CZ33210U1 - Reinforced concrete corner profile - Google Patents

Description

The technical solution concerns concrete elements reinforced with technical textiles. It is a modern relatively new material called textile reinforced concrete (TRC). The solution is suitable for variable spatial concrete constructions, where the textile concrete slab is wrapped into blunt, sharp and right angles depending on the technological and architectural requirements of shaping. The solution is therefore suitable for various elements used in construction, industry or small architectural elements. For example, there may be benches, molded tables, permanent shuttering and various supporting structures, molded facade panels with folds, profiled ceiling structures, bridge walkways, railings and railings. It can be a load-bearing and non-load-bearing structure depending on the dimension size of the member and its reinforcement.

BACKGROUND OF THE INVENTION

If concrete of common properties is considered in combination with standard reinforcing steel reinforcement, reinforced concrete structures with a full cross-section, possibly additionally lightened inside with a cavity or liner of other materials with lower bulk density, are realized. However, these traditional designs are relatively massive due to the nature of the materials and their mechanical properties. These material thicknesses are influenced both by the load-bearing capacity and, in particular, by the standard requirements for durability. It is necessary to passivate the steel bar reinforcement with a layer of alkaline concrete to prevent its corrosion. The thickness of the concrete around the reinforcement, depending on the different conditions and the material used, given by the standard requirements of the currently valid Eurocode, is in the order of centimeters.

Composite reinforcements, literally fiber-reinforced polymers (FRP), which have similar or better mechanical parameters compared to traditional steel reinforcement, but they are not subject to corrosion and need not be protected with such a significant thickness of concrete to achieve the required durability. The design of the elements is carried out only with regard to consistency and sufficient anchoring of the reinforcing profiles. In the last decades the first TRC constructions have appeared. These are concretes reinforced with technical textiles, without and with saturation with polymer matrix with different spacing and warp shape. In the case of saturation, it is also possible to speak of composite type of reinforcement, which are, however, significantly finer in comparison with conventional FRP reinforcing bars substituting traditional steel reinforcement. These modern reinforcement materials are conveniently and often combined with high performance concrete (HPC) cement composites and ultra-high performance concrete (UHPC) cement or other groups. Concretes are fine-grained, with excellent mechanical and visual properties, with long durability.

TRC is particularly useful in areas where weight savings are desired, and more and more applications can be expected in the future thanks to savings on primary raw material resources and improved material knowledge. However, the presently discovered solutions of TRC structures at the time of filing do not describe and solve the local method of reinforcement at the point of the textile reinforcement plate breaking by special shaping of the textile reinforcement inside the element without the need of additional connecting elements or external attachments or local cross-sectional changes. This is a new technical solution that allows to safely transmit the necessary stress even at kinks due to the shaping of the reinforcement.

Currently, there are a number of similar and innovative solutions in this technical field. Many of them focus directly on TRC textile concrete. An example of a seemingly similar

The technical solution is the patent EP 2530217, which focuses on a prefabricated spatial structure having 3 connected walls in a seamless manner - without connecting elements. The present new solution, however, directly defines the methods of shaping the reinforcement in the break 2 of the slabs so that the break is bearable, which is not the subject of this patent, as also shown in Figures 2 (Fig.2) and 3 (Fig.3), shim from another material, eventually by changing the cross-section - by adding mass at the point of kink, not by solving the reinforcement. Furthermore, the present invention is without prejudice and claimed that the plates surround the interior space, only the method of shaping the textile reinforcement in a bend is solved. The case of another technical solution is patent WO 2018043970, which however solves a hybrid beam, that is to say a combination of modern and textile reinforcement with traditional reinforcement, eventually additional reinforcement of structures. Again, the shaping of the textile reinforcement in concrete is not solved and described - in the breaking of the slab (insert), ie in the actual part of the beam member with textile reinforcement. Marginally similar solution offers patent CN 107675831, which mentions fiber reinforced laminated concrete, but again does not comment on a possible way of shaping reinforcement in the break of the slab as a whole. Thematically close is also patent EP 3323922, where a fabric with two intertwined layers that can be filled with a cement composite is solved. The fabric can be shaped, but the fabric as a whole, which indicates the possible formation of organic shapes, not the formation of resilient kinks using textile reinforcement, again the shape of the textile reinforcement in the kink to provide sufficient load-bearing capacity is not specified at all. Further, a similar solution is in the patent JP 2007131966, similarly JP 2002180599, where the textile netting is designed as a sheet-like element, its shaping in kinks and kinks is not solved at all. Similarly, patent DE 20207945, further patent CZ 2016595, which solves the lightening of the flat plate element, not the local shaping of the reinforcement in the plate break. Other technical solutions found did not correspond with the presented solution.

The essence of the technical solution

The above-mentioned disadvantages are overcome by the present solution, which consists in locally shaping the textile reinforcement at the point of kink of the reinforced concrete corner profile. Shaping is given in possible alternatives depending on the required anchoring length of the textile reinforcement, which is dependent on the required bearing capacity of the element. Shaping is achieved by the absence of the need for additional external shims and other connecting profiles outside the concrete part, it is not necessary to change the cross-section at the point of the kink, it is not necessary to divide the kink to several pieces and their additional interconnection. The present solution thus allows for an aesthetically clean kink of the concrete slab, which in addition is capable of carrying significantly higher loads than the element without the reinforcement and the shaping of the reinforcement in the corner area.

The reinforced concrete corner profile comprises concrete and at least two reinforcements formed by a layer of technical fabric placed in the concrete. The corner profile consists of two arms in the form of reinforced concrete slabs and a common corner area of reinforced concrete in which the arms join, the corner profile having two inner walls which meet at the inner edge of the corner profile and two outer walls which meet at the outer edge of the corner profile. The first inner wall is substantially parallel to the first outer wall and the second inner wall is substantially parallel to the second outer wall. Further, the corner profile arrangement is such that there is a plane substantially perpendicular to the first inner wall and the second inner wall at the same time. The inner reinforcement is located closer to the inner walls of the corner profile than the outer reinforcement and the inner reinforcement is simultaneously positioned such that it extends inside the concrete along at least a portion of the first inner wall of the corner profile with which it is substantially parallel. the inner wall of the corner profile, the lowering being substantially parallel. Similarly, the outer reinforcement is positioned such that it extends within the concrete along at least a portion of the first outer wall of the corner profile with which it is substantially parallel, and also extends within the concrete along at least a portion of the second outer wall of the corner profile, lowering it substantially parallel. The essence of the present invention is that inside the concrete there is a reinforcing element made of technical fabric for reinforcing the corner of the corner profile, the technical fabric of the reinforcing element being positioned and shaped so that

33210 U1 includes a reinforcing intersection of the technical fabric or fabrics which, in projection, in a plane perpendicular to the corners of the corner profile, is disposed substantially at the junction of the inner edge of the corner profile and the outer edge of the corner profile.

In a preferred embodiment, the reinforcing element comprises a first technical fabric extension section and a second technical fabric extension section. The first technical fabric extension section adjoins a portion of the inner reinforcement that is substantially parallel to the first inner wall of the corner profile and the second technical fabric extension section adjoins a portion of the inner reinforcement that is substantially parallel to the second inner wall of the corner profile. The reinforcing cross-over of technical textiles is formed by cross-over the first stretch of the technical fabric and the second stretch of the technical fabric.

Preferably, the technical fabric extension sections are positioned and shaped such that in the projection perpendicular to the corner profile walls, the first technical fabric extension section is straight and oriented perpendicularly to the second outer wall of the corner profile, and likewise the second technical fabric extension section is perpendicular projection. directed to the walls of the corner profile and oriented perpendicularly to the first outer wall of the corner profile.

In another preferred embodiment, the technical fabric extension sections are positioned and shaped such that, in projection to a plane perpendicular to the corners of the corner profile, they have ends bent apart and facing the external reinforcement between the reinforcement crossings of the technical fabrics and the outer reinforcement.

Also preferred is an embodiment in which the reinforcing element also comprises a pair of curved tabs, which are made of a technical fabric layer and which are positioned and shaped such that they cross each other in projection to a plane perpendicular to the walls of the corner profile. The first curved spacer is connected with its first end to the first technical fabric extension section and the second curved spacer is connected with its first end to the second technical fabric extension section. The other ends of the curved plates are directed from the intersection of the curved plates to the outer reinforcement and are curved apart.

The technical fabric extension sections can also be positioned and shaped such that, in projection to a plane perpendicular to the walls of the corner profile, the ends are twisted together in the form of an open loop, the open portion of the loop facing the outer reinforcement and oriented towards the outer edge of the corner profile. Advantageously, the technical fabric extension sections can also be positioned and shaped such that the projection of the technical fabric extension sections in a plane perpendicular to the corner profile walls comprises a closed loop shape between the reinforcement crossings of the technical fabrics and the outer reinforcement. reinforcement.

Also preferred is an embodiment in which the reinforcing element comprises a looped tab made of a technical fabric layer and one end of which is applied to a portion of the inner reinforcement substantially parallel to the first inner wall of the corner profile and the other end to the portion of the inner reinforcement. substantially parallel to the second inner wall of the corner profile. The loop is shaped in such a way that in the projection to a plane perpendicular to the walls of the corner profile, it is in the form of a loop which, with its part, is oriented towards the outer reinforcement and crosses itself substantially on the outer edge and inner edges of the corner profile when this cross-over of the loop tab creates a reinforcing cross-over of the technical fabric.

In another preferred embodiment, the reinforcing element comprises a molded part made of technical fabric, which is positioned and shaped such that it is crossed twice in projection to a plane perpendicular to the walls of the corner profile, the two intersections of the molded part substantially lying on the outer and inner junction. the edge of the corner profile, and that from crossing the shaped part closer to the inner edge of the corner profile creates a reinforcing crossover of the technical fabric. Between its two intersections, the shaped part is projected in a plane perpendicular to the walls of the corner profile in the form of a loop when the inner reinforcement section is over this shaped part,

Which is substantially parallel to the first inner wall, directly connected to the substantially parallel section of the outer reinforcement. Also, through this shaped part, a portion of the inner reinforcement that is substantially parallel to the second inner wall is directly connected to the substantially parallel portion of the outer reinforcement.

The reinforcing element may also comprise a pair of u-shells made of technical fabric, the first u-shank being abutted to one end of the inner reinforcement section, which is substantially parallel to the first inner wall of the corner profile, and the other end to the outer reinforcement section. which is substantially parallel to the first outer wall of the corner profile. The second clamp is applied at one end to a portion of the inner reinforcement substantially parallel to the second inner wall of the corner profile and to its other end a portion of the outer reinforcement substantially parallel to the second outer wall of the corner profile. In the projection in a plane perpendicular to the walls of the corner profile, these U-shims form a loop shape, and the crossing of the loop facing the inner edge of the corner profile forms a reinforcing crossover of the technical textiles.

Advantageously, the reinforced concrete corner profile also comprises a corner sheath made of a technical fabric layer that substantially conforms to the outer corner of the corner profile.

Also preferred is an embodiment in which at least one of the technical fabrics used is saturated with a polymer matrix.

Clarification of drawings

Examples of forming textile reinforcements in the corner region of a reinforced concrete corner profile are shown in the accompanying drawings. 1 to 9 show three views of a particular embodiment of a corner profile, indicated by letters a), b), c).

In Figures a) there is a schematic representation of the corner region of the concrete layer 1 in projection to a plane perpendicular to the main surfaces of the concrete layer 1.

In Figures b) there is a 3D model of a corner region showing one row of longitudinal bars of technical fabrics and with indications of transverse bars of technical fabrics.

In Figures c), the longitudinal bars model of technical textiles is shown without designating the cross bars and the mass of the concrete.

FIG. 1 shows an embodiment with a first type of forming of the technical textile extension sections 3.1, 3.2.

FIG. 2 shows an embodiment similar to that of FIG. 1 except that a corner flange 5 is used.

FIG. 3 shows an embodiment with another type of shaping of the technical textile extension sections 3.1, 3.2.

Figure 4 shows an embodiment with a pair of curved shims 8.1, 8.2.

FIG. 5 shows an embodiment with another type of shaping of the technical textile extension sections 3.1, 3.2.

FIG. 6 shows an embodiment of yet another type of forming of the technical textile extension sections 3.1, 3.2.

-4GB 33210 U1

FIG. 7 shows an embodiment with a loop tab 11.

FIG. 8 shows an embodiment with a shaped part 12.

Fig. 9 shows an embodiment with a pair of u-shims 13.1. 13.2.

Fig. 10 shows a larger whole in 3D view of a part of the reinforced concrete corner profile, it is an embodiment according to Fig. 8.

Examples of technical solutions

The reinforced concrete corner profile comprises concrete 1 and at least two reinforcements 2, 3 formed by a layer of technical fabric placed in the concrete 7. The corner profile consists of two arms in the form of reinforced concrete slabs 1 and a common corner area of reinforced concrete 1 in which the arms join. In the figures, the right angle of the legs of the corner profile is always given, but shapes with sharp or obtuse angles are also possible. The corner profile has two inner walls a, b that meet on the inner edge c of the corner profile, and two outer walls d, e that meet on the outer edge f of the corner profile, the first inner wall a being substantially parallel to the first outer wall The corner profile arrangement is further such that there is a plane that is substantially perpendicular to the first inner wall a and the second inner wall b. The inner reinforcement 3 is located closer to the inner wall b and the second inner wall b is substantially parallel to the second outer wall e. the walls a, b of the corner profile than the outer reinforcement 2 and the inner reinforcement 3 are simultaneously positioned such that it extends inside the concrete 1 along at least a portion of the first inner wall and the corner profile with which it is substantially parallel; a portion of the second inner wall b of the corner profile with which it is substantially parallel on. Similarly, the outer reinforcement 2 is positioned such that it extends within the concrete 1 along at least a portion of the first outer wall d of the corner profile with which it is substantially parallel and that it also extends inside the concrete 1 along at least a portion of the second outer wall e of the corner profile with essentially parallel.

The rounding 4 of the outer reinforcement 2 or the rounding of the corner shim 5 is not a necessary feature of the solution, it is important that the outer reinforcement 2 or corner shim 5 approximately copies the outer corner of the corner profile, which can be realized with sharp edges of outer reinforcement 2 or corner shim 5.

The term " substantially " throughout this application is intended to be within the normal manufacturing tolerances.

Since the crossing of some shaped elements, shims, reinforcements, technical textile elements, etc. is seen in projection to a plane perpendicular to the main walls of the concrete layer, it is meant that it would be visible when projected through the concrete.

The most important feature of the present invention is that inside the concrete 1 there is a reinforcement element 100 of technical fabric for reinforcing the corner of the corner profile, the technical fabric of the reinforcement element 100 is positioned and shaped to include a reinforcement crossover g of the technical fabric or a fabric which is projected in a plane perpendicular to the corners a, b, d, e of the corner profile substantially positioned at the junction of the inner edge c of the corner profile and the outer edge f of the corner profile.

Thanks to this feature, it is possible to achieve sufficient load-bearing capacity even in the case of very thin concrete layers 1 compared to traditional concrete structures.

The technical solution exhibiting this main feature can be realized in various ways, some of which are described in the following exemplary embodiments.

-5 CZ 33210 U1

Figures 1 to 6 show embodiments in which the reinforcing element 100 comprises a first technical fabric extension section 3.1 and a second technical fabric extension section 3.2, when the first technical fabric extension section 3.1 is connected to a portion of the inner reinforcement 3 that is substantially parallel to the first inner wall a of the corner profile, and when the second lengthening section of the technical fabric 3.2 connects to a portion of the inner reinforcement 3 which is substantially parallel to the second inner wall b of the corner profile. The reinforcing cross-over g of the technical textiles is here formed by the cross-over of the first technical fabric extension section 3.1 and the second technical fabric extension section 3.2.

In the embodiment of Fig. 1, the technical fabric extension sections 3.1, 3.2 are positioned and shaped such that in the projection perpendicular to the corners a, b, d, e of the corner profile, the first technical fabric extension section 3.1 is straight and perpendicular to the second outer wall e of the corner profile, and likewise, the second technical fabric extension section 3.2 is straight in the projection perpendicular to the corner profile walls a, b, d, e and is oriented perpendicular to the first outer wall d of the corner profile. This example solution is suitable for elements with a greater thickness or weaker reinforced elements with a lower load-bearing capacity due to the small anchoring length of the extension sections 3.1, 3.2 of technical textiles.

In Fig. 2, the embodiment is similar to that of Fig. 1, where the outer reinforcement 2 is interrupted in a region close to the outer edge f of the corner profile and a corner spacer 5 is attached thereto. higher thickness, possibly weaker reinforced elements with lower load-bearing capacity due to small anchoring length of extension sections 3.1, 3.2 of technical textiles.

Fig. 3 shows an embodiment in which the technical fabric extension sections 3.1, 3.2 are positioned and shaped such that, in projection to a plane perpendicular to the walls a, b, d, e of the corner profile, they have between the reinforcement crossing g of technical fabrics and the outer reinforcement 2. the ends bent apart and pointing towards the outer reinforcement 2. The example solution is suitable for kinking the corner profile with obtuse angles, ie on the inside there is an angle of 90 to 180 °.

Fig. 4 is an embodiment in which the reinforcing element also comprises a pair of curved inserts 8.1, 8.2, which are made of a layer of technical fabric and which are positioned and shaped so as to project in a plane perpendicular to the walls a, b, d, The corner profile crosses one another. The first curved shim 8.1 is connected with its first end to the first technical fabric extension section 3.1 and the second curved shim 8.2 is connected with its first end to the second technical fabric extension section 3.2. The other ends of the bent inserts 8.1, 8.2 are directed from the intersection of the bent inserts 8.1, 8.2 to the outer reinforcement 2 and are bent apart. This example solution is also suitable for an element with the required higher load-bearing capacity due to the greater anchoring length of the extension sections 3.1, 3.2. An example solution is suitable for corner angle with blunt angles, ie on the inside there is an angle of 90 to 180 °.

Fig. 5 shows an embodiment in which the technical fabric extension sections 3.1, 3.2 are positioned and shaped such that they have a projection in a plane perpendicular to the walls a, b, d, e of the corner profile between the reinforcement crossing g of the technical fabrics and the outer reinforcement 2. the non-closed part of the loop is facing the outer reinforcement 2 and oriented towards the outer edge f of the corner profile. The example solution is suitable for elements with lower required load-bearing capacity due to shorter anchorage length of extension sections 3.1, 3.2 of technical textiles.

Fig. 6 shows an embodiment in which the technical fabric extension sections 3.1, 3.2 are positioned and shaped such that the projection of the technical fabric extension sections 3.1, 3.2 in a plane perpendicular to the walls a, b, d, e of the corner profile includes between reinforcing crossings g of technical textiles and external reinforcement 2 the shape of a closed loop with its arch part oriented towards the external reinforcement 2. The example solution is suitable for elements with the required higher load-bearing capacity due to the possible large anchorage length of the extension textiles 3.1, 3.2.

-6GB 33210 U1

In Fig. 7 there is an embodiment in which the stiffening element comprises a loop tab 11, which is made of a technical fabric layer and one end of which is applied to a portion of the inner reinforcement 3 substantially parallel to the first inner wall and corner profile and its other end. applied to a portion of the inner reinforcement 3 substantially parallel to the second inner wall b of the corner profile. The loop 11 is shaped so as to project in a plane perpendicular to the walls a, b, d, e of the corner profile in the form of a loop which, with its arc, is oriented towards the external reinforcement 2 and intersects itself substantially at the junction of the outer edge f and the inner edge c of the corner profile when this cross-over of the loop tab 11 forms a reinforcing cross-over g of the technical fabric. An example solution is suitable for elements with the required higher load-bearing capacity due to the possible large anchoring length of the loop-shaped spacer 11.

Fig. 8 is an embodiment in which the stiffening element comprises a molded part 12 made of technical fabric, which is positioned and shaped so as to project twice perpendicularly to the plane perpendicular to the walls a, b, d, e of the corner profile, this cross-over of the shaped part 12 lies substantially at the junction of the outer edge f of the corner profile and the inner edge c of the corner profile, and this cross-over of the shaped part 12 closer to the inner edge c of the corner profile creates a reinforcing cross over g. Between its two intersections, the shaped part 12 is projected in a plane perpendicular to the walls a, b, d, e of the corner profile in the form of a loop. Through this shaped component 12, a portion of the inner reinforcement 3, which is substantially parallel to the first inner wall and is directly connected thereto with a substantially parallel portion of the outer reinforcement 2 and also through this shaped component 12 is a portion of the inner reinforcement 3 which is substantially parallel with a second inner wall b, directly connected to the substantially parallel section of the external reinforcement 2. This is a very load-bearing and technologically easy-to-carry example solution suitable for all the angles of the reinforced concrete corner profile.

In the embodiment of Fig. 9, the reinforcing element 100 comprises a pair of u-shims 13.1, 13.2 made of technical fabric, the first u-sheath 13.1 being abutted at one end to a portion of the inner reinforcement 3 that is substantially parallel to the first inner wall and corner and the other end of the outer reinforcement portion 2, which is substantially parallel to the first outer wall d of the corner profile, and the second u-shank 13.2 is abutted at one end to the inner reinforcement portion 3 substantially parallel to the second inner wall b of the corner profile, and with its other end to a portion of the outer reinforcement 2, which is substantially parallel to the second outer wall e of the corner profile. In a projection to a plane perpendicular to the corners a, b, d, e of the corner profile, these u-shims 13.1, 13.2 form a loop shape and the crossing of this loop facing the inner edge c of the corner profile forms a reinforcing crossing g of technical textiles. This example solution is suitable for elements with the required high load-bearing capacity, is technologically easy to implement and is suitable for all angles of break of concrete layer 1.

In Fig. 10, for illustration, one of the above embodiments is shown in a 3D view on a larger section of both slabs forming a slab concrete member. The concrete is shown transparently for clarity. This is an embodiment corresponding to the embodiment of FIG. 8, but all other exemplary embodiments could be shown in 3D in a similar manner.

In some embodiments illustrated in the above figures, it will be appreciated that the reinforced concrete corner profile also includes a first shim 5 made of a technical fabric layer that substantially conforms to the outer corner of the corner profile.

It may be advantageous if at least one of the technical fabrics used is saturated with the polymer matrix in order to ensure a good concreting during pouring or spraying of the concrete, in order to ensure the desired shape of the reinforcement. matrix of the cement composite. A variant of the reinforcement without polymer matrix saturation is also possible by providing the required position of the reinforcement by means of shaped spacers. The interaction of the textile reinforcement with the cement matrix is then ensured by penetration of the cement composite particles into the individual fiber bundles - by their concrete embedding.

-7 GB 33210 U1

The shaping of the textile reinforcement with polymer matrix saturation is possible by means of a template during the polymer matrix curing process. Furthermore, when using a thermoplastic polymer matrix, the reinforcement can be additionally heated for the purpose of shaping and then shaped according to a template to the desired shape.

The present solution thus achieves the absence of the need for additional external attachments and other connecting profiles, it is not necessary to change the size of the cross-section at the point of the kink (thickness change), or to split the kinks into several pieces and to connect them together. The solution thus allows for the creation of an aesthetically clean kink of the concrete slab, which is able to carry significantly higher loads than the element without reinforcement, without local shaping of the reinforcement of technical fabric and without attachments.

Industrial applicability

The technical solution can be used for general subtle concrete slab elements with one or more angles of blunt, right and blunt with special shaping of textile reinforcement. The bend reinforcement solution without external joints is suitable for a variety of concrete elements used in construction, industry or small architectural elements. For example, benches, molded tables, molded elements for permanent shuttering and other various supporting structures, molded facade panels with folds, profiled ceiling structures, bridge footbridges, railings and railings. It can be a load-bearing and non-load-bearing structure depending on the function of the element, dimension and amount of required reinforcement, where the present reinforcement shaping can be used.

PROTECTION REQUIREMENTS

Claims (13)

A reinforced concrete corner profile comprising concrete (1) and at least two reinforcements (2, 3) formed by a layer of technical fabric placed in concrete (1), said corner profile consisting of two arms in the form of reinforced concrete slabs (1) and common a corner area of reinforced concrete (1) in which the arms are joined, the corner profile having two inner walls (a, b) that meet at the inner edge (c) of the corner profile and two outer walls (d, e) which meet at the outer edge (f) of the corner profile, the first inner wall (a) being substantially parallel to the first outer wall (d) and the second inner wall (b) being substantially parallel to the second outer wall (e), and furthermore, the arrangement of the corner profile is such that there is a plane substantially perpendicular to the first inner wall (a) and the second inner wall (b) when the inner reinforcement (3) is located closer to the inner walls (a b) a corner profile than the outer reinforcement (2), and the inner reinforcement (3) is simultaneously positioned such that it extends inside the concrete (1) along at least a portion of the first inner wall (a) of the corner profile with which it is substantially parallel; also extends inside the concrete (1) along at least a portion of the second inner wall (b) of the corner profile with which it is substantially parallel, and likewise the outer reinforcement (2) is positioned such that it passes along at least a portion of the first outer wall ( d) a corner profile with which it is substantially parallel and that it also extends inside the concrete (1) along at least a portion of the second outer wall (e) of the corner profile with which it is substantially parallel, characterized in that inside the concrete (1) a reinforcing element (100) of technical fabric for reinforcing the corner of the corner profile is provided, wherein the technical fabric of the reinforcing element (100) is positioned 33210 U1 and shaped to include a reinforcing intersection (g) of the technical fabric or fabrics which, in projection, in a plane perpendicular to the corner profile walls (a, b, d, e), is positioned substantially on the inner edge junction (c) the corner profile and the outer edge (f) of the corner profile. Reinforced concrete corner profile according to claim 1, characterized in that the reinforcing element (100) comprises a first technical fabric extension section (3.1) and a second technical fabric extension section (3.2) when the first technical fabric extension section (3.1) is connected to a portion of the inner reinforcement (3) which is substantially parallel to the first inner wall (a) of the corner profile, and when the second technical fabric extension section (3.2) adjoins the portion of the inner reinforcement (3) substantially parallel to the second inner wall (b) a corner profile, wherein the reinforcing cross (g) of the technical fabrics is formed by crossing the first technical fabric extension section (3.1) and the second technical fabric extension section (3.2). Reinforced concrete corner profile according to Claim 2, characterized in that the technical textile extension sections (3.1, 3.2) are positioned and shaped such that the first extension is the projection perpendicular to the corner profile walls (a, b, d, e). the technical fabric section (3.1) is straight and oriented perpendicular to the second outer wall (e) of the corner profile, and likewise the second technical fabric extension section (3.2) is straight in projection perpendicular to the corner profile walls (a, b, d, e); is oriented perpendicular to the first outer wall (d) of the corner profile. Reinforced concrete corner profile according to claim 2, characterized in that the technical textile extension sections (3.1, 3.2) are positioned and shaped such that they have a projection in a plane perpendicular to the walls (a, b, d, e) of the corner profile. between the reinforcing cross (g) of the technical textiles and the outer reinforcement (2), the ends bent apart and facing the outer reinforcement (2). Reinforced concrete corner profile according to claim 3, characterized in that the reinforcing element (100) also comprises a pair of curved shims (8.1, 8.2) which are made of a technical fabric layer and which are positioned and shaped so as to project in projection. a plane perpendicular to the walls (a, b, d, e) of the corner profile cross each other when the first curved bar (8.1) is connected at its first end to the first technical fabric extension section (3.1) and the second curved bar (8.2) is its first the second ends of the bent tabs (8.1, 8.2) extend from the intersection of the bent tabs (8.1, 8.2) to the outer reinforcement (2) and are bent apart. Reinforced concrete corner profile according to claim 2, characterized in that the technical textile extension sections (3.1, 3.2) are positioned and shaped such that they have a projection in a plane perpendicular to the walls (a, b, d, e) of the corner profile. between the reinforcing cross (g) of the technical textiles and the outer reinforcement (2), the ends twisted together in the form of an open loop, the open portion 33210 U1 of the loop is facing the outer reinforcement (2) and oriented towards the outer edge (f) of the corner profile. Reinforced concrete corner profile according to Claim 2, characterized in that the technical textile extension sections (3.1, 3.2) are positioned and shaped such that the projection of the technical textile extension sections (3.1, 3.2) in a plane perpendicular to the walls (a, b, d, e) the corner profile comprises, between the reinforcing cross-over (g) of the technical textiles and the outer reinforcement (2), a closed loop shape, which is partially arched towards the outer reinforcement (2). Reinforced concrete corner profile according to claim 1, characterized in that the reinforcing element (100) comprises a loop-like shim (11) which is made of a technical fabric layer and which is attached at one end to a portion of the inner reinforcement (3). substantially parallel to the first inner wall (a) of the corner profile and with the other end thereof adjacent to a portion of the inner reinforcement (3) substantially parallel to the second inner wall (b) of the corner profile, the loop closure (11) being shaped to have in a projection to a plane perpendicular to the walls (a, b, d, e) of the corner profile, the shape of a loop which, with its arc, is oriented towards the outer reinforcement (2) and crosses itself substantially on the outer edge (f) the inner edges (c) of the corner profile when this crossing of the loop tab (11) creates a reinforcing crossing (g) of the technical fabric. Reinforced concrete corner profile according to claim 1, characterized in that the reinforcement element (100) comprises a molded part (12) made of technical fabric, which is positioned and shaped so as to project in a plane perpendicular to the walls (a, b, d, e) the corner profile is crossed twice, the two crossings of the shaped part (12) lying substantially on the connection of the outer edge (f) of the corner profile and the inner edge (c) of the corner profile, which is closer to the inner edge (c) of the corner profile, forms a reinforcing cross (g) of the technical fabric and wherein, between its two crossings, the shaped part (12) has a projection in a plane perpendicular to the walls (a, b, d, e) of the corner profile a loop shape when a portion of the inner reinforcement (3), which is substantially parallel to the first inner wall (a), is directly connected to this shaped part (12) directly to the a substantially parallel section of the outer reinforcement (2) therewith and also through this shaped part (12) a section of the inner reinforcement (3) which is substantially parallel to the second inner wall (b) is directly connected to the substantially parallel section external reinforcement (2). Reinforced concrete corner profile according to claim 1 or 2, characterized in that the reinforcing element (100) comprises a pair of u-shims (13.1, 13.2) made of technical fabric, the first u-shank (13.1) being applied at one end thereof a portion of the inner reinforcement (3) substantially parallel to the first inner wall (a) of the corner profile and a second end of the portion of the outer reinforcement (2) substantially parallel to the first outer wall (d) of the corner profile, and a second the u-shim (13.2) is attached to its inner end with one end - 332GB U1 of a reinforcement (3) which is substantially parallel to the second inner wall (b) of the corner profile and with its other end to a portion of the outer reinforcement (2) which is substantially parallel to the second outer wall (e) of the corner profile when, in projection to a plane perpendicular to the corner profile walls (a, b, d, e), these u-flaps (13.1, 13.2) form a loop shape and the crossing of this loop facing 5 to the inner edge (c) of the corner profile forms a reinforcing crossing (g) technical textiles. Reinforced concrete corner profile according to any one of claims 1 to 10, characterized in that it also comprises a corner shim (5) made of a technical fabric layer, which by its shape essentially follows the outer corner of the corner profile. Reinforced concrete corner profile according to any one of claims 1 to 11, characterized in that at least one of the technical textiles used is saturated with a polymer matrix. 10 drawings - 11 GB 33210 U1 List of reference marks: 1 - concrete 2 - external reinforcement 3 - internal reinforcement 3.1 - the first extension of the technical fabric 3.2 - second extension of the technical fabric 4 - fillet (external reinforcement 2) 5 - corner bracket (rounded) 8.1 - first curved shim 8.2 - second curved shim 11 - loop wedge (which crosses itself and has the shape of a loop) 12 - shaped part (for connection of inner reinforcement 3 with outer reinforcement 2) 13.1 - first u-clamp (for connection of inner reinforcement 3 with outer reinforcement 2) 13.1 - second u-clamp (for connection of inner reinforcement 3 with outer reinforcement 2) 100 - reinforcing element a - first inner wall (corner profile) b - second inner wall (corner profile) c - inner edge of corner profile d - first outer wall (corner profile) e - second outer wall (corner profile) f - outer corner profile edge g - reinforcing the intersection of technical or technical textiles.