DE19716986A1 - Spiral flight of steps - Google Patents

Abstract

The flight of steps on a steel support structure, has a beam support carrier as a central carrier (30). Spaced plates (23), at the carrier (30), each support the steps (5). Each step (5) on each under plate (23), is positioned by at least two rotary axes (27,28). The walking surfaces (22) on each step (5) are of artificial stone, wood overlays or they are metal steps.

Description

The invention relates to a substructure stairs, in particular a special steel substructure stairs

• - At least one clamped spar support beam and
• - Step elements with at least one step element.

A steel substructure staircase of the type mentioned at the outset is known from the DE catalog leaflet from BRAUCKMANN: Stahlunterkonstructionstreppen, 1994, and is shown in FIG. 1.

From one level to a higher level is a certain number in a slope ratio Levels are provided to ensure safe access. The tread elements designed as step supports supported by a steel substructure. To do this, run two spar support beams parallel to each other from floor to floor Floor level.

The well-known steel substructure staircase according to FIG. 1 has proven itself as a spiral staircase with different turns or as a platform staircase, but is extremely expensive in terms of material and production technology. Because in order to be able to implement every step height and step support, correspondingly long steel sections have to be cut and then welded together.

The invention is therefore based on the object Steel substructure stairs of the type mentioned at the beginning to develop further so that they are less material and is expensive to manufacture.

According to the invention, this object is achieved by

• - That the spar support beam as a central spar support beam is formed
• - That spaced apart on the central strut support beam of the sub-plate elements arranged on which the steps elements are held, and
• - That each step held on a sub-plate element element around at least two axes of rotation.

The advantages achieved with the invention are in particular the fact that instead of the cut beam beams only continuous, if necessary, podiums considered gender central strut support beam is used. This with telholm support beam can be according to the desired Stei be inclined. The fixed in at least two axes of rotation the lower plate elements allow a uni verselle prefabrication of these parts and on the other a di right and quick adjustment to the individual Steel substructure stairs to be delivered. The substructure tion can also be made from other high-strength steel Materials such as wood, stone, plastic and others Metals such as titanium. Because with one Axis of rotation, the lower plate element can be adjusted so that the step element held by her is always horizontal is held. With the second axis of rotation, the required Turn of the stairs are taken into account. This turn can as with the well-known steel substructure stairs a quarter turn, a two and a quarter turn, or be a pedestal.

The first axis of rotation can be a circular plate Be sub-plate element. It has proven to be advantageous that the circular plate has a radius of 100 mm.  

The second axis of rotation can be at least one on a Haltpro fil adjustable support with a fixing element be profile element. This creates a joint that with Using the fixing element were at different angles is adjustable. This joint design ensures a very quick and exact leveling of the step elements compared to the installed central spar support beam.

The first and second axes of rotation allow a three dimensional adjustment of the step elements compared to the Center strut support beam. To further facilitate the Monta ge can also add a third to these two axes of rotation be added, which with a fastener on the Center spar support beam can be arranged holding profile. The fastener can be a screw or Welded joint. This third rotation so trained axis effectively supports the through the circular plate realized first axis of rotation.

The tread elements held by the circular plate of each stu fenelements can be made of artificial stone or wooden steps be trained. The tread elements can also be made of stretch metal or a known for the training of Stairs used to be made of material.

The invention is explained in more detail with reference to the drawing. Here are shown in

Fig. 1 shows a known steel substructure staircase

Fig. 2 is a steel substructure staircase according to the invention in a schematic plan view,

Fig. 3a is a partial side view of a constructive Stahlunterkon tion staircase according to Fig. 2,

FIG. 3b is a further partial side view of a steel substructure staircase according to Fig. 2,

Fig. 4 is an enlarged section of a partial side view of a steel substructure staircase and shown in FIG. 3b

Fig. 5 is a partial plan view of a detail according to Fig. 4.

A steel substructure staircase shown in FIG. 1 and already known in detail in the description is used to overcome a height difference between a floor level E1 and a floor level E2.

In Fig. 2 the overcoming of such a floor level is shown with the help of a steel substructure according to the invention. It runs within a space delimited by boundary walls 40 , 41 , 42 . 40 , 41 , 42 are constructive but not necessary.

It is essential to the invention that the steel substructure staircase according to FIG. 2 is held by a single central beam support 30 made of metal, preferably steel. This is subdivided into incline beams 29 , between which, as shown in FIG. 3a, a central spar support beam 31 is arranged, depending on the design of the stairs. The central spar support beam 30 is held in the level E1 by a stair bearing 15 and in the higher level E2 by a further stair bearing 16 . Statically, the central strut support beam 30 thus behaves like a clamped bridge construction.

In the central stringer support beams 30 are step elements 1. . . 14 arranged. The step elements 1 ,. . . 14 , as shown in FIGS . 4 and 5, consist of a lower plate element 23 on which a step element 22 is arranged as a step support. The tread elements are formed in known formations from wood, stone, marble, metal, expanded metal and the like.

Essential to the invention is the formation of the Unterplattenele element 23 and the substructure supporting it.

So the lower plate member 23 is formed as a circular plate 23 ', are introduced into the mounting recesses 32 , 33 , 34 and 35 for holding the tread element 22 . The circular plate 23 'has a disk diameter of D = 200 mm at a radius of 100 mm. The circular plate 23 thus forms a first axis of rotation for a variable attachment of the tread elements 22nd The selected disc diameter of D = 200 mm gives the step element 1 ,. . . the required static stability. In addition to being circular, the sub-plate element 23 can also have other geometric shapes such as an ellipse, triangle, square, pentagon, hexagon. . . be trained.

Two tongue-shaped support profile elements 24 , 25 are arranged at a distance from one another under the lower plate element 23 . They are each traversed by a recess. On the incline bracket 29 and the heel bracket 31 of the central strut support bracket 30 , a holding profile element 26 is arranged. The holding profile element 26 can be realized either by a fastening element 28 , a welded connection or by shaping the carrier. The holding profile element 26 is provided with a recess. From the recesses of the support profile elements 24 , 25 and the Haltepro filelement 26 , a locking element 27 is carried out in the form of a bolt with a screw. This makes the determination of element lisiert 27 further rotational axis rea locally. The type of attachment of the holding profile element 26 z. B. in the form of a fastener 28 represents a white tere axis of rotation. The axes of rotation 23 'and 27 allow the tread element 22 to be adjusted three-dimensionally. This makes it possible to adapt the individual step elements 1 ,. . . 14 given the respective slope of the center strut support beam 30 and the installation site during assembly. The third axis of rotation 28 can be used to further increase the possible variations. The axis of rotation 28 already enables the recesses to be adapted to the fastening recesses 32 , 33 , 34 and 35 of the lower plate element 23 . By using the axis of rotation 28 , the adaptation work between the lower plate element 23 and the attached tread element 22 can be reduced.

A comparison of the steel substructure staircase according to FIG. 1 and that of FIGS. 2 to 5 makes it clear that the material and manufacturing costs are significantly reduced by the steel substructure staircase according to the invention. The presence of at least two axes of rotation 23 'and 27 allows a quick and optimal adjustment of the step elements 1 ,. . . 14 at the respective site. Any manufacturing tolerances that arise during the prefabrication of the steel substructure stairs can also be effectively compensated for.

Claims (6)

1. Substructure stairs, in particular steel substructure stairs, with

• - At least one clamped spar support beam ( 30 ) and
• - Step elements ( 1 ,... 14 ) with at least one tread element ( 22 ),
  characterized by
• - That the spar support beam is designed as a central spar support beam ( 30 ),
• - That on the central strut support beam ( 30 ) spaced un one below the other, arranged plate elements ( 23 ) on which the step elements ( 1 ,... 14 ) are held, and
• - That each on a sub-plate member ( 23 ) nes step element ( 1 ,... 14 ) held by at least two axes of rotation ( 23 ', 27 , 28 ).

2. Staircase according to claim 1, characterized in that the first axis of rotation is a bottom plate element ( 23 ) designed as a circular plate ( 23 '). 3. Staircase according to claim 1 or 2, characterized in that the second axis of rotation is at least one on a holding profile ( 26 ) with a fixing element ( 27 ) adjustably arranged support profile element ( 24 , 25 ). 4. Staircase according to one of claims 1 to 3, characterized in that the third axis of rotation is the holding profile ( 26 ) which is adjustably arranged with a fastening element ( 28 ) on the central strut support beam ( 30 ). 5. Staircase according to one of claims 1 to 4, characterized in that the fastening element ( 28 ) is made as a screw or welded connection. 6. Staircase according to one of claims 1 to 5, characterized in that the tread elements ( 22 ) are constructed as artificial stone or wooden step pads or metal steps.