IT201800002473A1 - THERMICALLY INSULATED EXOSTRUCTURE APPLICABLE TO EXISTING BUILDING STRUCTURES TO BE REINFORCED OR MADE ANTISISMIC. - Google Patents

Description

THERMAL INSULATED EXOSTRUCTURE APPLICABLE TO EXISTING BUILDING STRUCTURES TO BE REINFORCED OR MADE ANTISISMIC.

The present invention refers to a thermally and acoustically insulated, anti-seismic exostructure applicable, for example to walls of buildings built in the past with any known technology: stones, bricks, reinforced concrete, wood, iron, raw earth, tuff, etc.

Thermally insulated technologies of this type called "coats" for walls of buildings are known which are designed to thermally insulate the interior of the buildings themselves made by means of panels that are positioned on the walls of the same.

These panels are made in various shapes and in insulating material and can be positioned by gluing, or mechanical fixing, on vertical and horizontal building structures to obtain an "external coat" insulation.

For example, panels are known which present on at least two of the sides defining the thickness of the panel itself portions provided with a plurality of protuberances, which can have various shapes in addition to those shown here: rounds, triangles, trapezoids, various polygons, which define between their as many seats, in which similar protuberances of another panel of the same type are inserted. In this way the panels are hooked to each other. In addition, on the surface of the panel that will be laid facing the wall of the existing building there are grooves that allow the easy insertion of the gluing material to the wall inside them.

It is also known that to make a building anti-seismic, with regard to the walls, iron rod nets or GFRP (Glass Fiber Reinforced Polymer) nets can be used and the walls can be reinforced by applying reinforced plaster on such nets or concrete castings or injections with various materials. or with armed raw earth.

It is also known that to make a building anti-seismic, reinforced concrete or reinforced plaster walls of various thicknesses can be built against existing walls or structures. The walls or reinforced plaster or reinforced raw earth are usually made of inert material, binder, all mixed with water, which can consist of cement, lime, resins, any additives, lightening material, etc. Inside the walls the reinforcing rod iron is housed, be it an electro-welded mesh or the straight rod placed vertical and / or horizontal or the GFRP or carbon mesh. The connection of the new wall with the structure to be consolidated takes place with connectors placed perpendicularly that enter the existing wall, sometimes exiting from the other side to connect to a similar reinforced wall or reinforcement plaster that will be carried out on the other side of the existing wall. . These connectors are sometimes fixed to the existing wall by Fisher or mechanical or chemical embedding or fixed with mortar or various binder or simply inserted into holes specially made on the existing wall. The connectors and the iron rod are positioned according to what, from time to time, is indicated by a computer or by a proceduralized, standardized or intuitive technical practice of the operator. The connectors and reinforcement rods can be made of steel or composite materials, fiberglass, carbon, plastic, various materials such as aluminum and all other materials according to known or unknown techniques.

The execution of these reinforcement walls are usually carried out against the existing walls or structures, formworking with rigid panels towards the outside. These rigid panels, in iron, wood or plastic, are positioned at the desired distance from the existing wall after positioning the reinforcement iron. After assembly, the concrete is poured between the formwork and the existing wall.

Keeping the formwork in place during casting is very difficult as the pouring of concrete in the first liquid phase generates very important lateral thrusts in the panel. Once the material, usually concrete or cement, constituting the stiffening wall has hardened, the rigid formworks are removed and then the insulating panels are positioned to form an insulating "coat".

The present invention has tackled the problem of how to make a building structure anti-seismic by using insulating panels of "external coat" structures in place of rigid non-insulating formworks, thus eliminating many intermediate processes. In particular, the present invention relates to an "external coat" exostructure that uses the insulating panels typical of insulating coats, connectors and reinforcing nets, arranged in such a way that a reinforcement and insulation wall placed externally to the existing wall and bound to it.

The present invention relates to an exostructure having the characteristics of the attached claim 1.

Further characteristics of the hexostructure according to the present invention are contained in the attached dependent claims.

The characteristics and advantages of the present invention will be better clear and evident from the following, exemplary and non-limiting description of an embodiment with reference to the attached figures which respectively illustrate:

• Fig. 1a represents a top view of an angled portion of the exostructure according to a first embodiment of the present invention applied to a pre-existing wall of a building;

• figure 1b illustrates a perspective view of an insulating panel of the exostructure of figure 1;

Figure 1c illustrates a perspective view of a coupling element of this first embodiment;

• Fig. 2a represents a top view of an angled portion of an exostructure according to a second embodiment of the present invention applied to a pre-existing wall of a building;

• figure 2b illustrates a perspective view of an insulating panel of the exostructure of figure 2a;

• Fig. 3a represents a top view of a portion of an insulating panel with connector according to a third embodiment of the present invention applied to a pre-existing wall of a building;

Figure 3b shows a perspective view of an insulating panel of figure 3a;

• Fig. 4a represents a top view of a portion of an insulating panel with insert according to a fourth embodiment of the present invention applied to a pre-existing wall of a building;

Figure 4b shows a perspective view of an insulating panel of figure 4a;

• Fig. 5a represents a top view of an angled portion of the exostructure according to a fifth embodiment of the present invention applied to a pre-existing wall of a building;

Figure 5b shows a perspective view of an insulating panel of the hexostructure of figure 5a;

• figure 6 represents a top view of a portion of the insulating panel according to a sixth embodiment of the present invention, applied to an existing wall of a building;

• figure 7 represents a top view of a portion of the insulating panel of the exostructure according to a seventh embodiment of the present invention, applied to an existing wall of a building;

• figure 8 represents a top view of a portion of the insulating panel of the exostructure according to an eighth embodiment of the present invention, applied to an existing wall of a building;

Figures 9a-9h respectively illustrate in perspective view as many embodiments of connectors according to the present invention;

Figures 10a and 10b illustrate two embodiments of connectors adapted to be arranged at the junction of panels such as those illustrated in Figure 5b.

• Figures 10c and 10d illustrate two forms of connectors designed to be arranged by piercing the insulating panel and then fixing it to the outside with flat retaining elements;

• Figures 11a and 11b illustrate connectors obtained from a bent rod.

With reference to the aforementioned figures, the exostructure according to the present invention is applicable to building structures and in particular to pre-existing walls P of the same and comprises a plurality of thermally insulating panels 2 side by side and overlapping each other so as to substantially cover this wall. They are connected to the wall by means of a plurality of connectors 3 which keep the panels spaced from the wall to form an interspace I in which a reinforcement structure is positioned (for example, a network composed of metal rods 4). Said cavity being able to be filled with concrete or other equivalent material, or even raw earth, so as to form a further reinforced wall which is positioned in contact and joins with this pre-existing wall. These insulating panels can be made of insulating plastic, expanded polystyrene, expanded polystyrene, expanded polyethylene, expanded polypropylene, expanded polyurethane, cellular glass, rock wool, wood fiber, glass wool, plaster, wood, concrete, etc. or in general other materials having insulating, thermal or acoustic characteristics.

The connectors comprise a head 31 which rests or is associated with the panel 2, a spacer portion 32 which determines the gap between the panels and the pre-existing wall. Furthermore, in some embodiments associated with the head of the connector there is a hooking rod 33 which crosses the panel and hooks onto its external surface.

The connectors also comprise, on the side opposite the head 3, a portion for fixing to the wall (not shown in the figures).

This portion of fixing to the wall is inserted into the wall and is conveniently made according to one of the known systems of attachment to the walls, such as for example Fisher-type anchors, chemical anchors, fixing with cement mortar, gypsum mortar, lime mortar, various resins, or even simply by making a hole and inserting the portion of the plug suitable for this, or by adopting self-drilling or self-tapping portions of the plug.

The new reinforced wall acts as a sort of support exostructure for the pre-existing building structure, while the insulating panels provide a thermal protection typical of a “coat” structure. Moreover, sometimes, due to the stratigraphy that is formed or the materials used, an acoustically insulated structure is also obtained.

In this way, the present invention achieves the double or triple function of an anti-seismic reinforcement structure and thermal and sometimes acoustic protection designed to improve the energy, seismic and acoustic efficiency of the building on which it is placed. In the embodiment of figures 1a-1c, the insulating panels on at least two of the sides defining the thickness of the panel itself comprise a plurality of protuberances 21, which can have various shapes in addition to those shown here: rounds, triangles, trapezoids, various polygons , which define an equal number of seats 22, in which similar protuberances of another panel of the same type are inserted, which must be hooked to it to cover such a building structure.

These protuberances 21 and 22, which can have various shapes in addition to those shown here: rounds, triangles, trapezoids, various polygons, once inserted together, first of all determine the maintenance in place of the panels and also a barrier to the entry and exit of liquids, but above all they prevent the formation of direct cracks with the passage of air which would otherwise lead, once the panels have been installed, to deleterious formation of interstitial condensation; furthermore, they allow a mutual resistance of the panels to the hydrostatic thrust during the pouring of the concrete between the panels and the existing wall, emulating a monolithic formation of the wall consisting of insulating panels.

This panel in the face that faces the building structure can include vertical grooves 23, while the face that faces outwards can be conveniently smooth. These grooves can be of any shape that allows the easy insertion of the concrete poured into the cavity during casting and the subsequent bond of the solidified concrete to the insulating panel.

The exostructure includes coupling elements 5a, 5b, composed of elements or pins 5a, made of rigid plastic material, such as polyethylene, polypropylene, polystyrene, ABS, PVC, nylon, etc., or metal or even wood, or synthetic, such as fiberglass , various resins, aluminum, and profiles 5b which are associated both with the pins and with the connectors to tie the panels to the existing wall.

Such pins or elements 5a can be inserted in said grooves 23 or inserted in smooth parts of the panels, and therefore protrude from the panel. In particular, these sections 5b are shaped as two "C" 51 and 52 constrained to each other by their vertical portions (back to back). This section is advantageously realized as a double "C" section. This section can be a few centimeters long, the minimum necessary to be able to be combined with the head 31 of the connector, or even longer up to a total length of the insulating portion. These profiles can be made of rigid plastic material, such as polyethylene, polypropylene, polystyrene, ABS, PVC, nylon, etc., or metal or even wood, or synthetic, such as fiberglass, various resins, aluminum. The two "Cs" are suitable for one 51 to be inserted into the element or pin 5a of the panel and the other 52 to accommodate the head 31 of the connector 3.

A further variant provides that the head 31 of the connectors has a "C" shape so as to be joined directly on the element 5a without the aid of the element 5b.

In the embodiment of figures 2a-2b, the insulating panels include, similarly to that of figure 1b, both the protuberances 21 and the seats 22, which can have various shapes in addition to those shown here: rounds, triangles, trapezoids, various polygons . In the internal part of the panel that facing the pre-existing wall there is a substantially smooth layer 24 which has vertical grooves 23 on the surface facing this wall. The concrete poured into the cavity during casting is inserted into them for an integral connection between the insulation and the exostructure. In this panel there are no elements 5a.

The panel of which Fig. 2b is associated with each connector by means of the hooking rod 33, while the head 31 of the same rests on the internal surface of the panel.

This fastening and connection system can also be adopted for the completely smooth insulating panels in the six faces, such as the one provided in figure 5b.

In the embodiment of figures 3a-3b, the insulating panels are substantially smooth and comprise only vertical grooves 23 in the internal surface.

The heads 31 of the connectors 3 can be inserted directly into these grooves, thus binding the panel directly to the wall.

In the embodiment of figures 4a-4b, the insulating panels comprise, similarly to that of figure 1b, both the protuberances 21 and the seats 22 which can have various shapes in addition to those shown here: rounds, triangles, trapezoids, various polygons. In the internal wall of the panel, the one facing the pre-existing wall, there are vertical grooves 23 in which coupling elements 5 are inserted which in this embodiment include a rigid plastic profile, such as polyethylene, polypropylene, polystyrene, ABS, PVC , nylon, etc., or metal or even wood, or synthetic, such as fiberglass, various resins, aluminum, with a single "C" stuck in the throat. This “C” shape accommodates the head 31 of the connector 3.

In the embodiment of figures 5a-5b, the insulating panels have a parallelepiped shape and are substantially smooth. They are associated with the pre-existing wall by means of the connectors 3 provided with hooking rods 33. In particular, as illustrated in figure 5a 5b, the hooking rods cross the thickness of the panel and are locked, by means of suitable locking means, on the external surface of the panel . All the insulating panels can also be sandwich panels or made with different materials coupled together, for example, insulating materials of different densities, of different types, of different constitution, of different colors, or with external couplings to the faces or even on one of the faces, the internal or external one, of various materials, such as metal sheets, wooden panels, finishing elements in plastic, metal, wood, resins, cementitious materials, etc.

In the embodiment of Figure 6, the coupling elements comprise only the pin 5a inserted in these grooves 23.

In the embodiment of Figure 7, the pin 5a is provided with a hole 55 so as to mate with the connector of Figure 9g which has a corresponding hole 311 in the head. The connection between the connector and the pin takes place by inserting a plug at the inside holes 55 and 311 once aligned.

In the embodiment of figure 8, the pin 5a is provided with a hole 55 so as to mate with the connector of figure 9f which has a corresponding hole 311 in the head. The connection between connector and pin takes place by inserting a plug at the inside holes 55 and 311 once aligned.

As previously indicated, the connectors in all embodiments include a head 31 and a spacer portion 32. The head 31 can also be of the same diameter as the spacer 32 and therefore be a whole.

In figure 9a the spacer portion is simply cylindrical, it can be smooth or threaded so that the element 31 and 32 'mates with the portion 32 through a thread so as to allow the adjustment of the position inside and outside the head 31, so that if the pre-existing wall is out of plumb or irregular, the insulating panels can be positioned straight.

In figure 9b the spacer portion comprises means for adjusting the length of this portion consisting for example of a threaded part 32 'on which the head is screwed.

In figure 9c the spacer part provides an eccentric which allows, with its rotation, to move the head 31 from the axis of the connector so as to center it with the hooking elements 5b or 5, or the grooves 23. Furthermore, also in this If necessary, threads or other adjustment means can be provided on which the head 31 can be positioned more inward or outward.

In this way it is possible to adjust the length of this portion to compensate for any misalignments or misalignments of the walls.

In figure 9d the connector includes both an eccentric and length adjustment means consisting of a threaded portion 32 '' associated with a stem of the head 31 which is screwed into the eccentric.

In figure 9e the connector includes both an eccentric and length adjustment means consisting of a threaded portion 32 '' associated with a stem of the spacer portion 32 onto which the eccentric is screwed.

In figure 9f the connector also comprises a hooking rod 33 associated with the head 31 comprising an advantageously pointed stem 35 to easily cross the insulating panel and locking means, for example made by means of a disk, or other shaped locking elements 36.

Figures 10a-10d are variants of assembly between the panels and the walls, in which the connectors 3 are placed at the junction of two panels 2.

In particular, in figure 10a the tie-rod comprises two "U" -shaped brackets 37 and 38 associated with the stem 35 arranged opposite each other which receive the edges of adjacent panels; a locking disc 36 locks the panel in place. In figure 10d the brackets 37 'and 38' are "L" shaped. In figure 10c the brackets are not provided, but there is an external plate 39 which is placed under the locking disk. In figure 10b a single plate 39 'is associated with multiple connectors.

The elements 35, 36, 37, 38 can be in several pieces or even in one piece.

In particular, the connector (3) and the tie rod (33) can be separated from each other and the tie rod can have a plug-in portion that fits into the existing wall. In this way the connector simply acts as a spacer element while the tie rod determines the fixing of the panel to the wall. In this embodiment, the connector and the tie rod are positioned offset from each other.

The adjustments of the distance between the head 31 and the existing wall can be made by threading or by other known means which fix the head 31 after having been adjusted in a certain desired position: toothed, bayonet coupling, with sliding and fixing with lateral screws, gluing and all other means of known art.

Claims (18)

CLAIMS 1. Thermally and acoustically insulated, anti-seismic structure, applicable to building structures and in particular to pre-existing walls of the same comprising: • a plurality of thermally insulating panels (2) placed side by side so as to substantially cover this wall, • a plurality of connectors (3) which bind the panels to the wall, keeping them spaced from it to form a cavity (I), • a reinforcement structure (4) being positioned in this interspace (I), • this interspace (I) being able to be filled with concrete, so as to form a further reinforced wall which is positioned in contact with this pre-existing wall. 2. Structure according to claim 1, in which said connectors comprise a head (31) which is associated with the panel, a spacer portion (32) which determines the gap between the panels and the pre-existing wall and a portion for fixing to the pre-existing wall. 3. Structure according to claim 2, wherein associated with the head of the connector there is a hooking rod (33) which crosses the panel and hooks onto its external surface. 4. Structure according to claim 1, wherein the insulating panels (2) on at least two of the sides defining the thickness of the panel itself comprise a plurality of protuberances (21), which define each other as many seats (22), into which they are inserted similar protuberances of another panel of the same type, which must be hooked to it to cover such a building structure. 5. Structure according to claim 1, in which said panel in the face that will face the building structure comprises vertical grooves (23). 6. Structure according to claim 1, comprising coupling elements (5a, 5b) which cooperate with the connectors to tie the panels to the pre-existing wall comprising pins (5a) which are associated with the panels and profiles (5b) which are associated with both pins with both connectors. 7. Structure according to claim 1 in which said pins (5a) comprise a hole (55) and said connectors comprise a similar hole (311) in their head (31), these holes, once aligned with each other, are suitable for receiving a joint to connect the connectors to the panels and tie them to the existing wall. 8. Structure according to claims 5 and 6 in which said pins can be inserted in said grooves or on the smooth part of the panels (2) and said profiles are shaped as two "Cs" (51,52) constrained to each other due to their vertical portions, the two “Cs” are suitable one (51) to be inserted in the pin (5a) associated with the panel and the other (52) to receive the head (31) of the connector (3). Structure according to claims 3 and 5, in which the panel is associated with each connector by means of the hooking rod (33), while the head (31) rests on the internal surface of the panel. 10. Structure according to claim 5, in which the heads (31) of the connectors (3) can be inserted directly into these grooves (23) thus binding the panel directly to the wall. 11. Structure according to claim 1, wherein said reinforcement is a metal mesh. Structure according to claim 1, wherein said spacer portion comprises an eccentric, which allows, by rotating the head, to adjust its position with respect to the guide into which it is to be inserted. 13. Structure according to claim 1, wherein the spacer portion comprises means for adjusting the length of said portion. 14. Structure according to claim 1 in which the interspace (I) is filled with raw earth, material based on resins or various conglomerates. 15. Structure according to claim 1, wherein said insulating panels (2) can be made of plastic, expanded polystyrene, expanded polystyrene, expanded polyethylene, expanded polypropylene, expanded polyurethane, cellular glass, rock wool, wood fiber, wool glass, plaster, wood, concrete, etc. or in general other materials having insulating, thermal and acoustic characteristics. 16. Structure according to claims 1 and 15 in which said insulating panels can be made of sandwiches or made with different materials coupled together, for example, insulating materials of different density, of different typology, of different constitution, or with couplings external to the faces or even on one of the faces, the internal or external one, of various materials, metal sheets, wooden panels, finishing elements in plastic, metal, wood, resins, cementitious materials. 17. Structure according to claim 3, in which the connector (3) and the tie rod (33) are separated from each other and the tie rod has a plug-in portion that fits into the wall, in this way the connector acts simply as a spacer element while the tie rod determines the fixing of the panel to the wall. 18. Structure according to claim 17, in which the connector and the tie rod are positioned offset from each other.