EP2784222A1 - Guard rail device, in particular guard rail connection system, comprising a locking unit and short lowering - Google Patents

Abstract

The device (1) has mobile barrier element (2) that is pivoted about pivot axis (A1) extending perpendicular to plane (H). A mobile barrier element (3) pivoted about pivot axis (A2) is spaced apart from pivot axis (A1), and arranged at right angles to plane (H). Locking units (4,5) are locked with respective barrier elements that are extended along respective longitudinal axis (L) that extends parallel to plane. Each locking unit has respective locking element for providing locking between the barrier elements with respect to movement transverse to longitudinal axis.

Description

TECHNICAL AREA

The present invention relates to a guard rail device, in particular a guard rail transfer system, with a locking unit according to the preamble of claim 1.

STATE OF THE ART

Mobile crash barriers are known from the prior art. Such mobile crash barriers are used, for example, as transfer systems.

Such a transfer system, for example, in the US 6,402,421 shown. Here are two mobile crash barriers pivotally mounted to permanently installed crash barriers. By pivoting a passage can be created, which serves as a transition for the vehicles.

From the system known from the prior art, there is the disadvantage that the mobile guard rail parts or guard rail arms are in the closed state only insufficiently lockable. In a collision of a vehicle on the mobile guard rail parts in the closed state, it can lead to a displacement or a breakthrough of the same, the vehicle may possibly get on the opposite lane.

Furthermore, a collision in the open state can lead to a frontal impact on the guard rail arms.

PRESENTATION OF THE INVENTION

Based on this prior art, the invention has for its object to provide a crash barrier device whose mobile guard rail parts can be locked better, in particular non-positively. In particular, the lock is in the event of a collision of a vehicle, the mobile guard rail elements lock each other so that the guard rail elements remain connected to each other under the influence of greater forces.

Such a problem is solved by the crash barrier device according to claim 1. Accordingly, a crash barrier device comprises a first mobile guard rail element, a second mobile crash barrier element and a locking element for providing a lock between the first mobile crash barrier element and the second mobile crash barrier element. The crash barrier device is arranged on a plane extending substantially in the horizontal plane, in particular a driving plane. The first mobile guard rail element is pivotable about a first axis of rotation which is perpendicular to said plane. The second mobile guard rail element is pivotable about a second axis of rotation which is perpendicular to said plane and spaced from the first axis of rotation. The first mobile crash barrier element and the second mobile crash barrier element each extend along a longitudinal axis, which longitudinal axis runs parallel to said plane. In the connected or locked state, the longitudinal axis of the first guard rail element is aligned or collinear with the longitudinal axis of the second guard rail element. In the separated or unlocked state, the longitudinal axes are usually at an angle to each other. The locking unit comprises at least a first locking element and a second locking element, which provide a locking between the mobile guard rail elements with respect to a relative movement transversely to the longitudinal axis.

By blocking the relative movement transversely to the longitudinal axis, the locking elements thus prevent a relative movement of the guard rail elements with respect to one another Rotation about at least one of said axes of rotation and about a rotation about a right angle to the axis of rotation and perpendicular to the longitudinal axis extending axis. When used on a road, this means that the movement on the driving plane around the two axes of rotation is prevented and that a pivoting movement up to the driving level is also prevented.

By locking with respect to a relative movement transversely to the longitudinal axis, the locking elements also act at transversely or at an angle to the longitudinal axis acting forces, as they may occur in a collision advantageous.

By the term substantially horizontal is meant a direction perpendicular or at an angle of up to 15 ° inclined to the direction of gravity.

Preferably, each of the locking elements locks said relative movement transverse to the longitudinal axis. Thus, at least two locking points are provided which, in the event of a collision, hold the two guard rail parts with respect to the transverse forces in the most different directions relative to one another.

In a development of the invention, at least one, preferably each, of the locking elements comprises a stop element. The stop element is opposed in principle to a relative movement between the guard rail elements in the longitudinal direction. Particularly preferably, however, the stop element allows a relative movement between the guard rail element along the longitudinal axis within a predetermined game. With the stop elements also longitudinal force can also be absorbed in the direction of the longitudinal axis.

Preferably, the locking element comprises a fluidic actuator with a locking bolt and a locking receptacle for receiving the locking bolt. The actuator is arranged with the locking bolt on one of the guard rail elements and the locking receptacle is arranged on the other of the guard rail elements. The actuator and the locking receptacle are preferably fixedly connected to the respective guard rail element. Preference is given to welding or screw connections. The locking receptacle can also by the Guard rail element itself be provided. The fluidic actuator is for example a pneumatic cylinder which is operated with air, or a hydraulic cylinder which is operated with oil. Alternatively, a geared motor can be used.

Particularly preferably, the locking bolt is guided in a guide opening of a guide element, which guide element is arranged on the same guard rail element as the actuator, which is in contact with the locking bolt. The guide element is connected, for example via a welding or screw connection with the respective guard rail element. The guide element further improves the locking with respect to the direction transverse to the longitudinal axis.

Preferably, said locking receptacle comprises a receiving space bounded by side walls, wherein a receiving opening for receiving the locking bolt is arranged in at least one of the side walls, preferably in two side walls opposite to the receiving space. The locking bolt thus protrudes through the opening (s) of the side walls into the receiving space or through the receiving space. The opening (s) and the locking bolt projecting through the opening form the locking with respect to the transverse forces in various directions.

Particularly preferably, the locking element, in particular the first locking element, comprises a locking pin, wherein the locking bolt in the locked state protrudes into an opening in the locking pin. The locking pin is oriented at right angles to the locking bolt and is preferably fastened to the same guard rail element as the locking bolt, wherein the locking pin protrudes into said locking receptacle, in particular into the receiving space.

The said locking pin protrudes into the receiving space in the closed state, thus providing the stop element with respect to a movement in the longitudinal direction, between the side walls and the locking pin preferably play in the direction of the longitudinal axis is present.

Particularly preferred are the side walls with the openings and the locking pin associated with an upper locking element.

Preferably, in particular in the second locking element, the stop element is provided by two transverse to the longitudinal axis tabs, wherein one of the tabs on the first guard rail element and the other of the tabs on the second guard rail element is arranged.

The stop element with the tabs is preferably associated with a lower locking element, which lies with respect to the driving plane below the upper locking element.

Particularly preferably, the actuators of the first locking element and the second locking element are arranged on the same guard rail element. This has the advantage of supplying the fluidic energy.

Preferably, the second guard rail element has an inclined surface to the horizontal, wherein the surface extends from the driving plane upwards. The surface thus extends inclined to the horizontal or to the driving plane. This surface provides a collision protection. This collision protection can also be described as a short cut.

Particularly preferably, one of the guardrail elements, in particular the first guardrail element, comprises a flap element which is pivotable relative to the guardrail elements about an axis which is parallel to the horizontal.

The flap element preferably has a receiving region which partially overlaps the second guard rail element. As a result, the lock can be improved.

Particularly preferred is the flap element with its opposite the said axis lying free end on the roadway is deductible. The flap element is then inclined with its surface to the road. The flap element has the advantage in the lowered state that a so-called short drop is made possible in the open state.

The flap element thus prevents a frontal impact.

Preferably, parts of the first locking element and / or parts of the second locking element, in particular the actuators, are arranged on the flap element.

In a particularly preferred embodiment, the closer the driving level locking element provides a greater resistance than the lying away from the driving plane locking element.

Further embodiments are given in the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1

eine Seitenansicht eines Leiplankensystems nach einer Ausführungsform im verriegelten Zustand;

Fig. 2

die Leitplankenvorrichtung gemäss Figur 1 im entriegelten Zustand;

Fig. 3

eine Seitenansicht eines Leitplankenelements der Leitplankenvorrichtung nach Figur 1 im getrennten Zustand;

Fig. 4

eine Detailansicht eines oberen Verriegelungselementes der Leitplankenvorrichtung nach Figur 1 im verriegelten Zustand;

Fig. 5

eine Detailansicht des oberen Verriegelungselementes nach Figur 4 im entriegelten Zustand;

Fig. 6

eine Detailansicht eines unteren Verriegelungselementes der Leitplankenvorrichtung nach Figur 1 im verriegelten Zustand;

Fig. 7

eine Detailansicht des oberen Verriegelungselementes nach Figur 6 im entriegelten Zustand;

Fig. 8

eine Schnittdarstellung nach Figur 1 entlang der Schnittlinie B-B; und

Fig. 9

eine Schnittdarstellung nach Figur 1 entlang der Schnittlinie C-C.

Preferred embodiments of the invention will be described below with reference to the drawings, which are given by way of illustration only and are not to be interpreted as limiting. In the drawings show:

Fig. 1

a side view of a Leipankensystems according to an embodiment in the locked state;

Fig. 2

the crash barrier device according to FIG. 1 in the unlocked state;

Fig. 3

a side view of a guard rail element of the guard rail device according to FIG. 1 in the separated state;

Fig. 4

a detailed view of an upper locking element of the crash barrier device according to FIG. 1 in the locked state;

Fig. 5

a detailed view of the upper locking element after FIG. 4 in the unlocked state;

Fig. 6

a detailed view of a lower locking element of the guard rail device after FIG. 1 in the locked state;

Fig. 7

a detailed view of the upper locking element after FIG. 6 in the unlocked state;

Fig. 8

a sectional view to FIG. 1 along the section line BB; and

Fig. 9

a sectional view to FIG. 1 along the section line CC.

DESCRIPTION OF PREFERRED EMBODIMENTS

In the FIGS. 1 to 9 a guardrail device 1 according to an embodiment of the present invention is shown. The crash barrier device 1 stands on a driving plane. The driving plane lies substantially horizontally, ie horizontally or at an angle of up to 15 ° slightly inclined to the horizontal. In the figures, the driving plane bears the reference H.

The crash barrier device 1 comprises a first mobile crash barrier element 2 and a second mobile crash barrier element 3. Each of the crash barrier elements 2, 3 can be pivoted about a respective axis of rotation A1 A2 assigned to the crash barrier elements 2, 3. The axes of rotation A1 A2 are spaced and arranged parallel to each other and extend in a direction perpendicular to the plane H. The axes of rotation A1 and A2 are symbolically indicated in the figures. By pivoting the first guard rail element 2 and the second guard rail element 3, a passage between the two guard rail elements 2, 3, for example, rescue vehicles, created.

The axes of rotation A1 and A2 are stationary and are provided for example via the connection to a further guard rail device not shown in the figures.

Furthermore, the guard rail device 1 comprises a locking unit 4, 5, with which the mobile crash barrier elements 2, 3 can be locked together. By means of the locking unit 4, 5, the two guard rail elements 2, 3 are thus locked in such a way that a relative movement between the two guard rail elements 2, 3 is substantially prevented. The locking unit 4, 5 ensures that the guard rail device can be set into a locked state and an unlocked state. In the latter, the two guard rail elements 2, 3 can be pivoted about the axes of rotation A1 A2, whereby a relative movement between the axes of rotation A1 A2 is allowed.

The locking unit comprises a first locking element 4 and a second locking element 5. The two locking elements 4, 5 provide a lock between the mobile guard rail elements 2, 3 with respect to a relative movement transverse to the longitudinal axis L ready. In other words, the locking elements 4, 5 provide resistance with respect to a force acting on the guard rail elements 4, 6 from the outside.

In an impact of a vehicle on the guard rail device, this locking has the advantage that the two guard rail elements 2, 3 are not moved relative to each other. The function of the guardrail as such is thus maintained.

The locking thus prevents a relative movement of the guard rail elements 2, 3 with respect to a pivoting about at least one of said axes of rotation A1 A2 and also to a pivoting about a perpendicular to the axes of rotation A1 A2 and at right angles to the longitudinal axis L extending axis X.

In the embodiment shown, an upper or first locking element 4 and a lower or second locking element 5 is present. Both locking elements 4, 5 are designed such that it locks the relative movement transversely to the longitudinal axis L. In other words, each of the locking elements 4, 5 blocks said relative movement transversely to the longitudinal axis L.

Furthermore, in the present embodiment, each of the locking elements 4, 5 comprises a stop element 21. The stop element 21 is opposed to a relative movement between the guard rail elements 2, 3 in the longitudinal direction L. Particularly preferably, the stop element 21 allows relative movement between the guard rail elements 2, 3 along the longitudinal axis L within a predetermined play. As a result, differences in length that result due to temperature fluctuations can be compensated. The stop elements thus also have a dilatation effect. The game is preferably in the range of a few centimeters, such as in the range of 5 cm to 10 cm. The play of the stop element on the first guard rail element 2 is preferably substantially equal to the clearance of the second guard rail element 3.

Each of the locking elements 4, 5 in the present embodiment comprises an actuator 6, 27, in particular a fluidic actuator 6, 27, such as a hydraulic cylinder or a pneumatic cylinder. The actuator 6, 27 is connected to a locking bolt 7, 28 in connection, which protrudes in the locked state into a locking receptacle 8, 32 and in the unlocked state does not protrude into the locking receptacle 8, 32. The locking pin 7, 28 and the locking receptacle 8, 32 in this case represent parts of the locking element 4, 5. The actuator may also be a geared motor.

The actuator 6, 27 is arranged with the locking bolt 7, 28 on one of the guard rail elements 2, 3 and the locking receptacle 8, 32 is arranged on the other of the guard rail elements 3, 2. In the present embodiment, the actuator 6, 27 with the locking pins 7, 28 of the two locking elements 4, 5 on the first guard rail element 2 and the locking receptacle 8, 32 of the two locking elements 4, 5 is arranged on the second guard rail element 3. Of course, a reversed arrangement can be provided. Alternatively, not all actuators need to be arranged on the same guard rail element.

The locking pin 7, 28 is guided in a guide opening 15, 31 of a guide element 16, 30. The locking element 16, 30 is arranged on the same guard rail element 2, 3, as the actuator 6, 27. The guide member 16, 30 serves as a reinforcing element for the locking pin 7, 28, wherein forces acting on the locking pin 7, 28, on the crash barrier elements 3, 4 are transferable.

In the FIG. 1 and 2 It is shown that one of the crash barrier elements 2, 3 comprises a flap element 18. Here, the first guard rail element 2 comprises the flap element 18. The flap element 18 is pivotable about an axis X, which is parallel to the plane H and extends substantially at right angles to the axes of rotation A1, A2. For this purpose, an actuator, not shown, is present. The axis X is provided by a corresponding hinge 37. The flap element 18 essentially has the function of completing the connection between the first guard rail element 2 and the second guard rail element 3 such that in the closed state a continuous guardrail is available.

Next, the flap member 18, as in the FIG. 3 are shown lowered to the driving plane H, so that with respect to the plane H, an inclined surface 23 can be provided. In the lowered state, the flap element 18 rests with a free end 20 on the driving plane H. This can be referred to as short-cut. The said lowering takes place when the guard rail element 2, 3 are pivoted to each other and the longitudinal axis L no longer run collinear to each other. This inclined surface 23 serves as Auffahrschutz, so that in case of a collision, a vehicle is lifted onto the guardrail, whereby a frontal impact is prevented. In this case, the second guard rail element has a surface 17 arranged inclined with respect to the horizontal surface, the surface 17 extending upward from plane H. The surface 17 has the same effect as the surface 23. In the lowered state, the second locking element 5 is in the unlocked state.

The flap element 18 has a receiving region 19 which partially surrounds the second guard rail element 2. The flap element 18 may therefore also have the function of a locking element, because it extends over the guard rail element 3 and surrounds this accordingly. The flap element is formed in a cross-section at right angles to the longitudinal axis L is substantially U-shaped.

Based on FIGS. 4 and 5 Now, the upper locking element 4 is explained in more detail. The actuator 6 and the locking bolt 7 are arranged here on the first guard rail element 2, more precisely on the flap element 18. The locking bolt 7 protrudes through a guide element 16 with the guide opening 15 and is guided there accordingly. In other words, it can also be said that the flap element 18 is locked to the upper locking element 4. Thus, upper locking element has two functions, on the one hand, the locking of the guard rail elements 2, 3 to each other and on the other hand, the locking of the flap element 18. The locking receptacle 8, which is arranged here on the second guard rail element 3, comprises a limited space with side walls 11 receiving space 12. The side walls 11th here include receiving openings 13 for the Receiving the locking bolt 7. In the present embodiment, two side walls 11 with corresponding receiving openings 13 are spaced apart from each other and define the receiving space 12. The locking pin 7 protrudes through the receiving openings 13 into the receiving space 12 or therethrough.

In the preferred embodiment according to the FIG. 5 The upper locking element 4 additionally comprises a locking pin 10. The locking pin 10 has an opening 9 in which the locking bolt 7 can protrude. In the locked state, the locking pin 10 extends at right angles to the locking pin 7. In addition, the locking pin 10 is preferably in the same guard rail element 2, 3 as the locking pin 7 is fixed. The locking pin 10 protrudes in the locked position in the locking receptacle 8, in particular in the receiving space 12 a. This is in the FIG. 4 shown accordingly. Now, if a force acts on the one guard rail element 2 or the other guard rail element 3, the force is absorbed by the locking element 4. For receiving the force of the locking pin 7 protrudes through the guide opening 15, through the receiving openings 13 and through the opening 9 in the locking pin 10. The locking takes place at several different points.

There is thus a clearance 24 between the receiving space 12 and the locking pin 10. This clearance along the longitudinal direction L has the advantage that temperature expansions of the guard rail elements can be accommodated with respect to its extension in the longitudinal axis L. In this case, the locking pin 10 moves within the receiving space 12. This recording of the change in length or the compensation of the change in length but has no effect on the type of locking and thus it can be said that this type of recording is particularly advantageous. The locking pin 10, together with the side walls 11, the stop element 21st

In the FIG. 5 the flap element 18 is shown in the pivoted state. Here it can be well recognized how the locking pin 10 is located outside of the receiving space 12. In the FIG. 5 It is also shown that the locking pin 10 and the guide member 16 are disposed on the same surface on the flap member 18.

Next can in the FIG. 5 be well recognized that the bolt 7 protrudes in the locked state through the surface 17 into the guard rail profile of the second guard rail element 3. Depending on the design, the surface 17 has openings for the passage of the locking bolts 7, 28 to the receiving spaces 12.

In the FIG. 8 is a sectional view through the first locking element 4 along the section line BB of FIG. 1 shown. Here can be well recognized as the locking pin 7 protrudes into the opening 9 in the locking pin 10. Next, the receiving space 12 can also be easily recognized here.

In the FIG. 8 can continue the profile of the guard rail element 3 are well recognized. This is a U-shaped profile 25 which rests on the driving plane. In the upper portion of the profile 25, the receiving space 12 is arranged. Other types of profiles are also conceivable. For example, composed of a sub-profile and a top profile.

Based on FIGS. 6, 7 and 9 Now, the lower and the second locking element 5 will be explained in more detail. The actuator 27 and the locking pin 28 are arranged here on the first guard rail element 2, more precisely profile 29 of the first guard rail element 2. The locking bolt 7 protrudes through a guide element 30 with a guide opening 31 and is guided there accordingly. The locking receptacle 32, which is arranged here on the second guard rail element 3, comprises a receiving space 12 bounded by side walls 33.

In the FIG. 6 is the locked and in the FIG. 7 the unlocked state shown. In this case, the locking pin 28 has been withdrawn by the actuator 27.

In the FIG. 7 the stop element 21 is further shown, which here has the shape of two tabs 22. One of the tabs 22 is on the first guard rail element 2 and one of the tabs is arranged on the second guard rail element 3. In the locked state, the tabs are spaced from each other, so that between the tabs 22 game 24 is present. The game 24 preferably corresponds to the play 24 of the stop element 21st of the upper and first locking element 4 and is preferably in the range of a few centimeters, such as in the range of 5 cm to 10 cm.

In the FIG. 9 is a sectional view through the second locking element 5 along the section line BB of FIG. 1 shown. Here can be well recognized as the locking pin 28 protrudes into the locking receptacle 32.

In the FIG. 9 can continue the profile of the guard rail element 2 are well recognized. This is a U-shaped profile 34, which stands up on the driving level. Other types of profiles are also conceivable. For example, composed of a sub-profile and a top profile. LIST OF REFERENCE NUMBERS 1 guardrail device 18 flap element 2 first guard rail element 19 reception area 3 second guard rail element 20 free end 4 first locking element 21 stop element 5 second locking element 22 tabs 6 fluidic drive 23 inclined surface 7 locking bolt 24 game 8th locking receptacle 25 profile 9 opening 27 actuator 10 locking pin 28 locking bolt 11 Side wall 29 profile 12 accommodation space 30 guide element 13 receiving opening 31 guide opening 32 locking receptacle 15 guide opening 33 side walls 16 guide element 34 profile 17 area

Claims (15)

Guard rail device (1) for arrangement on a plane lying substantially in the horizontal plane (H), in particular a driving plane comprising
a first mobile guard rail element (2), which is pivotable about a first axis of rotation (A1), which extends substantially perpendicular to said plane (H),
a second mobile guard rail element (3), which is pivotable about a second from the first axis of rotation (A1) spaced and at right angles to said plane (H) extending axis of rotation (A2) is pivotable, and
a locking unit (4, 5) with which the first and the second mobile guard rail element (2, 3) can be locked together,
wherein the first mobile crash barrier element (2) and the second mobile crash barrier element (3) extend along a respective longitudinal axis (L), which longitudinal axis (L) runs parallel to said plane (H),
characterized in that the
Locking unit (4, 5) at least a first locking element (4) and a second locking element (5), which provide a locking between the mobile crash barrier elements (2, 3) with respect to a relative movement transverse to the longitudinal axis (L). Guard rail device according to claim 1, characterized in that each of the locking elements (4, 5) prevents said relative movement transverse to the longitudinal axis (L) or provide a locking against the said relative movement transverse to the longitudinal axis (L). Guard rail device according to claim 1 or 2, characterized in that at least one, preferably each, of the locking elements (4, 5) comprises a stop element (21), which counteracts a relative movement between the guard rail elements in the longitudinal direction (L), wherein the stop element (21 ) preferably permits a relative movement between the guard rail element along the longitudinal axis (L) within a predetermined play. Guard rail device according to one of the preceding claims, characterized in that the locking element an actuator (6, 27), in particular a fluidic actuator (6, 27), with a locking pin (7, 28) and a locking receptacle (8, 32) for receiving the Locking bolt (7, 28), wherein the actuator (6, 27) with the locking bolt (7, 28) on one of the guard rail elements (2, 3) and the locking receptacle (8, 32) on the other of the guard rail elements (3, 2) is arranged or attached. Guard rail device according to claim 4, characterized in that the locking bolt (7, 28) in a guide opening (15, 30) of a guide element (16, 31) is guided, which guide element (16,31) on the same guard rail element (3, 4) is like the actuator (6, 27) which is in contact with the locking bolt (7, 28). Guard rail device according to claim 4 or 5, characterized in that the locking receptacle (8) comprises a receiving space (12) delimited by side walls (11), wherein in at least one of the side walls (11), preferably in two side walls opposite (with respect to the receiving space). 11), a receiving opening (13) for receiving the locking bolt is arranged. Guard rail device according to one of claims 4 to 6, characterized in that the locking element, in particular the first locking element (4), a locking pin (10), wherein the locking pin (7) in an opening (9) in the locking pin (10) protrudes, wherein the locking pin (10) is oriented at right angles to the locking pin (7) and preferably on the same guard rail element (2, 3) as the locking pin (7) is fixed, wherein the locking pin (10) in said locking receptacle (8), in particular in the receiving space (12). Guard rail device according to one of claims 4 to 7, characterized in that the locking pin (10) protrudes in the closed state into the receiving space (12), and thus the stop element (21) provides, wherein between the side walls (11) and the locking pin (10) play in the direction of the longitudinal axis (L) is present. Guard rail device according to one of the preceding claims, characterized in that the stop element, in particular the second locking element (5), by two transversely to the longitudinal axis (L) extending lugs (22) is provided, wherein one of the tabs (22) on the first guard rail element (2 ) and the other of the tabs (22) on the second guard rail element (3) is arranged, and wherein between the tabs (22) preferably play is present. Guard rail device according to claim 8 or 9, characterized in that the play of the stop element of the first locking element (4) is equal to or substantially equal to the play of the stop element of the second locking element (5). Guard rail device according to one of the preceding claims, characterized in that the actuators (15) of the first locking element (4) and the second locking element (5) on the same guard rail element (3, 4) are arranged. Guard rail device according to one of the preceding claims, characterized in that the second guard rail element (2) has a surface (17) arranged inclined to the horizontal, the surface (17) extending upward from the driving plane (H) and the locking bolts (7 , 28) penetrate the surface (17) in the locked state and protrude through the surface (17) in the second guard rail element (3). Guard rail device according to one of the preceding claims, characterized in that the first guard rail element (2) comprises a flap element (18) about an axis (X), which is parallel to the horizontal, with respect to the guard rail elements (2, 3) is pivotable. Guard rail device according to claim 13, characterized in that the Flap element (18) has a receiving area (19) which engages over the second guard rail element (2) partially and / or that the flap element (18) with its relative to the said axis (X) lying free end (20) is deductible on the road, wherein one of the top of the flap element (18) provides a plane inclined to the driving plane (23), so that a front impact protection can be provided. Guard rail device according to one of claims 12 to 14, characterized in that parts of the first locking element (4) and / or parts of the second locking element (5), in particular the actuators (6), on the flap element (18) are integrally formed.

Images