KR20010107897A - Method for reinforcing a bottom slab using wire tension unit - Google Patents

Abstract

The present invention is to increase the rigidity by mounting the post-tension by tensioning the pierce steel wire using a hydraulic jack, and then attaching the ￢ section steel, wire mounting holes and two-way tensioning device at regular intervals at both ends of the bottom surface of reinforced concrete floor slab lacking strength The floor slab reinforcement method using a wire tensioning device that can increase the safety of the building by this, the reinforcement method is a process of fixing the L-shaped bracket 40 to the middle point of the two pillars 12, the L-bracket Mounting the bidirectional wire tensioning device 20 by using the T-shaped bracket 22 bolted to the 40, fixing the fixing unit bracket 50 at a position adjacent to the two pillars 12, Bolting one or more wire anchorages 30 with a load cell to the anchorage bracket 50, and one end of the two wires 14 and 16 The other end is coupled to the non-wire mounting hole 30, the other end is coupled to the bidirectional wire tensioning device 20, and the process of tensioning each of the wires (14, 16) by a hydraulic jack.

Description

Floor slab reinforcement method using wire tensioning device {METHOD FOR REINFORCING A BOTTOM SLAB USING WIRE TENSION UNIT}

The present invention relates to a floor slab reinforcement method using a wire tensioning device, and more particularly, to reinforce a floor slab of a reinforced concrete structure having insufficient load capacity by using a wire anchorage provided with a bidirectional wire tensioning device and a load cell. It relates to a floor slab reinforcement method using a wire tensioning device that can increase the rigidity.

Usually, the structure of a building can be classified into four types. That is, reinforced concrete structure, steel structure, steel reinforced concrete structure and synthetic structure.

Among them, reinforced concrete structure is a structure in which concrete bears compressive force and reinforcement embedded in concrete bears tensile force. Concrete has a low unit cost per unit volume, but lacks tensile force and cannot receive moment or tensile stress alone. Expensive reinforcement is mainly placed in the area where tensile stress occurs in the structure to enable economical design as a whole.

However, the reinforced concrete structure is more likely to cause deformation due to the load transmitted from the outside than the steel structure or the steel reinforced concrete structure. In particular, in the case of the floor slab, the rebar amount is often insufficient or when the upper reinforcing bar breaks down a predetermined position often occurs.

As the upper end of the reinforcing bar sinks, the structural slab becomes thinner, resulting in a decrease in bearing capacity, resulting in an upper crack. At most construction sites, the upper reinforcing bar sinks because many people have to work on the reinforcing bars before they reinforce or pour concrete.

In this way, when the strength of the end bending moment of the bottom slab is reduced, the reduced bending moment value is automatically simulated in the bending moment of the center portion. At this time, if there is no room in the center lower reinforcement, the bottom crack occurs in the center.

Therefore, in principle, it is good to lift the upper end reinforcement that originally caused the lack of strength of the floor slab to the original position or add the reinforcing bar at the top, but it is generally difficult to remove the floor finishing material and concrete. Applies the method of reinforcing the bottom slab bottom.

Conventional floor slab reinforcement method is to remove the finishing material and to increase the strength by attaching a fiber sheet or steel sheet to the bottom of the bottom slab, according to the attachment method, the fiber sheet or steel sheet is firmly attached to the bottom of the bottom slab. In order to remove the finishing material and evenly wipe the base surface to have a smooth and clean arrangement.

Another conventional method of reinforcing floor slab is to reinforce by attaching steel beams, such as H-beams, to the lower part of the floor slab. According to this support method, there is a problem in that the utilization of space in the ceiling is limited and space utilization is lowered. have.

Another method of floor slab reinforcement is the use of a bidirectional truss, which requires tensioning the bidirectional wires twice, creating an unbalanced force resulting from different tensions in both directions, which may present a risk, Because of the tension in the workability is bad and accurate construction is difficult.

The present invention for solving this problem is to increase the strength in the state of eliminating the occurrence of the unbalanced force in both directions by tensioning the floor slab with a deflection and cracking at the first time by a wire, sag due to lack of strength, The purpose of the present invention is to provide a floor slab reinforcement method using a wire tensioning device that improves rigidity, improves workability, and is advantageous in terms of space utilization in the ceiling.

1 is a front view showing a state of reinforcing the floor slab by the reinforcement method of the present invention,

Figure 2 is a bottom view looking up the configuration of Figure 1,

3 is an enlarged view of part III of FIG. 1;

4 is a cross-sectional view taken along the line IV-IV in FIG.

5 is an enlarged view of portion V of FIG. 1;

♣ Explanation of symbols for main part of drawing ♣

10: floor slab 12, 12: pillar

14, 16: Wire 20: Bidirectional wire tensioning device

22: T bracket 30: Wire anchorage

40: L-bracket 50: Fixture bracket

The floor slab reinforcement method using the wire tensioning device of the present invention for achieving the above object is a step of fixing the L-type bracket to the middle point of the two pillars in the bottom slab reinforcement method of the reinforced concrete structure, the L-bracket Mounting a two-way wire tensioning device using a T-shaped bracket bolted to the step; fixing the fixing bracket at a position adjacent to the two pillars; and bolting at least one wire fixing device provided with a load cell to the fixing bracket. And a step of coupling the one end of the two wires to the wire mounting hole provided with the load cell, and the other end to the bidirectional wire tensioning device, and the step of tensioning each of the wires by a hydraulic jack. It is characterized by including.

Hereinafter, with reference to the accompanying Figures 1 to 5 will be described in detail with respect to the floor slab reinforcement method using a wire tensioning apparatus according to a preferred embodiment of the present invention.

1 is a front view showing a state of reinforcing the floor slab by the reinforcement method of the present invention, FIG. 2 is a bottom view of the configuration of FIG. 1 from below, FIG. 3 is an enlarged view of part III of FIG. 3 is a cross-sectional view taken along the line IV-IV and FIG. 5 is an enlarged view of portion V of FIG. 1.

The post-tensioning method is adopted in the preferred embodiment of the present invention as a method for lifting up the bottom slab, which is sagging and cracked due to lack of strength, and basically reinforcing it. In addition, in the conventional reinforcement method using a bidirectional truss, the bidirectional wire should be tensioned twice, in order to prevent other forces imbalance and deterioration of workability, in the present invention, as shown in Figures 1 and 2, the bidirectional wire tensioning device Was adopted.

That is, the wire anchorage 30 is fixed to the adjacent portions of both pillars 12 to couple the ends of the wires 14 and 16, and then the bidirectional wire tensioning device is fixed to the intermediate points of the pillars 12 so that the wires 14, By tensioning the other end of 16, it was possible to lift up the sagging bottom slab. In this way, by tensioning the wires 14 and 16 at once by the bidirectional wire tensioning device, the tension force of the wires at both ends becomes equal, whereby a bidirectional unbalanced force is not generated.

At this time, it is important to check the tension force for tensioning the wires 14 and 16, which are pierced steel wires, with the hydraulic jack and the stresses to reinforce the spacing of the wire anchoring positions in the structural calculation so that the tension force is maintained as it is. Tensioned wires are sometimes loosened and not at their proper value, so check the tension of the wires periodically. To this end, at least one of the wire anchorage is configured as a anchorage provided with a load cell, so that the tension force of the wires 14 and 16 can be measured at any time.

3 and 4, the L-shaped bracket 40 is secured by the bolts 46 for mounting the bidirectional wire tensioning device 20 to the intermediate point bottom slab 10 of both columns. The T-shaped bracket 22 is fixed to the L-shaped bracket 40 by the bolt 42 and the nut 44. The T-type bracket 22 is equipped with a bidirectional wire tensioning device 20.

Inside the bidirectional wire tensioning device 20, two extension holders 24 and 26 having a tapered shape for holding one ends of the wires 14 and 16 are provided. Since the structure and operation principle of the bidirectional wire tensioning device employed in the present invention are disclosed in detail in Korean Patent Application No. 2001-55577 of the applicant, the description thereof will be omitted.

Next, as shown in FIG. 5, the fixing unit bracket 50 is fixed to the bottom slab 10 for fixing the wire fixing unit 30 provided with one of the two load cells. The fixing bracket 50 is provided with a long hole 52. The bolt 54 is inserted into the long hole 52 and then fixed with a nut 56.

The extension holder 34 is also inserted into the taper portion of the inner hole 32 of the wire anchorage 30 having the load cell employed in the present invention, so that one end of the wires 14 and 16 are firmly gripped. Since the structure and operation principle of the wire anchorage provided with the load cell are disclosed in detail in Korean Utility Model Registration Application No. 2001-27738 of the applicant, the description thereof is omitted here.

The process of reinforcing the bottom slab 10 using the bidirectional wire tensioning device 20 and the wire anchorage 30 of this configuration is as follows.

First, the L-shaped bracket 40 is fixed to the intermediate point of the two pillars 12 using the bolt 46, and then the bolt 42 and the nut 44 are used for the L-shaped bracket 40. Fix the T-type bracket (22). Therefore, it is possible to fix the bidirectional wire tensioning device 20 integrally formed with the T-shaped bracket 22 to the L-shaped bracket 40 by welding or the like.

Next, the fixing unit bracket 50 is fixed to a position adjacent to both pillars 12, and then at least one of the fixing unit brackets 50 is bolted to the wire fixing unit 30 provided with a load cell. Subsequently, one end of the two wires 14 and 16 is coupled to the wire mounting holes 30 provided with the load cells, respectively, and the other end is coupled to the bidirectional wire tensioning device 20, and then the wire is connected by a hydraulic jack. What is necessary is just to tension each of (14, 16).

At this time, in order to fix the wires 14 and 16, which are pierced wires, by a hydraulic jack, a minimum space is necessary to space the PS wires from the bottom of the floor slab by a predetermined distance, thereby having a very good structural effect. You get

That is, as the distance between the lower surface of the floor slab 10 and the wires 14 and 16 increases, the tensile stress of the wires 14 and 16 as well as the compressive stress of the floor slab concrete are reduced, even if the concrete strength of the floor slab is insufficient. The method of the present invention also enables reinforcement. Therefore, when there is room in the ceiling space, it is possible to increase the reinforcing effect by inserting wedges such as steel pipes between the floor slab and the wire.

On the other hand, the outer wall of the basement, as well as the outer wall of the water tank, the septic tank, etc., because the floor slab is vertically upright, it is possible to apply the floor slab reinforcement method of the present invention as it is.

According to the present invention described above, the overall slab of the building structure by increasing the strength in the state that the deflection caused by lack of strength and the cracked floor slab is tensioned by a wire at once to eliminate the occurrence of unbalanced bidirectional force Can increase. In addition, in the conventional case of attaching the fiber sheet or steel sheet to the lower surface of the floor slab, the workability is improved by eliminating the inconvenience of removing the ceiling finish and smoothing the lower surface. In addition, there is an advantage, such as advantageous in terms of utilization of the space inside the ceiling compared to the conventional method supported by the H-beam.

Claims (1)

In the floor slab reinforcement method of reinforced concrete structures, Fixing the L-shaped bracket 40 to the middle point of the two pillars 12, Mounting the bidirectional wire tensioning device 20 by using the T-shaped bracket 22 bolted to the L-shaped bracket 40; Fixing the fixing unit bracket 50 at a position adjacent to both pillars 12; Bolt-bonding the at least one wire anchorage 30 with a load cell to the anchorage bracket 50; Coupling one end of the two wires 14 and 16 to the wire mounting holes 30 provided with the load cells, respectively, and the other end to the two-way wire tensioning device 20; Floor slab reinforcement method using a wire tensioning device comprising the step of tensioning each of the wires (14, 16) by a hydraulic jack.