ITRM20130720A1 - METALLIC STRUCTURE FOR THE SUPPORT OF SCAFFOLDING BY POSTS OF BUILDINGS IN C.A. - Google Patents

Description

METALLIC STRUCTURE FOR SUPPORTING SCAFFOLDING FROM OVERHANGS OF

BUILDINGS IN C.A.

DESCRIPTION

The present invention refers to a structure for supporting scaffolding, in particular to a steel structure for supporting the scaffolding from the load-bearing elements of the overhangs (balcony joists, overhangs of any type, etc.) of reinforced concrete buildings , without supports on the ground.

In the current state of the art, the scaffolding necessary to redo, above all, the facades of buildings in reinforced concrete. (reinforced concrete), are mainly made with supports that start from the ground - sidewalks, roads, courtyards etc. - and rise to the full height of the facade.

The support supports that start from the ground can lead to various drawbacks: occupation of public land of great commercial interest, such as sidewalks, with sign covers; difficulty of pedestrian and / or vehicular passage; facilitation of thefts due to the ease of using the supports on the ground; aesthetic deterioration of the facades on the ground floors during the works; etc.

The purpose of the present invention is therefore to overcome the problems set out above and this is achieved by means of a structure for supporting scaffolding as defined in claim 1.

A further object of the present invention is a method for supporting a scaffolding from the projections of a facade of a building, without supporting the scaffolding on the ground, as defined in claim 11.

The present invention, overcoming the problems of the known art, entails numerous and evident advantages.

First of all, the use of the present invention allows not to occupy public land (therefore not to pay for its occupation or at least to reduce its costs) of great commercial and functional interest, with obvious advantages for commercial activities located on the ground floors. Furthermore, the ground floors of the buildings remain free, and therefore also signs, tables and other indications of a commercial nature.

A further advantage is given by the fact that the structure, according to the present invention, does not hinder in any way the passage and the pedestrian and vehicular transit as it leaves both the sidewalks and the roads free.

A further advantage derives from the fact that the possibility of theft is significantly reduced due to the lack of supports down to the ground and, consequently, the compulsory insurance of scaffolding will be less expensive.

In addition, the lower visual and functional impact of the facades due to the lack of occupation and coverage of the ground floors reduces the aesthetic deterioration of the property during the works.

Yet another advantage is given by the fact that each component of the structure can be recovered at the end of the work and then subsequently reused, with consequent savings also on the execution of the work itself.

Further advantages, together with the characteristics and methods of use of the present invention, will become evident from the following detailed description of its preferred embodiments, presented by way of non-limiting example.

Reference will be made to the figures of the attached drawings, in which:

Figure 1 is a perspective view of a support structure according to the present invention;

Figure 2 is a first sectional view of a support structure according to the present invention, during the fastening on an overhang of a facade;

Figure 3 is a view of one of the plates (the lower one) of a support structure according to the present invention;

Figure 4 is a second sectional view of a support structure according to the present invention, fixed on a projection of a facade;

Figure 5 is a view of an articulated joint device according to the present invention;

Figure 6 is a schematic view of a facade of a building in which a scaffolding is supported according to the present invention; And

Figure 7 shows the graphs of the breakdown of the acting forces according to which the total weight of the scaffolding is supported by the plate system according to the present invention.

The present invention will be described below with reference to the figures indicated above.

As already indicated, through the use of this industrial invention, the scaffolding is supported by the cantilevered bearing structures of the reinforced concrete buildings. and without supports on the ground.

Referring first of all to Figure 1, this shows a support structure 1 according to the present invention, in particular for supporting a scaffolding from the overhangs of a facade of a building, without supporting the scaffolding on the ground.

The structure 1 first of all comprises a first plate 2 and a second plate 3.

In use, as can be seen in figures 2 and 4 and as will be better described hereinafter, said first and second plates are respectively suitable for being positioned above and below an overhang of the facade and for being connected and clamped together. For this purpose, the structure 1 in fact comprises removable connecting elements 5, 6, 7.

Preferably, the removable connecting elements 5, 6, 7 comprise one or more threaded bars 5, passing through corresponding holes made on the plates, and respective tightening nuts 6.

The plates are both metallic, preferably in steel. Furthermore, both plates 2, 3 can have one or more stiffening and reinforcing ribs 8.

Furthermore, the structure 1 comprises a first segment of tubular element 10 integrally connected or connectable to said second plate 3.

This first tubular segment 10, for example a portion of a metal barrel, can be directly welded to the plate 3, or can be removably connected to it by means of an interlocking or screw system.

The first tubular element 10 is fixed to the plate 3 in a substantially central position thereof and in such a way as to develop in a direction substantially orthogonal to the plane of the plate itself.

In this way, the two plates can be fixed to a projection 50 of the facade, for example the overhang of a balcony or terrace. The first plate 2 will be positioned above the overhang slab, while the second plate 3 will be positioned correspondingly below the cantilever slab. According to the preferred embodiment of the present invention, after having drilled the ceiling of the overhang in correspondence with the holes on the plates, the two plates can be connected to each other by means of two threaded bars and tightened by means of nuts 6 and washers 7.

Advantageously, the two plates can be positioned so that one or more reinforced joists of the balcony floor are also tightened inside them.

In terms of dimensions, materials and the presence of reinforcing ribs, the two plates can reasonably be equal to each other.

Advantageously, the structure can also comprise at least one plate-like protection element 9, able to be interposed between at least one of the plates and the projection.

Preferably, two plate-like protection elements 9 are provided, one for each of the plates. These protection elements have both the function of protecting the plates themselves and the projection from any damage, and to facilitate adherence between the components and avoid unwanted movements.

According to an embodiment, these plate-like protection elements 9 are neoprene sheets, having dimensions substantially equal to those of the plates 2, 3.

With reference to Figure 5, the structure further comprises a device with an articulated joint 11 suitable for the removable connection of a second segment of tubular element 12 to the first tubular element 10.

In this way, the second segment of the tubular element 12 can be connected in such a way as to present an inclination with respect to the first segment of the tubular element 10, for example preferably an inclination of about 45 °.

It is to be understood that additional fastening components 101, of a known and standardized type, can be used simultaneously, for example to fix the scaffolding on the fronts of the overhangs 50, as shown in Figure 6.

According to the present invention, therefore, a method is provided for supporting a scaffolding 100 by overhangs 50 of a facade 40 of a building, without supporting the scaffolding on the ground.

This method first of all comprises a step of supplying at least one pair of support structures 1 according to what has been described up to now.

The number of supporting structures 1 will naturally depend on the extension of the scaffolding 100 to be supported and on the height (in number of floors) of the facade 40. The method therefore provides for fixing the structures 1 to respective projections 50 of the facade by tightening of the first and second plates on the overhangs themselves.

It has already been said that the overhangs can be overhangs of balconies or terraces, and that said structures are preferably fixed on said overhangs close to the facade, as illustrated by way of example in figure 6.

Therefore, the method provides for connecting a scaffolding 100 to the second tubular elements 12 which will have been connected to the support structures 1, as already described in detail previously.

As already described, the support structures 1 will be positioned so as to tighten inside them one or more reinforced joists of the floor 50 of the balcony or terrace.

In order to analyze in detail the forces that come into play and, consequently, to size the various component parts, it is advantageous to start from a practical example.

Suppose you need to build a scaffolding to maintain the facade of a common reinforced concrete building for civil dwellings of six floors, in addition to the ground floor, with an inter-floor height of 3 meters (the height of the ground floor has no importance because the scaffolding starts from the attic of the first floor).

Assuming a distance between two draft of 2 meters and a total load of the scaffold (own weight, weight of the material, etc.) for a width of 2 meters and a height of two floors, of kg. 700, this will be the weight that must be supported by the structures of the present invention.

As can be seen in figure 7 which represents the graphs of the decomposition of the acting forces in which the total weight of the scaffolding is indicated with the letter P (which for simplicity is indicated equal to 100 to have the various forces decomposed as a percentage) and is decomposed according to the direction of the second tubular segment connected to the scaffold and to the first tubular segment of barrel protruding from the lower plate through the articulated joint.

The weight P, decomposed in the direction of the second tubular segment, arranged at 45 °, and in the direction orthogonal to it, gives: P = Po Pv (Po component along the second tubular segment = 70.7; Pv component orthogonal to the second tubular segment = 70.7).

The Po component, having reached the first vertical tubular segment welded to the plate, breaks down into a force according to the first tubular segment and into a force orthogonal to it: i.e. Poo Pov (Pov, according to the first tubular segment, = 50; Poo, orthogonal to the first tubular segment, = 50).

Poo is a secondary shear stress in the horizontal direction of the floor, which is absorbed by the metal structure of the present invention. The Pov = 50, is half the weight P supported by the same structure.

The Pv component of the P weight, orthogonal to the second tubular segment, weighing on the lowest horizontal metal rod to which the second tubular segment arrives, is broken down according to the same rod, into: Pvo Pvv. The Pvo = 50, acts horizontally along the same rod and pushes against the edge of the floor through a normal fixing system. The Pvv = 50, acts vertically on the crossbar, at 45 °, and breaks down, in turn, into Pvvo Pvvv. The Pvvo = 35.5, acts according to the second tubular segment and, having reached the first vertical tubular segment welded to the lower plate, it breaks down into two forces: Pvvoo Pvvov.

The first (Pvvoo = 25) acts along the axis of the barrel and constitutes the fourth part of the weight. The second (Pvvov = 25) acts orthogonally to the barrel and determines a cutting action of the barrel on the plate, canceled by the cutting action of one of the two components of the Pvvv. In fact, this exerts a tangential action along the crossbar and once it reaches the vertical barrel welded to the plate, it breaks down into Pvvvo Pvvvv. The first acts according to the barrel and constitutes the fourth part of the weight; the second acts orthogonally to the barrel, in the opposite direction to the Pvvov and cancels the cutting action of this, as mentioned above.

All the weight is carried and supported by the structure through the following components: Poo (= 50) Pvvoo (= 25) Pvvvo (= 25) = 100.

According to an exemplary embodiment, the dimensions of the various component elements of the structure are as follows.

The lower and upper plates have a thickness of 5 mm. The reinforcement ribs have a section of 20 x 20 mm.

The threaded bars have a diameter of Φ 14 mm. . The dimensions of the lower and upper plates are 30 x 55 cm. The center distance between the threaded bars is cm.

25. The location of the first reinforced tubular segment of welded barrel is in a barycentric position with respect to the lower plate and therefore in a median position on the alignment of the two passage holes of the threaded bars. The external diameter of the reinforced barrel is 48.25 mm, while the thickness is 5 mm.

The above dimensions are those considered to be of greater use but, in relation to particular situations and different needs, elements making up the structure with different dimensions can be had.

The present invention has been described up to now with reference to its preferred embodiments. It is to be understood that each of the technical solutions implemented in the preferred embodiments described here by way of example, may advantageously be combined differently with each other, to give rise to other embodiments, which pertain to the same inventive core and all in any case fall within the scope protection of the claims set out below.

Claims (13)

CLAIMS 1. Structure for the support of a scaffolding from the overhangs of a facade of a reinforced concrete building, without ground support of the scaffolding, comprising: - a first plate and a second plate; - removable connecting elements of said first and second plates; - a first segment of tubular element integrally connected or connectable to said second plate, in a substantially central position of said second plate and so as to develop in a direction substantially orthogonal to the plane of said second plate, said first and second plates being respectively adapted to be positioned above and below a projection of said facade and connected and clamped together by means of said removable connection elements. 2. Structure according to claim 1, wherein said removable connection elements comprise at least a pair of threaded bars, passing through corresponding holes on said first and second plates, and respective tightening nuts. 3. Structure according to claim 2, comprising two threaded rods. 4. Structure according to one of the preceding claims, further comprising at least one plate-like protection element, able to be interposed between one of said plates and said projection. 5. Structure according to claim 4, comprising two plate-like protection elements, one for each of said first and second plates. 6. Structure according to claim 4 or 5, in which said plate-like protection elements are sheets of neoprene, having dimensions substantially equal to those of the plates. 7. Structure according to one of the preceding claims, in which said first and second plates are preferably made of steel. 8. Structure according to one of the preceding claims, in which at least one of said first and second plates has one or more stiffening ribs. 9. Structure according to one of the preceding claims, further comprising a device with an articulated joint suitable for the removable connection of a second segment of tubular element to said first tubular element, said second segment of tubular element being able to be connected in such a way as to present a inclination with respect to said first segment of tubular element. 10. Structure according to claim 9, wherein said inclination is about 45 °. 11. Method for supporting a scaffolding from the overhangs of a facade of a reinforced concrete building, without ground support of the scaffolding, including the steps of: - providing one or more support structures according to one of claims 1 to 10; - fixing said structures to respective projections of said facade by tightening said first and second plates on said projections; - connecting said scaffolding to the second tubular elements connected to said support structures. 12. Method according to claim 11, wherein said protrusions are balcony or terrace protrusions, and said structures are fixed on said protrusions close to the facade. 13. Method according to claim 12, wherein said support structures are positioned so as to tighten inside them one or more reinforced joists of the floor of the balcony or terrace.