travel (6) are arranged in the rear part of the damping element (2), wherein in the event of an impact of the power flow from the side plates (3) the damping element (2) extends onto the segment plate (5). Impact damper (1) according to one of the preceding claims, wherein the damping elements (2) in the direction of travel (6) by at least one push bar (7) are interconnected, characterized in that the segment plate (5) to at least the push bar (7) extends. Impact damper (1) according to one of the preceding claims, characterized in that the segment plates (5) arranged in the interior (8) of the damping element (2) and whose shape are adapted accordingly. Impact damper (1) according to one of the preceding claims, with a plurality of side plates (3) which at least on the outside facing the road surface (4) are arranged and connect the damping elements (2), characterized in that overlap the segment plates (5) with at least the edge region of the side plates (3). Impact damper (1) according to one of the preceding claims, characterized in that the segment plates (5) with the side plates (3) and respectively associated damping element (2) are connected (9). Impact damper (1) according to one of the preceding claims, characterized in that different height segment plates (5) are provided. Impact damper (1) according to one of the preceding claims, characterized in that the segment plates (5), viewed from the direction of travel (6), increase in height. Impact damper (1) according to claim 1 or 7, characterized in that the side plates (3) on the outside (4) and on the inside (10) can be formed with different wall thicknesses. Impact damper (1) according to one of the preceding claims, characterized in that the side plates (3) and the push webs (7) in the direction of travel (6) seen front damping element (2) have the same attachment point (11). Impact damper (1) according to claim 1, characterized in that the tubular damping element (2) has a circular cross section (12) and a tube axis is aligned at right angles to the bottom (13). Impact damper (1) according to at least one of the preceding claims, characterized in that the segment plates (5) on the bottom side flush with the edge of the damping elements (14). Impact damper (1) according to at least one of the preceding claims, characterized in that at least two segment plates (5) are arranged symmetrically to each other on the damping elements (2). Impact damper (1) according to at least one of the preceding claims, characterized in that at least four segment plates (5) are arranged symmetrically to each other on the damping elements (2).

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