KR101600679B1 - Socket shaped anchor - Google Patents

Abstract

The present invention relates to a method for repairing, reinforcing and remodeling an aged existing building including arranging an earthquake-reinforcement device on an old concrete of an existing structure or a case of a concrete having a relatively low strength or a case where the strength of the concrete is low due to a long life of the building To a shear socket anchor applied between old concrete and new concrete.
According to another aspect of the present invention, there is provided a shear socket anchor comprising: a socket portion having a hemispherical shape with a convex upper portion and an inner hollow portion, a coupling hole penetrating through an upper center portion thereof and having a plurality of through holes; A sleeve having a cylindrical shape in which a hollow is formed, the sleeve being coupled to the hollow of the socket portion so as to communicate with the hollow; And a sleeve bolt inserted into the hollow of the sleeve to expose both ends thereof.

Description

Socket shaped anchor

The present invention relates to a shear socket anchor, and more particularly, to an anchor for a shear socket, and more particularly, to an anchor for a shear socket, and more particularly to a shear socket anchor for use in a case where an earthquake-reinforcement device is installed in an old concrete of an existing structure or a case in which the strength is relatively low And to a shear socket anchor applied between old concrete and new concrete for repair, reinforcement and remodeling of an old, deteriorated existing building.

The seismic strengthening method for existing buildings is reinforced by steel frame and reinforced by concrete.

Steel reinforcing methods include brace and moment columns, reinforcement of existing members by steel plates, and reinforcement of joints such as beams and braces, and these are used alone or in combination. Reinforcing by reinforced concrete includes reinforcement of reinforced concrete walls, reinforcement of concrete covering of pillars and braces, reinforcement of concrete fillings of steel pipe columns, and reinforcement of main parts. These are used alone or in combination.

In this case, it is very important that the existing structure and the additional member are integrated with each other. When the reinforcing device such as the vibration-damping brace is installed on the building, High joint strength and rigidity are required for the joints of new and old concrete.

 When repairing, retrofitting and remodeling an old building, including placing an anti-seismic reinforcement in an old concrete of an existing structure, or in the case of a concrete having a relatively low strength or a low strength of concrete due to a long life of the building, Dowell joints and anchor bolts are attached to the concrete, and new concrete is put in place to combine the old concrete and the new concrete.

As a background of the present invention, there is a utility model registration No. 20-0173853 entitled "Tablet pin for bonding a new and old concrete structure" (patent document 1). 8, at least one concave groove 4 is formed in the impression rod 3 behind the other barrel 2 and the boundary 5 between the other barrel 2 and the impression rod 3 is formed in a tapered shape. On the other barrel 2, Wherein the guide pin (6) made of a plastic material is inserted and joined.

However, in the background art, the type depth of the fastening pin for joining new and old concrete structures is differently defined according to the diameter of the fastening pin for joining new and old concrete structures. In the conventional case, however, the type depth is inevitably deep. Deep depths can interfere with the reinforcement during drilling and can cause damage to the structure due to large holes in the old concrete. In addition, as the number of installed parts and the depth of the embedded parts are increased, vibration and noise generated during installation are increased, and efficient construction can not be performed.

Utility Model Registration No. 20-0173853 "Tablet pin for bonding new and old concrete structures"

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a shear socket anchor in which a socket portion having a concave shape with a lower portion is coupled to an outer periphery of an upper end portion of a sleeve to which a sleeve bolt is coupled, The vertical lower part is embedded in the old concrete, and it is possible to exhibit the high shear composite force and the shear stiffness by receiving the pressure resistance against the horizontal force acting on the joint surface of the old concrete and the new concrete. Thus, the number of the existing anchor bolts can be greatly reduced The shear reinforcement performance can be effectively increased, and the depth of embedding of the existing anchor bolts can be reduced to increase the workability and workability, and the shear force to reduce the interference with other members while minimizing the damage to the old concrete, The purpose of socket anchor is to provide.

According to the present invention, there is provided a socket comprising: a socket portion having a hemispherical shape which is convex on its upper portion and has a through hole penetrating through an upper center portion thereof and formed with a plurality of through holes; A sleeve having a cylindrical shape formed with a hollow and coupled vertically such that the coupling hole of the socket portion and the hollow communicate; And a sleeve bolt inserted into the hollow of the sleeve to expose both ends thereof.

Also, a filler made of any one of concrete, high-strength mortar, epoxy, and fiber-reinforced concrete is filled in a lower portion of the socket portion from a lower end of the socket portion to a position spaced apart from the upper portion by a certain distance.

Further, it is desirable to provide a shear socket anchor in which a plurality of through-holes are formed in the socket portion.

The through hole may be formed at a predetermined position of the socket portion, or may be formed by cutting the lower end portion of the socket portion to be open.

The present invention also provides a shear socket anchor, wherein the sleeve is formed with a cut-out portion having a predetermined length in the axial direction and a sleeve bolt coupled to the sleeve is an expandable anchor bolt.

In addition, a semi-spherical main body of which the inside is hollow and whose upper and lower parts are opened or the upper and lower parts are opened so that the upper and lower parts are opened and the coupling disk is coupled with the upper part of the main body, A socket portion; A sleeve having a cylindrical shape formed with a hollow and coupled vertically such that the coupling hole of the socket portion and the hollow communicate; And a sleeve bolt inserted into the hollow of the sleeve to expose both ends thereof.

Also, a filler made of concrete, high-strength mortar, epoxy, or fiber-reinforced concrete is filled up to a lower portion of the socket portion from a lower end of the main body to a position spaced apart from the upper portion by a predetermined distance.

Also, it is desirable to provide a shear socket anchor in which a plurality of through holes are formed in the body of the socket portion.

The through hole may be formed at a predetermined position of the socket portion, or may be formed by cutting the lower end portion of the socket portion to be open.

The present invention also provides a shear socket anchor, wherein the sleeve is formed with a cut-out portion having a predetermined length in the axial direction and a sleeve bolt coupled to the sleeve is an expandable anchor bolt.

Further, it is desirable to provide a shear socket anchor in which at least one air hole is formed in the coupling disk.

The shear socket anchor of the present invention is characterized in that a socket portion having a concave shape at the bottom is joined to an outer periphery of an upper end portion of a sleeve to which a sleeve bolt is coupled so that the axial end surface of the sleeve bolt is increased and the vertical lower end portion of the socket portion is embedded in the old concrete, Shear strength and shear stiffness by allowing the shear resistance to be applied to the horizontal force acting on the joint surface between the new concrete and the new concrete so that the number of existing anchor bolts can be greatly reduced and the shear reinforcement performance can be effectively increased It is possible to reduce the depth of the existing anchor bolts to increase the workability and workability and to minimize the damage of the old concrete while reducing the interference with other members, thereby achieving an efficient construction.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is a view showing an embodiment in which a shear socket anchor of the present invention is applied.
2 is a perspective view showing a first embodiment of the present invention.
3 is a cross-sectional view of a state in which the first embodiment of the present invention is applied to an old concrete 100. FIG.
4 is a perspective view showing a second embodiment of the present invention
5 is a perspective view of the socket portion 10a of the other embodiment of FIG.
6 is an exploded perspective view showing a state of engagement with the member to be bonded of the second embodiment of the present invention and a cross-sectional view of the state of the construction.
7 is a view for explaining the shear resistance at the time of construction of the shear socket anchor of the present invention.
8 is a perspective view showing one embodiment of a conventional tattoo pin for coupling a new and old concrete structure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

 Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

1 is a view showing an embodiment in which a shear socket anchor of the present invention is applied.

As shown in FIG. 1, the shear socket anchor 1 (1a) of the present invention is constructed by inserting and fixing the lower end portion of the socket portion 10 (10a) into the old concrete 100 and inserting the new concrete 200 . In this way, it can be used when placing the seismic retrofitting apparatus 300 on the old concrete 100 of the existing structure, and also in the case of the concrete having a relatively low strength or the case where the strength of the concrete is low due to the long life of the building. It can also be used for repairing, reinforcement and remodeling of existing buildings, or for the purpose of building walls.

The present invention relates to a socket 10 having a hemispherical or cylindrical shape with a concave bottom and a bottom open and a hollow cylindrical sleeve 20 coupled to the socket 10, And a sleeve bolt 30 which is exposed at both ends.

The shear socket anchor 1 of the present invention is configured such that the socket portion 10a having a concave shape at the bottom is joined to the outer periphery of the sleeve 20 to which the sleeve bolt 30 is coupled, 30 and the lower ends of the sockets 10 and 10a are embedded in the old concrete 100 so as to be subjected to shear resistance so that high shear strength and shear rigidity can be exhibited, It is possible to effectively increase the shear reinforcement effect while reducing the depth of embedding of the anchor, thereby reducing the interference with other members such as the stud or the anti-shear bar.

The present invention has the same configuration as the first embodiment and the second embodiment, but differs only in the shape of the socket portions 10 and 10a. In the first embodiment, the socket portion 10 is formed in a hemispherical shape in which the inside is hollow. In the second embodiment, a disk-shaped coupling disk 15a is coupled to the upper portion of the socket portion 10a, 15a to facilitate the joining of members to be joined such as the H-shaped section 400. FIG.

The first embodiment and the second embodiment will be described in detail with reference to the drawings.

2 is a perspective view showing a first embodiment of the present invention.

The sleeve 20 has a hemispherical shape with a convex upper portion and an upper portion. The sleeve 20 has a cylindrical shape and an upper end is vertically coupled to a central portion of the socket portion 10. And a sleeve bolt 30 to be inserted.

The socket portion 10 is formed in a hemispherical shape having an upper convex interior and an insertion hole 11 formed vertically in the center portion. When the socket portion 10 is formed in a hemispherical shape, the new concrete 200 can be installed to maximize the area of the end portion contacting the new concrete 200 at the time of embedding.

Since the end portion of the socket portion 10 is hemispherical in shape, the end portion of the socket portion 10 may not be embedded at a right angle with the old concrete 100, so that the socket portion 10 may extend vertically downward from the lower end portion of the socket portion 10, The lower end portion of the socket portion 10 can be easily inserted into the old concrete 100 by making the rectangular portion 100 perpendicular to the old concrete 100 when the socket portion 10 is embedded.

The socket portion 10 is formed in a hemispherical shape having an empty interior, and the through-hole 12 may be formed, or the through-hole may not be formed. If the lower end of the socket portion 10 is fixed to the old concrete 100, the lower portion of the socket portion 10 is emptied when the new concrete 200 is poured, unless the socket portion 10 has a separate through- So that a high shear strength and shear rigidity can not be exhibited.

Therefore, as shown in FIG. 3A, the filling material 40 is filled in the lower portion of the socket portion 10. [ That is, the filler 40 is filled in the lower portion of the socket portion 10 to a position spaced apart from the lower end of the socket portion 10 by a predetermined distance.

The filler 40 is only filled up to a portion spaced a certain distance from the lower end of the socket portion 10 without completely filling the bottom of the socket portion 10 so that the lower end of the socket portion 10 is inserted into the old concrete 100 To be fixed.

The filling material 40 may be made of ordinary concrete, or may be reinforced by using any one of high strength mortar, epoxy, and fiber reinforced concrete.

Also, as shown in FIG. 3B, a plurality of through-holes 12 may be formed in the socket portion 10. The through hole 12 is formed in order to smoothly flow the concrete when the socket portion 10 is fixed to the old concrete 100 and the new concrete 200 is poured and is combined with the new concrete 200, And shear stiffness.

The construction procedure of the present invention will be described with reference to FIG.

The anchor bolt insertion hole is formed in the anchor bolt insertion hole and the lower end of the socket portion 10 is inserted into the groove of the anchor bolt insertion hole and the lower end insertion groove of the socket portion 10, The filling filler 50 is filled.

3A, when the through hole is not provided, the filler 50 is filled in the lower portion of the socket portion 10, and when the lower end portion of the socket portion 10 is fixed to the old concrete 100, The filler material 50 may be separately filled in the anchor bolt insertion hole where the groove and the sleeve bolt 30 are inserted in the portion where the lower end of the socket 10 is to be inserted, And the filling filler 50 is also filled between the lower surface where it is located and the old concrete 100.

3B, when the through hole 12 is formed, the gap between the groove and the old concrete 100 and the gap between the groove and the sleeve bolt 30 are formed in the portion where the lower end of the socket portion 10 is to be fitted So that the injected filler 50 is charged separately in the inserted bolt insertion hole.

Thereafter, the lower end of the socket section 10 of the shear socket anchor 1 of the present invention is inserted and fixed.

Thereafter, the anchor bolt 60 is passed through the coupling hole 11 of the front end socket anchor 1 and is fixed to the anchor bolt insertion hole.

Finally, although not shown, the new concrete 200 is placed on the upper portion of the old concrete 100 to be completed.

As shown in FIG. 2A, the through-hole 12 may be formed at a predetermined position of the socket unit 10, or may be formed to be opened so that the lower end of the socket unit 10 is opened, as shown in FIG. 2B.

A cylindrical sleeve 20 is vertically coupled to the lower end of the socket portion 10. The sleeve 20 has a long cylindrical shape and a hollow portion 21 is formed at the center of the socket portion 10, 11 and the hollow 21 of the sleeve 20 have the same size. The hollow 21 is configured to insert a sleeve bolt 30 to be described later.

The sleeve 20 may be configured such that the upper end of the sleeve 20 is coupled to the lower end of the socket 10 so that the coupling hole 11 of the socket 10 is aligned with the hollow 21 of the sleeve 20, The upper end of the sleeve 20 may protrude from the upper end of the sleeve 10.

The length of the sleeve 20 projecting downward from the socket 10 may be longer or shorter than the outer lower end of the socket 10 and may be the same height as the outer lower end of the socket 10.

The sleeve bolt 30 is formed through the coupling hole 11 of the socket portion 10 and the hollow 21 of the sleeve 20. [

The sleeve bolt 30 is inserted into the hollow 21 of the sleeve 20 so that both ends are exposed.

The sleeve bolt 30 is inserted into the hollow 21 of the sleeve 20 so that both ends are exposed. Various types of anchor bolts, rebars, rib bolts, etc. may be used for the sleeve bolts 30. Since the sleeve bolts 30 are required to be assembled through the bolt insertion holes in the old concrete 100, Or an expansion anchor should be used.

As the expansion anchor, a sleeve anchor, a shell expansion anchor, a wedge anchor, a rock / concrete expansion anchor, a drop in anchor, a sleeve anchor, a sleeve anchor, , Self drilling anchors, stud anchors, undercut anchors, and so on.

An expansion anchor is also called an expanding anchor (hereinafter referred to as an expanding anchor) and inflates in the bolt insertion hole when the anchor is fixed. Therefore, it is preferable to use the expandable anchor since the sleeve bolt 30 can be inserted into the bolt insertion hole and expanded and easily fixed.

Examples of the method of expanding an expandable anchor include a method of tightening a nut such as an expansion anchor for torque control, a method of applying an impact to an anchor by a hammer such as an expansion anchor for expansion, and an undercut formed in concrete such as an undercut anchor .

The expansion anchor can transmit the tensile force of the sleeve bolt 30 to the old concrete 100 by the inflation pressure, the friction force, the side effect of the bolt insertion hole, and the like.

In order to use the expandable anchor as described above, the sleeve 20 should be formed with a cut-out portion 22 having a predetermined length in the axial direction at the lower end, as shown in FIG. 2C.

In addition, a nut may be formed at the upper end of the sleeve bolt 30 so as to be detachable. When the nut is constructed as described above, the seismic strengthening device or the like can be coupled to the sleeve bolt 30 and fixed with the nut before the new concrete 200 is poured.

3 is a cross-sectional view of a state in which the first embodiment of the present invention is applied to an old concrete 100. FIG.

3, the lower end portion of the socket portion 10 and the lower end portion of the sleeve 20 are embedded in the old concrete 100, and the sleeve bolt 30 is inserted through the sleeve 20 to be engaged. (10) is formed in a hemispherical shape so that the new concrete (200) can be laid down to enlarge the end surface area that contacts the new concrete (200) at the time of embedding, and the through hole (12) is formed in the socket part The through hole 12 smoothes the inflow of the concrete when the new concrete 200 is poured, so that it can be combined with the new concrete 200 to exhibit high shear strength and shear stiffness.

Fig. 4 is a perspective view showing a second embodiment of the present invention, and Fig. 5 is a perspective view of a socket portion 10a of another embodiment of Fig.

Since the shapes of the socket portions 10 and 10a differ only in the first and second embodiments, the description of the second embodiment will focus on the socket portion 10a excluding the sleeve 20 and the sleeve bolt 30 do.

4, the socket portion 10a includes a disk-shaped coupling disk 15a and a main body 16a coupled to the lower portion of the coupling disk 15a.

The main body 16a has a columnar shape or a convex hemispherical shape. When the main body 16a is formed into a hemispherical shape, the top portion of the main body 16a is cut off for coupling with the coupling disc 15a.

That is, the main body 16a is formed to have a cylindrical shape with an open top and bottom, or a hemispherical shape with an open top and bottom so that the top and bottom portions thereof are opened so that the socket portion 10a is shaped like an inverted bowl, It is possible to maximize the area of the end portion contacting the new concrete 200 when the new concrete 200 is installed.

The coupling disc 15a is formed in a plate shape having a predetermined thickness and has a coupling hole 11a formed at the center thereof and coupled to the upper portion of the main body 16a to close the upper portion of the main body 16a.

The coupling hole 11a is configured to penetrate through the sleeve bolt 30.

The socket portion 10a is formed in a shape in which the bottom of the socket is turned upside down and the main body 16a has a plurality of through holes 12a or no through holes. If the lower end of the socket portion 10a is fixed to the old concrete 100 without forming another through hole in the socket portion 10a, the lower portion of the socket portion 10a is emptied when the new concrete 200 is poured, So that a high shear strength and shear rigidity can not be exerted.

Therefore, although not shown, the filler 40 may be filled in the lower portion of the socket portion 10a, as in the first embodiment. That is, the filler 40 is filled in the lower portion of the socket portion 10a from the upper end of the main body 16a to a position spaced apart from the lower end of the main body 16a by a predetermined distance.

Filling the filler 40 only up to a portion spaced upward from the lower end of the main body 16a without filling the lower portion of the socket portion 10a completely requires that the lower end of the socket portion 10, So as to be fitted and fixed to the concrete 100.

The filling material 40 may be made of ordinary concrete, or may be reinforced by using any one of high strength mortar, epoxy, and fiber reinforced concrete.

In addition, a plurality of through-holes 12a may be formed in the main body 16a. The through hole 12a is formed to fix the socket portion 10a to the old concrete 100 and to smooth the inflow of the concrete when the new concrete 200 is poured. The through hole 12a is combined with the new concrete 200, And shear stiffness.

4A, the through hole 12a may be formed in a predetermined position of the socket portion 10a, or may be formed so as to be opened so that the lower end of the socket portion 10a is opened as shown in FIG. 4B have.

4, the main body 16a may be formed in a hemispherical shape having an upper portion opened so as to have upper and lower portions, and may have a cylindrical shape with upper and lower portions opened as in Fig. In addition, the length of the main body 16a may be configured differently depending on the construction environment as shown in Figs. 5A and 5B.

A cylindrical sleeve 20 is vertically coupled to the lower end of the socket portion 10a. The sleeve 20 has a long cylindrical shape and a hollow 21 is formed at a central portion thereof. 11a of the sleeve 20 and the hollow 21 of the sleeve 20 are the same. The hollow 21 is configured to allow the sleeve bolt 30 to be inserted.

The upper end of the sleeve 20 is coupled to the lower end of the coupling disk 15a of the socket portion 10a so that the coupling hole 11a of the socket portion 10a and the hollow 21 of the sleeve 20 coincide with each other. And the sleeve bolt 30 is formed through the coupling hole 11a of the socket portion 10a and the hollow 21 of the sleeve 20. [

6 is an exploded perspective view showing a state of engagement with the member to be bonded of the second embodiment of the present invention and a cross-sectional view of the state of the construction.

6A, the planar coupling disk 15a is formed on the upper portion of the socket portion 10a to facilitate coupling of the members to be joined such as the H-shaped portion 400 to the coupling disk 15a.

As shown in FIG. 6B, an embodiment of the construction procedure d of the shear socket anchor 1a according to the second embodiment of the present invention will be described as follows.

First, an anchor bolt insertion hole is formed in the old concrete 100 by various known methods, a groove is formed at a portion where the lower end of the socket portion 10 is to be inserted, with the anchor bolt insertion hole being centered, and the anchor bolt insertion hole and the socket portion 10) Filling the injection filler 50 into the lower end insertion groove.

Thereafter, the lower end of the socket section 10 of the shear socket anchor 1a of the present invention is inserted and fixed, and the anchor bolt 60 is inserted into the anchor bolt insertion hole through the fitting hole 11a of the front end socket anchor 1a And fix it.

Thereafter, the H-shaped beam 400 is closely attached to the coupling disk 15a of the front end socket anchor 1a and fixed to the anchor bolt 60 with a nut. Finally, a new concrete 200 are installed and completed.

In addition, at least one air hole 17a may be formed in the coupling disk 15a. The formation of the air hole 17a in this manner is for discharging air to the outside easily when the new concrete 200 is filled in the socket portion 10a so that the air hole 17a can be filled tightly . The air holes 17a may be formed by one or more holes.

Since the shear socket anchor 1 (1a) of the present invention is constructed by inserting the sleeve (20) at the outer periphery of the sleeve bolt (30), the shaft end face increases and high shear strength and shear rigidity can be exhibited.

7 is a view for explaining the shear resistance at the time of construction of the shear socket anchor of the present invention.

That is, as shown in FIG. 7, the lower end portion of the socket portion 10a is embedded in the old concrete 100 so that the shear resistance (1, 2) The shear socket anchor 1 (1a) of the present invention can exhibit a higher shear strength and shear rigidity than the conventional shear connector.

As described above, in the shear socket anchor of the present invention, the lower end portion of the socket upper end portion of the sleeve upper portion to which the sleeve bolt is coupled is coupled to the lower end portion of the socket portion to increase the axial end surface of the sleeve bolt, Shear strength and shear stiffness by making it possible to reduce the number of existing anchor bolts and to improve the shear reinforcement performance of the existing anchor bolts. It is possible to effectively increase the thickness of the anchor bolt and reduce the depth of the existing anchor bolt to increase the workability and workability and minimize the damage of the old concrete while reducing the interference with other members.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

1, 1a: Shear socket anchor
10, 10a:
11, 11a:
12, 12a:
15a: Combined disk
16a:
17a: Air hole
20: Sleeve
21: hollow
22: incision
30: Sleeve bolt
100: Old concrete
200: New concrete
300: Seismic strengthening device
400: H beam

Claims (11)

(12) having a through hole (11) formed at an upper center portion thereof and having a through hole formed at a predetermined position or a lower end portion of the through hole (12) (10);
A sleeve 20 having a cylindrical shape with a hollow 21 formed therein and coupled vertically such that the coupling hole 11 of the socket 10 communicates with the hollow 21;
And a sleeve bolt (30) inserted into the hollow (21) of the sleeve (20) to expose both ends thereof. The method according to claim 1,
A filling material 40 made of any one of concrete, high strength mortar, epoxy, and fiber reinforced concrete is filled up to a position spaced apart from the lower end of the socket portion 10 by a predetermined distance, Socket anchor. delete delete The method according to claim 1,
The sleeve 20 is formed with a cut-out portion 22 of a shape cut in an axial direction of a predetermined length at a lower end,
Wherein the sleeve bolt (30) coupled to the sleeve (20) is an expandable anchor bolt. (12a) formed in a cylindrical shape having an open top and bottom or a hemispherical shape having an open top and bottom and cut at an upper portion and formed at a predetermined position or cut open at a lower end, And a coupling disc 15a coupled to an upper portion of the main body 16a to close an upper portion of the main body 16a in a disc shape having a coupling hole 11a at the center thereof.
A sleeve 20 having a cylindrical shape formed with a hollow 21 and coupled vertically such that the coupling hole 11a of the socket portion 10a and the hollow 21 are communicated with each other;
And a sleeve bolt (30) inserted into the hollow (21) of the sleeve (20) to expose both ends thereof. The method of claim 6,
A filling material 40 made of any one of concrete, high-strength mortar, epoxy, and fiber-reinforced concrete is filled up to the lower portion of the socket portion 10a from the lower end of the main body 16a to a position spaced apart by a predetermined distance. anchor. delete delete The method of claim 6,
The sleeve 20 is formed with a cut-out portion 22 of a shape cut in an axial direction of a predetermined length at a lower end,
Wherein the sleeve bolt (30) coupled to the sleeve (20) is an expandable anchor bolt. The method of claim 6,
Characterized in that at least one air hole (17a) is formed through the coupling disc (15a).

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