WO2000065156A1 - Guide wall for traffic routes - Google Patents

Abstract

The invention relates to a guide wall for traffic routes which comprises a plurality of wall elements (3) that are interlinked with their front faces. Said wall elements (3) are linked with at least one anchoring element (2, 5) that is mounted on the ground, for example, on the pavement, the superstructure of a bridge or the like, via at least one fastening element (1). The at least one fastening element (1) is slidably guided vis-à-vis the at least one anchoring element (2, 5) so that the wall element (3) can be moved with its at least one fastening element (1) from an initial position to a position that is set off by a predetermined distance.

Description

 Guide and for traffic routes

The invention relates to a guide wall for traffic routes with a plurality of wall elements connected to one another at the end, which wall elements each have at least one fastening element with at least one on the floor, e.g. anchoring element attached to a road surface, a bridge superstructure or the like.

Baffles of the aforementioned type are used to separate traffic flows and consist in the vast majority of cases of precast concrete wall elements, which are connected to one another at their end faces via couplings, whereby there is a continuous, tensile connection of all wall elements, which reinforces the restraining effect of the individual Wall elements causes, because these strung together form a very high inhibitory effect against displacement. The main purpose of such a baffle is to enable different traffic flows to be separated and, in the event of a side approach by a motor vehicle, to counteract this movement with sufficient restraining action to prevent the motor vehicle from getting onto another roadway or footpath or at bridges at depth falls.

Due to the continuous connection of the wall elements, in addition to the higher inertia of the guide wall, too much deflection of the individual wall elements from their rest position is prevented, since the inertia of all wall elements helps to reduce the starting force due to the composite effect achieved.

In addition, floor anchoring of the wall elements is also possible, so that they are not only held in place by their own weight, but also by fixing them to the floor. This can prevent a far-reaching displacement of the wall elements, but there is a disadvantage in many cases that the guide wall with anchored wall elements acts as a completely rigid obstacle, which can cause a correspondingly high level of damage to the approaching motor vehicles, because of the almost negligible flexibility a very high proportion of the kinetic energy of the vehicle is converted into deformation work of the body. In addition to the high damage to property, the rigid guide wall poses a very high risk of injury for the vehicle occupants, since the vehicle speed is delayed within a very short distance.

The object of the invention is therefore to provide a guide wall of the type mentioned at the outset, with the aid of which a reduction in the impact energy acting on a vehicle and a securing of the guide wall against excessive displacement can be achieved. According to the invention, this is achieved in that the at least one fastening element is displaceably guided relative to the at least one anchoring element, so that the wall element with its at least one fastening element can be moved from a rest position into a position offset by a predetermined distance.

In this way, when a motor vehicle approaches the side of the guide wall according to the invention, a limited displacement of those wall elements which come into contact with the vehicle is possible, it being possible for adjacent wall elements to also be displaced by the end connection of the wall elements. This is made possible by the displaceable guidance of the fastening element relative to the anchoring element. The forces acting when moving off are absorbed by the inertia of the wall elements, their floor friction and the tie rod effect of the coupling elements in the longitudinal direction of the guide wall. Within the guide wall according to the invention, the individual wall elements can perform a limited movement by displacement relative to the anchoring element. The limited displaceability of the wall elements makes it possible to convert part of the kinetic energy of the vehicle into displacement work that is involved in the displacement of the wall elements, but an excessive displacement is prevented.

In a further embodiment of the invention, it can be provided that the at least one anchoring element is formed from a rail element anchored to the floor, which extends essentially normal to the longitudinal direction of the wall element and is assigned to the displaceably guided fastening element. The rail element enables the sliding movement of the respective wall element to be guided in a directed manner, as a result of which the evasive movement of the wall can be predicted very well and can thus be controlled. If, on the other hand, the shifting movement were uncontrolled and free, it could endanger other road users who are traveling on another lane or on a footpath and who are hindered or endangered in their movement by the guide wall suddenly deflected to the side.

A very stable design of the anchoring element is obtained if, according to a further embodiment of the invention, the rail element is T-shaped in cross section.

In order to prevent the wall elements from tipping over, it can be provided according to another development of the invention that the fastening member has an at least partially opposite profile to the associated rail element, which lies on or surrounds the profile of the rail element, so that the fastening element along the longitudinal direction of the associated rail element is displaceable.

Furthermore, according to a further exemplary embodiment of the invention, it can be provided that the fastening element, viewed in cross section, is a C-shaped one Approach. The C-shaped attachment encompasses the T-profile of the anchoring element and thus effectively prevents the wall elements from tipping over.

According to a further variant of the invention, the sliding movement of the wall element is guided very well if two parallel rail elements spaced apart from one another and two associated fastening elements are provided for each wall element. The guidance along two straight lines prevents a wall element from breaking out on one side.

In a further development of the invention, the attachment of the displaceable fastening member can be carried out in a particularly simple manner by excluding at least one downwardly open, tunnel-shaped opening in the lower region of each wall element transversely to the longitudinal direction of the wall element, and by arranging the rail element within the opening on the floor is.

In a guide wall in which the wall elements have a New Jersey profile with an upwardly tapering, trapezoidal cross-section, one side wall of which is directed towards motor vehicle traffic, it can be provided in a further embodiment of the invention that the at least one fastening member within the Opening is arranged in the region of the motor vehicle traffic-side wall.

According to a further embodiment of the invention, the downwardly open C-shaped attachment of the fastening members can engage in the T-shaped profile of the associated rail elements and can be guided displaceably along the same.

This results in a very reliable guidance, the tipping of the wall elements during the displacement movement being prevented by the engagement of the C-profile in the T-profile.

In a further embodiment of the invention, a, preferably elastic, stop element can be arranged on the side of the wall element cross section opposite the motor vehicle traffic side wall in the end region of the rail element, against which the fastening member strikes when the wall element is displaced. The impact-absorbing stop element prevents greater damage to the wall element, so that it can be brought back to its original installation location by resetting the fastener displaced during a start-up event.

Another feature of the invention can be that the fastening element is anchored in the wall element by means of a wire reinforcement loop. In this way, the installation of the fastening element within the wall element can take place during manufacture, whereby a very durable and firm connection between the wall element and the fastening element can be achieved.

In a further embodiment of the invention, the T-shaped rail element can be welded with its longitudinal web to a flat base rail which is anchored in the floor. Finally, in a further embodiment of the invention, the flat base rail can be anchored in the floor at opposite end regions of the wall element profile by means of anchor screws, as a result of which a very stable attachment of the base rail can be achieved which, even with high impact energy of the motor vehicle, enables the fastening member to be guided securely.

According to a further embodiment of the invention, at least one elastic element can be provided, on which the displaceably guided fastening element acts during its movement into the offset position.

The elastic element exerts a damping effect on the displacement movement and ensures a uniform introduction of the force transmitted by the fastening element during its displacement movement, wherein an additional portion of the kinetic energy can be reduced by the conversion into elastic energy.

In a further embodiment of the invention, the at least one elastic element can extend along part of the displacement path of the fastening member, the elastic element being in abutting contact with one end of an impact element, and the other end of the elastic element during the displacement movement of the wall element this comes into abutting contact during which the elastic element undergoes compression.

The work involved in compressing the elastic element reduces the impact of the starting motor vehicle on the wall element. The elastic element delays the introduction of the acting force into the wall element.

A very secure guidance of the fastening member can be achieved if, according to a further embodiment of the invention, the rail element - as seen in cross section - is composed of a T-profile and a U-profile, the U-profile partially surrounding the T-profile and the Longitudinal web of the T-profile is connected to the central web of the U-profile.

In a further embodiment of the invention, the elastic element can be formed from two rod-shaped profile pieces with an essentially L-shaped cross section, which are inserted into the U-profile on both sides of the centrally arranged T-profile.

In this way, the elastic element can be arranged in a very space-saving manner, ensuring that it can expand in cross-section during the compression process.

According to a further development of the invention, one or more shearing elements can be arranged along the path traversed by the fastening element during its displacement movement from the rest position into the displaced position, and can be sheared off by the fastening element in the course of its displacement movement. The work performed in the shear reduces the kinetic energy, which dampens the displacement movement of the wall elements.

Furthermore, the shearing elements can be formed by metal bolts oriented transversely to the direction of the displacement movement. By choosing the number of bolts and dimensioning the bolt diameter, the damping behavior of the shear elements can be changed in a relatively fine gradation.

A very balanced movement of the wall elements can be achieved by metal bolts that are evenly spaced along the displacement path of the fastening element.

In order to facilitate the assembly of the metal bolts, it can be provided according to a further variant of the invention that they have a threaded part which can be passed through bores in the rail element and screwed with a lock nut. In this way, the number of metal bolts actually used can be changed in a very simple manner.

A particularly simple assembly of the shear bolts can be achieved in that the bores are arranged in the longitudinal web of the T-shaped rail element.

Furthermore, a railing can be attached to the wall elements of the guide wall, which rail can also be moved with the wall elements. The moving railing prevents a walker or cyclist walking next to the guide wall according to the invention from being pushed down in the event of a bridge or being crushed by the moving wall elements.

A further embodiment of the invention can consist in that the railing attached to the guide wall comprises a platform designed as a walkable path, which can also be displaced when the wall elements are moved. A pedestrian walking on the platform is moved to the side in the same way as the wall elements, but the full width of the sidewalk is preserved, which protects the pedestrian from the dangers arising from a collision event.

In order to achieve a movement of the railing and / or the walk-on platform with as little friction as possible, according to a further embodiment of the invention, these can be attached to the wall elements in a self-supporting manner.

The invention is explained in detail below with reference to the exemplary embodiments shown in the accompanying drawings. It shows

Fig.l is a side view of an embodiment of the guide wall according to the invention;

2 shows a section through a further embodiment of the guide wall according to the invention;

3 shows a detail of a side view of the embodiment according to FIG. 2; 4 shows a section through a further embodiment of the guide wall according to the invention;

5 shows a detail of a side view of the embodiment according to FIG. 4;

6 shows a section through a further embodiment of the guide wall according to the invention;

7 shows a detail of a side view of the embodiment according to FIG. 6;

8 shows a section through a further embodiment of the guide wall according to the invention;

9 shows a detail of a side view of the embodiment according to FIG. 8;

10 shows a section through a further embodiment of the guide wall according to the invention;

11 shows a detail of a section in the longitudinal direction of the wall element in the unloaded state of the elastic element;

12 shows the detail of the section according to FIG. 11 in the loaded state of the elastic element and

13 shows a section through a further embodiment of the guide wall according to the invention.

Fig.l shows a guide wall for traffic routes, which is formed from a plurality of wall elements 3 connected to each other at the end, which are lined up along a traffic route, so that they delimit it from an edge area or another traffic route. The frontal connection of the wall elements 3 takes place via coupling elements 11, which are anchored in the wall elements via a reinforcement 24 indicated by dashed lines in FIG. 1 and are brought into engagement at the ends of the wall elements 3 with the coupling elements 11 of the respectively adjacent wall elements 3, so that the wall elements 3 lined up in the longitudinal direction are continuously connected. The resulting composite of wall elements 3 forms the guide wall, which helps prevent motor vehicles that have got off their lane from entering pedestrian paths or other lanes of the road. The lateral collision of a motor vehicle onto the guide wall causes a displacement of one or more side wall elements 3, depending on the force of the impact. In order to avoid an excessive displacement, the side wall elements 3 are each provided with at least one fastening element 1 with at least one anchoring element 2 attached to the floor, 5 connected (Fig.2). An otherwise usual, completely rigid connection to the anchoring element of the floor prevented excessive deflection of the side wall elements from their rest position, at the same time a large part of the kinetic energy of the motor vehicle would be converted into deformation work, which would cause great damage to the vehicle and to those in it People.

2 and 3 show an embodiment of the guide wall according to the invention, with which a limited lateral evasion thereof is made possible. The Wall elements 3 of the guide wall rest on an edge beam 30, which in turn is fixed to a bridge structure 29 via anchors 32. Reinforcements 25 and 26 are provided to reinforce the edge beam 30 and the bridge structure. Over an insulating layer 23, which is drawn in between the bridge structure 29 and the edge beam 30, in addition to the edge beam 30, a floor covering 28 is applied, which forms a carriageway 27 which can be driven on by motor vehicles. When a motor vehicle hits the edge bar, the guide wall prevents it from falling into the depth beyond the edge bar 30.

According to the invention, it is provided that the fastening element 1 is displaceably guided relative to the anchoring element 2, 5, so that the wall element 3 with its at least one fastening element 1 can be moved from a rest position into a position offset by a predeterminable distance. The offset position of the wall element 3 is shown in FIG. 2 with dashed lines.

A plurality of fastening elements 1 and anchoring elements 2, 5 can also be provided in each wall element 3.

The displacement of the wall elements 3 takes place during a lateral impact, so that the guide of the fastening member 1 must be designed for correspondingly rough conditions.

The wall elements 3, which are designed according to FIG. 2 in the form of a New Jersey profile, rest on two base surfaces formed on the underside and are moved on these base surfaces when they are moved. The shape of the profile of the wall elements is not subject to any restrictions and can be freely selected within the scope of the invention.

In order to achieve the displaceable guidance of the fastening element 1, the anchoring element is formed from a rail element 2, 5 anchored to the floor, which extends essentially normal to the longitudinal direction of the wall element 3 and is assigned to the displaceably guided fastening element 1.

The rail element 2, 5 is T-shaped in cross section, as can be seen from FIG. The fastener 1 is designed to be displaceable and has a profile that is partially opposite to the associated rail element 2, 5, which rests on or surrounds the profile of the rail element 2, so that the fastening element 1 along the longitudinal direction of the assigned rail element 2, 5 is movable. For this purpose, the fastening element 1 seen in cross section, a C-fb ^'shaped projection 4 on.

The fastening element is preferably designed as a built-in part which has a length of approximately 80 mm for conventional New Jersey profiles. The dimension and shape of the fastener can be changed as required.

As can be seen from FIG. 1, in the lower area of each wall element 3, two downwardly open, corresponding to the number of fastening elements used, Except tunnel-shaped openings 10 transverse to the longitudinal direction of the wall element 3, in which the rail element 2, 5 is arranged on the floor. Sufficient space is available via the tunnel-shaped opening to ensure the displaceability of the associated fastening elements 1.

Accordingly, each wall element 3 can be displaced in a lateral impact along the mutually spaced, parallel rail elements 2, 5, the maximum displacement distance being limited by the end of the rail element. This results in a limited deflection of the wall elements 3, which converts part of the kinetic energy of the vehicle through the energy expended during the displacement, so that the deformation work available for the motor vehicle is reduced, thereby reducing the danger of the impact.

The wall elements 3 have a New Jersey profile with a trapezoidal cross-section tapering upwards, one side wall 17 of which is directed towards motor vehicle traffic. This side wall 17 is provided with a cover plate 17 '. In the event of a motor vehicle crashing, a pulse acting in the direction of the arrow is therefore emitted onto the wall element 3. As a result, the latter is displaced along the rail element 2, 5 until the fastening member 1 arranged in its rest position within the opening 10 in the region of the side wall 17 on the motor vehicle traffic side strikes the other end of the rail element 2, 5. The downwardly open C-shaped attachment 4 of the fastening member 1 engages in the T-shaped profile of the associated rail element 2, 5 and is thereby guided to be displaceable along the same.

In order to reduce its force in the event of an impact in which the wall element can move as far as the end of the rail element 2, 5, the side of the wall element cross section opposite the motor vehicle traffic-side wall 17 in the end region of the rail element 2, 5 is preferably a Elastic, stop element 15 is arranged, against which the fastening member 1 strikes when the wall element 3 is displaced. The stop element 15 is preferably made of an elastomer, e.g. Neoprene, formed.

The fastening element 1 is anchored in the wall element 3 by means of a wire reinforcement loop, which results in increased liability within the wall element 3. The T-shaped rail element 5 is welded with its longitudinal web to a flat base rail 2, which is anchored in the ground. The flat base rail 2 is anchored in the floor at opposite end regions of the wall element profile 3 by means of anchor screws 16. The floor can e.g. a road surface, a bridge superstructure or similar his. The steel base rail is anchored in the floor with the anchor screws 16 and plugs 21 in such a way that the existing moisture insulation 23 is not pierced.

Since the wall elements do not parallel to each other in the event of a side impact of a motor vehicle, but in one in accordance with the vehicle approaching to the side If the base rails 2 are deflected at an angle to one another, the base rails 2 can have corresponding slot holes through which the anchor bolts 16 are guided, so that the base rails 2 are held deflectable to a certain extent and thus prevent the wall elements 3 from jamming. Furthermore, an angle 33 is provided in the area of the guide wall on the motor vehicle side, which prevents the elements 3 from being displaced in the event of an impact. On the opposite side of the wall element profile, the anchor screw 21 is screwed to the base rail 2 via a square washer 34.

The forces occurring during an impact are derived in part via the displaceable guidance of the fastening members 1, in part via the floor friction of the wall elements 3 and in part via the tension band effect which results from the coupling elements 11. The guide wall according to the invention can preferably be used on a bridge edge, between a walkway or bike path and a roadway in tight spaces. This construction can also be used on similar structures, e.g. how embankment bank walls etc. are used.

In the exemplary embodiment according to FIGS. 4 and 5, a footpath and / or cycle path 41 is provided on the edge beam 30 next to the wall elements 3, which is separated from the carriageway 27 by the guide wall and is secured by a railing 40. To protect pedestrians or cyclists, the limitation of the deflection movement of the guide wall is dimensioned so that in the event of an accident they still have enough space to avoid the movement of the guide wall. Cable pulling pipes 45 are laid below the footpath and / or cycle path 41.

Another exemplary embodiment is shown in FIGS. 6 and 7. The bridge structure 29 and the edge beam 30 are connected to one another via head anchor strips 44. Just as in the exemplary embodiment according to FIGS. 8 and 9.

10, 11 show an embodiment of the guide wall according to the invention, in which the most uniform possible introduction of force during the displacement process into the anchoring element 2, 5 is achieved in that an elastic element 53, 54, e.g. is made of neoprene or a similar material, on which the slidably guided fastener 1 acts during its movement in the offset position. The elastic element 53, 54 extends along part of the displacement path of the fastening member 1, the elastic element 53, 54 being in abutting contact with one end of an impact element 150. The other end of the elastic element 53, 54 comes into abutting contact with the wall element 1 during the displacement movement thereof, during which the elastic element 53, 54 is compressed.

The elastic element can be designed in any way and could therefore also be designed such that it is subjected to tension during the displacement movement of the fastening member, for example. The function of the elastic element 53, 54 is to provide a time-delayed distribution when the Fastener 1 occurring forces and thus achieve a damping effect. As soon as the end face of the fastening member 1 comes into abutting contact with the elastic element 53, 54 and continues to move along the displacement path, the elastic element 53, 54 is compressed and its cross section undergoes a corresponding expansion, as shown in FIG. 12. During this compression process, the force on the impact element 150, which is arranged in the end region of the anchoring element 2.5, increases in accordance with the elastic deformation of the elastic element 53, 54 and only reaches that after a time required for the complete compression of the element 53, 54 full strength of the force transmitted via the fastening member 1. Part of the kinetic energy is converted into elastic energy of the elastic element 53, 54.

In the embodiment according to FIGS. 10, 11, the rail element - seen in cross section - is composed of a T-profile 5 and a U-profile 2, the U-profile 2 partially surrounding the T-profile 5 and the longitudinal web of the T- Profile 5 is connected to the central web of the U-profile 2. In the exemplary embodiment shown, the T-profile 5 is welded to the U-profile 2.

The fastening member 1 has a C-shaped profile which is opposite to the associated rail element 2, 5 and which surrounds the T-profile 5, so that the fastening element 1 can be displaced along the longitudinal direction of the assigned rail element 2, 5.

According to this special design of the rail element 2, 5, the elastic element is formed from two rod-shaped profile pieces 53, 54 with an essentially L-shaped cross section, which are inserted into the U-profile 2 on both sides of the centrally arranged T-profile 5. The shape of the elastic element is not limited to this embodiment but can be any. The front side of the C-shaped fastening member 1 abuts the rod-shaped profile pieces 53, 54 during a rear-end collision and the associated displacement process and presses them together during its displacement movement within the U-profile 2 so that they move from the unloaded state in Fig.l 1 in change to the loaded state in FIG. 12, in which the cross section of the profile pieces 53, 54 extends into the free cross section part of the U-profile 2.

In the event of a motor vehicle crashing, an impulse acting in the direction of the arrow is therefore delivered to the wall element 3. As a result, this is moved along the rail element 2, 5 until the fastening member 1, which is arranged in its rest position within the opening 10 in the region of the side wall 17 on the motor vehicle traffic side, strikes the free end of the elastic element 53, 54 and compresses it until the greatest possible deformation state this element is reached. The downwardly open C-shaped attachment of the fastening member 1 engages in the T-shaped profile of the associated rail element 2, 5 and is thereby guided to be displaceable along the same. The fastening element 1 is anchored in the wall element 3 by means of two rear hooks 51, 52, which results in increased liability within the wall element 3. The U-profile 2 of the anchoring element 2 is anchored in the floor with its central web 60 at opposite end regions by means of anchor screws 16 and dowels 21.

On the side of the wall element profile opposite the motor vehicle-side area, the base rail 2 is screwed to the bridge structure by means of an anchor screw 21 via a square washer 59.

Fig. 13 shows an embodiment of the invention, in which the sliding movement of the wall element 3 next to the rod-shaped, elastic profile pieces 53, 54 is damped by shearing elements 133 arranged along the path traversed by the fastening element 1 during its sliding movement from the rest position into the offset position. The elastic profile pieces 53, 54 reinforce the damping effect, but can also be omitted as well.

The shear elements 133 are attached in such a way that they are sheared off by the fastening member 1 in the course of its displacement movement, as a result of which the kinetic energy is partially converted into shear work.

As can be seen from FIG. 13, the shear-off elements in the exemplary embodiment shown are formed by metal bolts 133 oriented transversely to the direction of the displacement movement, which are evenly spaced along the displacement path of the fastening member 1. The spacing of the bolts 133 can also be selected in an irregular shape. Furthermore, the shear elements can be made of any other material suitable for shearing, e.g. Plastic.

The metal bolts 133 preferably have a threaded part with which they can be passed through bores in the rail element 2, 5 and screwed by means of threaded nuts, but they can also be connected to the rail element 2, 5 in any other manner known to the person skilled in the art.

In Fig.13 the bores are arranged in the longitudinal web of the T-shaped rail element 5, so that the screwed-in metal bolts 133 protrude perpendicularly from the struts and can be sheared off by the fastening member.

Furthermore, in the exemplary embodiment according to FIG. 13, a railing 130 is fastened on the wall elements 3 of the guide wall and can be moved along with the wall elements 3.

In this way, a pedestrian walking on a walk-on platform 131 running along the guide wall is secured from being pushed or crushed by the moving wall element 3.

The railing 130, together with the platform 131, is cantilevered on the wall elements 3 via a plate 134 anchored in the wall elements 3. Embodiments are conceivable in which only one railing or only one walkable platform is connected to the wall elements 3.

Claims

PATENT CLAIMS

1. Guide wall for traffic routes with a large number of wall elements connected to one another at the end, which wall elements each have at least one fastening element with at least one on the floor, e.g. anchoring element attached to a road surface, a bridge superstructure or the like, characterized in that the at least one fastening element (1) is displaceably guided relative to the at least one anchoring element (2, 5), so that the wall element (3) with its at least one fastening element ( 1) can be moved from a rest position into a position offset by a predeterminable distance.

2. Guide wall according to claim 1, characterized in that the at least one anchoring element is formed from a rail element (2, 5) anchored to the floor, which extends essentially normal to the longitudinal direction of the wall element (3) and the displaceably guided fastening member (1) assigned.

3. Guide wall according to claim 2, characterized in that the rail element (2, 5) is T-shaped in cross section.

4. Guide wall according to claim 2 or 3, characterized in that the fastening member (1) has an at least partially opposite profile relative to the associated rail element (2, 5), which rests on the profile of the rail element (2) or engages around it, so that the fastening element (1) is displaceable along the longitudinal direction of the associated rail element (2, 5).

5. guide wall according to claim 4, characterized in that the fastening element (1) seen in cross section has a C-shaped projection (4).

6. Guide wall according to one of claims 2 to 5, characterized in that two spaced-apart, parallel rail elements (2, 5) and two associated fastening elements (1) are provided for each wall element (3).

7. guide wall according to one of claims 2 to 6, characterized in that in the lower region of each wall element (3) at least one downwardly open, tunnel-shaped opening (10) transverse to the longitudinal direction of the wall element (3) is excluded, and that the rail element ( 2, 5) is arranged inside the opening (10) on the floor.

8. guide wall according to claim 7, wherein the wall elements have a New Jersey profile with an upwardly tapering, trapezoidal cross-section, one side wall of which is directed towards motor vehicle traffic, characterized in that the at least one fastening member (1) within the opening (10) is arranged in the region of the side wall (17) on the motor vehicle side.

9. guide wall according to claim 8, characterized in that the downwardly open C-shaped projection (4) of the fastening members (1) engages in the T-shaped profile of the associated rail elements (2, 5) and are guided displaceably along the same.

10. Guide wall according to claim 8 or 9, characterized in that on the motor vehicle traffic side wall (17) opposite side of the wall element cross section in the end region of the rail element, a preferably elastic, stop element (15) is arranged, against which the fastening member (1 ) stops when the wall element (3) moves.

11. Guide wall according to one of the preceding claims, characterized in that the fastening element (1) is anchored in each case by means of a wire reinforcement loop in the wall element (3).

12. Guide wall according to one of claims 3 to 11, characterized in that the T-shaped rail element (5) with its longitudinal web is welded to a flat base rail (2) which is anchored in the ground.

13. Guide wall according to claim 12, characterized in that the flat base rail (2) is anchored in the floor at opposite end regions of the wall element profile (3) by means of anchor screws (16).

14. Guide wall according to one of claims 1 to 13, characterized in that at least one elastic element (53, 54) is provided, on which the displaceably guided fastening member (1) acts during its movement into the offset position.

15. Guide wall according to claim 14, characterized in that the at least one elastic element (53, 54) extends along a part of the displacement path of the fastening member (1), the elastic element (53, 54) having one end on an impact element (150) is in abutting contact, and that the other end of the elastic element (53, 54) during the displacement movement of the wall element (1) this comes into abrupt contact, during which the elastic element (53, 54) undergoes compression.

16. Guide wall according to claim 15, characterized in that the rail element - seen in cross section - is composed of a T-profile (5) and a U-profile (2), the U-profile (2) the T-profile ( 5) partially surrounds and the longitudinal web of the T-profile (5) is connected to the central web of the U-profile (2).

17. Guide wall according to claim 16, characterized in that the elastic element is formed from two rod-shaped profile pieces (53, 54) with a substantially L-shaped cross section, which on both sides of the centrally arranged T-profile (5) in the U- Profile (2) are used.

18. Guide wall according to one of the preceding claims, characterized in that one or more shearing elements (133) are arranged along the path of the fastening element (1) during its displacement movement from the rest position into the displaced position, which from the fastening element (1) in the course its displacement movement can be sheared off.

19. Guide wall according to claim 18, characterized in that the shearing elements are formed by metal bolts (133) oriented transversely to the direction of the displacement movement.

20. Guide wall according to claim 19, characterized in that the metal bolts (133) are evenly spaced along the displacement path of the fastening member (1).

21. Guide wall according to claim 19 or 20, characterized in that the metal bolts (133) have a threaded part for their attachment, which can be passed through bores in the rail element (2, 5).

22. Guide wall according to claim 12 and 21, characterized in that the bores are arranged in the longitudinal web of the T-shaped rail element (5).

23. Guide wall according to one of the preceding claims, characterized in that a railing (130) is attached to the wall elements (3) of the guide wall, which rail can be displaced with the wall elements (3).

24. Guide wall according to claim 23, characterized in that the railing (130) fastened on the guide wall (3) comprises a platform (131) designed as a walkable path, which can also be moved when the wall elements (3) are moved.

25. Guide wall according to claim 23 or 24, characterized in that the railing (130) and / or the platform (131) are cantilevered on the wall elements (3).