KR100382300B1 - A fireproof reinforcement method by burying steel strand - Google Patents

Abstract

The present invention relates to a fireproof reinforcement method by embedding a strand wire, and in reinforcing a reinforced concrete structure, a groove digging step of digging the strand wire groove 12 and the anchorage groove 14 by cutting the coated concrete at both ends of the member to be reinforced. a), a fixing unit installation step (b) of fixing the fixing unit 20 to the anchor bolt 30 and the anchor nut 32 in the fixing unit groove 14, and the polymer mortar 38 in the strand wire groove 12. The step of filling the polymer mortar filling (c) and the wire strand tightness step of tightening both ends while wiring the strand wire 36 to the strand wire groove 12, and then fastened to the anchorage 20 by a fastening cone 34. (d) filling the polymer mortar 38 in the strand wire groove 12 and the fixing groove groove 14 in which the strand wire 36 and the fixing hole 20 are installed and curing the polymer mortar finishing step (e). Because of the strong adhesion of the polymer mortar 38, high strength and adhesion with the strand 36 It is better to increase the reinforcing function of the tensile stress, of course, it is possible to increase the fire resistance sufficient reinforcing function.

Description

Fireproof reinforcement method by burying steel strand

The present invention relates to a fire-resistant reinforcement method by embedding a stranded wire to reinforce the strength of the reinforced concrete member, and more particularly, by inserting the stranded wire and tension-tightening both ends thereof, and then filling the polymer mortar to finish the adhesive force of the polymer mortar, It relates to a fire-resistant reinforcement method by embedding a stranded wire that can be effectively reinforced while being integrated with a reinforced concrete member by high tensile stress generated due to high strength and strong adhesion to the stranded wire.

In general, the beam or slab of reinforced concrete structures are flexural deformation due to continuous loads, so the cracks are generated due to the compressive stress at the top and the tensile stress at the bottom. Therefore, the strength of the structure should be reinforced after a certain period of time after construction. .

Such a reinforcement method includes a steel plate reinforcing method for wrapping a portion to be reinforced of a reinforced concrete member with an iron plate and injecting epoxy resin into the space between the iron plate and the member, and applying an epoxy resin to a portion to be reinforced and carbon fiber and The fiber reinforcing method of attaching and reinforcing the same reinforcing fibers has been mainly used.

By the way, the reinforcement method using the epoxy resin as described above is based on the integration of the epoxy member with the concrete member by the adhesion of the epoxy resin, but the epoxy resin is vulnerable to heat and the molecule starts to break at around 80 ℃, 130 ℃ Since it starts to liquefy at low fire resistance is not good safety, in particular, in the event of a fire, there is a problem in that the loss of adhesion to the concrete member completely loses the reinforcing function.

In order to solve this problem, as shown in Figure 5 to install a stainless steel wire mesh 102 on the beam or slab of the concrete structure to fix the anchor pin 106 to the binding unit 104, and then plastered with polymer mortar Stainless steel wire mesh reinforcement 100 has been proposed, but when the stainless steel wire mesh 102 is attached, it is not tensioned enough to provide sufficient reinforcement for tensile stress, and after buying carbon rods or carbon fiber meshes In the case of the finishing method of plastering with polymer mortar, there is a shortcoming that the both ends are not shortened, and thus, sufficient reinforcing effect is not obtained, and there is a disadvantage that there is no fire resistance.

The present invention was developed to solve these problems, by inserting a stranded wire in the site to be reinforced of the reinforced concrete member to tighten the ends of the tension and then filling and curing the polymer mortar to the strong adhesion, high strength and The reinforcement function is improved by increasing the tensile stress due to the adhesion with the stranded wire, and the fire resistance reinforcement method is provided by embedding the stranded wire to secure sufficient reinforcement function compared with the conventional reinforcement method by epoxy resin. The purpose is.

1a to 1e is a construction step diagram for the reinforcement method according to the invention.

FIG. 2 is a cross-sectional view illustrating a cross section taken along a line A-A in FIG. 1E; FIG.

3 is a perspective view showing a state in which the strand reinforcement body is installed in the beam of the building according to the basic embodiment of the present invention.

Figure 4 is a perspective view showing a state in which the strand wire reinforcement is installed in the beam of the building according to an embodiment of the present invention.

5 is a plan view showing a state in which the stainless steel wire mesh reinforcement according to the prior art is installed in the building.

Explanation of symbols on the main parts of the drawings

10: beam 12: stranded groove

14: anchorage groove 16: bolt insertion hole

18: rebar 20: anchorage

22: bolt fitting hole 24, 52: fastening cone hole

26: central passage 28: tension support plate

30: anchor bolt 32: anchor nut

34,54: fastening cone 36: stranded wire

38: polymer mortar 40: fixing member

42: hook portion 44: bolt connection portion

50: support member 60: strand wire reinforcement

Refractory reinforcement method by embedding the strand wire of the present invention for achieving the above object, in reinforcing the reinforced concrete structure, the groove digging step of selling the strand wire groove and the anchorage groove by cutting the coated concrete at both ends of the member to be reinforced, and A fixture installation step of fixing the anchorage in the anchorage groove with anchor bolts and anchor nuts, and a polymer mortar filling step of filling the polymer mortar in the strand wire grooves; The wire tightening step of fastening by the fastening cone, and the polymer mortar filling step and curing the polymer mortar in the stranded wire groove and the anchorage groove is installed, the strand and the anchorage is characterized in that it comprises a polymer mortar finishing step.

In addition, in the groove digging step, the strand wire groove and the anchorage groove are formed to have a depth equal to the thickness of the strand to be embedded plus 30 mm, and in the fixing unit installation step, the support member and the fixing member are used instead of the anchorage to support and fix the strand wire. It is characterized by being used alternatively.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1A to 1E and 2 are cross-sectional views taken along line AA of FIG. 1E illustrating a step of constructing a fire-resistant reinforcement method of a reinforced concrete member according to the present invention, and a polymer mortar finishing step (e) finally performed during the step. 3 is a view illustrating a state in which a strand wire reinforcement 60 is installed in a beam 10 of a building according to a basic embodiment of the present invention, and FIG. 4 is a strand wire reinforcement according to an embodiment of the present invention. 60 shows the state installed in the beam 10 of the building.

As shown in the drawings, the fire-resistant reinforcement method by embedding the strand wire of the present invention by cutting the coated concrete for the reinforcing bars 18 at both ends of the reinforcement member such as the beam 10 of the reinforced concrete structure or slab (12) and a groove digging step (a) of selling the anchorage groove 14, and the anchorage installation step of fixing the anchorage 20 by the anchor bolt 30 and the anchor nut 32 in the anchorage groove 14 ( b), the polymer mortar filling step (c) for filling the polymer mortar 38 into the strand wire groove 12, and the strand wire 36 is wired to the strand wire groove 12 to tension both ends of the anchoring hole. And a wire tightening step (d) to be fastened to (20), and a polymer mortar finishing step (e) of filling the polymer mortar 38 into the strand wire groove 12 and the anchorage groove 14.

First, in the grooving step (a), as shown in FIG. 1A, V-cutting or chipping is performed by using an electric cutting tool such as a cutting disc or a hammer breaker at the installation position of the strand 36 and the fixing unit 20 of the member to be reinforced. Digging the strand wire groove 12 and the anchorage groove 14 by (chipping).

At this time, the strand wire groove 12 and the anchorage groove 14 is dug by the depth of the cover concrete, the width is preferably formed by the value of the thickness of the strand wire 36 to be added plus 30mm or more and more preferably the strand wire ( The thickness of 36) is formed by adding 30 mm, and the fixing unit grooves 14 are formed in accordance with the shape of the fixing unit 20 formed to have a narrow width from one side to the other side.

At this time, the fixing hole 20 is narrowed from the tension supporting plate 28 to the bolt fitting hole 22 side, and is formed so that the central through portion 26 penetrates in the center thereof, and the bolt fitting hole 22 has an anchor bolt 30. Is fixed and anchored by the anchor nut 32, and the tension support plate 28 is inserted into the fastening cone 34 into which the strand wire 36 is fitted into the fastening cone hole 24 of the tension support plate 28. Since the hook is formed according to the depth difference between the strand wire groove 12 and the anchorage groove 14, the tension supporting plate 28 serves to maintain the supporting force when the strand wire 36 is tensioned in the direction of the end of the member. Done.

And as shown in Figure 1b, in the fixing fixture installation step (b) after drilling the bolt insertion hole 16 with a hammer drill in the anchor bolt 30 fixing position of the anchorage groove 14 and fixed to the anchor bolt 30 is inserted , The anchorage 20 is inserted into the anchor bolt 30 and the anchor nut 32 is fastened to fix the anchorage 20 to the reinforcing member.

In this case, in order to increase the anchoring force of the anchor bolt 30 inserted into the bolt insertion hole 16, the anchor bolt 30 is inserted after the filler of the polymer cement-based filler is filled in the bolt insertion hole 16.

Next, in the polymer mortar filling step (c), as shown in FIG. 1C, the polymer mortar 38 blended at an appropriate ratio is filled into the strand wire groove 12 using an iron trowel or hera, and the polymer mortar 38 is It is formed by mixing latex or acrylic polymer with silver cement and sand, and it has high strength and excellent adhesion without drying shrinkage during construction.

In addition, the polymer mortar 38 is an inorganic cement series, and its physical properties and expansion coefficients are similar to those of concrete, making it easy to integrate with the concrete structure.

In the wiring fastening step (d), as shown in FIG. 1D, the wire is passed through the stranded wire 36 through the fastening cone holes 24 of the anchoring holes 20 installed at both ends of the beam 10, and then the stranded wire. 36 is fastened to the anchorage 20 by respective fastening cones 34 fitted to both ends thereof.

In this case, the strand wire 36 is passed through the fastening cone holes 24 in the direction of the other fixing device 20 from one fixing device 20, and the strand wire 36 is connected to the beam 10 by the fastening cones 34. After fixing to both ends of the c) by using a tensioner at both ends thereof, it is tensioned tightly while giving tensile stress to the strand 36.

Finally, as shown in FIG. 1E, in the polymer mortar finishing step (e), the polymer mortar 38 with iron trowels or hera is placed in the anchorage groove 14 and the strand wire groove 12 in which the anchorage 20 and the strand wire 36 are installed. Secondary filling and curing after finishing.

On the other hand, if the application of the strand reinforcement body 60 according to the present invention does not require high-performance long crystallization at both ends of the strand wire 36, the strand strand (b) in the anchorage installation step (b) as shown in FIG. Fastening cones 54 fitted to both ends of the strand 36 are fastened to the fixing member 40 by using the supporting member 50 and the fixing member 40 instead of the fixing member 20 for supporting and fixing 36. It can be reinforced by the method of being inserted into the fastening cone hole 52 of the support member 50.

At this time, in the fixing member 40, the bolt fastening portion 44 of one side is fitted to the anchor bolt 30, and then fastened to the anchor nut 32, and the other end of the hook portion 42 is the supporting member 50 on both sides. It is formed in the structure that the strand 36 is fixed to the anchorage 20 by the fastening cone 54 fitted to the support member 50 while fixing the, the material is to give a tensile stress to the strand 36 It is preferable to form with the steel wire which can.

Such a strand wire reinforcement 60 is grooved to protrude to a certain thickness over the concrete surface of the member to be reinforced when the filling depth of the polymer mortar 38 is not more than 25mm because the concrete covering thickness of the member to be reinforced is not sufficient. Plastering after installation, or when the concrete is deteriorated may be installed by directly spraying the polymer mortar 38 to a thickness of 25mm or more after fixing the wire directly to the concrete surface of the member without grooving.

Fire-resistant reinforcement method by embedding a stranded wire according to the present invention is widely used not only for beams 10 and slabs of reinforced concrete structures, but also for reinforcement of structures such as sewage culvert boxes, subway tunnels, etc., which were conventionally reinforced by epoxy resins vulnerable to moisture and heat. It may be applied, and if a high performance refractory function is required, refractory polymer mortar may be used instead of the polymer mortar 38.

In addition, the present invention is not limited to the above-described embodiment, and those skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed to the extent that various changes can be made. There is a technical spirit of the invention.

According to the fire-resistant reinforcement method by embedding the strand wire of the present invention as described above, the wire is inserted into the portion to be reinforced of the reinforced concrete member, and the both ends of the wire are tension-tightened, and the polymer is filled through the reinforcement method to finish and cure the polymer mortar. The reinforcing function can be improved by increasing the tensile stress due to the strong adhesion of the mortar, high strength and adhesion to the strand.

In addition, the fire resistance performance is improved compared to the conventional reinforcement method by epoxy resin, and compared to the conventional post-tensioning reinforcing method, there is no excessive stress on the fixing part and the other members at the both ends compared to the conventional post-tensioning reinforcement method. Sufficient reinforcement can be ensured without giving this information.

Claims (3)

In reinforcing reinforced concrete structures, A groove digging step (a) of digging the strand wire groove 12 and the anchorage groove 14 by cutting the coated concrete at both ends of the member to be reinforced; A fixing unit installation step (b) for fixing the fixing unit 20 to the anchor bolt 30 and the anchor nut 32 in the fixing unit groove 14; Polymer mortar filling step (c) for filling the polymer mortar 38 in the strand wire groove 12, A wire tightening step (d) of tightening both ends of the strand wire 36 to the strand wire groove 12 and then tightening the ends of the strand wire 36 by the fastening cone 34 to the anchorage 20; Filling the polymer mortar 38 in the strand wire groove 12 and the fixture groove 14, the strand wire 36 and the anchoring hole 20 is installed and curing the polymer mortar finishing step (e) after the finish, characterized in that it comprises Fireproof reinforcement method by purchase of stranded wire. The method of claim 1, In the groove digging step (a), the strand wire groove 12 and the anchorage groove 14 are formed to have a width equal to the thickness of the strand wire 36 to be embedded plus a value of 30 mm. Method. delete