KR102189935B1 - Seismic reinforcement method using steel frame - Google Patents

Abstract

The present invention relates to an earthquake-resistant reinforcement method using a steel frame and, particularly, to an earthquake-resistant reinforcement method using a steel frame, in order to ensure safety of an existing structure by means of a steel frame by preventing construction defects, comprising: a marking step of marking a position of a chemical anchor to be constructed on an existing structure exposing columns and beams; a steel bar exploration step of exploring steel bars within the existing structure to check whether the steel bars interfere with the marked position; a perforating step of perforating the position, where marking is finished since the steel bars do not interfere therewith, up to a predetermined depth with thickness conforming to the standard of the chemical anchor to be constructed; a steel frame production step of perforating an H-shaped steel beam to correspond to the perforation position of the existing structure and producing a steel frame with a perforated H-shaped steel beam; and a chemical anchor construction step of making the perforation position of the existing structure consistent with the perforation position of the steel frame and then constructing the chemical anchor.

Description

Seismic reinforcement method using steel frame}

The present invention relates to a seismic reinforcement method using a steel frame, in particular, to a seismic reinforcement method using a steel frame capable of preventing construction failure.

In general, buildings are constructed with masonry walls between windows and concrete columns and beams for lighting, ventilation, and outflow. The windows and masonry walls have a greater concentration of stress than other parts. In particular, when a horizontal load such as an earthquake is applied, tensile cracks may start in the windows and masonry walls, leading to collapse of the building.

In the case of reinforced concrete buildings completed before 1989 when the seismic design standard was enacted, the seismic performance is insufficient, and there is a risk of great damage due to structural damage caused by the opening in the event of an earthquake. To minimize, various seismic reinforcement methods are applied.

One of the seismic reinforcement methods is a seismic reinforcement method using a steel frame, and the following construction method is currently applied. First, the construction demolition work to expose the columns and beams of the existing structure is performed, and then the H-beam is drilled at intervals of chemical anchors based on specifications, and a steel frame is fabricated from the drilled H-beam. After that, for the construction of chemical anchors, the steel frame is temporarily fixed in the section where the demolition has been completed, and then the concrete surface is drilled.

At this time, a drilling drill is used, and the concrete surface is drilled in a state that is inclined by 45° due to the mechanical limitation of the drilling drill, and the chemical anchor constructed in this state is inclined by 45°. Because it does not meet the standards for seismic reinforcement, it is frequently judged as a construction defect during supervision and inspection.

In addition, re-drilling work is performed while the drilling drill is further laid down in order to avoid rebar interference when rebars inside the existing structure are in progress.However, it is difficult to determine the depth of drilling because the exact location of the rebars is not known. When drilling the reinforcing bar during the work, not only the construction defect occurs, but also the problem of hindering the safety of the existing structure occurs.

1. Korean Patent Registration No. 10-1820628'Seismic reinforcement construction method of buildings and seismic reinforcement structure manufactured by the method'

An object of the present invention is to provide a seismic reinforcement method using a steel frame capable of securing the safety of an existing structure by a steel frame by preventing construction defects as to solve the above problems.

The seismic reinforcement method using a steel frame according to the present invention for achieving the above object comprises: a step of marking a position of a chemical anchor to be constructed on an existing structure exposing columns and beams; A reinforcing bar exploration step of examining the reinforcing bar inside the existing structure to check whether or not the reinforcing bar interferes at the marked position; A perforation step of perforating a predetermined depth with a thickness suitable for a chemical anchor standard to be constructed at a location where the reinforcing bar is not interfered and the inking is completed; A steel frame manufacturing step of drilling H-beams to correspond to the drilling positions of the existing structures and fabricating a steel frame from the perforated H-beams; And a chemical anchor construction step of constructing a chemical anchor after matching the piercing position of the existing structure with the piercing position of the steel frame.

In addition, after the drilling step, a detection step of measuring the drilling depth and position of the existing structure; further comprising, the steel frame manufacturing step, the H-beam to correspond to the drilling position of the existing structure measured in the detection step Can be perforated.

In addition, in the steel frame manufacturing step, before drilling the H-beam, the drilling position may be marked on the H-beam so as to correspond to the drilling position of the existing structure measured in the detection step.

In addition, when the interference of the reinforcing bar is confirmed in the reinforcing bar exploration step, a re-alignment step of re-displaying the position of the chemical anchor by changing to a position where no interference of the reinforcing bar occurs in the existing structure; Steps can be performed.

In addition, in the chemical anchor construction step, when the drilling position of the existing structure and the drilling position of the steel frame do not coincide, it is orthogonal to one side of the H-beam to be drilled using a magnetic drill so as to match the drilling position of the existing structure. After re-perforating the mounted steel frame, it is possible to construct a chemical anchor.

According to the present invention, by accurately identifying the location of the reinforcing bars inside the existing structure, it is possible not only to prevent damage to the reinforcing bars of the existing structure during the construction process, but also to accurately know the depth to be drilled, thereby preventing construction defects while preventing the construction of a steel frame for seismic reinforcement. The safety of the existing structure can be secured according to the frame construction.

In addition, since it is constructed orthogonally to one side of the H-beam on which the chemical anchor is installed, the performance of the steel frame installed for seismic reinforcement can be properly exhibited.

1 is a flowchart of a seismic reinforcement method using a steel frame according to the present invention,
Figure 2 is an exemplary view showing the step of the seismic reinforcement method using a steel frame according to the present invention,
3 is an exemplary view showing a reinforcing bar exploration step of the seismic reinforcement method using a steel frame according to the present invention,
Figure 4 is an exemplary view showing the drilling step of the seismic reinforcement method using a steel frame according to the present invention,
5 and 6 are exemplary views showing the detection step of the seismic reinforcement method using a steel frame according to the present invention,
7 is an exemplary view showing the steel frame manufacturing step of the seismic reinforcement method using the steel frame according to the present invention,
8 and 9 are exemplary views showing a chemical anchor construction step of the seismic reinforcement method using a steel frame according to the present invention,
10 is an exemplary view showing a state in which a steel frame is installed in an existing structure by the seismic reinforcement method using a steel frame according to the present invention.

In the present invention, in order to prevent construction defects and secure the safety of the existing structure by the steel frame, the step of marking the position of the chemical anchor to be constructed on the existing structure exposed to the columns and beams; A reinforcing bar exploration step of examining the reinforcing bar inside the existing structure to check whether or not the reinforcing bar interferes at the marked position; A perforation step of perforating a predetermined depth with a thickness suitable for a chemical anchor standard to be constructed at a location where the reinforcing bar is not interfered and the inking is completed; A steel frame manufacturing step of drilling H-beams to correspond to the drilling positions of the existing structures and fabricating a steel frame from the perforated H-beams; It proposes a seismic reinforcement method using a steel frame comprising a; chemical anchor construction step of constructing a chemical anchor after matching the drilling position of the existing structure with the drilling position of the steel frame.

The scope of the present invention is not limited to the embodiments described below, and various modifications may be made by those of ordinary skill in the art without departing from the technical gist of the present invention.

Hereinafter, the seismic reinforcement method using a steel frame according to the present invention will be described in detail with reference to FIGS. 1 to 10.

The seismic reinforcement method using the steel frame of the present invention is basically an ink mating step (S10), reinforcing bar exploration step (S20), drilling step (S30), steel frame manufacturing step (S50), chemical anchor construction as shown in FIG. It includes a step (S60), and may further include a detection step (S40) and a re-eating step.

The ink mating step (S10) is the first process to proceed with the seismic reinforcement work, and as shown in FIG. 2, the position of the chemical anchor 300 to be constructed on the existing structure 100 exposing the columns and beams is displayed. do. In this case, the position of the chemical anchor 300 may be displayed at predetermined intervals based on the specification.

In the reinforcing bar exploration step (S20) that proceeds after the ink grading step (S10), as shown in FIG. 3, the reinforcing bar 110 included in the existing structure 100 is explored and in the ink grading step (S10) Indication) Check whether the reinforcing bar 110 interferes at one location. When constructing the chemical anchor 300 for seismic reinforcement, it is a process performed in order not to damage the reinforcing bar 110 inside the existing structure 100. For example, the location of the reinforcing bar 110 using the ultrasonic probe 10 And it is possible to grasp the thickness, covering, etc.

At this time, it is preferable to use a device capable of detecting a covering thickness of 150 mm or more for a rebar probe such as the ultrasonic probe 10.

Even if the ink grading step (S10) based on the specifications is performed in this way, the safety of the existing structure 100 can be prevented from deteriorating due to the construction for seismic reinforcement by grasping the exact location of the reinforcing bar 110 inside. .

In addition, when interference of the reinforcing bar 110 is confirmed at the location marked by the reinforcing bar exploration step (S20), the reinforcing step is additionally performed. In the re-eating step, the position of the chemical anchor 300 to be constructed is displayed again by changing to a position where the interference of the reinforcing bar 110 does not occur in the existing structure 100.

After performing the reinforcing bar exploration step (S20) or the reinforcing step, it is confirmed that there is no interference of the reinforcing bar 110, so that the reinforcing bar 110 is completed, and then the drilling step (S30) is performed. In the drilling step (S30), as shown in FIG. 4, a predetermined depth is drilled with a thickness suitable for the standard of the chemical anchor 300 to be constructed at the position where the ink marking is completed in the existing structure 100. In the drilling step (S30), the existing structure 100 can be drilled using an electric drill. At this time, the drill bit of the electric drill is made orthogonal to one surface of the column or beam to be drilled, so that the chemical anchor 300 is It is desirable to be able to be constructed orthogonally on one side of. In addition, in the drilling step 30, it is preferable to perform an additional cleaning operation after drilling the existing structure 100 to remove residues, dust, contaminants, etc. inside the drilled hole.

On the other hand, after the drilling step (S30), the steel frame manufacturing step (S50) may be immediately performed, as well as the detection step (S40) may be additionally performed.

The detection step (S40) is a step of measuring the depth and position of the perforated hole of the existing structure 100, for example, by accurately measuring the perforation depth using the vernier caliper 30 as shown in FIG. You can check whether it conforms to. This is because in order to secure the correct performance of the chemical anchor 300, it must be drilled to an appropriate depth. As another example, as shown in FIG. 6, the puncturing position may be measured using a tape measure 40. This is to accurately drill H-beams in manufacturing the steel frame 200 to be described later.

After the drilling step (S30) or the detection step (S40), the steel frame manufacturing step (S50) is performed. Steel frame manufacturing step (S50) is a step of manufacturing a steel frame 200 that will be combined with the existing structure 100 to exhibit seismic reinforcement performance, and the steel frame 200 is made of H-beam as shown in FIG. Is produced. The steel frame 200 may be composed of a lattice-shaped frame that forms a lattice shape to be fixed to both pillars and upper and lower beams of the existing structure 100, and a reinforcing frame formed to form an oblique line inside the lattice-shaped frame.

In the steel frame manufacturing step (S50), the steel frame 200 must be drilled so that the chemical anchor 300 can be installed later, and the steel frame 200 composed of the grid-shaped frame and the reinforcing frame is fabricated as above and then drilled. However, in this case, there is a possibility that the perforation may not be made orthogonal to one side of the H-beam forming the steel frame 200. After perforating the H-beam to correspond to the perforation position of the existing structure 100, The steel frame 200 is manufactured using the H-beam.

And if the detection step (S40) is in progress, in the steel frame manufacturing step (S50), the H-beam is drilled so as to correspond to the drilling position of the existing structure 100 measured in the detection step (S40). In addition, before drilling the H-beam, the drilling position was first marked on the H-beam in order to correspond to the drilling location of the existing structure 100 measured in the detection step (S40), and then the drilling was performed. desirable.

In addition, in the steel frame manufacturing step (S50), a steel frame 200 composed of a lattice-shaped frame and a reinforcing frame is manufactured by welding the perforated H-beams to each other, and a welded part non-destructive inspection may be performed after the welding operation is completed. The non-destructive testing of welded parts includes, for example, an ultrasonic test (UT) in which ultrasonic waves are transmitted to an object to be inspected to analyze the ultrasonic waves reflected from internal defects to read the position and size, and discontinuous by magnetizing the object to be inspected. A magnetic particle test (MT: Magnetic Particle Test) can be performed to detect defects by observing the magnetic particle indication caused by the leakage magnetic field generated in the negative. Only the steel frame 200 that has passed this welding part destructive test is brought into the site.

After the steel frame manufacturing step (S50), a chemical anchor construction step (S60) of fixing the steel frame 200 to the existing structure 100 is performed. In the chemical anchor construction step (S60), first, the existing structure 100 is fitted to the steel frame 200, and the drilling position of the existing structure 100 and the drilling position of the steel frame 200 are matched.

If the drilling position of the existing structure 100 and the drilling position of the steel frame 200 do not match in the chemical anchor construction step (S60), for the exact construction of the chemical anchor 300, the drilling position of the existing structure 100 The steel frame 200 mounted orthogonally to one side of the H-beam to be drilled is re-perforated using a magnetic drill so as to match with. At this time, the magnetic drill used is preferably a micro-miniature magnetic drill so that the work can be performed inside the H-beam.

When the drilling position of the existing structure 100 and the drilling position of the steel frame 200 match through the above process, the chemical anchor 300 is constructed as shown in FIGS. 8 and 9. As shown in FIG. 10, when the construction of the chemical anchor 300 is completed, the operator can easily perform the construction to be orthogonal to one side of the H-beam through which the chemical anchor 300 passes through the nut fastened after the construction of the chemical anchor 300. Can be confirmed.

As described above, the seismic reinforcement method using the steel frame of the present invention accurately grasps the location of the reinforcing bar 110 inside the existing structure 100, so that the reinforcing bar 110 of the existing structure 100 is damaged during the construction process. In addition to preventing the construction of the chemical anchor 300, the depth at which the existing structure 100 is to be drilled can be accurately known, while preventing the construction failure, the existing steel frame 200 for seismic reinforcement The safety of the structure 100 can be ensured. In addition, since the chemical anchor 300 is constructed to be perpendicular to one side of the H-beam to be installed, the performance of the steel frame 200 installed for seismic reinforcement can be properly extracted.

10: ultrasonic probe
20: electric drill
30: vernier caliper
40: tape measure
100: existing structure
110: rebar
200: steel frame
300: Chemical anchor

Claims (5)

An ink painting step of marking the position of the chemical anchor to be constructed on the existing structure exposing the columns and beams;
A reinforcing bar exploration step of examining the reinforcing bar inside the existing structure to check whether or not the reinforcing bar interferes at the marked position;
A perforation step of perforating a predetermined depth with a thickness suitable for a chemical anchor standard to be constructed at a location where the reinforcing bar is not interfered and inking is completed;
A detection step of measuring the drilling depth and position of the existing structure;
A steel frame manufacturing step of marking a perforated position on the H-beam to correspond to the perforated position of the existing structure measured in the detection step, and punching the H-beam to correspond to the marked perforated position to produce a steel frame from the perforated H-beam;
A chemical anchor construction step of constructing a chemical anchor after matching the perforation position of the existing structure with the perforation position of the steel frame;
Seismic reinforcement method using a steel frame comprising a. delete delete The method of claim 1,
When interference of reinforcing bars is confirmed in the rebar exploration step,
A seismic reinforcement method using a steel frame, characterized in that after further proceeding with the step of re-indicating the position of the chemical anchor by changing to a position where the interference of the reinforcing bar does not occur in the existing structure; and then performing the drilling step . The method of claim 1,
In the chemical anchor construction step, when the drilling position of the existing structure and the drilling position of the steel frame do not coincide, it is mounted perpendicularly to one side of the H-beam to be drilled using a magnetic drill so as to match the drilling position of the existing structure. Seismic reinforcement method using a steel frame, characterized in that the re-drilling of the steel frame, and then constructing a chemical anchor.

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