CH716169A2 - Floor stand system for traffic signals and signs. - Google Patents

Abstract

The floor stand system (1) comprises a floor stand (3), consisting of a main frame (5) and two secondary frames (21) articulated to the main frame (5). Beacon feet (35) can be placed and held on the secondary frame (21). In strong winds, the floor stand system (1) can take on a Z-shape and thereby reduce the projected surface of the wind.

Description

The invention relates to a floor stand system for traffic signals and signs according to the preamble of claim 1.

Traffic signals and boards, which have to be set up temporarily on motorways, highways but also on traffic routes without guidance systems, such as crash barriers and the like, require wind-resistant floor stands. Usually beacon feet are used in which the tensioning tubes for the signals can be inserted. These beacon feet are heavy, but they have a relatively small footprint and at higher wind speeds, especially strong winds, cannot hold the traffic signals safely and tip over. A gust of wind can also be triggered by fast moving trucks and tilt the signal. A tilted signal is no longer visible to the driver and therefore danger zones can no longer be recognized in good time. In addition, a tilted beacon base can form a dangerous obstacle.

It is now an object of the present invention to provide a floor stand system for traffic signals and signs that can also be used in strong wind conditions, e.g. Withstand over 65 km / h safely.

This object is achieved by a floor stand system according to the features of claim 1. Advantageous configurations of the floor stand are described in the dependent claims.

[0005] The floor stand comprising a main frame and two secondary frames articulated thereon has a very large, in particular a multiple of the floor area of a beacon base. By placing one or two beacon feet on the secondary frames, which are spaced apart from the tensioning tube, it can be achieved that the traffic signals no longer overturn even at high wind speeds. At an even higher wind speed, the traffic signals can incline temporarily and decrease by reducing the projected area of attack of the wind. Immediately after a gust of wind or a prolonged high wind speed has subsided, the floor stand returns to its original position. This property is made possible by the articulated connection between the main frame and the secondary frame. At even higher wind speeds, which would also lead to the floor stand falling over, the traffic signal on the tensioning tube can have an elastic connection area between two tensioning tube sections, as is known from ski racing. Overturning can be prevented by the traffic signal flipping horizontally and consequently resisting the strong wind forces by completely reducing the area of attack.

[0006] The stability of the floor stand can also be increased significantly by placing additional beacon feet or other elements suitable as weights, such as steel or concrete slabs or containers or sandbags filled with water.

Both the floor stand and the beacon feet are stackable. To stack the floor stands, the side frames are swiveled by approx. 180 ° and sunk into the main frame, so that 10 or 20 floor stands can be stacked and transported on a standard pallet with minimal space requirements.

[0008] The invention is explained in more detail using an illustrated exemplary embodiment. Show it: <tb> <SEP> Figure 1 shows a floor stand with a main and secondary frame lying in a common plane and an attached and attached receptacle for a clamping tube, <tb> <SEP> Figure 2a shows a vertical section through the floor stand in Figure 1, <tb> <SEP> FIG. 2b a perspective view of the floor stand with a partially cut receptacle, <tb> <SEP> Figure 3 a floor stand with the holder removed, <tb> <SEP> Figure 4 a floor stand, each with a beacon foot placed on the side frame with an attached receptacle, <tb> <SEP> Figure 5 shows a floor stand with attached beacon feet, the main frame of which is raised by a gust of wind or strong wind at an angle α to the stand surface and <tb> <SEP> Figure 6 a floor stand with folded side frame, ready for transport.

Reference number 1 denotes a floor stand system. This comprises a floor stand 3 with a main frame 5 made of two bars 7, two bars 9 connecting the bars 7 and a central bar 11. The two bars 7 are preferably made of U-shaped profiles made of steel or aluminum, the legs of the bars 7 according to are directed above. The webs 9 are, for weight reasons, also U-shaped profiles. You could also have closed rectangular cross-sections. The central web 11 consists of a tube which is connected to the two bars 7. A receptacle 13 made of a pipe, preferably a rectangular pipe, is held on three sides by a holder 29 fastened to the central web 11 and by a carrier 12 with a recess into which the lower end of the receptacle 13 can engage. The receptacle 13 can be removed from the holder 29 on the central web 11 and, in the assembled state, can be kept tensioned by a tensioning means 15, for example a lashing strap. At the ends of the spars 7, bores are formed in their legs which receive pivot pins 17. The first ends of spars 19, which laterally form a secondary frame 21, are hinged to the pivot pin 17. The bars 19 of the secondary frames 21 are also webs 23 and 25 connected to one another. On the outer second ends of the webs 23, 25 tabs 27 are formed. These can be attached to the outer web 23, 25 or made in one piece with the web 23, 25 by a stamping / bending process.

Next, a stop plate 31 is attached to the spars 19 of the secondary frame 21 in the area of the joint at the pivot pin 17, which on the one hand restricts the pivot angle between the main frame 5 and the secondary frame 21. Furthermore, a bearing plate 33 connecting the bars 7 can be inserted between the bars 7 of the main frame 5, on which the receptacle 13 can be placed and stowed after its dismantling when not in use.

As shown in the figures, beacon feet 35 can be placed on the two secondary frames 21 as weights. Beacon feet 35 are usually made of waste rubber and the like or concrete bodies for inserting tensioning tubes 43 suitably shaped holes 37 and handles 39 designed for their transport. Of course, plates made of steel or concrete, sandbags or containers filled with water can also be used as weights.

Figure 5 shows the floor stand system 1 in strong winds, for example wind over 50 km / h (see arrow F). The main frame 5 is pivoted around the joint between the secondary frame 21 and the main frame 5 by an angle α to the bearing surface on the floor. The secondary frame with the beacon foot 35 on the right side continues to lie on the floor; the secondary frame 21 on the left has pivoted downwards by the angle α and continues to lie horizontally, i.e. parallel to the ground. The secondary frame 21 on the right-hand side is held in this position by the latching plate 31 against shifting. The locking plates 31 are shaped as triangularly protruding teeth from the spars 19 of the secondary frames 21. The upwardly protruding prong prevents the beacon foot 35 from sliding against the main frame 5 when there is a lot of wind. Suitable means (not shown) prevent the secondary frames from pivoting by more than the angle α. The pivoting of the main frame 5 and thus also of the receptacle 13 with the clamping tube 43 inserted therein, which carries a traffic signal at its upper end, is also inclined by the angle α to the ground surface. As a result, the projected area of the traffic signal, which is exposed to the force F of the wind, has been reduced. The floor stand 3 consequently does not tilt. As soon as the force F of the wind decreases, the main frame 5 and the left side frame 21 return to the ground and are again in the extended common ground plane.

Figure 6 shows the floor stand 3 in the transport position. The two secondary frames 21 are pivoted about the pivot pins 17 and placed in the main frame 5. They are partially sunk between the legs of the spars 7 of the main frame 5 and thus do not protrude beyond the webs 9 or their upper edges at the height H. They can therefore easily be stacked on top of one another to save space. In order to prevent the floor stands 3 stacked on top of one another from shifting during transport, bores 45 for pins 47 are formed in the webs 9, which interlock with the stacked floor stands 3.

The floor stand 3 are inexpensive from commercially available profiles for the bars 7, 19 and the webs 9, 23, 25 and the receptacle 13 or from simple profiles generated by a punching and bending process, which is placed on the bearing plate 33, manufacturable.

Legend of the reference symbols

1 floor stand system 3 floor stand 5 main frame 7 spar 9 web 11 central web 12 support 13 receptacle 15 clamping means 17 pivot pin 19 spars of 21 21 secondary frame 23 webs on 21 25 webs on 21 27 tabs 29 retaining bracket 31 locking plate 33 bearing plate 35 beacon base 37 holes 39 Handle 41 Elevation 43 Clamping tube 45 Holes 47 Pins

Claims (8)

1. Floor stand system (1) with a floor stand (3) for traffic signals and signs, comprising a stand with a standing surface for installation on asphalt, gravel or meadow surfaces and a receiving tube (13) for attaching a clamping tube (43) for a Traffic signal, characterized in that the stand comprises a main frame (5) for fastening the receptacle (13) and two secondary frames (21) which can be deflected on the main frame (5). 2. Floor stand system according to claim 1, characterized in that the main frame (5) comprises two spaced bars (7) consisting of profiles, two webs (9) connecting the bars (7) and a central web (11) on which the receptacle (13) can be fastened. 3. Floor stand system according to one of claims 1 or 2, characterized in that the webs (9) have a greater height H than the height h of the spars (7) and have means (45, 47) for holding floor stands (3) stacked one above the other . 4. Floor stand system according to one of claims 1 to 2, characterized in that the receptacle (13) is releasably connected to the central web (11) by a holder (29) and is designed to be braced with a clamping element (15) with the central web (11) . 5. Floor stand system according to one of claims 1 to 4, characterized in that means (31, 27) for holding the beacon feet (35) are formed on the secondary frame (21). 6. Floor stand system according to one of claims 1 to 5, characterized in that the secondary frames (21) are connected to pivot pins (17) with the main frame (5), the pivot angle from the stretched, lying in line with the main frame (5) Working position down is smaller than from the working position up. 7. Floor stand system according to one of claims 1 to 6, characterized in that the cross sections of the spars (7) of the main frame (5) are U-shaped and that the spars (19) of the secondary frame (21) for transport between the legs of the Spars (7) of the main frame (5) are designed to be insertable. 8. Floor stand system according to claim 7, characterized in that on the spars (19) of the secondary frame (21) locking plates (31) to prevent sliding and to hold the beacon feet (35) plates made of steel or concrete or filled with water or sand Containers are arranged.