ITMS20120004A1 - STAR: SEISMIC ISOLATOR SUSPENDED - Google Patents

Description

DESCRIPTION

suspended seismic isolator

The basic concept is that an object hanging from a rope cannot be pushed by shaking the upper support of the rope. The purpose of the invention is to obtain the insulation of a structure by hanging it to the substructure by means of a rope (or a wire, or a cable); the reference configurations are as follows:

1. double tetrahedron: the suspension is achieved through two tetrahedral spatial structures connected by a wire

- Technological field

The invention relates to a technologically advanced structural support device to be applied under a structure, with particular reference to a construction or a building. The invention is related to the field of anti-seismic structures.

- State of the art

The current technique for insulation is based on elastomeric isolators, which in the event of an earthquake allow the superstructure to move, but do not have an adequate capacity to bring the system back into position after the earthquake. This entails a permanent deformation of the insulator and the need to replace it. The isolators require checks and maintenance. Elastomeric isolators. being composed of compressed rubber, over time they lose their characteristics and must be replaced, with static commitment and considerable cost. The cost of the isolators is high. The transfer between the structure and the foundation occurs by compression, with a rigid transfer that slightly disconnects the structure from the substrate.

Roller or ball insulators can trigger important movements; the balls transmit rigidly by compression. The costs of braces and shock absorbers are high.

Often the insulation systems do not re-center and are damaged after the earthquake.

Insulators with suspended structure with rigid vertical connection bars, with joints at the ends, do not transmit the horizontal actions of harmonic motion, but in the return phase they can transmit dangerous actions if the bar is put in compression.

- Technical problems solved

-Effective isolation: The advantage of the invented device is to isolate the superstructure from the substrate during wave seismic actions.

-The system in the event of a wave earthquake protects the upper part since the rope that hangs the structure from the foundation does not transfer cutting actions. When the base is moved considerably, the superstructure undergoes a slight motion, which quickly tends to weaken. The structure returns after the earthquake to the position that existed before the earthquake.

-The system has an intrinsic internal stable equilibrium, with the rope tending to return to the vertical and therefore to the initial position, bringing the constrained point of the superstructure to the initial position prior to the earthquake.

-Self-centering: the system returns to its position avoiding the dislocation of the post-seismic structure.

- Anti-seismicity: after the earthquake it remains intact; it must not be replaced after the earthquake.

-Durability: The duration of the isolation device is long and in any case greater than the useful life of the building.

-Reduced costs: The cost of the insulator is very low and allows the application also to inexpensive structures or in poorer countries, since its realization can take place with cheaper or more locally available materials.

- compared to other devices with vertical bars, the wire avoids the transfer of horizontal actions because a string without flexural stiffness and compressive strength does not interact with such actions, while rigid bars in any case can transmit dangerous interactions coming from the base and transfer them to the facility; in particular, the compression resistant bar is able to transmit impulsive actions of motion which initially in one direction suddenly reverses its direction.

suspended structures with dissipative mechanical mechanisms connected to the base, a transfer of horizontal actions can take place through the mechanical apparatus, even if there are wires that transform everything into articular quadrilaterals. Since a transfer is still present, a dissipative system is required for them. The invented system, on the other hand, completely avoids the passage of wave energy, so that the superstructure is completely decoupled from the base, in a simple and linear way. However, it is not excluded that any dampers or stabilizers may be positioned parallel to the insulator.

Description of the invention

The object of the present invention is to drastically limit the stresses connected to the action of the wave earthquake induced on a building.

In the event of an undulatory earthquake, the base moves vibrating around its rest position but is unable to set the superstructure in motion, since 'a rope cannot be pushed'; the superstructure is completely decoupled from the motion of the substrate; if the superstructure nevertheless presents a certain displacement, at the end of the ground motion it quickly returns to the starting situation, due to the stable equilibrium situation in which the taut vertical cable that connects the underlying structure and the superstructure is found. The wire system can be equipped with secondary elements to make assembly easier to adjust the flatness of the terminal parts and to dissipate energy

The materials used are the following:

- for supports and fixings: stainless or galvanized steel, but also any material suitable to resist the compression and bending actions induced in the individual elements.

- suspension wire: stainless steel or harmonic steel, rope or cable in carbon fiber composite material or in any case suitable to withstand the imposed traction without having a compression or bending stiffness.

The reference configurations respond to a precise operating logic:

- The double tetrahedron is made of spatial substructures with excellent position stability and allows the system to work well in every direction;

The insulator can be used as one of the support points of the structure, with a minimum of three;

With a set of insulators working in parallel, the insulation system is suitable for supporting the base plates of buildings of any size and weight, since it is sufficient to increase the number of insulators.

Further conformations

The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept. Furthermore, all the details can be replaced with other technically equivalent ones. The system transforms the compression between the superstructure and the underlying part into traction. The taut connection wire supports the upper part which weighs on the lower extremity and transfers the action to the substructure, connected to the upper extremity by means of a dedicated subsystem. In practice, the subsystem anchored to the superstructure and the one anchored to the sub-structure can have different shapes, for example they can be flat elements or spatial elements. Their conformation must be such as to be able to transfer the loads and such as to allow an appropriate horizontal sliding between the bound ends without the wire coming into contact with the substructures to which it is anchored. The typical conformation of the supporting structures is a double tetrahedron

Method of realization with reference to the drawings

The main conformation of the invention is illustrated in fig. 1.

Figure 1 illustrates the anti-seismic system with double tetrahedron; A and D are two elevations; C is the plan seen from above; B and E are two isometric views.

The wire (1), that is the heart of the system, is connected through the upper attachment device (2) to the lower subsystem (2-4-5-6-7) connected to the underlying structure; the wire (1) is connected through the lower attachment device (3) to the upper subsystem (3-8-9-10-1 1) connected to the structure above. The upper subsystem connects to the superstructure via a flat structure made with a flat part (10) and a connection structure (9) between the diagonals (8). Fixing takes place by means of fixed or removable metal elements 111), embedded in the casting, welded, fixed with nuts or locking elements. The lower subsystem connects to the substructure via a flat structure made with a flat part (6) and a connection structure (5) between the diagonals (4). The fixing takes place by means of fixed or removable metal elements (7), embedded in the casting, welded, fixed with nuts or locking elements. The elements (12) are suitable for making the complex stable before and during installation, regulating the planarity of the ends; they are of fixed length or with adjustable ends; they can be equipped with internal dissipative systems and can be shape memory.

The reference configuration responds to a precise operating logic:

1. The tetrahedron shape has excellent position stability and allows the system to work well in any direction;

2. lends itself to being used as one of the support points of the structure, with a minimum of three; It is suitable for supporting the base plates of buildings of any size and weight, since it is sufficient to increase the number of insulators.

Claims (1)

suspended seismic isolator CLAIMS 1) seismic isolator to isolate a structure at the base by means of two spatial structures in the shape of a tetrahedron (tetrahedra) joined by a wire (steel, FRP, other) (fig. 1): the isolator suspends the upper structure with a wire ( 1) stretched between two tetrahedral spatial substructures, the upper tetrahedron connects to the structure above via a flat part (10) and a (9) which connects the diagonals (8), the lower tetrahedron connects to the substructure via a flat structure (6 ) and a connection (5) between the diagonals (4). 2) the devices according to claim 1 are equipped with elements (12) suitable for dissipating energy, made with shape memory elements or with wires that deform in the plastic field during the seismic motion. 3) installation of the devices as per the preceding claims: assembly takes place as indicated below: preparation of the base structure and fixing of the device bases by means of fixed or removable metal elements (11); positioning of devices; positioning and fixing of the overlying structure, by means of fixed or removable metal elements (7), embedded in the casting, welded, fixed with nuts or locking elements; the devices as per claim 1 are equipped with elements (12) suitable for making the tetrahedra stable during assembly, regulating the planarity and dissipating energy.