CZ2008475A3 - Non-metallic building reinforcement intended particularly for prestressed building structures and process of treating thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a non-metallic structural reinforcement, particularly for prestressed building structures, comprising an anchoring body which is formed by at least one roller (2) which is a thermoset polymer and / or a thermosetting polymer matrix with fiber and / or fillers. The invention also relates to a method for treating non-metallic building reinforcement, in particular for prestressed building structures, in which an anchor body is formed on the reinforcement. A single-base mold (3), through which the reinforcement (1) passes, is inserted into the reinforcement, and a polymer or polymeric matrix with fiber and / or fillers is filled into the mold (3) with the open side (5) leaving the filler in the mold the mold is removed and the upper part (6) of the roller (2) is removed and the newly formed surface of the roller (2) is removed and the newly formed roll surface (2) is ground.

Description

Non-metallic building reinforcement, in particular for prestressed building structures, and method of its treatment

Technical field

The invention relates to non-metallic building reinforcement, in particular for prestressed building structures, which comprises an anchor body.

The invention also relates to a method of treating non-metallic building reinforcement, in particular for prestressed building structures, in which an anchor body is formed on the reinforcement.

BACKGROUND OF THE INVENTION

For FRP building reinforcements, which are non-metallic reinforcements based on epoxy resin-bonded glass, basalt, carbon or other non-metallic fibers, it is necessary to create a place to transfer the prestressing to the concrete structure or to increase the natural cohesion of the reinforcement with concrete. Due to the low compressive strength of FRP reinforcement, it is not possible to use the classical method of anchoring the reinforcement by means of anchor sleeves and tapered cones without modification. Such modifications of conventional anchoring methods are known in the art.

US 2004250497 discloses a composite anchor joint and method for providing an additional anchoring method in which a special insert is used in which the anchor itself is inserted. The disadvantage is the need to use a special insert and drill holes, which is also a significant restriction of use in concrete structures.

An anchoring system for prestressed or loaded members is known from WO 165023, in which anchoring bodies with anchoring cones with a modified longitudinal profile and a toothed surface for the gradual distribution of compressive and tensile forces. The anchor plugs are located at the ends of the non-metallic reinforcement and are embedded in the cylindrical body. The disadvantage is the relatively complicated design and the need to create a specially treated cone surface.

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PS358 & Z

It is known from WO 0037749 to provide an anchor end of a carbon composite rope in which the rope is unraveled at its end into a central and a plurality of circumferential portions, an annular separating body being threaded onto the central portion. The conical end of the rope thus formed is placed in a mold and cast with a suitable mass. The anchoring end of the rope is thus formed with the mold. The disadvantage is the need to untangle the rope, which could damage it and also the possibility of performing this treatment only at the end of the rope.

An anchorage system is known from JP 11324228, in which a group of non-metallic reinforcements anchored in a common body are placed in a cone with a modified inner surface to avoid a large increase in the force applied to the reinforcement. The disadvantage is that it can only be used at the ends of the reinforcement.

WO 9529308 discloses an anchoring system with a gradual increase in shear and compression forces in the anchoring region, which is achieved by varying the rigidity of the anchoring cone located on the composite reinforcement cable. The disadvantage is the difficulty in achieving variable stiffness of the anchor cone, in particular the correct positioning and homogeneity of the materials with different stiffness.

JP 5118100 discloses anchoring by means of a non-metallic riser on a reinforcing rope, wherein the riser has a conical front surface and is housed in a metal sleeve with thread and nut for proper anchoring and tensioning.

An anchorage system is known from JP 1163344 (EP 314 927), in which a specially shaped synthetic resin end is provided with a serration on the outer periphery for attachment to the prestressing device, the rope is prestressed and the gap between the terminal and the body is formed. anchored, poured with additional mass.

It is known from DE 3640549 to anchor non-metallic reinforcements in which a body or boss of larger diameter than the anchored reinforcement is formed at the end of the non-metallic reinforcement, the end portion of the anchored reinforcement being cast into the die and secured with a ring. A disadvantage of this embodiment is its considerable complexity for forming the anchor.

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PS358 & Z

It is an object of the invention to overcome or at least minimize the disadvantages of the prior art.

SUMMARY OF THE INVENTION

The object of the invention is achieved by a non-metallic building reinforcement, in particular for prestressed building structures, which comprises an anchoring body, characterized in that the anchoring body is formed by at least one roller comprising a thermoset polymer and / or thermoset polymer matrix with fiber admixture and / or fillers.

The solution according to the invention is simple to carry out, both in production preparation and on site as required. It is also advantageous that the solution according to the invention not only allows the endings of FRP reinforcement to be anchored, but it is also possible to join FRP reinforcements into longer units. In particular, the FRP reinforcement joints made according to the invention need not even be embedded in the concrete body, but may also be situated outside the concrete body, for example with loose FRP cables drawn outside the structure.

The object of the invention is also achieved by a method of treatment of non-metallic building reinforcement, in particular for prestressed building structures, which consists in placing a one-floor mold through which the reinforcement passes and then infuses the polymer or polymer matrix with admixture The filler is allowed to cure in the mold, the mold is removed and the top of the roll is removed and the newly formed face of the roll is ground.

Preferred embodiments of the invention are the subject of the dependent claims and are described in more detail in the examples.

Overview of the drawings

The invention is schematically illustrated in the drawing, wherein FIG. 1 shows the formation of a single anchor roller on the reinforcement, FIG. 2 shows a series of 3 anchor rollers on the reinforcement, FIG.

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DETAILED DESCRIPTION OF THE INVENTION

The invention is used both for anchoring non-metallic building reinforcement 1, eg FRP reinforcement, as well as for joining the ends of reinforcement 1 in case of need of reinforcement 1.

The actual treatment of the reinforcement 1 consists in that one or more rollers 2 of larger diameter are formed on the reinforcement 1, the roller 2 or rollers 2 being formed of a thermoset polymer or a thermoset polymer matrix with admixtures of fibers and / or other fillers. Exemplary thermosetting polymer is epoxy resin, polyester resin, vinyl ester resin, acrylate resin, phenolic resin, polyurethane resin, etc., including mixtures and modifications thereof. Exemplary primer fibers for the thermoset polymer matrix are glass, basalt and carbon fibers. Exemplary other fillers for the thermoset polymer matrix are cement, quartz sand, finely ground limestone, barite, corundum, basalt, etc. When using a thermoset polymer matrix with admixture of fibers and / or other fillers, dosing of 5 to 300 parts by weight of filler is preferred. per 100 parts by weight of polymer matrix (optimally 80 to 150 parts by weight of filler per 100 parts by weight of polymer matrix) or dosing 1 to 100 parts by weight of fibers per 100 parts by weight of polymer matrix (optimally 5 to 50 parts by weight of fibers per 100 parts by weight of polymer matrix) . Advantageous synergistic properties can then be obtained by the simultaneous use of both fibers and filler in the polymer matrix, since the fillers increase the compressive strength and modulus and the fibers increase the tensile and flexural modulus and also reduce the creep.

The rollers 2 are formed as shown in Fig. 4 by means of a mold 3, eg a longitudinally divided cylindrical mold with one bottom 4, which is provided with an opening for the passage of reinforcement 1. The mold 3 is put on the reinforcement 1 and In the interior space, one or more of said polymers or polymer matrices with an admixture of fibers and / or fillers are poured, injected or pressed, and the material of the roller 2 is allowed to cure in the mold. The mold 3 can be without heating or heated as needed, which shortens the curing times of the material of the rollers 2 to be formed. To improve the technology, the use of «* • ·· • ·· is advantageous.

VS3583CZ of mold 3 with an anti-adhesive surface, such as teflon, polyolefin plastics, etc., which facilitates removal of mold 3 after curing of the formed roller 2 and reduces the likelihood of damage to mold 3, making it impossible to reuse it. After the material of the roller 2 in the mold 3 has cured, the mold 3 is removed. If necessary, the upper part 6 of the material of the roller 2, i.e. in the region of the open side 5 of the mold 3 through which the mold 3 was filled with material, is removed in a length of about 20 mm. homogeneous especially due to trapped air bubbles. By selecting the chemical composition of the rollers, the need to remove the upper end of the roll can be minimized or eliminated completely. The end face of the roller 2 at its upper end is aligned, e.g., ground, perpendicular to the longitudinal axis of the roller 2 and the reinforcement 1. The roller 2 thus formed on the FRP reinforcement 1 can be used for anchoring the prestressed FRP reinforcement 1 in a concrete structure. For post-tensioned FRP reinforcement, if the anchorage system is located outside the concrete, 1 it is necessary to protect the roller 2 against longitudinal tear.

In the embodiment of FIG. 1, there is shown a FRP reinforcement 1 provided with an anchor roller 2 constructed according to the invention near its end.

In the embodiment shown in FIG. 2, there is shown a FRP reinforcement 1 provided near its end with a triple (generally any selected number) of anchor rollers 2 constructed according to the invention.

In the exemplary embodiment of FIG. 3, the ends of two FRP reinforcements 1 are connected by an anchor roller 2 constructed according to the invention.

In the embodiments of Figs. 1 to 3, the lengths of the individual rollers 2 as well as their possible spacing between them are determined based on the material characteristics of the FRP reinforcement material 1, the roller material 2, the material to which the reinforcement 1 and the rollers 2 are to be anchored. .

In the case of the need for additional reinforcement of the roller 2, according to one embodiment, a single-purpose non-metallic mold 3 can be used to form the roller 2, eg a plastic tube or FRP tube which is left on the roller 2 even after the roller 2 has cured. 2, after removal of the mold, additionally wrap with a fabric of FRP material that remains on the roller 2 even after it has been cast into the concrete structure. According to another? "- w τ> v · V · 4 · f · H 444" · 4 4 4 4 444 · · 4 44414444 * "PS3583EN" a pipe, preferably thick-walled, with transverse holes to create a dowel effect and to improve the coherence of the pipe with concrete, the pipe being left on the roller 2 even after the roller 2 has cured. However, the use of a steel pipe is less advantageous considered a negative effect.

Claims (10)

PATENT CLAIMS Non-metallic building reinforcement, in particular for prestressed building structures, comprising an anchoring body, characterized in that the anchoring body is formed by at least one roller (2) consisting of a thermoset polymer and / or a thermoset polymer matrix with admixture of fibers and / or fillers. The non-metallic building reinforcement according to claim 1, characterized in that the thermosetting polymer is an epoxy resin or a polyester resin or a vinyl ester resin or an acrylic resin or a phenolic resin or a polyurethane resin or a resin mixture or a resin modification. Non-metallic building reinforcement according to claim 1 or 2, characterized in that the admixed fibers are glass fibers and / or basalt and / or carbon fibers. Non-metallic building reinforcement according to claim 1 or 2, characterized in that the fillers for the thermosetting polymer matrix are cement and / or quartz sand and / or finely ground limestone and / or barite and / or corundum and / or basalt. Non-metallic building reinforcement according to any one of claims 1 to 4, characterized in that the roller (2) is a thermosetting polymer matrix with a filler in a dosage of 5 to 300 parts by weight of filler per 100 parts by weight of polymer matrix. 6. The non-metallic building reinforcement according to claim 5, wherein the filler dosage is 80 to 150 parts by weight of filler per 100 parts by weight of polymer matrix. Non-metallic building reinforcement according to any one of claims 1 to 4, characterized in that the roller (2) is a thermosetting polymer matrix with admixed fibers at a dosage of 1 to 100 parts by weight of fibers per 100 parts by weight of polymer matrix. * * ·· • ·· 4 4 44 444 44 4 • ♦ 4 4 4 4 4444 ..... PŠ3583CZ ” 8. The non-metallic building reinforcement according to claim 7, wherein the fiber dosing is 5 to 50 parts by weight of fibers per 100 parts by weight of polymer matrix. 9. Method of treatment of non-metallic building reinforcement, especially for prestressing 5 a building structure in which an anchoring body is formed on the reinforcement, characterized in that a mold (3) with one bottom is inserted on the reinforcement, through which the reinforcement (1) passes, and then filled with the open side (5) into the mold (3) a polymer or polymer matrix with an admixture of fibers and / or fillers, after which the filling is allowed to cure in the mold, the mold is removed and the end face of the roller (2) is aligned. Method according to claim 10, characterized in that the mold (3) is heated during curing of the roller (2).