DE29714266U1 - Rolling scaffold - Google Patents

Description

Company

ALTEC Aluminum Technology

Hans-J. Gebauer GmbH
Nicholas-Otto-Street

56727 Mayen

Roll scaffolding

The invention relates to a rolling scaffold with two or more scaffold ladders into which work platforms are suspended, and with triangular outriggers assigned to vertical struts of the scaffold ladders to increase the stability of the rolling scaffold, each of which has a support arm resting on the ground and a spacer arm to determine the distance of the lower end of the support arm from the assigned vertical strut, and which can be detachably attached to this vertical strut via coupling pieces,

Such mobile scaffolding is available in a wide variety of designs (systems) and is primarily used for work in and on buildings. A characteristic feature of some of the

Rolling scaffold systems are support arms, so-called triangular arms to increase stability. In practice, certain angle positions must be observed. Since optimal horizontal angle positions of the triangular arms promote the stability of rolling scaffolds, the employers' liability insurance association has a requirement to take measures to ensure these angle positions by means of structural measures.

One object of the present invention is therefore to create a rolling scaffold of the type mentioned above, in which the optimal horizontal angular positions of the triangular booms are ensured in a simple and cost-effective manner.

This object is achieved by the characterizing features of claim 1. Advantageous further developments of the invention are specified in the subclaims.

Accordingly, the proposal according to the invention for ensuring optimal horizontal angular positions of the triangular booms consists in the extremely simple measure of providing a positive connection in the form of a complementary projection/recess connection between each triangular boom coupling piece and the associated vertical strut of the rolling scaffold. In the simplest form, the projection consists of a pin or pin or the round head of a rivet and the recess consists of a circular recess or a circular hole, whereby it is irrelevant whether the projection is arranged on the coupling piece of the triangular boom and the recess or recesses on the associated vertical strut part or vice versa.

· I

In principle, the projection can also be formed in one piece with the coupling piece or the vertical strut part 1. In order to subsequently equip existing coupling pieces and vertical strut parts with the measure according to the invention, the projection preferably consists of the head of a rivet, preferably a round-head rivet.

According to a particularly preferred embodiment, the recess has a slot shape and the projection is a rib adapted to this slot shape, with the longitudinal axis of these connecting elements running parallel to the vertical struts of the scaffold ladders. This embodiment is particularly advantageous because, while ensuring the optimal horizontal angular position of each triangular boom, it also allows the height of this connection to be optimized, namely by adapting it to an optimal standing position of the rolling scaffold according to the invention.

For a free-standing mobile scaffold, the optimal horizontal angle position of each triangular boom is approximately 60° in relation to the longitudinal center line of the mobile scaffold or a working platform of the same. If the mobile scaffold is set up close to the building wall, at least the two triangular booms that are to be located close to the building wall are arranged parallel to the said longitudinal center line.

In order to be able to implement these two alternative optimal horizontal angle positions of the triangular booms, either two recesses are assigned to one projection or two projections are assigned to one recess in the coupling piece or the associated vertical strut.

The invention is explained in more detail below using the drawing as an example; in the drawings:

Fig. 1 is an exploded view of an embodiment of the rolling scaffold according to the invention,

Fig. 2 is a schematic plan view of the assembled rolling scaffold with a first preferred optimal horizontal angular position of the triangular booms,
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Fig. 3 is a schematic plan view of the assembled rolling scaffold with a second preferred optimal horizontal angular position of the triangular booms,

Fig. 4 a detailed view of a triangular bracket close to the wall from Fig. 3,

Fig. 5 a detailed view of a triangular boom remote from the wall from Fig. 3 or a triangular boom from Fig. 2,

Fig. 6 shows a plan view of a first embodiment of the coupling piece according to the invention,

Fig. 7 a cross-sectional view of a vertical strut of the inventive rolling scaffold in the coupling piece assembly area ,

Fig. 8 is a view of the rolling scaffold in the area of the vertical strut of Fig. 7 in the direction of arrows A,A of Fig. 7,

Fig. 9 shows a second embodiment of the coupling piece according to the invention as a modification of the embodiment of Fig. 6, and

Fig. 10 is a view similar to Fig. 7 of the vertical strut interacting with the coupling piece of Fig. 9.

The embodiment of the rolling scaffold shown in Fig. 1 consists of prefabricated and partially assembled modules, comprising: a basic folding unit 1, four triangular outriggers 2, 3, 4 and 5, two working platforms 6 and 7, a vertical structure 41, a frame or toe board 8 for the upper working platform 7, and a round railing 9.

The basic folding unit consists of two lateral scaffolding ladder parts 10 and 11, which are connected to one another via a folding part 12, and a horizontal bar 13. Each scaffolding ladder part 10, 11 consists of two vertical strut parts 14, 15 and 16, 17, respectively, which are each connected to one another via a plurality of mutually spaced rungs, of which the lowest rungs are designated 18 and 19 respectively in Fig. 1 and a top rung is designated 19'. In order to be able to move the fully assembled rolling scaffold to the respective location and position it precisely there, lockable rollers are provided at the lower end of the vertical strut parts 14 to 17, of which the roller of the vertical strut 17 is designated 20 in Fig. 1 as a representative of the other rollers.

The triangular booms 2 to 5, which are to be linked to the vertical strut parts 14 to 17, each consist of a

Support arm 21, 22, 23 and 24 and a spacer arm 25, 26, 27 and 28, which is hinged to the lower end of the respective support arm in order to determine its base-side distance from the associated vertical strut parts 14 to 17. Coupling pieces 29 to 32 or 33 to 36 or 37 to 40 are used to link the spacer arms 25 to 28 to the support arms 21 to 24 and to link the support arms 21 to 24 to the upper ends of the associated vertical strut parts 14 to 18 and the spacer arms 25 to 28 to the lower ends of these vertical strut parts 14 to 17. Either the coupling pieces 33 to 36 or the coupling pieces 37 to 40 or both of these types of coupling pieces are designed according to the invention, as explained below with reference to Fig. 6 and 9, and they are pre-assembled on the vertical strut part-side ends of the support arms 21 to 24 and the spacer arms 25 to 28. The coupling pieces 29 to 32 for connecting the support arms 21 and 24 to the spacer arms 25 to 28 can be designed in a conventional manner and are preferably permanently connected to these arms in order to provide the triangular outriggers pre-assembled at the location of the mobile scaffold for easy on-site assembly.

The vertical structure 41 consists of scaffolding ladder parts arranged in pairs opposite one another with vertical strut parts 42, 43 and 44, 45 similar to the vertical strut parts 14 to 17 of the basic folding unit 1 . These vertical strut parts 42 to 45 are also firmly connected to one another by mutually spaced rungs to form ladder elements, of which the lowest rungs are designated with the reference numbers 46 and 47. Two or four horizontal rods 48 are used to connect the ladder elements to one another.

and 49 and two diagonal bars 50 and 51. Several vertical structures can also be provided one above the other and can also be stiffened with double railings,

The all-round railing 9 consists of two lateral scaffolding or railing parts 52 and 53 with vertical struts 54, 55 and 56, 57, which are each firmly connected to one another via horizontal struts. Two horizontal rods 59, 60 and a horizontal H-shaped connecting part (double railing) 61 are used to connect the railing parts 52 and 53 to one another.

The assembly of the mobile scaffold from its modular individual parts is now briefly explained.

First, the basic folding unit 1 is set up; ie the basic folding unit 1, which is delivered to the site of use in a space-saving manner with the side ladder sections 14, 15 and 16, 17 placed next to one another and the folded folding part 12, is pulled apart so that the folding part 12 comes to lie in a vertical plane, and this position is secured by hooking the horizontal bar 12 into the lowest rungs 18, 19 opposite the folding part 12. The work platform 6 is then placed on the top rungs of the basic folding unit 1.

Next, the vertical structure 41 is positioned on the basic folding unit 1 by attaching the ladder parts 42, 43 and 45, 46 to the ladder parts of the basic folding unit 1 and securing them against lifting off by securing clips (not shown) in the respective vertical strut parts.

Positioning of the ladder sections with the vertical strut sections 42, 43 and 45, 46 into which the horizontal bars 48 and 49 and the diagonal bars 50 and 51 or double bars are suspended. The work platform 7 is then placed on the 5 top rungs of the ladder sections 41, 42 and 42, 44 respectively.

Next, for safety reasons, before any further assembly of the rolling scaffold, the triangular outriggers 2 to 5 are mounted on the side parts of the basic folding unit 1, using the coupling pieces 33, 34, 37, 38 or 35, 36 and 39, 40, which are designed as claws with a foldable claw element, as explained below. An important safety aspect is the optimal horizontal angular position of each triangular outrigger 2 to 5. The corresponding optimal angular positions are shown schematically in Fig. 2 and 3, which show top views of the fully assembled rolling scaffold, once with a free-standing rolling scaffold (Fig. 2) and secondly with the rolling scaffold set up against a building wall (Fig. 3). In the case of free-standing mobile scaffolding, the optimum horizontal angle of each triangular boom 2 to 5 relative to the longitudinal center line 62 of a working platform 6 or 7 of the mobile scaffolding or to its longitudinal edge is approximately 60°.

The same applies to the wall installation close to the building in Fig. 3 for the triangular outriggers 2 and 4 that are far from the building wall, while the other two triangular outriggers 3 and 5 that are arranged adjacent to the building wall 63 are arranged at an angle of 90° to the narrow side of the working platform of the rolling scaffold or parallel to the longitudinal center line 62, i.e. at an angle of 0° to the long side of these working platforms, in order to be able to position the rolling scaffold as close as possible to the building wall 63.

The distance of the mobile scaffold from the wall is determined by wall spacers 64, 65 which project from the mobile scaffold, are connected to it by a coupling and rest with their free ends against the building wall 63.
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After the rolling scaffold has been firmly positioned using the triangular outriggers 2 to 5, the construction of further vertical structures or the all-round railing 9 is carried out starting from the work platform 7 after the toe board 8 has been attached to the edge of this, whereby the side railing parts 52, 53 are first attached to the ladder elements 42, 43 and 44, 45 underneath. To complete the all-round railing 9, the railing parts 52 and 53 are connected to one another using the horizontal bars 59 and 60 and the H-shaped connecting part (double railing) 61.

The rolling scaffold thus completed consists of two lateral scaffold ladders into which work platforms are suspended, each consisting of a pair of vertical struts formed from the vertical strut parts 14 to 17, 42 to 45 and 54 to 57, which are firmly connected to one another by rungs.
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The design of the coupling pieces and the vertical struts or vertical strut parts that interact with them in a form-fitting manner according to the invention and that serve to determine the optimal horizontal angular position of each triangular boom according to the invention will now be explained using Fig. 4 to 9. As already explained above, these coupling pieces are coupling pieces 33, 34 and 35, 36.

at the upper end of the support arms 21, 22 or 23, 24 and/or around the couplings at the railing-side ends of the spacer arms 25, 26 or 27, 28. Preferably, the said optimal horizontal angular position of each triangular extension is determined by coupling pieces designed according to the invention at the scaffold ladder-side ends of the support arms 21 to 24, i.e. around the coupling pieces 33 to 36, of which the coupling piece 36 is shown in Fig. 6 or 9 as a representative of the identically designed coupling pieces 33 to 36.

Detailed views of the fully assembled mobile scaffold in the area of the claw 36 are shown in Fig. 4 and 5, respectively for a free installation of the mobile scaffold and an installation close to the wall (shown in Fig. 4).

As can be seen from Fig. 6 (and Fig. 9), the coupling piece 36 is claw-like and consists of a first claw element and a second claw element 67. The first claw element 66 has a cylindrical bore 68 at a sleeve-shaped end with an inner diameter that corresponds to the outer diameter of the support arm 24 so that the latter is received in the bore 68 in a form-fitting manner. For example, the sleeve end is additionally firmly connected to the support element by welding. The end of the first claw element 66 opposite the sleeve end has a partially cylindrical recess 69 running perpendicular to the bore 68, the contour of which is adapted to the cylindrical outer contour of the vertical strut part 17. A corresponding partially cylindrical recess 70 is located on the opposite inner side of the second claw element 67, which has a

Pivot pin 71 is pivotally connected to the first claw element 66. In the closed state, the two claw elements 66 and 67 releasably grip the vertical strut part 117 from the outside by means of their recesses 69 and 70. This connection position can be locked in a manner known per se.

According to the invention, a positive connection is provided between the coupling piece 36 and the vertical strut part 17 in order to determine the said optimal horizontal angular position of each associated triangular boom, namely in the form of a projection and a recess formed complementarily thereto. In the embodiment shown in Figs. 6, 7 and 8, the projection 72 is formed in the base of the recess 69 of the claw part 66, projecting therefrom, and two recesses 73 and 73 complementary thereto are formed in the vertical strut part 17 at a mutual circumferential distance of 60° in the same radial plane in order to be able to realize the two horizontal angular positions of the triangular boom 5 shown in Figs. 4 and 5 respectively. In the embodiment shown, the projection 72 is formed in the shape of a partial sphere, and the complementary recesses 73 and 74 therefore have a general circular shape. The projection 72 can, for example, be formed from the same material as the claw element 66. Alternatively, the projection 72 can be the round head of a round head rivet that is set into the base of the recess 69. The latter embodiment is also suitable for the disadvantageous fitting of conventional coupling pieces with the projection 72, whereby

In this case, only the circular holes 73 and 74 need to be made on existing vertical strut parts.

Fig. 9 and 10 show an alternative to the projection/recess arrangements of Fig. 6 and 7, i.e. a kinetic reversal of this structure with a recess or bore 75 formed in place of the projection 72 in the base of the recess 69 of the first claw element 66. Accordingly, the recesses 73 and 74 designed as circular bores in the vertical strut part 17 of Fig. 7 are replaced by dome-shaped projections 76 and 77 which are intended for alternative engagement in the recess 75.

As an alternative to the embodiments explained above, vertically running ribs or longitudinal slots can be provided instead of hemispherical or dome-shaped projections and corresponding circular holes or recesses for the positive connection between the coupling piece and the triangular boom arm. This embodiment, while retaining the option of being able to set the optimal horizontal angle position of each triangular boom, has the advantage of being able to find the correct angle position on the respective vertical strut part more quickly, whereupon the height can be changed to an optimal standing position of the mobile scaffold if necessary.

In summary, the following can be said. The invention relates to a rolling scaffold with two scaffold ladders, into which work platforms are suspended, and with vertical struts (17) of the scaffold ladders associated with triangular booms for

Increasing the stability of the rolling scaffold, each of which has a support arm resting on the ground and a spacer arm for determining the distance of the lower end of the support arm from the associated vertical strut, and which can be detachably attached to this vertical strut via coupling pieces (36). In order to always ensure that the rolling scaffold is set up safely, the invention provides that, in order to determine at least one optimal horizontal angular position of each triangular boom, a positive connection is provided between the coupling piece (36) of at least one of the arms (24) of the triangular boom and the associated vertical strut (17) in the form of at least one projection (72) and a complementary recess (73) interacting with it.

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Reference list

1 basic folding unit

2 triangular booms

3 triangular booms

4 triangular booms

5 Triangular boom &dgr; Working platform

7 Working platform

8 Toe board

9 All-round railings
10 Scaffolding ladder part

11 Scaffolding ladder part

12 Folding part

13 Horizontal bar

14 Vertical strut part1

15 Vertical strut part1 16 Vertical strut part1

17 Vertical strut part1

18 lowest rung

19 bottom rung 19' top rung

20 roll

21 Support arm

22 Support arm

23 Support arm

24 Support arm

25 Spacer arm

26 Spacer arm

27 Spacer arm
28 Spacer arm

29 Coupling piece

30 Coupling piece

31 Coupling piece

32 Coupling piece 33 Coupling piece

34 Coupling piece

35 Coupling piece

36 Coupling piece

37 Coupling piece 38 Coupling piece

39 Coupling piece

40 Coupling piece

41 Vertical structure

42 Vertical strut part1 43 Vertical strut part1

44 Vertical strut part

45 Vertical strut part1

46 bottom rung

47 bottom rung 48 horizontal bar

49 Horizontal bar

50 Diagonal bar

51 Diagonal bar

52 Railing part
53 Railing part

54 Vertical strut

55 Vertical strut

56 Vertical strut

10

20

57 Vertical brace 59 Hori zontai rod 60 Hori zontai rod 61 H-shaped connecting part, Double railing 62 Longitudinal centerline 63 Building wall 64 Wall spacers 65 Wall spacers 66 first claw element 67 second claw element 68 cylindrical bore 69 deepening 70 deepening 71 Pivot 72 head Start 73 deepening 74 deepening 75 deepening 76 head Start 77 head Start

Claims (9)

I · · » »ti* · t I I * Claims 1. Mobile scaffold with two scaffold ladders, into which work platforms are suspended, and with vertical struts (14 to 17, 42 to 45, 54 to 57) of the triangular booms (2 to 5) assigned to the scaffold ladders to increase the stability of the mobile scaffold, which each have a support arm (21 to 24) standing on the ground and a spacer arm (25 to 28) for determining the distance of the lower support arm end from the assigned vertical strut, and which can be detachably attached to this vertical strut via coupling pieces (33 to 36), characterized in that in order to determine at least one optimal horizontal angular position of each triangular boom (2 to 5), a positive connection between the coupling piece (33 to 36) of at least one of the arms (21 to 28) of the triangular boom and the assigned vertical strut (14 to 17) in the form of at least one projection (72, 76, 77) and a complementary recess (73, 74, 75) cooperating therewith. 2. Rolling scaffold according to claim 1, characterized in that the projection (72) or the recess (74, 75) is provided on the coupling pieces (33 to 36) of the support arms (21 to 24).
5 3. Rolling scaffold according to claim 1 or 2, characterized in that the recess (73, 74, 75) has the shape of a hole and the projection (72, 76, 77) is a pin or pin head adapted to the shape of the hole. 4. Rolling scaffold according to claim 1 or 2, characterized in that the recess (73, 74, 75) has a slot shape and the projection (72, 76, 77) is a rib adapted to the slot shape, and the slot-shaped recess and the rib run essentially parallel to the respective vertical strut (14 to 17). 5. Rolling scaffold according to one of claims 1 to 4, characterized in that the optimum horizontal angle relative to the longitudinal center line (62) of a working platform (6, 7) is approximately 60 degrees. 6. Rolling scaffold according to one of claims 1 to 4, characterized in that the optimum horizontal angle relative to the longitudinal center line (62) of a working platform (6, 7) is approximately 0 degrees. 7. Rolling scaffold according to claim 6 and 7, characterized in that the vertical struts (14 to 17) two projections (76, 77) or recesses (73, 74) are provided for the realization of both optimal angular positions, which are provided with a Recess (75) or a projection (72) on the associated coupling piece (33 to 36) cooperate. 8. Rolling frame according to one of claims 1 to 7, characterized in that the coupling pieces (33 to 36) are claw-shaped. 9. Rolling scaffold according to claim 8, characterized in that one claw element (66) is fixedly attached to one end of a triangular boom arm (24) and the other claw element (67) is pivotally attached to this fixed claw element, that the two claw elements (66, 67) are adapted on the inside to the outer contour of the respective vertical strut (17), and that the fixed claw element is provided on its inside with the projection (72) or the recess (75).