The invention relates to a vehicle restraint system for delimiting roadways, including base bodies that can be detachably coupled to one another, wherein the base bodies can be placed on a road surface and have at least one weighting body.
Vehicle restraint systems for delimiting roadways are known from the prior art. DE 200 03 791 U1 discloses a mobile protective steel wall for delimiting roadways made of individual wall segments which can be arranged end-to-end. Every wall segment has crash barriers arranged in parallel to the roadway and resting on at least two supports standing on plate-like foot members. The crash barriers are bolted to mounting surfaces that extend upwards from the supports and vertically relative to the roadway. Finally, the mobile protective steel wall is formed by two opposing mounting surfaces with bolted-on crash barriers. Located in between the bottom crash barriers is a heavy material.
Protective steel walls that are built according to this design have the disadvantage of possessing a high dead weight. Especially for storage, transport and installation elaborate aids for generating large forces are required for moving the protective steel walls. Thus, the protective steel walls have to be short to keep the weight of each individual segment low.
Several protective steel walls linked end-to-end can have a poor tension strap property in the case of a vehicle impact resulting in a poor protective characteristic.
US 2006/024826 discloses a vehicle restraint system which has an internal container for the uptake of water, sand or similar fillers. Up until the filling process, the entire vehicle restraint system is relatively lightweight. The container can be filled within the vehicle restraint system through openings in the head region of the vehicle restraint system and emptied through openings in the foot region of the vehicle restraint system. The container is connected to the vehicle restraint system and is malleable in its unfilled state and thus folds in when segments of the vehicle restraint system are stacked upon each other. During refilling, the container recovers its initial position.
This system is disadvantageous in that the vehicle restraint system has to be filled with weighting material after being deployed at the desired location. This filling process is quite elaborate, time-consuming and cost-intensive. Additionally, the unfavorable weight distribution of the filler inside the container with regard to the vehicle restraint system results in a high center of gravity, depending on the filling degree.
Therefore, based on the state of the art, the object of the present invention is to provide a vehicle restraint system which can realize different restraint levels through superstructures and different coupling variants and through loading or unloading.
The afore-mentioned object is solved according to the features of patent claim 1 in that the weighting body has a outer casing which is filled with a curable filler and in that fasteners are provided on the weighting body and protruding in relation to the weighting body, thus allowing the weighting body to be fixed in the base body through, or by means of, the fasteners.
Sub-claims 2 to 13 set forth further advantageous embodiments and refinements of the basic inventive idea.
The advantage of the solution according to the present invention is that the base bodies of the vehicle restraint system can be equipped with weighting bodies in a modular fashion. The weighting bodies are designed to be particularly easy to store, transport and install. Depending on the demands on the restraint value of the vehicle restraint system, the base bodies can be equipped with single or several weighting bodies.
The weighting bodies have fasteners for fastening in the base bodies. This offers the particular advantage that the weighting bodies can be mounted inside the base body through the fasteners or arranged before or after mounting through engagement on the fasteners.
In the case of a collision of a vehicle with the base body, the weighting bodies remain securely anchored in their position and therefore cannot flail. At their top end, the base bodies further have means for receiving superstructures and thus are adaptable in height.
Maximal loading of the vehicle restraint system with weighting bodies results in a high restraint level with small transversal displacement. Thus, restraint levels T1 to T3 can be realized through the loading state of the system.
Preferably, the weighting body has a cylindrical shape. This offers the particular advantage that the cylindrical shape can be optimally integrated into the base body. Because of the cylindrical design, the weighting body contacts the base body on each side only in one line. This provides for a sufficient deformation behavior of the remaining part of the base body above and below the line of contact. A cylindrical shape further promotes transport and storage of weighting elements and further offers an optimal size-weight ratio.
Further shapes of the weighting body are also subject matter of the present invention. The outer geometry of the weighting body can be adapted to the inner contour of the base body to achieve a maximal weighting of the base body.
In a preferred embodiment, the weighting body has a length of 50 to 200 cm, a width of 10 to 35 cm and a height of 10 to 35 cm. Especially preferred is a length between 85 and 95 cm.
According to the invention, a cylindrical shape of the outer casing also relates to a cross sectional profile that is circular, elliptical, angular or any combination of the afore-mentioned features.
Preferably, the outer casing of the weighting body is formed as a plastic tube. During manufacturing this offers a particularly simple manufacturing design of a permanent formwork and gives the weighting body greater dimensional stability. During use of the vehicle restraint system, the plastic tube has the further advantage of minimizing the projection effect of the curable filler located inside the plastic tube. During assembly and disassembly of vehicle restraint systems, a plastic tube also protects the weighting bodies particularly well against external influences from shock or weather conditions. Preferably, the plastic tube has a diameter of about 25 cm and a wall thickness in the range of 1 to 20 mm.
In a preferred embodiment of the present invention, the curable filler is concrete. This offers the advantage that the filler can be very easily introduced into the outer casing as fluid where it then cures. A further advantage of concrete is that it can be favorably used during manufacture and, because of the density of concrete, an optimal size to weight ratio can be achieved with regard to the geometric shape of the weighting body. Especially suitable as filler is a B25-concrete.
Preferably, reinforcing bars are cast-in in the curable filler. The curable filler tends to have a brittle material property and can thus break from shocks which occur during assembly or transport. The reinforcing bars provide additional dimensional stability to the cured filler in the outer casing. In a possible embodiment, the reinforcing bars are disposed in the inside of the outer casing as cross struts, such that they prevent shifting of the curable filler inside of the outer casing.
The fasteners are preferably formed as mounting brackets, wherein the mounting brackets are located at the ends of the weighting body. With the aid of the mounting brackets, the weighting bodies are particularly advantageously mountable in the base body. To ensure a particularly easy modular assembly of the vehicle restraint system, the mounting brackets are formed with protruding legs which point in the longitudinal direction of the weighting body. Further, the mounting brackets prevent shifting of the cured filler in axial direction inside the outer casing after manufacture of the weighting body. Through the shape of the mounting brackets the weighting body can be adapted to the respective vehicle restraint system or the respective base body, respectively.
In a preferred embodiment, the mounting brackets have an abutment section which is formfittingly fixed in the weighting body by the curable filler. According to the invention, an abutment section relates to an extension of the mounting bracket in axial direction of the outer casing. To achieve an optimal formfitting connection between curable filler and the abutment section, the extension is shaped in a particular way at its end. For example, at its end the extension can be spread out or have a thickening. Particularly preferably, the abutment section is formed as Nelson-anchor.
To achieve an additional increase of the strength of connection between the mounting bracket and the weighting body, a forced connection between the abutment section and the curable filler can be generated by using an additive. In a further embodiment according to the present invention the mounting brackets can also be bolted to the weighting body.
Preferably, the mounting brackets at the end faces of the weighting body have different leg lengths in longitudinal direction of the weighting body. This offers the advantage to accommodate the different receiving areas for weighting bodies of different vehicle restraint systems. Further, through the different leg lengths, the weighting body is defined in its orientation, which means that an accidental switching of left and right side is excluded.
In a preferred embodiment, a weighting body with one mounting bracket on each end face is mountable on runners in a foot area of the base body, especially preferably through formfitting mounting with through bolts. In this case, the runners of the base body extend in cross direction with regard to the base body. By mounting the weighting body in the foot area, a low center of gravity is established for the base body and particularly for the vehicle restraint system as a whole. The low center of gravity allows for a high tilt resistance in case of a collision of a vehicle with the vehicle restraint system as well as small displacement perpendicular to the roadway. Mounting with through bolts allows for a particularly cost-efficient, simple and fast mounting and at the same time offers high reproducibility and quality of the generated connection, independent of the experience of the installer.
Preferably, the runners of the base body have oblong holes extending in longitudinal direction with regard to the base body, with two mounting brackets from neighboring weighting bodies being fastened in common oblong holes. In combination with the fastening of mounting brackets on the runners by means of through bolts, the oblong holes form the analogous counterpart to through bores in the mounting brackets for receiving the through bolts. The oblong holes in the runners allow for clearance in longitudinal direction of the weighting bodies for mounting in the base bodies. This makes the overall assembly easier especially when several weighting bodies are arranged in a base body.
In a further preferred embodiment, the base bodies have support feet on a bottom side of the runners, wherein a support foot is formed by an elastomer body which is connected to a metallic main body. Preferably, the elastomer body has a hardness of more than 50 Shore, especially preferred 70 Shore. Suitably, the support feet are fixed to the runners. The runners are provided with oblong holes for receiving threaded bolts of the support feet, with the oblong holes extending perpendicularly to the road surface.
In the event of a collision of a vehicle with the vehicle restraint system, a first energy dissipation occurs in view of a displacement of the vehicle restraint system via the oblong holes. As a result, the base body shifts on the support feet transversely to the road. The support feet remain firmly standing on the road surface until the end of the distance or possible avoidance provided by the oblong holes is reached. Subsequently, displacement of the vehicle restraint system is kept small through the connection of the vehicle restraint system with the road surface through the elastomer bodies. This has the advantage that inadmissibly high transverse forces are avoided. The degree of severity of acceleration exerted on the vehicle passengers is lowered by the inventive solution. An example for measuring the degree of severity is the ASI-value, Acceleration Severity Index.
Further, the elastomer body offers the advantage to compensate tolerances in the road surface over the length of the base body for the coupling of a second base body.
In a further preferred embodiment, the runners of the base body have oblong holes which are oriented towards the road. In the event of a collision with a vehicle, a first dissipation of energy can occur on these holes through displacement perpendicular to the road, reducing the force of impact.
Preferably, a base body has holes at its end faces, to connect several base bodies end-to-end to one another. This results in a very good tension strap property of the vehicle restraint system in the event of a collision with a vehicle. Preferably, couplers in the form of threaded bolts are used as connection. The base bodies can be connected to each other through a central hole or through two holes in side-by-side relationship, depending on the desired restraint level. For a low restraint level, two base bodies can be connected through a central hole, and for a higher restraint level, the base bodies can be coupled through two holes in side-by-side relationship.
Further, superstructures can be added to the base bodies to achieve a higher restraint level. The superstructures are fixed on the base bodies with coarse threaded bolts. For this purpose internal threads are present on a sheet metal in the interior space of the base body, with the sheet metal extending horizontally along the length of the base body. At the same time, this sheet metal improves the deformation characteristics of the base body in event of a collision.
Further advantages, features, properties and aspects of the present invention follow from the description below. Preferred embodiments are shown in the drawings which merely serve for ease of understanding of the invention. It is shown in:
In the Figures, same reference signs are used for same or similar parts, whereby corresponding or comparable advantages are achieved even though, for sake of simplification, a repetitive description is omitted.
In
1—Vehicle restraint system
2—Roadway delimitation
3—Base body
3
a—Face plate
3
b—Hole
4—Road surface
5—Weighting body
6—Outer casing
7—Curable filler
8—Fastener
9—Reinforcing bars
10—Mounting bracket
11—End face
12—Abutment section
13
a—Horizontal leg
13
b—Horizontal leg
13
c—Vertical leg
13
d—Vertical leg
14—Runners
15—Foot area
16—Through bolt
17—Oblong hole
18—Bottom
19—Support foot
20—Main body
21—Elastomer body
22—Superstructure
23—Coarse threaded bolt
L—Longitudinal direction
S—Steel cable
Number | Date | Country | Kind |
---|---|---|---|
10 2009 050 266.1 | Oct 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/DE2010/001196 | 10/12/2010 | WO | 00 | 1/10/2012 |