IT201600098850A1 - Improved device or tape for anchoring to a masonry or reinforced concrete structure, or for joining two masonry or reinforced concrete structures, with characteristics of resistance to extraction. - Google Patents

Description

Improved device or tape for anchoring to a masonry or reinforced concrete structure, or for joining two masonry or reinforced concrete structures, with characteristics of resistance to slipping

The present invention relates to a structural anchoring system for masonry or reinforced concrete structures, or for the junction of two masonry or reinforced concrete structures, made by means of an improved device or tape for anchoring with characteristics of resistance to slipping.

More specifically, the invention relates to a geometrically configured device or tape of the above type which allows to obtain a better resistance to slipping from the anchor filling material, and a better resistance to the extraction of the filling material from the masonry or reinforced concrete support.

Therefore, the present invention is part of the anchoring systems but differs from them in some important aspects.

In particular, currently known anchoring systems of the aforementioned type are substantially divided into two distinct categories, namely i) anchoring systems cast in place or "log bolts", ii) anchoring systems installed subsequently.

The first anchoring systems created a compression seal in the lower part.

The second anchoring systems can be divided into two subfamilies, i.e mechanical and chemical. Mechanical systems include undercut systems and expansion systems, which exploit an action by friction. The chemical ones, on the other hand, exploit a seal by adhesion along the entire surface.

An established technique for the consolidation of masonry and reinforced concrete structures is the system called CAM <®>, Active Seams of the Artifacts.

In the following, in presenting and describing the technology and the solution according to the present invention, explicit reference will be made to the CAM <®> system, but it is to be understood that the solution according to the present invention should in no way be limited to this type of system, as its peculiarities can also be exploited in consolidation systems of masonry or reinforced concrete structures of different types.

Referring therefore to the CAM <®> system, it provides for the use of metal strips designed to create, in the masonry structures, a three-dimensional grid consisting of meshes which, crossing the thickness of the masonry structure itself, create a diffused reinforcement for a panel, that is a shear, torsion and bending reinforcement in the case of reinforced concrete structures.

For example, in the case of masonry structures, the CAM <®> system allows for an improvement in compressive strength due to induced confinement, an improvement in shear strength by means of horizontal bandages which constitute an effective shear reinforcement, and an improvement of the in-plane and out-of-plane flexural strength by means of the vertical bandages which constitute an effective tensile reinforcement. Each shirt is made up of a ribbon closed on itself.

Still in the CAM <®> system, in the walls that rest on the foundations or in the intersection between orthogonal walls, when it is not possible to make holes on both sides, or when one of the sides is inaccessible, the belts cannot be blocked by means of the realization of the closed link described in the preceding one.

A similar problem arises when the tape is applied to concrete or wood structures and the tape must be anchored to inaccessible end elements (e.g. beam and column).

A possible solution to this type of problem, which, as mentioned, is not limited to the CAM <®> system, consists in blocking the thickness of the wall / foundation or beam / pillar in reinforced concrete, could be the use of classic metal shoes, connected through log bolts or mechanical or chemical anchoring devices, to the support structure.

However, very often this solution cannot be adopted. For example, it is inapplicable in existing masonry structures, in which the foundations are made of the same masonry, with limited or no section enlargements.

The tape used in the CAM system, or also the same one proposed in the present invention, is made of carbon steel, stainless steel or plastic material, such as polyester or polyethylene.

This tape has smooth and slightly rough surfaces, as it is made by mechanical processing to obtain regular surfaces, so it may not have high adhesion or friction capacity with the mortar or other anchoring material for filling in the hole. .

Of course, this adhesion is always present both in terms of friction (normally with coefficients between 0.1-0.2) and in terms of bonding, but it may be difficult to establish the entity a priori.

With respect to the adhesion between mortar and support, however, this is normally and commonly entrusted to the ability to bond chemically (resins or two-component mortars), a capacity that is closely linked to the mechanical characteristics (in particular the tensile and shear strength) of the support. which in the case of poor masonry can be extremely limited.

The main purpose of the present invention is to solve the aforementioned limitations, providing a solution capable of obtaining an anchoring in general, and in particular of the tapes in a masonry or reinforced concrete structure, in any condition, solving the problems mentioned above. .

To this end, the Applicant, in order to overcome this problem, which automatically extends to the problem of anchoring in general, has studied and perfected the solution proposed according to the present invention, which allows direct anchoring of the belt, suitably made with a particular predisposition, in a hole made on the support element (wall, foundation, reinforced concrete beam, etc.), which hole is then filled, for example with high resistance mortar such as EMACO <®> or resin or other suitable material.

Therefore, the main purpose of the present invention is to provide a solution that allows to obtain an anchoring of a tape resistant to the slipping of the tape itself from the mortar or other anchoring material, and resistant to the slipping of the mortar or other anchoring material from the substrate in masonry or reinforced concrete.

A further object of the present invention is to provide an anchoring device or tape which allows to make a hole exactly corresponding to its own dimensions, being the intrinsic resistance characteristics of the device or tape itself.

The solution proposed according to the present invention replaces the traditional anchoring element, normally a prefabricated steel bar of an assigned length, with a tape, shaped on site or even pre-shaped, and with a flexible and adaptable anchoring length directly on site. Even the shape and the shaping methods, as will be better explained below, can be modulated directly on site according to the resistance to be achieved or the quality of the support (masonry or reinforced concrete) or the position envisaged for anchoring, often not known a priori.

Therefore, the specific object of the present invention is a structural anchoring system for masonry or reinforced concrete structures, or for the junction of two masonry or reinforced concrete structures, with characteristics of resistance to slipping, characterized by the fact of providing at least one device or tape , said at least one device or belt having a longitudinal axis and providing at least a first section and at least a second section, said at least a first section and at least a second section generated by a translation and rotation of the transverse section, with respect to said longitudinal axis, assuming for said at least a first portion of the direction of rotation and direction of arbitrary translation, and for said at least a second portion of the direction of translation concordant with that of said at least a first portion and direction of rotation opposite to that of said at least a first portion.

Preferably, according to the invention, said at least one device or tape has a constant section along the longitudinal axis for both said at least a first section and at least a second section.

Furthermore, according to the invention said at least one device or tape has a rectangular section.

at least one device or tape has a rectangular section. Again according to the invention, said at least one portion is obtained by means of a simultaneous translation (along the longitudinal axis) and rotation (around the longitudinal axis with constant rotation gradient along the longitudinal axis) of the cross section of the device or belt according to a first direction, unchanged from one to the other end of the section and by the fact that said at least one section is obtained through a simultaneous translation (along the longitudinal axis (z)) and rotation (around the longitudinal axis with rotation gradient constant along) of the cross section of the device or belt, according to a direction of translation concordant with said at least a first portion and a direction of rotation opposite to that of said at least a first portion, unchanged from one end to the other said at least a second treatment.

Furthermore, according to the invention, said at least one device or tape is subjected to surface treatment, in particular roughening.

Still according to the invention, said system provides for multiple devices or tapes repeated in succession.

Still according to the invention, said system provides for a plurality of superimposed devices or tapes.

Furthermore, according to the invention, around said at least one device or strip a suitable material is poured or injected to guarantee its adhesion to the structure, in particular mortar, mortar with additives with fibers, epoxy or other types of resins, or other filling material. .

Finally, according to the invention, said at least one device or tape is inserted inclined in the structure.

The present invention will now be described, for illustrative but not limitative purposes, according to its preferred embodiments, with particular reference to the figures of the attached drawings, in which:

Figure 1 is a perspective view of an embodiment of the device according to the invention; Figure 2 is a cut-away view of the device of Figure 1;

Figure 3 schematically shows an application of the device according to the invention;

Figure 4 is a perspective view of the device of Figure 1;

Figure 5 shows the diagram of the stress exchange between the device according to the invention and the anchoring material;

figure 6 shows the solution of figure 3 applied in a wall structure; And

Figures 7a and 7b show further applications of the device according to the invention.

Observing now in particular figures 1 and 2, an embodiment of a device or tape according to the invention is shown, generically indicated with the numerical reference 1, which has a particular geometric configuration that will be described and claimed below.

In particular, the device or tape 1, which in the illustrated embodiment has a substantially rectangular section, can be divided into two sections:

section A: obtained through a simultaneous translation (along the z axis) and rotation (around the z axis) of the rectangular section of the belt 1. In the generation of the volume, the direction is not predetermined neither for translation nor for rotation, the only constraint being that it remains unchanged from one extreme to the other.

section B: obtained through a simultaneous translation (along the z axis) and rotation (around the z axis) of the rectangular section of the belt 1. In the generation of the volume, the direction of translation and rotation is predetermined and opposite to that of the section A, with the same constraint indicated for section A.

In a symbolic union of the two sections, a particular "helix and counter helix" geometry is obtained, which is typical and characterizing the present invention.

In particular, the parameters that describe this geometry are:

- the dimensions of the transverse rectangular section of the device 1 (always the same for sections A and B);

- the length la, of section A. in which section A is both translated and rotated, along the z axis; - the function that describes the angle of rotation of the section of section A along the z axis;

- the length lb, of section B, in which the section is both translated and rotated, along the z axis; - the function that describes the angle of rotation of the section of section B along the z axis.

In particular, the device 1 according to the invention allows to solve the main aforementioned typical of the known solutions by:

- the study of a particular geometric configuration to be assigned to the tape 1 inside the anchor hole, which allows locking on the mortar, or other material, mainly due to its shape and capable of developing or improving resistance by friction or adhesion;

- the geometric configuration that allows a transversal expansion of the anchoring mortar, improving the mechanical meshing with the support.

Referring now in particular to figures 3 - 5 of the attached drawings, it is shown how the device or tape 1 according to the invention allows to solve the problem of the slipping of the tape 1 from the mortar or other fastening material.

The device or tape 1 according to the invention allows it to be bound to the mortar, using the particular geometric configuration described in the preceding one, which guarantees its locking by "shape".

As can be clearly seen from the description, and from the figures, the innovative solution consists of the particular shape with an inverted double spiral (or helix and counter-helix of sections A and B that make up the device or tape 1 according to the invention.

The inversion of the course of the belt 1 constitutes the true anchoring constraint between the belt 1 itself and the filling material, since, in the change of geometry, or in the inversion of the direction of torsion, the reactions that the filling material exerts on the belt 1 produce (see in particular Figure 5) an action which balances the stressing action of extraction.

As can be seen from Figure 5, throughout the development of the belt 1, but especially in the area of change of direction of the torsion, strong stresses are activated between the belt 1 and the filling material, orthogonal with respect to the surfaces in contact with the components. in the direction of the unthreading, said solicitations being able to balance the external action, the whole, as mentioned, by "shape".

On the belt 1 according to the invention, a roughening surface treatment could also be performed, which can develop and / or improve the holding capacity for friction however present, which is added to that for "shape" alone.

It is emphasized that in the present invention the retention by friction or adhesion can be exploited to further improve the anchoring capabilities, but that the object of the invention is the geometric shape given to the belt which makes it capable of locking only by "shape" but which it provides a further increase in the holding capacity due to friction or adhesion.

Referring now to figures 6 and 7a - 7b, the geometric module "helix and counter helix" provided in the device or tape 1 according to the invention is represented.

It is quite clear how multiple overlapping tapes 1 can be used, to be inserted in the anchoring hole, if, for example, greater anchoring strengths are required.

Furthermore, the modular device or belt 1 (section A section B) can conveniently be repeated in succession.

The functioning of the anchoring is also given by the ability of adhesion between mortar (or other filling material) and support (masonry or reinforced concrete), so it may be necessary to have high driving depths, especially for low-capacity masonry, as will be better described below.

To activate this adhesion on a significant length of the hole (for example greater than 50-60cm), as mentioned, it may be appropriate to repeat tape 1 with "helix and counter helix" two or more times so as to activate, thanks to the dilating effect that the helix generates on the filling material, and therefore on the support, all the lateral contact surface between it and the support.

In cases where (as often happens) it is not possible to make the anchor hole in the axis with the direction of introduction of the tape 1, for example because there is not always a foundation, or because the foundation has the same size as the masonry, according to the invention (see Figures 7a and 7b) it is possible to make the inclined hole, whereby the length of the anchor is increased with respect to the height of the foundation and therefore the tension on the walls of the hole is lowered.

This inclination could also be 90 °, for example where there is not enough space.

The use of the belt 1 according to the invention instead of a traditional rigid element, such as a bar or a pre-made anchoring element, therefore allows great flexibility since it is possible to assign an inclination to the anchor according to the invention with respect to the direction of the load. absolutely modular according to the need and above all with the possibility of being defined directly on site. In these cases, in the area of change of direction, it may be necessary to insert only a simple object, for example a deep drawn plate 2, or the like, capable of acting as a "pulley" and of distributing the reaction at the fold of the belt 1 in contact with the support.

The device or tape 1 according to the invention is also able to give an excellent response to the problem of adhesion between the filling material (e.g. mortar) and the support.

On the basis of what has been described in the foregoing in relation to the exchange of stresses between the belt 1 and the filling material, it is to be pointed out that the stresses applied to the filling material are of strong radial expansion.

The particular geometry of the specially designed tape 1 also allows to improve the adhesion capacity between the filling material and the support, as the dilating action applied to the anchoring filling material in turn is carried out on the masonry or on the surrounding reinforced concrete.

The expansion action between the filling material and the support activates an additional meshing mechanism with respect to the only chemical adhesion between the components, that is a radial tension that activates friction resistances with the following adhesion law:

Where µ is the friction coefficient and �n is the radial tension generated by the expansion of the filling material on the support.

From the above, it is evident how the device 1 according to the invention allows an anchoring, made with a metal band or other material (e.g. plastic material), which works thanks to a particular geometric configuration that allows mechanical locking, while the classic ones anchors are made using "rigid" and pre-established metal elements (such as threaded bars, mechanical anchoring devices having a predetermined diameter and length) inserted into a hole that is made on the anchoring support (in masonry or reinforced concrete) dry or injected with highly resistant mortars with good adhesion to the substrate.

The solution according to the present invention is the result of the study of a particular geometric configuration of the device or tape 1, which guarantees its locking by "shape" in the anchoring hole.

The tape 1 according to the invention, unlike the classic metal bars or anchors, is a non-rigid and particularly "flexible" element in terms of use. For example, it allows an anchoring with an inclination different from the classic one, i.e. orthogonal to the support, and gives the possibility to be chosen and modulated without further elements to be specially made (e.g. inclined metal shoes, welded on site or in the workshop). Furthermore, the tape 1 according to the invention is also flexible as regards the anchoring length, which can be chosen and modified directly on site by simply making a deeper hole, without the need to replace the metal element (anchoring device). with a longer one.

These results are obtained in particular with the described form of "helix and counter helix", which allows several advantages, including

- the locking mainly by "shape" between the tape and the anchoring filling material;

- the activation or full exploitation, thanks to the "shape", of the holding capacity by friction or adhesion between the belt and the filling material;

- the creation of a state of lateral expansion to the filling material, which improves its adherence and meshing with the support (expansion anchoring).

Furthermore, as mentioned, the "helix and counter helix" device or tape 1 can be repeated several times in the development of the anchor, to obtain anchors with a greater driving depth, necessary for example for supports with low resistance or in the case of stresses high.

The anchoring can be configured with depth, number of modules and number of belts 1 overlapping directly on site, without having to make changes to the type of anchoring, as is the case for other types of commercial anchors.

A further field of application of the tape 1 according to the invention is that of reinforced seams for masonry structures, or also of a metal joint element.

In both of these uses, it is sufficient to insert the tape in a hole passing through the entire wall thickness (double facing and core) in the case of the metal joint, or the intersection between two walls for the reinforced seam, with at least one " helix-counter-propeller ”for the flap (and possibly also further internal“ counter-propellers ”to improve distribution and anchoring capacity).

In this way, one could think of obtaining an internal tie rod operation capable of counteracting the distancing between two wall faces or between two intersecting walls.

The present invention has been described, for illustrative but not limitative purposes, with particular reference to its preferred embodiments, but it is understood that variations and / or modifications may be made by an expert in the art, without thereby departing from the relative scope of protection, as defined in the attached claims.

Claims (9)

CLAIMS 1. Structural anchoring system for masonry or reinforced concrete structures, or for the junction of two masonry or reinforced concrete structures, with characteristics of resistance to slipping, characterized by the fact of providing at least one device or tape (1), called at least a device or belt (1) having a longitudinal axis (z) and providing at least a first section (A) and at least a second section (B), called at least a first section (A) and at least a second section (B) generated by a translation and a rotation of the transverse section, with respect to said longitudinal axis (z), assuming for said at least a first section (A) direction of rotation and direction of translation arbitrary, and for said at least a second section (B) direction of translation it agrees with said at least a first section (A) and opposite direction of rotation to said at least one first section (A). 2. Structural anchoring system according to claim 1, characterized in that said at least one device or belt (1) has a constant section along the longitudinal axis (z) for both said at least a first section (A) and at least a second stretch (B). 3. Structural anchoring system according to claim 1 or 2, characterized in that said at least one device or tape (1) has a rectangular section. 4. Structural anchoring system according to one of the preceding claims, characterized in that said at least one section (A) is obtained through a simultaneous translation (along the longitudinal axis (z)) and rotation (around the longitudinal axis (z) with constant rotation gradient along z) of the cross section of the device or belt (1) according to a first direction, unchanged from one to the other end of the portion (A) and by the fact that said at least one portion (B) is obtained by a simultaneous translation (along the longitudinal axis (z)) and rotation (around the longitudinal axis (z) with constant rotation gradient along the longitudinal axis (z) of the cross section of the device or belt (1), according to a direction of translation agrees with said at least a first section (A) and a direction of rotation opposite to that of said at least one first section (A), unchanged from one end to the other end of said at least a second section (B). 5. Structural anchoring system according to one of the preceding claims, characterized in that said at least one device or tape (1) is subjected to surface treatment, in particular roughening. 6. Structural anchoring system according to one of the preceding claims, characterized in that it provides several devices or tapes (1) repeated in succession. Structural anchoring system according to one of the preceding claims, characterized in that a plurality of superimposed devices or tapes (1) is provided. Structural anchoring system according to one of the preceding claims, characterized in that around said at least one device or tape (1) a suitable material is poured or injected to guarantee its adhesion to the structure, in particular mortar, mortar with additives with fibers, epoxy or other resins, or other filling material. Structural anchoring system according to one of the preceding claims, characterized in that said at least one device or tape (1) is inserted inclined in the structure.