ITMI20100928A1 - DEVICE FOR ANTI-SEISMIC STRUCTURAL CONNECTION OF CEMENT-BASED FEATURES - Google Patents

Description

DEVICE FOR ANTI-SEISMIC STRUCTURAL CONNECTION

OF CEMENTITIOUS PRODUCTS

The present invention refers to a device for the anti-seismic structural connection of cementitious products, in particular the components of the deck of a precast concrete structure.

The current legislation on construction (new "Technical Standards for Construction") has changed the approach to the design of prefabricated concrete structures to be built in seismic areas. The same rules give extreme importance to the way in which the connections between the main structural elements (pillars, beams, tiles, etc.) of a building or structure in general are made.

However, the not always excellent performance of precast concrete structures during past seismic events has contributed to the emergence of a series of needs. Among these there is the need to "tie" the prefabricated elements together in order to limit displacements and prevent any loss of support. It is therefore necessary to "tie" together not only the pillars and beams, but also the individual tiles which, resting on the beam, make up the deck of a building.

In recent years, earthquake-resistant structural connection devices have been developed capable of increasing the level of earthquake-resistant performance of buildings and structures, while keeping the construction cost at reasonable levels. Some of these structural connection devices are designed to dissipate the seismic energy introduced into a structure, by means of additional dissipative mechanisms, and / or to limit the transmission of seismic energy to the supporting structure, by isolating the main structural elements. .

Seismic resistant structural connection devices typically use special mechanical elements, activated by the movement of the main structural system, to reduce the overall seismic response by dissipating energy. The main structural elements are thus protected, since the seismic energy is dissipated in these mechanical elements, which can be inspected and / or replaced following a seismic event.

As previously mentioned, in the prefabricated construction sector the connection between beams and tiles of the deck of a building is particularly critical. Consequently, the need is felt to obtain a bond between the components of the deck that guarantees the stability of the tiles on the beams during seismic actions.

The purpose of the present invention is therefore to provide a device for the anti-seismic structural connection of cementitious products, in particular the components of the deck of a prefabricated concrete structure, which is able to obtain the structural constraint by transforming the kinetic energy of the earthquake in thermal energy. In detail, the connection device is able to deform and yield, transforming the kinetic stress into heat.

Another object of the invention is to provide a device for the anti-seismic structural connection of cementitious products whose yield characteristics can be "projected" and therefore can be dimensioned as needed.

Yet another object of the invention is to provide a device for the anti-seismic structural connection of cementitious products that can be easily replaced with a similar device after the earthquake, so as to restore the characteristics of the anchoring prior to the earthquake itself without having to intervene on the artifacts. cementitious (tiles and beams).

These purposes according to the present invention are achieved by making a device for the anti-seismic structural connection of cementitious products, in particular the components of the deck of a prefabricated concrete structure, as set forth in claim 1.

Further characteristics of the invention are highlighted by the dependent claims, which are an integral part of the present description.

The characteristics and advantages of a device for the anti-seismic structural connection of cementitious products, in particular the components of the deck of a prefabricated concrete structure, according to the present invention, will become more evident from the following description, exemplary and not limiting, referring to the schematic drawings attachments in which:

figure 1 is a side view, partially in section, of a portion of the deck of a building, showing a beam and the leg of a tile, to which a device is applied for the anti-seismic structural connection of cementitious products according to the invention;

Figure 2 is a front view, partially in section, of the portion of the deck of Figure 1;

figure 3 is a front view of a first embodiment of the device for the seismic structural connection of cementitious products according to the invention;

Figures 4 and 5 are side and top section views respectively of the connection device of Figure 3;

figure 6 is a front view of a second embodiment of the device for the seismic structural connection of cementitious products according to the invention;

figure 7 is a front view of a component of the device for the seismic structural connection of cementitious products according to the invention; And

Figures 8-11 are other views, some of which are in section, of the component of Figure 7.

With reference to figures 3 and 6, two preferred embodiments are shown of a device for the anti-seismic structural connection of cementitious products according to the invention, indicated as a whole with the reference number 10 in figure 1.

The connection device 10 first of all comprises one or more anchoring plates 12 each having a substantially L-shaped section, manufactured in reinforced metal material and operating as the active "heart" of the device 10 itself. The two operating surfaces 14 and 16 of each anchoring plate 12 are configured to be connected respectively to a first concrete product Tl, such as for example a deck beam of a prefabricated concrete structure, and to a second concrete product T2, as for example for example, a tile of the deck itself, arranged orthogonally with respect to the first cementitious product Tl.

In particular, the first operating surface 14 of the anchoring plate 12 is configured to be constrained to the beam Tl by means of the interposition of an anchoring profile 18, having a substantially C-shaped section and made integral with the beam Tl itself. This first operating surface 14 of the anchoring plate 12 is then fixed to the anchoring profile 18 by means of suitable adjustment and fixing means 36 and 38, described in more detail below. The second operating surface 16 of the anchoring plate 12 is instead configured to be constrained to the tile T2 by means of a steel block 20 or a through bolt.

The anchoring plate 12 consists of a steel sheet, folded in an L-shape and reinforced with a pair of lateral ribs 22 and 24 which connect the two operating surfaces 14 and 16 of the anchoring plate 12 itself. The lateral ribs 22 and 24 are in fact welded, at their respective ends, to the two operating surfaces 14 and 16 of the anchoring plate 12. On the first operating surface 14 of the anchoring plate 12, i.e. the one in contact with the beam Tl, there is a first hole 26 for the passage of the aforementioned adjustment and fixing means 36 and 38. On the second operating surface 16 of the anchoring plate 12, that is to say the one in contact with the tile T2 and perpendicular to the beam Tl, there is instead there is a second hole or slot 28 for the plug 20 for connection to the tile T2 itself.

On at least one of the two operating surfaces of the anchoring plate 12, conveniently but not necessarily the second operating surface 16, there is also obtained at least a weakening portion 30 dimensioned in such a way as to have a diversified mechanical strength which is lower than the mechanical strength of the others. parts of the anchor plate 12 itself. Said weakening portion 30 is therefore capable of deforming due to the twisting moment induced by the relative displacement between the beam Tl and the tile T2 following the occurrence of a seismic event. Basically, the weakening portion 30 operates as a so-called "seismic fuse", since its operation can be metaphorically similar to that of the fuse of an electrical system.

The weakening portion 30 can be made with different shape, dimensional and geometric characteristics according to the project requirements and the level of seismicity of the territory on which the concrete product is built. Preferably, according to the embodiments shown in the figures, the weakening portion 30 is arranged perpendicularly to the direction of development of the second operating surface 16 of the anchoring plate 12 or, in other words, it is arranged parallel to the direction of development of the T2 tile (figure 2). The weakening portion 30, conveniently arranged between the lateral ribs 22 and 24 and the hole or slot 28 of the second operating surface 16 of the anchoring plate 12, occupies a dimensionally reduced surface with respect to the overall area of said second operating surface 16, thus to reduce the mechanical resistance of the second operating surface 16 itself. The weakening portion 30, given the difference with the second operating surface 16 of the anchoring plate 12, constitutes the area of concentration of the seismic actions.

Alternatively or in addition to the different dimensional characteristics, one or more holes, slots, notches or anything else capable of further reducing the mechanical strength of this weakening portion 30 can be obtained on the weakening portion 30. for example, based on the first embodiment of the anchoring plate 12, shown in Figure 3, a single slot 32 is formed on the weakening portion 30, arranged centrally with respect to the direction of development of the second operating surface 16, and two notches 34, arranged at the lateral edges of the second operating surface 16 itself. On the other hand, on the basis of the second embodiment of the anchoring plate 12, shown in Figure 6, only a central slot 32 is made on the weakening portion 30.

Operationally, the L-shaped anchoring plate 12 is firstly connected to the beam Tl, by fixing its first operative surface 14 to the anchoring profile 18 integral with the beam Tl itself. Subsequently, the second operating surface 16 of the anchoring plate 12 is fixed integrally to the tile T2, by means of the appropriate steel plug 20 or by means of a through bolt.

Once the anchoring has been carried out, the L-shaped plate 12 will be rigidly constrained both to the beam Tl and to the tile T2 and, in particular, the first operating surface 14 will be constrained to the beam Tl and the second operating surface 16 will be constrained to tile T2. During the occurrence of a seismic phenomenon, when the beam Tl will tend to move from its original position with respect to the tile T2, the weakening portion 30 placed on the second operating surface 16, above the lateral ribs 22 and 24, will deform by twisting, limiting however the relative displacement of the beam Tl with respect to the tile T2. Therefore, the connection device 10 according to the invention is activated only under seismic stress. After the seismic event, the functions of the connection device 10 can be restored by simply replacing the L-shaped anchoring plate 12, damaged in correspondence with its weakening portion 30, with a new intact plate, possibly provided with a portion of weakening 30 different according to the needs.

For the correct installation of the L-shaped anchoring plate 12 it is possible to operate on the slot 28 of the second operating surface 16 and on the anchoring profile 18 integral with the beam Tl. In particular, the slot 28 and the relative anchor 20 allow to obtain the vertical adjustment of the anchoring plate 12, while the anchoring profile 18 and the relative adjustment and fixing means 36 and 38 allow to obtain the longitudinal adjustment of the anchoring plate 12 itself.

The means for adjusting and fixing the first operating surface 14 of the anchoring plate 12 comprise a bolt 36 and an anti-slip plate 38 which engage with the anchoring profile 18. More precisely, with the use of the anti-slip plate 38, during tightening of the nut of the bolt 36 causes the controlled deformation of the pair of lips 40 (Figure 2) of the C-shaped anchoring profile 18. The anti-slip plate 38 is in fact provided with a central hole 42 for the passage of the bolt 36, as well as with two lateral surfaces 44 parallel and inclined with respect to a plane perpendicular to the central axis of rotation of the anti-slip plate 38 itself.

Therefore, during the tightening of the nut of the bolt 36 with anchor head, the lips 40 of the anchoring profile 18 are deformed in proximity to the anchor of the bolt 36 itself, since these lips 40 are forced to follow the shape of the head of the bolt 36 , as long as the two lateral surfaces 44 of the anti-slip plate 38 prevent further deformations. Basically, the deformation of the lips 40 of the anchoring profile 18 stabilizes and ends when these lips 40 close against the lateral surfaces 44 of the anti-slip plate 38, assuming their shape.

In this way the sliding load, ie the load impressed on the bolt 36 in the longitudinal direction of development of the anchoring profile 18, increases significantly, assuming a useful value similar to or greater than the tensile value of the anchoring profile 18 itself. An effective anchoring of the L-shaped plate 12 on the beam T1 is therefore ensured.

It has thus been seen that the device for the anti-seismic structural connection of cementitious products according to the present invention achieves the purposes highlighted above.

The device for the anti-seismic structural connection of cementitious articles of the present invention thus conceived is susceptible in any case of numerous modifications and variations, all falling within the same inventive concept; furthermore, all the details can be replaced by technically equivalent elements. In practice, the materials used, as well as the shapes and sizes, may be any according to the technical requirements.

The scope of protection of the invention is therefore defined by the attached claims.

Claims (9)

CLAIMS 1. Device (10) for the seismic structural connection of cementitious products, comprising one or more anchor plates (12) having a substantially L-shaped section, a first operating surface (14) and a second operating surface (16) of each anchoring plate (12) being configured to be connected respectively to a first cementitious product (Tl) and to a second cementitious product (T2), arranged orthogonally with respect to said first cementitious product (Tl), said first operating surface (14) of each anchoring plate (12) being configured to be constrained to the first concrete product (Tl) through the interposition of an anchoring profile (18), having a substantially C-shaped section, and through adjustment and fixing means (36, 38 ), characterized by the fact that on at least one of the two operating surfaces (14, 16) of each anchoring plate (12) there is obtained at least a weakening portion (30) dimension ata in such a way as to have a diversified mechanical strength which is lower than the mechanical strength of the other parts of the anchoring plate (12). 2. Device (10) according to claim 1, characterized in that the anchoring plate (12) is reinforced with a pair of lateral ribs (22, 24) which connect the two operating surfaces (14, 16) of said plate anchor (12). Device (10) according to claim 2, characterized in that on the first operating surface (14) of the anchoring plate (12) there is a first hole (26) for the passage of said adjustment and fixing means (36, 38) and on the second operating surface (16) of said anchoring plate (12) there is a second hole or slot (28) for a plug (20) for connection to the second concrete product (T2). 4. Device (10) according to claim 3, characterized in that said weakening portion (30) is arranged between the pair of lateral ribs (22, 24) and the second hole or slot (28), perpendicular to the direction of development of the second operating surface (16) of the anchoring plate (12) and parallel to the direction of development of the second cementitious product (T2). Device (10) according to claim 3 or 4, characterized in that said weakening portion (30) occupies a dimensionally reduced surface with respect to the overall area of the second operating surface (16) of the anchoring plate (12). Device (10) according to any one of claims 3 to 5, characterized in that one or more holes or slots or notches (32, 34) are made on said weakening portion (30). 7. Device (10) according to any one of the preceding claims, characterized in that said adjustment and fixing means (36, 38) comprise a bolt (36) and an anti-slip plate (38) which engage with the anchoring profile ( 18). 8. Device (10) according to claim 7, characterized in that the anti-slip plate (38) is provided with a central hole (42) for the passage of the bolt (36), as well as two parallel and inclined lateral surfaces (44) with respect to a plane perpendicular to the central axis of rotation of said anti-slip plate (38). Device (10) according to claim 8, characterized in that the anchoring profile (18) is provided with a pair of lips (40) capable of following the shape of the anchor head of the bolt (36) during tightening of the nut of said bolt (36), said pair of lips (40) ending in contact with the lateral surfaces (44) of the anti-slip plate (38) deforming, the deformation of said pair of lips (40), controlled and limited by the tightening between the anchor head of the bolt (36) and the lateral surfaces (44) of the anti-slip plate (38), ensuring an effective anchoring of the first operating surface (14) of the anchoring plate (12) on the first concrete product (Tl).