IT201600099915A1 - CAVITY TRAINING, IN A NON-INVASIVE AND PRE-STRENGTH MANNER, THROUGH THE USE OF SPECIFIC EQUIPMENT, INSIDE THE PILLARS OF EXISTING BUILDED CONCRETE BUILDINGS FOR THE ALLOCATION OF CENTRAL STEEL OR OTHER SUITABLE MATERIALS AT THE CROSS-BEARING CROSSING- PILLARS, THAT IS, TO STRUCTURAL KNOTS, THAT MAKE THESE BUILDINGS MORE RESISTANT TO EARTHQUAKES - Google Patents

Description

CAVITY FORMATION, IN A NON-INVASIVE WAY AND WITH

PRE-REINFORCEMENTS, THROUGH THE USE OF SPECIFIC EQUIPMENT,

INSIDE THE PILLARS OF EXISTING CONCRETE BUILDINGS

REINFORCEMENT FOR THE ALLOCATION OF CENTRAL REINFORCEMENTS IN STEEL OR OTHER SUITABLE MATERIAL FOR THE CROSSING OF BEAMS-PILLARS, THAT IS TO STRUCTURAL NODES, WHICH MAKE THESE BUILDINGS MORE RESISTANT

EARTHQUAKES.

DESCRIPTION

At the present state of the art to increase the structural resistance of existing buildings in reinforced concrete. above all external interventions are carried out in correspondence with the structural nodes and in any case not in the center of the pillars and beams. The present invention, on the other hand, allows, with little invasiveness and cheapness, to be able to allocate central reinforcements of possible different shapes and materials, whose greater effectiveness has already been demonstrated, to make existing buildings in reinforced concrete. more resistant to earthquakes, thus operating a fast and functional innovative anti-seismic retrofit.

The formation of cavities, of the relative pre-reinforcements and the connected central reinforcements, to be allocated in the pillars and beams by continuous coring, also takes place with the use of specific equipment, described in a specific paragraph, and essentially depends on the state in which the existing structure in reinforced concrete on which to intervene.

For example, the reinforced concrete structures, built before Law no. 1086 of 5 November 1971, show reinforcements with partially different positions and quantities both for the longitudinal rods and for the stirrups, compared to those of the subsequent regulations, up to the one in force.

The present patent application solves these problems even more quickly and economically than the usual known techniques.

The cavities on the pillars, whose construction method will be described in a specific paragraph, must be made in correspondence with the central part of the height of the pillar, that is, where the stresses are lower (Main Figure).

From the internal base of said cavity, continuous coring is carried out downwards until reaching and crossing the corresponding beam for a distance almost equal to the one cored above. In the case of a cavity made of pillars resting on the foundation beam, the continuous coring must develop from the base of the created cavity until it almost reaches the lower face of the foundation beam, except in cases where it is necessary to go beyond it to reach a lower laying ground. suitable.

Before carrying out any intervention on the pillars of existing buildings in reinforced concrete it is necessary to carry out a series of preliminary activities to be implemented in order to subsequently prepare the most suitable interventions.

Before starting the construction of the cavity, sensors (optical fiber or other suitable type) must be installed on the metal reinforcements and on the concrete surrounding the cavity in order to be able to carry out a comparison monitoring of the stress state of the materials before and after construction. of the cavity.

The main types of cavities are listed below, depending on the size of the pillar, the face of the same (long side or short side) on which it is more appropriate to intervene, the relative pre-reinforcements, and depending on the state in which the different buildings are located. in c.a. object of the intervention and the related central reinforcements to be allocated.

Existing structures in reinforced concrete in very precarious conditions

• Existing structures in reinforced concrete in non-precarious conditions

The cavities to be made and the subsequent continuous coring must be proportionate to the different types of central reinforcement that will be allocated there: metal tubing, or other material, solid or pre-drilled, metal cage, or other material, with stirrup or continuous spiral, combination tubular plus cage or full iron (or other material) armor, solid iron (or other material).

It should be noted that, for the benefit of minimal invasiveness, the cavity that must start from about 40-50 cm from the beam-pillar connection, will have a maximum height of about 80 cm in order to allocate the specific equipment suitable for continuous core drilling. ; the total reinforcement will be obtained by connecting (by screwing, welding or otherwise) the various sections together. The basal section, the lower one to be inserted into the foundation beam, must have a size such as to be located about 10 cm from the bottom face of the foundation and about 20 cm from the upper one in order to obtain the attachment point of the first two sections of the reinforcement in a less stressed area. Where necessary, these cavity opening operations will also be repeated on the upper floors (such as for example in the case of height adjustment of the pillar section).

Preliminary Activities

In order to obtain sufficient knowledge of the real state in which the building object of anti-seismic reinforcement and consolidation is located, before carrying out any intervention on the pillars of existing buildings in reinforced concrete. it is necessary to carry out the technical anamnesis, a series of preliminary activities to be carried out in order to subsequently prepare and perform the most suitable interventions.

Documentary investigation, which concerns the acquisition of design documents (drawings, calculations, checks, variants, tests, etc.)

Structural and instrumental investigation: must be performed both on the structure and on the site. Sclerometric, pacometric and / or georadar examination, tests for local checks (foundation thickness, concrete cover thickness, etc.), verification of the discharges in the foundation of each pillar, installation of sensors (optical fiber or other suitable type) before and after opening of the cavity for the comparison of stress states, any static structural and lift checks, adequate investigations and checks in situ, etc.

Intervention project that will strictly depend on the results of the two previous phases and on the real state in which the building is presented.

Figures 1a, 1b and 1c are shown below which show the areas of the pillars that are most stressed and susceptible to breakage and the correct position of the cavity with respect to stresses.

Fig. 1 a: Indication of the most stressed areas, in the "head" and "foot" of the pillar.

Fig. 1 b: Breakage of the most stressed areas, in the "head" and "foot" of the pillar following the earthquake.

Fig. 1 c: Position of the cavity with respect to the most stressed areas, indicated by the “butterfly” diagram typical of seismic stresses.

Description of the cases of intervention

1) Existing structures in reinforced concrete in very precarious conditions

In such cases, the following must first be carried out: • Apply a special metal bandage or other suitable material, of adequate thickness, all around the pillar on which to intervene, starting from the walking surface and up to a slightly higher height (about 10 centimeters) at the top of the cavity to be made. Said bandage, shaped according to the geometry of the pillar, must be pre-drilled exactly in correspondence with the cavity to be made. Fig.2 Obviously, the installation of said sheet will require a suitable hole in the closing walls on the sides of the pillar.

• In order to solidify the bandage to the pillar, some through holes will be drilled at various heights which will connect the opposite sides to the opening of the cavity by means of suitable threaded bars, or other material, connected and tightened by means of a metal plate and fixing nuts. With this pre-reinforcement activity, a consolidation of the entire banded portion is obtained. Fig.2a.

Fig. 2: Wrapping with metal sheet, or other suitable material, and connection of the opposite faces with threaded rods and nut and lock washers (Fig. 2a)

• Possible further pre-reinforcement at the beam-pillar connection by means of "x-stitching" between the basal part of the pillar and the lower beam, to be carried out with a preventive continuous coring of a suitable diameter and insertion of metal reinforcement (threaded bar, harmonic cable, or other material) suitably fixed for better beam-pillar solidarity. Fig. 3. Fig. 3: “X” seams in the pillar with the beams.

• The opening of the cavity can take place as described below. Starting from one of the two vertical edges of the bandage hole, continue in an inclined direction towards the central part of the cavity to be made. Then you change sides and continue in the same way until you create a triangular wedge of concrete. Finally, horizontal cuts are made at the two ends of the short sides of the hole and then the concrete wedge is extracted.

• Continue with the cuts by appropriately varying the inclination on the two long sides and making the necessary horizontal cuts on the short sides of the cavity being created.

• Once the cavity is completed, an internal pre-reinforcement is inserted consisting of pre-drilled metal sheet, shaped metal grid, or other material, of adequate thickness on each internal face except the base one (on which the coring will be carried out), to facilitate, with the discharge of adequate filling mortar, also colored for subsequent checks, of the cavity, the best adhesion connection between the pre-existing part and the new one.

Fig. 4

• The specific equipment is inserted to carry out continuous coring at the base of the cavity. Fig. 5

· The core drilling was performed. Fig. 6

• The central armature is inserted. Fig.7a, 7b, 7c

• Put back the reinforcement rods (brackets and / or vertical bars) previously cut to allow the core barrel to be housed. Fig. 8

• The filling is carried out with suitable mortar, also pigmented (colored). Fig. 9

2) Existing structures in reinforced concrete in non-precarious conditions

In these cases, the pre-reinforcement activities external to the pillar are not carried out using the bandage described above, while the cavity inside the pillar and the pre-reinforcement of it are made on each internal face except the base one (on which the core drilling will be performed).

Installation of sensors for voltage state monitoring

The installation of fiber optic sensors for pillar monitoring purposes is characterized as a preventive moment in the management of the quality of the structure over time as it provides immediate information on the safety and conditions of the examined structure, i.e. it allows long-term monitoring of the its efficiency and safety. In this way, Γ “self-diagnosis” of the structure is obtained in real time.

Description of the method of making the cavities

In order to interfere and alter the pre-existing state as little as possible, it is advisable to use suitable tools, such as water jet, diamond wire, a circular saw or the like, to make the cuts according to a scheme described below. Once the dimensions of the cavity have been established, in depth and in width (preferably interfering, in order to avoid cutting longitudinal rods), the contour of the cavity to be made is marked on the face of the pillar. The saw is then positioned at one side edges and the blade is directed vertically and cut towards the middle of the face opposite to the front one; the operation is repeated on the opposite side edge. We then proceed to the horizontal cut at the top and at the base of the cavity for the entire width; the triangular wedge is thus extracted. We then proceed to the vertical cut in depth along the two side edges. Then the blade is oriented vertically starting from one of the external edges and the blade is oriented towards the opposite corner on the internal face; the cut wedge is then extracted. The operation is then repeated on the opposite edge (see figure). Thus only two small triangular wedges remain attached only on the internal face of the cavity which will be removed with further similar successive cuts.

Description of the types of intervention

First of all, the following is stated:

in the choice of the faces of the pillars on which to make the cavities described, where possible, the long side will be preferred as this will almost certainly avoid the cutting of vertical reinforcing bars and only some horizontal brackets will be cut in order to create access to specific equipment;

if this is not possible, it will be done on the short side and some vertical iron may be cut, in addition to some horizontal brackets;

however, it is clarified that, once the cavity has been created, the pre-reinforcement has been inserted inside it, the continuous core drilling has been carried out at its base and the appropriate central reinforcement has been inserted, before the concrete casting, the previously cut sections of armor.

where possible, it will be preferred to carry out the interventions for the implementation of the anti-seismic reinforcement and consolidation only on each pillar of the external facades of the building;

action will also be taken on those internal pillars that the preliminary analysis will have identified as most loaded;

The types of intervention are essentially the following:

• Creation of the cavity preferably on the long side of the pillar, as illustrated in the figures from no. 4 to no. 8.

In the figure nr. 1 shows the pillar before the intervention.

In the figure nr. 2 indicates the application of the pre-reinforcement with external bandage to the pillar.

Figure 3 shows the pre-reinforcements by means of "x-stitching"

Figure 4 indicates the cavity to be made.

In the following figure no. 4 shows the implementation of the pre-reinforcement (pre-perforated metal sheet, shaped metal grid, or other suitable material) inside the cavity with the cutting of some horizontal brackets and without cutting vertical rods.

Figure 5 indicates the vertical drilling with continuous core drilling, to be carried out at the base of the cavity, for the insertion of the central anti-seismic reinforcement.

Figures 7a, 7b and 7c indicate the allocation of the central anti-seismic reinforcement consisting of a cage of vertical reinforcements, of an adequate number and diameter, with horizontal or continuous spiral stirrup.

Figure 7a indicates the allocation of the central anti-seismic reinforcement consisting of a pre-drilled tubular with associated barycentric iron, the latter may not even be necessary.

Figure 7b indicates a type of central reinforcement different from the previous one as it is made up of the lower section (located in the foundation) of pre-drilled tubular to which the upper section is connected, consisting of a cage of vertical rods clamped with horizontal brackets or continuous spiral. Alternatively, it is possible to insert a type of central reinforcement different from the previous one as it is composed of the lower section (located in the foundation) of pre-drilled tubular on which the upper section consisting of a single iron is connected.

Figure 7c indicates a type of central reinforcement different from the previous one as it consists of a single reinforcement of adequate diameter for the entire thickness.

Figure 8 shows the restoration, by means of suitable welding, of the previously cut reinforcements.

Figure 9 shows the closure of the cavity by means of a suitable casting with suitable mortar.

and that the same differ in activities depending on whether the existing structures in reinforced concrete. whether or not they are in very precarious conditions.

Description of the specific equipment

The possibility of being able to carry out continuous core drilling operations in the cavity created is delegated to the use of a particular specific equipment formed by a core drill which, by means of a 90 ° return, a right angle joint, allows the core drilling machine to be used as a unit. external to the cavity (Main Figure and Fig. 5), in which only the core barrel is positioned, thus avoiding having to create a much larger opening in the pillar to house the drilling equipment, and therefore being able to affect much less invasively in the pillar itself, without the need to shear the vertical reinforcement of the pillar.

Claims (1)

CLAIMS 1. Procedure for strengthening and anti-seismic consolidation of existing reinforced concrete structures, comprising the following phases: • Installation of suitable sensors all around the cavity being created to know the real stress state of the materials (reinforcement and concrete) before and after the intervention and for structural monitoring and the effectiveness of the system built over time; • Pre-reinforcement outside the pillar by means of a metal bandage or other suitable material, of adequate thickness, all around the pillar on which to intervene, starting from the walking surface and up to a height slightly higher (about 10 centimeters) at the top of the cavity which the bandage must be made and joined to the pillar by means of suitable threaded bars, or other, connected and tightened by means of a metal plate and fixing nuts; · Cavity opening technique; • Internal pre-reinforcement of the cavity by means of pre-perforated metal bandage, shaped metal grid, or other material, of adequate thickness on each internal face except the base or other suitable material, of adequate thickness; · Specific equipment equipped with a 90 ° return (joint) for continuous coring in the cavity; • Possible pre-reinforcement at the beam-pillar connection by means of "x-stitching" between the basal part of the pillar and the lower beam; • Mortar for filling the cavity, with suitable characteristics, also pigmented (colored) to allow subsequent checks.