KR20110018251A - Earthquake-proof steel frame structure joint structure and joint method - Google Patents

Abstract

PURPOSE: Joint constitution of an earthquake-proof steel frame structure and a joint construction method thereof are provided to enable efficient replacement control of a structure in case of earthquake by being attached to posts or beams of the existing structure for reinforcement through steel plates. CONSTITUTION: Joint constitution of an earthquake-proof steel frame structure comprises an adhesion reinforcement plate, a fixing anchor(120), an adherence synthetic resin(30), a load transmission board(140), and mortar(150). The adhesion reinforcement plate is welded on a base surface(11) of a ferroconcrete structure and comprises an anchor through-hole. The fixing anchor passes through the anchor through-hole and is embedded in an anchor hole punched in the surface of the ferroconcrete structure. A space between the base surface and the adhesion reinforcement plate is filled with adherence synthetic resin. The lower section of the load transmission board is welded on the upper surface of the adhesion reinforcement plate, and the upper section thereof is welded on an earthquake-proof steel frame structure.

Description

Earthquake-proof Steel Frame Structure Joint Structure and Joint Method

The present invention enables the seismic reinforcement steel structures and the existing reinforced concrete structures to be integrated in the event of an earthquake, thereby efficiently transferring the horizontal load of the existing reinforced concrete structures to the reinforcing steel structures in the event of an earthquake, thereby improving the efficiency of seismic reinforcement. The present invention relates to a joint structure and a joining method of an earthquake-proof reinforcing steel structure and an existing reinforced concrete structure.

In recent years, the earthquake that occurs frequently in neighboring countries of Korea, and the enormous loss of life and property damage caused by it, cannot be considered safe from earthquakes. Moreover, more than 80% of existing buildings in Korea are defenseless against earthquakes, especially for school buildings.

     It is fortunate that the government has recently begun some basic investigations on earthquake-resistant reinforcement of important facilities and buildings and earthquake-resistant reinforcement.

     The seismic reinforcement of existing reinforced concrete structures is based on a variety of systemic seismic reinforcement methods, such as the damping reinforcement method using hydraulic dampers including steel frame and interlayer displacement amplification toggle, and K-brass installed on steel frame. The damping reinforcement method is actively used. In recent years, vibration damping reinforcement systems using steel dampers including steel frame and interlayer displacement amplification toggle have been developed and applied to the domestic environment.

     The seismic reinforcement methods of the vibration suppression system are compared with conventional seismic reinforcement methods (various fiber sheet reinforcement method, steel plate reinforcement method, bearing wall extension reinforcement method, etc.) and have excellent seismic performance in case of earthquake. The maximum control of the deformation prevents the loss of valuable lives and property, as well as the excellent constructability, economics and appearance design, which greatly contribute to the national disaster prevention caused by the earthquake.

     However, in order for the vibration suppression reinforcement methods to exert an excellent function, the vibration suppression system and the reinforced concrete structures to be reinforced must be securely joined to each other. It is possible to minimize the deformation of the building from the load as well as to minimize the loss of valuable life and property.

      As shown in Figure 1 as a method of joining a steel frame for seismic reinforcement and existing reinforced concrete structures at home and abroad, one or two rows of resin anchors are installed at a predetermined interval in the existing concrete structure 1, and seismic reinforcement is installed. The situation in which the stud bolts 3 are installed in one or two rows of the steel frame 4 for the steel frame 4 and the high-strength mortar 5 is provided by installing the spiral reinforcement and the formwork is provided.

     However, in this bonding method, it is inevitable that cracks are generated in the high-strength mortar (5) due to irregular tremor energy when an earthquake occurs, and at the same time, the seismic load may be difficult to transfer to the seismic reinforcing frame (4). In addition, there is a problem that the vibration suppression system is difficult to exhibit the desired seismic energy attenuation function.

     Therefore, the seismic reinforcement methods using the vibration suppression system are important as well as the seismic performance of the vibration suppression system itself. This is even more important.

Therefore, there is an urgent need to develop a reliable and stable joining device and construction method between the existing seismic reinforcing steel frame and reinforced concrete structures.

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide a solid joining structure and a joining method in which the existing reinforced concrete structure and the seismic reinforcing steel frame structure can be integrated despite the seismic load concentrated during the earthquake.

Second, the joint structure that can be effectively exerted displacement control of the target structure from seismic load concentrated during the earthquake by the adhesive reinforcement to the column or beam of the existing reinforced concrete structure where seismic reinforcement steel structure is installed It is another object of the present invention to provide a joining method.

Third, it is another object of the present invention to provide a stable joining structure and a joining method that there is no fear of corrosion that can occur in the joint by allowing the joint of the existing reinforced concrete structure and the earthquake-resistant reinforcing steel structure is installed inside the high-strength mortar. It is done.

Fourth, another object of the present invention is to provide a semi-permanent joining structure and joining method that does not require maintenance.

The present invention relates to a joint structure in which the reinforced concrete structure 10 and the seismic reinforcing steel frame structure 200 are integrally coupled to each other. As a plate member joined to the surface of the reinforced concrete structure 10, Adhesion reinforcement plate 110 is provided with an anchor through hole 111; A plurality of fixing anchors 120 which are embedded in the anchor holes 12 drilled on the surface of the reinforced concrete structure 10 by passing through the anchor through holes 111 provided in the adhesive reinforcing plate 110; Bonding synthetic resin 30 is filled in the space between the base surface 11 of the reinforced concrete structure 10 and the adhesive reinforcing plate 110; It has a plate shape as a whole, the lower cross section is welded to the upper surface of the adhesive reinforcing plate 110, the upper cross section is a load transfer plate 140 welded to the seismic reinforcing steel structure 200; And a mortar 150 that is poured into a space between the adhesive reinforcing plate 110 and the load transfer plate 140 welded to the space between the seismic reinforcing steel frame structures 200 welded thereto. Provides a description of the structure joint structure.

The present invention also relates to a joining method for integrally combining the reinforced concrete structure 10 and the seismic reinforcing steel structure 200, the reinforced concrete structure 10 to which the adhesive reinforcing plate 110 is attached by using a grinding machine or a planarizer. Grinding the base surface 11 of the first step; A second step of drilling the anchor hole 12 for fixing the adhesive reinforcing plate 110 to the base surface 11, the concrete using the hand drill; Anchor through hole 111 is provided and the fixing anchor plate 120 attached to the base surface 11, the adhesive reinforcing plate 110 welded to the stud bolt 130 on the upper surface and passed through the anchor through hole 111 Inserting into the anchor hole 12; A fourth step of welding the lower end surface of the load transfer plate 140 welded to the seismic reinforcing steel frame structure 200 to the adhesive reinforcing plate 110; A fifth step of tightening the fixing anchor 120 to hold the position of the load transfer plate 140; The periphery of the adhesive reinforcing plate 110 and the fixing anchor 120 are sealed using a synthetic resin 20 for sealing, and a synthetic resin inlet 21 and an air outlet 22 are installed in the synthetic resin 20 for sealing. A sixth step; A seventh step of filling the empty space between the adhesive reinforcing plate 110 and the base surface 11 by injecting the adhesive synthetic resin 30 through the synthetic resin inlet 21; An eighth step of installing the formwork on both sides of the seismic reinforcing steel structure 200 and filling the empty space between the formwork and the adhesive reinforcing plate 110 and the seismic reinforcing steel structure 200 by filling mortar 150; And a ninth step of curing the mortar 150 and removing the formwork, together with the seismic reinforcing steel structure joining method.

Technical effects of the configuration of the present invention are as follows.

First, despite the seismic load concentrated during the earthquake, existing reinforced concrete structures and seismic reinforcing steel structures can be integrated.

Secondly, the adhesive reinforcement is made of steel plates to the columns or beams of the existing reinforced concrete structures in which seismic reinforcing steel structures are installed, so that displacement control of the target structure can be efficiently exhibited from seismic loads concentrated during an earthquake.

Third, the joint of the existing reinforced concrete structure and the earthquake-resistant reinforcing steel structure can be installed in the high-strength mortar to prevent corrosion that may occur in the joint.

Fourth, it is possible to provide a semi-permanent joining structure and joining method that does not require maintenance.

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

Figure 2 shows a bonding structure of the adhesive reinforcing plate 110 and the stud bolt 130 as a specific embodiment of the present invention, Figure 3 is a specific embodiment of the present invention, the load transfer plate 140 and load transfer 4 shows a coupling structure of the reinforcing plate 160, and FIG. 4 shows a cross-sectional structure of the adhesive reinforcing plate 110 installed on the base surface 11 of the reinforced concrete structure 10, 5 illustrates a planar structure of the adhesive reinforcing plate 110 installed on the base surface 11 of the reinforced concrete structure 10 as a specific embodiment of the present invention, and FIG. 6 illustrates a base surface on the reinforced concrete structure 10. 11 shows the cross-sectional structure of the earthquake-resistant reinforcing steel structure joined structure completed.

Adhesive reinforcing plate 110 is a plate joined to the surface of the reinforced concrete structure 10, a plurality of anchor through holes 111 are provided along the longitudinal direction.

The size, quantity, and arrangement of the anchor through hole 111 is not particularly limited and may be appropriately changed in consideration of the specifications of the plate. In a specific embodiment of the present invention, the anchor through holes 111 are arranged in two rows, but in some cases, one or three rows may be arranged.

Fixing anchor 120 is embedded in the anchor hole 12 perforated on the surface of the reinforced concrete structure 10 through the anchor through hole 111 provided in the adhesive reinforcing plate 110 as shown in FIG. It serves to primarily fix the adhesive reinforcing plate 110 to the base surface 11 of the reinforced concrete structure (10).

The size and quantity of the anchor anchor 120 is not limited to the form of the accompanying drawings, and may be appropriately changed in consideration of the shape and specifications of the adhesive reinforcing plate 110 and the seismic reinforcing steel structure 200. .

The adhesive synthetic resin 30 is filled in the space between the base surface 11 of the reinforced concrete structure 10 and the adhesive reinforcing plate 110, so that the adhesive reinforcing plate 110 is the base surface 11 of the reinforced concrete structure 10. ) To secondary fixation.

The adhesive synthetic resin 30 is injected through the synthetic resin inlet 21 provided in the sealing synthetic resin 20 sealed along the circumference of the adhesive reinforcing plate 110 as shown in FIG.

The lower end of the stud bolt 130 is welded to the upper surface of the adhesive reinforcing plate 110 is protruded toward the earthquake-resistant reinforcing steel structure 200, the standard or arrangement of the stud bolt 130 is shown in the accompanying drawings The present invention is not limited thereto, and appropriate design changes may be made in consideration of the shape and specifications of the adhesive reinforcing plate 110 or the seismic reinforcing steel structure 200.

The load transfer plate 140 has an overall plate shape as shown in FIG. 3, and the lower end surface of the load transfer plate 140 is welded to the upper surface of the adhesive reinforcing plate 110 and the load transfer plate 140 of the load transfer plate 140. The upper section is welded to the seismic reinforcing steel structure 200 to bond the bonding reinforcing plate 110 and the seismic reinforcing steel structure 200 integrally.

The load transfer plate 140 may be composed of one plate or may be composed of a plurality of plates cut to a short length although not separately shown in the accompanying drawings. In addition, the load transfer plate 140 is not limited to being arranged in one row, but may be a structure arranged side by side in two or more rows, although not shown separately in the accompanying drawings.

The load transfer reinforcing plate 160 is installed at regular intervals along both sides of the load transfer plate 140, as shown in Figure 3 serves to reinforce the load transfer plate 140.

That is, one side of the load transfer reinforcing plate 160 is welded to the side of the load transfer plate 140 and the lower end surface of the load transfer reinforcing plate 160 is welded to the upper surface of the adhesive reinforcing plate 110 and the load transfer reinforcing plate The upper cross section of the 160 is welded to the seismic reinforcing steel structure 200 is combined with the load transfer plate 140, the adhesive reinforcing plate 110 and the seismic reinforcing steel structure 200 integrally.

The load transfer plate 140 is provided with a plurality of first mortar through holes 141, the load transfer reinforcement plate 160 is provided with a plurality of second mortar through holes 161 to pass through the mortar to be poured To increase the mortar's binding capacity.

Mortar 150 is poured into the space between the seismic reinforcing plate 110 and the load transmission plate 140 welded seismic reinforcing steel structure 200 is finally cured and reinforced seismic reinforcing steel structure 200 is reinforced concrete To the structure 10.

Thus, the mortar 150 is a structure that completely covers the adhesive reinforcing plate 110, fixing anchor 120, stud bolt 130, the load transfer plate 140, and the load transfer reinforcement plate 160, the junction It will prevent the corrosion of the source.

Hereinafter, the joining method according to the present invention will be described.

(1) First step

The ground surface 11 of the reinforced concrete structure 10 to which the adhesive reinforcing plate 110 is to be attached is polished or polished.

As such a chipping process, a base surface 11 of the type shown in FIG. 4 or 5 is provided.

(2) Second step

A step of drilling the anchor hole 12 for fixing the adhesive reinforcing plate 110 to the base surface 11, which is carried out using a concrete hand drill.

The anchor hole 12 is drilled in accordance with the arrangement of the anchor through-hole 111 provided in the adhesive reinforcing plate 110.

(3) Third step

Anchor through hole 111 is provided and the fixing anchor plate 120 attached to the base surface 11, the adhesive reinforcing plate 110 welded to the stud bolt 130 on the upper surface and passed through the anchor through hole 111 Is inserted into the anchor hole 12 to attach the adhesive reinforcing plate 110 to the base surface (11). The anchor hole 12 is filled with a filler to fix the anchoring anchor 120 to the anchor hole 12, and the upper end of the anchoring anchor 120 passing through the anchor through hole 111 of the adhesive reinforcing plate 110. By fastening the nut to the first to fix the adhesive reinforcing plate 110 is not separated from the fixing anchor 120.

If extended anchors are used, no additional fillers need to be filled.

(4) 4th step

The upper cross section is a step of welding the lower cross section of the load transfer plate 140 welded to the seismic reinforcing steel structure 200 to the adhesive reinforcing plate 110.

Through such a fourth step, the seismic reinforcing steel structure 200 is integrally coupled with the adhesive reinforcing plate 110.

(5) The fifth step

The fixing anchor 120 is tightened (that is, tightened by a nut) to hold the position of the load transfer plate 140.

Deformation may occur in the form of the load transmission plate 140 or the seismic reinforcing steel structure 200 when the fourth step welding operation is performed, and the final horizontal position of the seismic reinforcing steel structure 200 through such work It will correct the distortion caused by welding by holding and vertical position.

(6) Sixth step

The periphery of the adhesive reinforcing plate 110 and the fixing anchor 120 are sealed using a synthetic resin 20 for sealing, and a synthetic resin inlet 21 and an air outlet 22 are attached to the synthetic resin 20 for sealing to bond. The preparation for injecting the synthetic resin 30 for completion is completed.

The reason for installing the air outlet 22 is to fill the space between the adhesive reinforcing plate 110 and the base surface 11 so that the interior air is discharged as the adhesive synthetic resin 30 is injected, so that no empty space is generated. To do this faithfully.

(7) Seventh step

A step of filling the empty space between the adhesive reinforcing plate 110 and the base surface 11 by injecting the adhesive synthetic resin 30 through the synthetic resin inlet (21).

Through such a process, the adhesive reinforcing plate 110 may be more firmly bonded to the base surface 11 of the reinforced concrete structure 10.

(8) The eighth step

Forming the formwork on both sides of the earthquake-resistant reinforcing steel structure 200, and filling the empty space between the formwork and the adhesive reinforcing plate 110 and the earthquake-resistant reinforcing steel structure 200 by filling the mortar (150).

Through such a process, as shown in FIG. 6, the mortar 150 is an adhesive reinforcing plate 110, a fixing anchor 120, a stud bolt 130, a load transmitting plate 140, and a load transmitting reinforcing plate ( 160 is completely covered to prevent corrosion of the joint at the source.

(9) The ninth step

Curing the mortar (150) and removing the formwork. Through this process, even if the final cross-sectional structure is completed in the joint structure as shown in Figure 6 and the earthquake load is applied, the reinforced concrete structure 10 and the seismic reinforcing steel structure 200 can be integrated as a single action to effectively absorb the seismic energy. .

The seismic reinforcing steel structure 200 may be used in various forms, Figure 7 shows some embodiments thereof.

As described above, the technical spirit of the present invention has been described with reference to specific embodiments of the present invention, but the protection scope of the present invention is not necessarily limited to these drawings or embodiments, and does not change the technical gist of the present invention. Various design changes, addition or deletion of well-known technology, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

1 (a) and (b) show the cross-sectional structure of the prior art.

2 shows a bonding structure of the adhesive reinforcing plate 110 and the stud bolt 130 as a specific embodiment of the present invention.

3 shows a coupling structure of the load transfer plate 140 and the load transfer reinforcing plate 160 as a specific embodiment of the present invention.

4 illustrates a cross-sectional structure of the adhesive reinforcing plate 110 installed on the base surface 11 of the reinforced concrete structure 10 as a specific embodiment of the present invention.

FIG. 5 illustrates a planar structure of the adhesive reinforcing plate 110 installed on the base surface 11 of the reinforced concrete structure 10 as a specific embodiment of the present invention.

Figure 6 shows a cross-sectional structure of the earthquake-resistant reinforcing steel structure joined structure completed on the base surface 11 on the reinforced concrete structure (10).

Figure 7 (a), (b) is an embodiment of the seismic reinforcing steel structure 200 to transfer the deformation of the damper 230 and the seismic reinforcing steel structure 200 to absorb the seismic load to the damper 230 Consists of a load transfer member 210, it is not limited to the form shown in the drawings and various design changes are possible.

<Description of the symbols for the main parts of the drawings>

10: reinforced concrete structure

11: base 12: anchor hole

110: adhesive reinforcing plate

111: Through the anchor

120: fixed anchor

130: stud bolt

140: load transfer plate

141: First mortar passage hall

150: mortar

160: load transfer reinforcing plate

161: The second mortar passage hall

20: Sealing synthetic resin

21: Synthetic resin inlet

22: air outlet

30: adhesive synthetic resin

Claims (5)

Relates to a joint structure in which the reinforced concrete structure 10 and the seismic reinforcement steel structure 200 are integrally coupled to each other, A plate material bonded to the surface of the base surface 11 of the reinforced concrete structure 10, the adhesive reinforcing plate 110 is provided with a plurality of anchor through holes 111 along the longitudinal direction; A plurality of fixing anchors 120 which are embedded in the anchor holes 12 drilled on the surface of the reinforced concrete structure 10 by passing through the anchor through holes 111 provided in the adhesive reinforcing plate 110; Bonding synthetic resin 30 is filled in the space between the base surface 11 of the reinforced concrete structure 10 and the adhesive reinforcing plate 110; It has a plate shape as a whole, the lower cross section is welded to the upper surface of the adhesive reinforcing plate 110, the upper cross section is a load transfer plate 140 welded to the seismic reinforcing steel structure 200; And, Mortar 150 is poured into the space between the adhesive reinforcing plate 110 and the load transfer plate 140 welded seismic reinforcing steel structure 200 is cured; Earthquake-resistant reinforcing steel structure joining structure, characterized in that comprises a. In claim 1, A plurality of stud bolts 130 having a lower end welded to an upper surface of the adhesive reinforcing plate 110 so as to protrude toward the seismic reinforcing steel frame structure 200; Earthquake-resistant reinforcing steel structure junction structure characterized in that it further comprises. The method of claim 1 or 2, One side is welded to the side of the load transfer plate 140, the lower cross-section is welded to the upper surface of the adhesive reinforcing plate 110 and the upper cross-section is a plurality of load transfer reinforcement welded to the steel structure 200 for seismic reinforcement Plate 160; Seismic reinforcement steel structure junction structure characterized in that it is further provided. 4. The method of claim 3, The load transfer plate 140 includes a plurality of first mortar through holes 141; Is provided, The load transfer reinforcing plate 160 has a plurality of second mortar through holes 161; Seismic reinforcement steel structure junction structure characterized in that it is provided. Regarding the joining method of integrally combining the reinforced concrete structure 10 and the seismic reinforcing steel structure 200, A first step of grinding the base surface 11 of the reinforced concrete structure 10 to which the adhesive reinforcing plate 110 is to be attached using a grinding machine or a planarizer; A second step of drilling an anchor hole 12 fixing the adhesive reinforcing plate 110 to the base surface 11 which is doped using the concrete hand drill; Anchor through hole 111 is provided and the fixing anchor plate 120 attached to the base surface 11, the adhesive reinforcing plate 110 welded to the stud bolt 130 on the upper surface and passed through the anchor through hole 111 Inserting into the anchor hole 12; A fourth step of welding the lower end surface of the load transfer plate 140 welded to the seismic reinforcing steel frame structure 200 to the adhesive reinforcing plate 110; A fifth step of tightening the fixing anchor 120 to hold the position of the load transfer plate 140; The circumference of the adhesive reinforcing plate 110 and the fixing anchor 120 is sealed using a synthetic resin 20 for sealing, and a synthetic resin inlet 21 and an air outlet 22 are installed in the synthetic resin 20 for sealing. Step 6; A seventh step of filling the empty space between the adhesive reinforcing plate 110 and the base surface 11 by injecting the adhesive synthetic resin 30 through the synthetic resin inlet 21; An eighth step of installing the formwork on both sides of the seismic reinforcing steel structure 200 and filling the empty space between the formwork and the adhesive reinforcing plate 110 and the seismic reinforcing steel structure 200 by filling mortar 150; And, A ninth step of curing the mortar and removing the formwork; Earthquake-resistant reinforcing steel structure joining method, characterized in that consisting of.

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