FR3021682A1 - HELICOIDAL TEMPORARY STAIRCASE FOR SCAFFOLD STRUCTURE - Google Patents

Abstract

A helical staircase (1) for a scaffolding structure to be installed between a lower level element and a top level element (5), comprising at least one climbing assembly comprising a mast (6) and steps ( 7) secured to the mast (6); a cage structure (9, 10) comprising a plurality of removable elements (12, 15, 16, 22, 26); wherein the riser assembly is secured to the cage structure (9, 10), and the cage structure (9, 10) is arranged so that at least one upper removable member (22) comes into compression on at least a face (24) of the upper level element (5).

Description

This invention relates to a helical temporary staircase for a scaffolding structure, intended to be installed between a lower level element and an upper level element. A well-known problem in public works, and especially in scaffolding structures, is access to high levels of scaffolding. Particularly when the practicable areas are narrow, and when the openings between the levels 10 are small widths, it may be relatively complicated to climb on the scaffold. In addition, when it is necessary to climb to high heights, the use of ladders is not a sufficiently secure solution. It is known to install a temporary staircase, in particular a spiral staircase, installed between a lower level element and a higher level element. This type of temporary staircase is supported on the side walls of the scaffolding or construction and can not be installed inside the scaffold, but is attached to the scaffolding. In addition, this temporary staircase is generally made of expensive parts to manufacture and specific to this use. Also there is the need for a temporary staircase whose installation is less restrictive. It is proposed a helical temporary staircase for a scaffolding structure, for example a multidirectional scaffolding structure, intended to be installed between a lower level element and an upper level element, comprising: a climbing assembly comprising a mast and steps secured to the mast; at least one cage structure comprising a plurality of removable elements; wherein the riser assembly is secured to the cage structure, and at least one cage structure is arranged such that at least one of the plurality of dismountable elements of said cage structure is compressible over at least one of the plurality of removable members At least one side of the higher level element. For example, the upper demountable member may compress on an upper face of the upper level member, exerting a substantially vertical pressure from top to bottom. Alternatively or in addition, an upper removable member 40 can come into compression on a lower face of the upper level element, exerting a substantially vertical pressure, from bottom to top. Advantageously and without limitation, at least one of the plurality of dismountable removable elements can come into compression on at least one face of the lower level element. Thus the cage structure can be self-stabilized by top-to-bottom compression. The lower removable element can come into compression on an upper face of the lower level element, for example on an upper face of the ground, exerting a substantially vertical force from top to bottom.

Alternatively or in addition, a lower removable element can come into compression on a lower face of the lower level element, exerting a substantially vertical force, from the bottom upwards, especially when the upper removable element comes into compression on a upper face of the upper level element. In other words, the cage structure then sandwiches the assembly formed by the lower and upper level elements. The riser assembly can be secured to the cage structure via steps and / or mat. Thus the cage structure is self-stable, and can overcome lateral support. The cage structure or structures thus exert efforts on the upper level element and the lower level element. In other words, these levels are used, rather than vertical walls as in the prior art, to ensure the stability of the staircase. For example, the staircase can be mounted inside a scaffold instead of being attached to the scaffolding. The lower and upper level elements may be slabs, for example concrete slabs, frames, beams or roofs. The steps may be welded to the mat, but may also, for example, include a hooked end snapped into the mat. All the steps can be identical or not. The removable members of the cage structure may comprise scaffolding elements, including multidirectional scaffolding members, for example spars and posts and any other known means for mounting scaffolds, for example oblique reinforcements. The longitudinal members, the uprights and the oblique reinforcements may, for example, comprise steel or aluminum tubes, with ends shaped so as to be secured to each other so as to form a strong structure. Removable elements can be integrated into the scaffolding. Thus, the cage structure may comprise elements whose supply is relatively easy, and the temporary staircase may be relatively easy to assemble. At least one removable element among the upper removable element and the lower removable element may comprise: - a scaffolding element; and / or a compression means, for example a jack, a telescopic end, a support foot and / or other. Thus the cage structure can be relatively well pressed against the upper or lower level elements. Advantageously and without limitation, the staircase is arranged so that the cage structure is relatively distant from the mast, for example more than one meter. The mast and the steps may pass through the lower and / or upper level members through openings in these level members without the removable elements of the cage structure having to pass through these openings. The helical provisional staircase then makes it possible to pass between lower and / or higher levels by relatively small openings, for example, with a width that is substantially double the width of a step. For example, the mast can be secured to the cage structure via at least one securing spar. The securing between the riser assembly and the cage structure (s) may be sufficiently robust so that on a portion of the riser assembly, there is no securing to the cage structure (s). Thus the rise assembly can pass through a relatively small opening, for example through a level element. Advantageously and non-limitatively, at least one removable element among the upper removable element and the lower removable element can be adjustable in height. The height-adjustable dismountable element may for example comprise an extensible free end, for example a telescopic end or an adjustment jack, which can be adjusted in height, for example by substantially vertical sliding of the end or the jack with respect to the Remainder of the removable element. The removable height-adjustable element can be locked at a determined height, for example manually, by locking lever, by screwing or by clipping. The cage structure can thus relatively adapt well to different heights between the lower and upper levels, which makes it possible to obtain a relatively versatile helical temporary stair. Advantageously and in a nonlimiting manner, at least one removable element among the upper removable element and the lower removable element can define a ball joint to fill a horizontal defect of the lower or upper level element on which the removable element comes in compression. Alternatively, at least one removable element among the upper removable element and the lower removable element can define a pivot connection. This lower or upper detachable member, comprising a ball joint or pivot connection, can be locked at a desired angle, for example manually, by locking lever, by screwing, by clipping, or the like. Thus, the cage structure can be relatively well adapted to different types of lower and upper levels, for example to roofs or non-level floors, which makes it possible to obtain a relatively versatile helical staircase. The climbing assembly may be shaped so that the mast and the steps extend over a height at least equal to the distance between the lower and upper level elements. Each step of the riser assembly may be arranged with respect to the adjacent steps, at an angle substantially between 1 ° and 90 °, and preferably between 10 ° and 45 °, and at a usual height for a staircase, for example between 15cm and 30cm. Advantageously and non-limitatively, the riser assembly may comprise at least two riser modules, each riser module may comprise: a mast segment; and - a set of six steps; Thus the helical temporary staircase can be relatively easy to assemble, disassemble and transport.

Advantageously and in a nonlimiting manner, each mast segment may comprise an upper free end and a lower free end, the upper free end of a mast segment being associated with the lower free end of another mat segment. .

For example, an upper free end of a mast segment may be nested in the lower free end of another mat segment. The two nested mats segments can be attached to each other, for example pinned at the junction of the upper end of one with the lower end of the other.

Advantageously and in a nonlimiting manner, the ends of the mat segments may comprise a polarizing device adapted to allow the insertion of a lower end of a mast segment into an upper end of another mast segment only for an angular position of one relative to the other predetermined. Thus the steps of each riser module can be properly positioned relative to each other simply because of the insertion of one mast segment into the other. The invention also relates to a scaffolding structure comprising at least one helical staircase as described above, and a scaffolding, for example a multidirectional scaffolding.

Other features and advantages of the invention will appear on reading the following description of a particular embodiment of the invention, given by way of indication but not limitation, with reference to the accompanying drawings in which: FIG. 1 is a schematic cross section of a helical temporary staircase according to one embodiment of the invention; FIG. 2 is a perspective view of an example of helical temporary staircase according to the embodiment of FIG. 1; - Figure 3 is a perspective view of a climbing module for a staircase according to one embodiment of the invention.

In the present description, the vertical term corresponds substantially to the direction of the gravity vector and the horizontal term refers to the directions extending in a plane substantially perpendicular to the vertical direction, the staircase being placed on a so-called horizontal and flat ground but it will be understood that the staircase may be used differently. By substantially horizontal, longitudinal or vertical means a direction / plane forming an angle of not more than ± 20 °, or not more than 10 ° or not more than 5 ° with a direction / a horizontal, longitudinal or vertical.

By substantially parallel, perpendicular or at right angles, we mean a direction / an angle deviating by not more than ± 20 °, or even more than 10 ° or not more than 5 ° from a parallel, perpendicular direction. or a right angle. A helical provisional staircase 1 for a scaffolding structure, not shown, is installed between a lower level element 3, here the floor 3, and an upper level element 5, here a concrete slab 5, extending into a substantially horizontal plane, and which defines a through opening 4 vertical. The staircase 1 comprises a mounting assembly 8. The assembly 40 mounted 8 comprises a mast 6 extending substantially vertically, and a plurality of steps 7 welded to the mast 6.

The steps 7 extend substantially helically and are spaced relatively evenly along the mast 6. In other words, the steps 7 form a spiral stair structure, progressing vertically around the mast 6.

The steps 7 are offset around the axis of the mast 6, relative to the other adjacent steps 7, by an angle substantially equal to PI / 12 radians. Referring to FIG. 3, the riser assembly 8 includes riser modules 34 comprising a mast segment 32, one meter high, and a set 33 of six steps 7. Each mast segment 32 comprises an upper free end 30 and a lower end 31 of shape substantially complementary to that of the upper free end 30. In this way two mast segments 32 can be secured to one another by inserting the free end upper 30 of one in the lower free end 31 of the other. Thus, the rising modules 34 can be superimposed, which makes it possible to mount the climbing assembly 8 relatively easily. Each mast segment 32 comprises a polarizing device, 20 not shown, here a lug on the upper free end 30 and a complementary notch in the lower free end 31, for imposing an angular position between two mast segments secured to each other. In other words, the polarizing device makes it possible to insert one mast segment into another only in a single angular position with respect to the insertion axis. The polarizing device thus imposes an angular position adapted so that the angle formed by two consecutive steps 7 around the axis of the mast 6 remains the same, in particular when two consecutive steps 7 do not belong to the same rise module 34.

Thus, the steps 7 can be relatively well positioned relative to each other, in particular at the boundaries between the various rise modules 34. The staircase 1 further comprises two cage structures 9, 10, here a cage structure lower 9, and an upper cage structure 35, which each comprise a plurality of removable elements, here scaffolding elements. The lower cage structure 9 extends between the floor 3 and the concrete slab 5. The lower cage structure 9 comprises four columns 15 of 40 uprights arranged vertically in abutment on the ground 3, and forming on the ground the four corners a square, referenced 14 in Figure 2, substantially one meter side.

These four post columns 15 are connected to each other by longitudinal members 16. The four post columns 15 and the longitudinal members 16 connecting them to each other form a substantially rectangular parallelepiped-shaped structure of great length. vertical and square horizontal section. An upper cage structure 10 extends above the concrete slab 5 and has substantially the same shape as the lower cage structure 9. The pillar columns 15 of the upper cage structure 10 bear on an upper face 5A of the concrete slab 5. The mast 6 is secured to the cage structures 9, 10, via securing rails, referenced 12 in Figure 2.

A securing spar 12 is connected to the mast 6 every 0.5m, at an angular position chosen so as not to hinder the climb. As a result, the two cage structures 9, 10 are secured to one another via the mast 6. The lower cage structure 9 comprises four upper removable members 22, here compression posts 22. compression post 22 is adjustable in height and is substantially offset towards the outside of the lower cage structure 9, by means of a support spar 23 and an oblique reinforcement 26 for reinforcing the support spar 23.

The compression posts 22 are arranged in such a way that they form, in horizontal section, the corners of a square substantially larger than the square formed by the horizontal section of the lower cage structure 9. The compression uprights 22 each comprise at their upper free end, a ball joint, not shown, and a compression cylinder 29 which comes into compression on a lower face 24 of the concrete slab 5. Each compression post 22 can be previously adjusted in height relative to the associated support spar 23, so as to position the compression ram 29 relatively close to the lower face 24 of the concrete slab 5, so that the compression applied by the compression cylinder 29 is sufficiently good to maintain the lower cage structure 9 in place. The blocking of the desired height for each amount of compression 22 is ensured by means of a locking means, here a screw jaw 27 connecting the amount of compression 22 to the associated support spar 23.

The columns 15 of the lower cage structure 9 and upper 10 each comprise a lower demountable element 25, here an upright 25 comprising at its lower free end a foot 28. Each foot 28 has a ball joint connection to the upright 25. associated, for pivoting the foot 28 relative to the upright 25, so as to adapt to the level element 3,5, on which it rests, respectively the floor 3 or the concrete slab 5. So the feet 28 allow a relatively good compression of the uprights 25 and cage structures 9, 10 associated.

The helical provisional staircase 1 thus sandwiches the concrete slab 5, via the lower cage structure 9 and the upper cage structure 10, and bears on the floor 3 via of the lower cage structure 10. Each cage structure 9, 10 is connected to the mast 6. Thus the spiral provisional staircase 15 is self-stable, and provides relatively simple and secure access to the upper levels of a scaffolding structure. In a variant, provision could be made, for example, for a mounting assembly 8 secured to a single cage structure 9 resting on the ground 3 and coming into compression against the lower face 24 of the upper level 5. According to another variant, could for example provide a mounting assembly 8 secured to two cage structures 9, 10, one resting on the ground 3, the other on the upper face 5A of the upper level 5. According to another variant, one could also have more than two levels. According to a not shown embodiment one could provide a rise assembly 8 high enough to cross for example four levels, each level comprising a cage structure.

Claims (9)

REVENDICATIONS1. Helical temporary staircase (1) for a scaffolding structure for installation between a lower level element (3) and an upper level element (5), comprising: - at least one riser assembly (8) comprising a mast (6) and steps (7) secured to the mast (6); at least one cage structure (9, 10) comprising a plurality of removable elements (12, 15, 16, 22, 23, 26); wherein the riser assembly (8) is integral with the cage structure (9, 10), and at least one cage structure (9, 10) is arranged for at least one upper removable element (22) among the plurality of removable elements (12, 15, 16, 22, 23, 26) of said cage structure (9, 10) comes into compression on at least one face (24) of the upper level element (5) . 2. helical temporary staircase (1) according to claim 1, said staircase (1) being arranged so that at least one lower removable element (25) among the plurality of removable elements (12, 15, 16, 22, 23 , 26) comes into compression on at least one face of the lower level element (3). 3. helical temporary staircase (1) according to any one of claims 1 to 2, characterized in that the mast (6) is secured to the cage structure (9, 10) via at least one securing spar (12). 4. helical temporary staircase (1) according to any one of claims 1 to 3, characterized in that at least one removable element (22, 25) among the upper removable element (22) and the lower removable element (25) comprises a scaffolding element (22, 25) and a compression means (28, 29). 5. helical temporary staircase (1), according to any one of the preceding claims 1 to 4, characterized in that at least one removable element (22, 25) among the upper removable element (22) and the removable element lower (25) is adjustable in height. 6. helical temporary staircase (1) according to any one of claims 1 to 5, characterized in that at least one removable element (22, 25) among the upper removable element (22) and the lower removable element (25) defines a ball joint for filling a horizontal defect of the lower level element (3) or upper (5) on which the removable element (22, 25) comes into compression. 7. helical temporary staircase (1), according to any one of claims 1 to 6, characterized in that the mounting assembly (8) 3021682 10 comprises at least two mounting modules (34), each mounting module ( 34) comprising a mast segment (32) and a set (33) of six steps (7). 8. helical temporary staircase (1), according to claim 7, characterized in that each mast segment (32) comprises an upper free end (30) and a lower free end (31), the upper free end (30). ) a mast segment (32) being substantially complementary in shape to that of a lower free end (31) of another mast segment (32). 10 9. Scaffolding structure characterized in that it comprises at least one helical provisional staircase (1) according to any one of claims 1 to 8.