DE3341647C2 - - Google Patents

Description

The invention relates to a standpipe with an attached thereto Sign, in particular a traffic sign, the standpipe from a one-piece square tube section consists of two levels, parallel to the level of the shield extending and two transversely arranged side walls.

A standpipe of this type is known from DE-GM 18 83 157. In this known standpipe is the square tube section on all four sides and throughout its entire length provided with openings for attaching a Serve traffic sign. The standpipe is attached to the floor. In the event of a vehicle impact, the openings act as Predetermined breaking points, whereby the impact is weakened is, but there is also a risk that the standpipe breaks off and that the freed part of the standpipe and causes personal injury.

The invention has for its object a standpipe of the beginning mentioned type to create that when starting off across the plane bend the sign at any point along its length can, the risk of breaking off part of the Standpipe is low.

This object is achieved according to the invention in that the two side walls running across the plane of the shield  of the square tube section in the longitudinal direction of the Square tube section are continuously V-shaped, and that at the retracting edges and at the transitions of these retracted side walls to the parallel to the sign flat side walls the wall thickness of the retracted side walls is continuously reduced in the longitudinal direction in the form of a groove.  

The sign is parallel to the flat side walls on the Standpipe attached so that the direction of impact with the Direction coincides in which the retracted side walls run. When starting the standpipe the retracted side walls in the through the weakened wall areas folded in a predetermined manner, namely on each belie Big place in the longitudinal direction of the standpipe. The location of the fold depends on the point at which the impact forces are greatest. The standpipe will kink at this fold, but it will do not cancel. It doesn't matter how this standpipe works deep in the socket of a foot.

The folding and folding process is still one embodiment favors that the partial side walls of the retracted side walls a have a smaller wall thickness than the adjacent flat side walls.

So that no paragraphs due to the weakening of the retracted side walls on the outside of the standpipe, there is another issue staltung that the weakening of the wall thickness of the retracted Side walls made on the inside of the retracted side walls are.  

The folding process of the standpipe is connected with a kink according to further refinements also favored that, viewed in cross section, the dimension of the square tube section in the direction of the retracted side walls is larger than the dimension in the direction of the adjacent flat side walls and that the retracting edges by more than the wall thickness of the retracted sides walls are drawn in (rectangular pipe section).

For security reasons, it is also provided that all edges of the Square tube section are rounded.

The production of the standpipe is carried out in the simplest way Cutting a correspondingly designed profile strand that the indented side walls with the weakened wall areas in one work already in the right position.

The production can also be done so that the square tube section a rolled and electrically welded steel sheet is formed.

An embodiment of the invention is based on a cross shown in the drawing section of a standpipe explained in more detail.

As the cross-section reveals, the standpipe essentially has the cross-section of a square tube. In the square tube section 10 used , however, only the opposite side walls 11 and 12 are flat. The standpipe is aligned so that these side walls 11 and 12 run parallel to the shield attached to the standpipe. If the sign is approached in the direction of the arrow, the V-shaped side walls 13 and 14 are folded inwards.

The V-shaped retracted side walls 13 and 14 are divided into the partial side walls 13.1 and 13.2 or 14.1 and 14.2 of the same size. The central retraction edges 15 and 16 lie at a retraction depth 23 and 24 which is greater than the wall thickness of the retracted side walls 13 and 14 . The purpose of the drawn-in side walls 13 and 14 is that they can fold when the standpipe is started up. In order for this folding process to be promoted, the drawn-in side walls 13 and 14 in the area of the drawing-in edges 15 and 16 are continuously weakened in a groove-like manner, as the wall areas 17 and 18 show. The transitions to the flat side walls 11 and 12 , which have a greater wall thickness than the retracted side walls 13 and 14 , are weakened in the wall thickness ge, as the wall areas 19 and 20 , and 21 and 22 show. This specifies the folding edges for the folding process. Since the ge weakened wall regions 17, 18, 19, 20, 21 and 22 extend over the entire length of the square tube section 10, may be when starting the Standroh 10 res of the square tube section at any point together quantitative be suppressed. This depends on where the greatest impact force occurs. At the point deformed in this way, the square tube section 10 can then also bend without breaking off.

The cross section of the square tube section 10 , as shown in FIG. 1, is obtained in one operation if the extruded or rolled profile strand, from which the square tube section 10 is cut to length, already has this cross section. This can only be achieved by the tool used in the manufacture of the profile strand. An aluminum extrusion from which appropriate lengths are separated is preferred. However, a rolled and electrically welded steel sheet can also be used to produce the square tube section 10 .

Claims (8)

1. standpipe with a sign attached to it, in particular a traffic sign, the standpipe consisting of a one-piece square pipe section which has two flat side walls running parallel to the plane of the sign and two transversely arranged side walls, characterized in that
that the two transverse to the plane of the shield side walls (13, 14) of the square tube section (10) continuously in the longitudinal direction of the square tube section (10) are V-shaped in each case drawn in and
that at the retracting edges ( 15, 16 ) and at the transitions of these retracted side walls ( 13, 14 ) to the flat side walls ( 11, 12 ) running parallel to the shield, the wall thickness of the retracted side walls ( 13, 14 ) is continuously reduced in the longitudinal direction . 2. Standpipe according to claim 1, characterized in that the partial side walls ( 13.1, 13.2 and 14.1, 14.2 ) of the retracted side walls ( 13, 14 ) have a smaller wall thickness than the adjacent flat side walls ( 11, 12 ). 3. standpipe according to claim 1 or 2, characterized in that the weakening of the wall thickness of the retracted side walls ( 13, 14 ) on the inside of the retracted side walls ( 13, 14 ) are made. 4. Standpipe according to one of claims 1 to 3, characterized in that, viewed in cross section, the dimension of the square tube section ( 10 ) in the direction of the retracted side walls ( 13, 14 ) is greater than the dimension in the direction of the adjacent flat side walls ( 11th , 12 ). 5. Standpipe according to one of claims 1 to 4, characterized in that all edges of the square tube section ( 10 ) are rounded. 6. Standpipe according to one of claims 1 to 5, characterized in that the retracting edges ( 15, 16 ) are retracted by more than the wall thickness of the retracted side walls ( 13, 14 ). 7. Standpipe according to one of claims 1 to 6, characterized in that the square tube section ( 10 ) is cut to length from an extruded or rolled extruded profile. 8. Standpipe according to one of claims 1 to 6, characterized in that the square tube section ( 10 ) is formed from a rolled and elec trically welded steel sheet.