KR101902259B1 - Firefighting earthquake-resistant shaking prevention struting supporter concrete fixing structure of anchor bolt protrusion type - Google Patents

Abstract

The present invention provides a firefighting earthquake-resistant shaking prevention strut concrete fixing device of an anchor bolt protrusion type. The firefighting earthquake-resistant shaking prevention strut concrete fixing device of an anchor bolt protrusion type comprises: a base anchor bolt (10) in which a part is embedded on concrete which is supported and placed by a cast (3), and the remaining part passes through a through hole (3H) formed on the cast (3) and protrudes from an outer surface of the cast (3); and a hanger part (14) provided on the base anchor bolt (10), and hooked to a rebar (2) reinforced for concrete construction. When removing the cast (3), the part of the base anchor bolt (10) is removed from the through hole (3H) of the cast (3) and protrudes from a surface of the concrete. Therefore, the present invention does not need to perforate a slab with a drill to install the anchor bolt on the slab, thereby preventing serious accidents of reducing stability of a building by cutting the rebar embedded in the slab in the process of perforating the slab or generating a short by cutting an electric wire by penetrating an electric wire pipe.

Description

FIELD OF THE INVENTION [0001] The present invention relates to an anchor bolt protrusion type fireproof earthquake-resistant shaking prevention strut-

The present invention relates to an anchor bolt protruding type fireproof anti-vibration and anti-shake brace concrete securing apparatus, and more particularly, to a fireproof anti-shake brace concrete securing apparatus using an anchor bolt, The present invention relates to an anchor bolt protruding type fire-resistant seismic shake prevention brace concrete securing device, which is capable of joining an anti-shake brace material to a protruding base anchor bolt.

In many cases, seismic anchor bolts are used to fix the anti-shake braces to concrete. The concrete is drilled using a drill, and then the anchor bolt is attached to the perforation hole formed in the concrete.

The anti-shake brace is a structure such as a piping support that fixes important facilities of a building such as piping to a concrete such as a slab. After the hole is punched in the concrete, an anti-seizing anchor bolt is inserted and the seismic anchor bolt is tightened And an anti-shake brace is fixed to the anti-seize anchor bolt in a state where the anti-shake brace is supported by a facility such as a pipe, so that facilities such as piping are installed on the concrete with anti-shake braces.

At this time, there is a slab of the building in the concrete, and when the slab is built in the building, the slab reinforcement is arranged, the mold such as the euro foam and the wood block is placed on the outside of the reinforced bars, and then the concrete mortar is hardened . The concrete mortar placed inside the mold is hardened to form the slab of the building. At this time, various pipings are embedded in the slab of the building, and there are electric line pipes and water pipelines in which the electric lines enter the piping. In this way, the slab of the building is supplied with auxiliary facilities of important buildings such as electric cable piping.

On the other hand, there are many cases where important piping is installed under the slab of the building. An anchor bolt is installed on the slab to install the pipe under the slab, and a pipe such as a hanger supporting the pipe is connected to the anchor bolt to install the pipe under the slab. In addition to the piping, there are many other ceiling structures required for the building, but the ceiling structures other than the piping are also installed under the slab using anchor bolts installed on the slabs and supports such as the hanger.

At this time, in order to install the anchor bolts in the slab, the anchor bolt holes are drilled from the lower surface of the slab to a predetermined depth in the slab by using a drilling device such as a drill. Next, the anchor bolts are installed in the slabs by engaging the anchor bolts with the anchor bolt holes drilled in the slabs.

Conventionally, in order to install the anchor bolts on the slabs, drilling the slabs with drills cuts the reinforced bars embedded in the slabs, thereby reducing the stability of the buildings, or cutting through the conduits to cut off the electric wires. There are problems that cause serious accidents. If the rebar that has already been buried in the slab is damaged or the conduit is damaged, the slab must be re-opened to re-reinforce the steel bar or replace the wire. In this way, reworking of the slab and re- Even if the rebar is reworked or the wire is replaced by re-opening the slab, it is very undesirable in terms of economy and construction. Particularly, in order to install a weight structure such as a pipe under a slab, an anchor bolt must be deeply embedded in the slab, so that the slab should be punched at least 7 cm or more from below to form an anchor bolt hole. As a result, the reinforcing bars or the wires are often damaged when the anchor bolt hole is punctured by 7 cm or more in the slab. That is, the disadvantage of the anchor type (including the anchoring anchor type) in which the existing anchor bolts are installed on the concrete is that the penetration depth to which the anchor bolts should be inserted after drilling is 7 cm or more on average, It is often the case that the stability of buildings is degraded or holes in the electrical, telecommunication, and fire-fighting conduits are buried, making the use of conduits impossible.

Korean Registered Patent No. 10-0675814 (registered on Mar. 23, 2007) Korean Patent Laid-Open No. 10-2017-0099590 (published on September 1, 2017) Korean Registered Patent No. 10-0916185 (registered on September 1, 2009)

SUMMARY OF THE INVENTION The present invention has been developed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method of installing a concrete slab and a concrete anchor bolt in a building slab by connecting a base anchor bolt to a reinforcing bar in advance, The remaining part of the base anchor bolt protruding outward from the surface of the concrete is passed through the through hole of the formwork so that the base anchor bolt protruding from the concrete after disassembling the form can be prevented from shaking And to provide a new structure of anchor bolt protruding type fire-resistant seismic shake prevention brace concrete fixing device that can be installed by connecting a brace.

According to an aspect of the present invention, there is provided a floor anchor system comprising: a base anchor bolt partially embedded in a concrete supported in a formwork and partially protruded from an outer surface of the form through a through hole formed in the formwork; The anchor bolt protruding type anchor bolt protruding type fireproof anti-seismic and anti-shake brace concrete securing device is provided in the base anchor bolt and is attached to reinforcing bars arranged for concrete construction.

A part of the base anchor bolt protrudes from the through hole of the concrete mold and protrudes from the surface of the concrete and connects the anti-shake brace to the base anchor bolt protruded from the surface of the concrete .

And the hanger part is integrally connected to the upper end of the base anchor bolt.

And an upper end portion of the base anchor bolt is coupled with a buried sleeve, and the hanger portion is connected to an upper end portion of the buried sleeve.

And a stopper coupled to an outer circumferential surface of the base anchor bolt for blocking a gap between the outer circumferential surface of the base anchor bolt and the through hole of the die.

The base anchor bolt is formed in the shape of a straight bolt, the adjustment anchor bolt is coupled to the adjustment anchor bolt, and the hanger part is provided at an upper end of the adjustment anchor bolt.

According to the present invention, it is not necessary to drill the slab by a drill to install the anchor bolt on the slab. Therefore, in the process of drilling the slab, the reinforcing bars embedded in the slab are cut to reduce the stability of the building, It is possible to expect an effect of preventing a serious accident such as a short-circuit by breaking in the electric wire.

The above effect corresponds to the main effect of the present invention, and it will be understood that the present invention has various desirable effects in addition to the above effects.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a fireproof earthquake-proof anti-shake brace stiffener concrete anchor bolt protrusion according to a first embodiment of the present invention;
2 is a perspective view showing a state in which an anchor bolt protruding type anti-earthquake-proof anti-shake brace concrete fixing device according to a first embodiment of the present invention is installed between a reinforcing bar and a formwork
3 is a longitudinal sectional view showing a state in which the anchor bolt protruding type fire-resistant anti-vibration and anti-shake brace concrete securing apparatus shown in FIG. 2 is hooked on a reinforcing bar to pass through a through hole of a mold
4 is an enlarged longitudinal sectional view showing a part of the anchor bolt protruding type anti-earthquake-proof anti-shake brace concrete fixing device shown in Fig. 3
5 is a longitudinal sectional view partially enlarging a state in which the anchor bolt protruding type fire-resistant anti-vibration and anti-shake brace concrete securing apparatus according to the first embodiment of the present invention is embedded in a ceiling slab;
6 is a perspective view of a fireproof anti-seismic and anti-shake brace stiffener concrete anchor bolt protrusion according to a second embodiment of the present invention.
FIG. 7 is a longitudinal sectional view showing a state in which the anchor bolt protruding type fire-resistant seismic shake prevention brace concrete securing apparatus shown in FIG. 6 is hooked on a reinforcing bar so as to pass through a through hole of a mold
8 is a longitudinal sectional view of a fireproof earthquake-proof anti-shake bracing brace concrete anchoring bolt protrusion according to a third embodiment of the present invention
9 is a longitudinal sectional view showing a state in which the anchor bolt protruding type anti-earthquake-proof anti-shake brace concrete fixing device shown in FIG. 8 is embedded in a ceiling slab;
10 is a longitudinal sectional view showing a state in which a cap and a formwork are removed from an anchor bolt protruding type fire-proof anti-vibration and anti-shake brace concrete fastening apparatus shown in FIG.
11 is a vertical sectional view showing a state in which an anchor bolt protruding type fireproof anti-vibration and anti-shake brace concrete securing apparatus according to a fourth embodiment of the present invention is embedded in a ceiling slab (a state in which a cover tube is coupled to a cap,
12 is a longitudinal sectional view showing a state in which the cover tube and the form are dismantled as shown in Fig.
13 is a longitudinal sectional view showing a state in which an anchor bolt protruding type anti-earthquake-proof anti-shake brace concrete fixing device according to a fifth embodiment of the present invention is embedded in a slab;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. For example, if a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, It is to be understood that other components may be "connected "," coupled "

Referring to the drawings, an anchor bolt protruding type fireproof seismic shake prevention brace frame fixing apparatus according to the present invention is characterized in that a base anchor bolt 10 is engaged with a reinforcing bar 2 by a row rejection 14, 10 is embedded in a concrete such as a ceiling slab 4 and the remaining part of the base anchor bolt 10 passes through a through hole 3H formed in the formwork 3, 3 is removed, an anti-shake brace is connected to the base anchor bolt 10 protruded to the surface of the concrete. The present invention can be said to be a concrete-embedded type fire-proof earthquake-proof anti-shake brace concrete fixing device through a die (3). Meanwhile, it should be understood that the slab 4 belongs to one kind of concrete referred to in the present invention. In the following description, it is to be understood that concrete and slab 4 are used in combination.

The base anchor bolt 10 is formed in a straight bar shape. The outer peripheral surface of the base anchor bolt 10 is provided with threads.

The row rejection 14 is provided in the base anchor bolt 10. In one embodiment of the present invention, row rejection 14 is integrally connected to the upper end of base anchor bolt 10. The row rejection unit 14 is constructed such that the base anchor bolt 10 is supported by the reinforcing bar 2 by supporting the base anchor bolt 10 on the reinforced bar 2 laid for the concrete construction. The proximal end of the row rejection 14 is connected to the upper end of the base anchor bolt 10.

The row reject 14 is formed in an annular shape and a hanging hole 16 for fitting the reinforcing bar 2 is provided inside the row reject 14. The hanger hole 16 may be communicated to one side of the row reject 14 so that the row reject 14 is inserted into the reinforcing bar 2 from the side of the reinforcing bar 2. [ That is, the row reject 14 connected to the base anchor bolt 10 can be inserted next to the reinforcing bar 2. The row rejection 14 is caught by the reinforcing bars 2 laid in the inner area of the formwork 3 so that the base anchor bolts 10 are engaged with the reinforcing bars 2. [ Generally, a pair of parallel molds 3 are installed to place a concrete mortar for forming a slab 4 of a building, wherein the reinforcing bars 2 are laid in an inner area between a pair of side molds 3 The row reject 14 is inserted into the reinforcing bars 2 and the base anchor bolts 10 are installed in the area inside the form 3. [ A part of the base anchor bolt 10 is disposed in a concrete mortar placement space formed inside the form 3 and the remaining part of the base anchor bolt 10 is provided with a through hole 3H And protrudes from the outer surface of the form 3.

The outer circumferential surface of the base anchor bolt 10 is provided with threads. The base anchor bolt 10 has a bar shape with a circular section, and a thread is formed along the outer peripheral surface of the base anchor bolt 10.

The base anchor bolt 10 is fixed by hanging the row reject 14 provided on the base anchor bolt 10 to the reinforcing bar 2 provided in the formwork 3, A part of the base anchor bolt 10 is in a state of passing through the through hole 3H formed in the formwork 3. In this state, when the concrete mortar is placed in the area inside the formwork 3, A portion of the base anchor bolt 10 is embedded in the slab 4 and the remaining portion of the base anchor bolt 10 not buried in the slab 4 is inserted into the slab 4 As shown in Fig.

The anti-vibration anti-shake brace may be mounted in a state where a part of the base anchor bolt 10 protrudes from the outer surface of the concrete (ceiling slab 4 or the like). The anti-earthquake-proof anti-shake brace may be a hanger ring body for fixing building facilities such as piping installed under the slabs 4. When the anti-shake brace for supporting a building facility such as the outer pipe of the slab 4 is coupled to the base anchor bolt 10 protruding downward from the slab 4, The facility can be installed.

In the case of the present invention, the slab 4 is installed by placing the concrete mortar in the mold 3 and hardening the slab 4, and after the slab 4 is removed, the mold 3 is removed, So that a portion of the base anchor bolt 10 from the upper end to the lower end thereof is partially embedded. When a part of the base anchor bolt 10 is embedded in the slab 4 constituting the ceiling of the building, the remaining part of the base anchor bolt 10 (the outer surface of the slab 4 and the base anchor bolt 10) may protrude toward the lower surface of the slab 4. [0031] In this state, the anti-shake brace may be coupled to the base anchor bolt 10 as described above.

The effect of the anchor bolt protruding type fireproof seismic shake prevention brace concrete fixing device of the present invention having the above-described construction is as follows.

It is not necessary to drill the slab 4 to drill the slab 4 in order to install the anchor bolt on the slab 4 so that the reinforcing bar 2 embedded in the slab 4 is cut in the process of drilling the slab 4 There is an effect of preventing a serious accident such as shortening the stability of the building or penetrating the conduit and cutting off the electric wire. It is not necessary to drill at least 7 cm or more from the lower surface of the slab 4 by the drilling process so that the rebar 2 or the wire buried in the slab 4 is not damaged at all during drilling, 2) is cut off and the stability of the building is lowered, or holes buried in the conduction pipes for electric, telecommunication, and fire which are buried do not occur at all.

In the process of drilling slabs (4), due to the damage of the reinforcing bars (2) already buried in the slabs (4) or damage of the conduits, the slabs (4) must be re-opened and the rebar (2) It is possible to completely prevent the real difficulties due to the work such as the rework of the slabs 4 and the replacement of the wires and to prevent the economic loss due to the removal and rework of the slabs 4, the waste of the workforce, It can be prevented in advance.

In the present invention, the row rejection 14 is performed in a ring shape so that the row rejection 14 is hooked on the reinforcing bar 2 like a ring so that one end of the base anchor bolt 10 is connected to the reinforcing bar 2, Since the other end of the anchor bolt 10 can be connected to the formwork 3, there is a quick and convenient effect when the base anchor bolt 10 is installed in the reinforcing bar 2.

When the rebar 2 enters the hanger hole 16 formed in the row reject 14 and the row reject 14 is caught in the reinforcing bar 2, The lower hanger ring portion 14A is caught under the reinforcing bar 2 so that the row rejection 14 is prevented from falling to the upper side of the reinforcing bar 2 and the row rejection 14 The upper hangers 14B of the upper hangers 14B are supported on the upper surface of the reinforcing bars 2 so that the lowering of the reinforcing bars 2 in the downward direction of the reinforcing bars 2 . So that the base anchor bolts 10 are prevented from being separated from the upper and lower sides of the reinforcing bar 2.

In the present invention, the row reject 14 provided in the base anchor bolt 10 is connected to the reinforcing bars 2 disposed in the inner area of the form 3 via fixing means, Can be fixed to the reinforcing bar (2).

At this time, the fixing means may be any one of a welding portion for fixing the row reject 14 to the reinforcing bar 2, a binding wire, a clamp, and a reinforcing bar 2 coupling hole communicated with one side inside the row rejecting portion 14 have.

In the case of the welded portion, the row rejection 14 is welded to the reinforcing bar 2 and joined. When the row rejection 14 is fixed to the reinforcing bar 2 by the welding portion, the row rejection 14 does not fall off the reinforcing bar 2 unless the welding portion is intentionally broken during the operation.

The binding wire is a structure in which the row reject 14 is fixed to the reinforcing bar 2 by a wire. Since the binding wire is fastened to the reinforcing bars 2 in such a manner as to bind the row reject 14, it can be said that the bonding strength is higher when compared with the welded portion.

The clamp grips the row reject 14 and the reinforcing bar 2 and fixes the row reject 14 to the reinforcing bar 2. [ If the clamp is used, the reinforcing bar 2 and the row rejection 14 can be connected simply and quickly.

The reinforcing bar 2 coupling hole is formed in a bar shape in which the row reject 14 is connected to the base anchor bolt 10 so that the row reject 14 is pushed from the side of the reinforcing bar 2, (2). The reinforcing bars 2 are opened to the side of the row reject 14 in the row reject 14 so that the row reject 14 is disposed next to the reinforcing bars 2, When the hole is pushed into the reinforcing bar 2, the row rejection 14 can be coupled to the reinforcing bar 2. When the reinforcing bars 2 are formed in the row rejection 14 and the row rejection 14 is coupled to the reinforcing bar 2, the row rejection 14 is inserted between the reinforcing bars 2, It can be done simply.

In the other embodiment of the present invention, the row reject 14 is formed in a ring shape, and the base end of the row reject 14 is connected to the upper end of the base anchor bolt 10, An extension bar 18 extending downward is further provided.

The proximal end of the extension bar 18 is integrally connected to the distal end of the row rejection 14. The distal end of the extension bar 18 extends downward toward the base anchor bolt 10.

The row reject 14 has a lower hanger ring portion 14A and an upper hanger ring portion 14B and in addition an extension bar 18 is connected to the row reject 14.

The structure of the row rejection 14 and the extension bar 18 in a state where the base anchor bolt 10 is set up in the vertical direction will be described.

The proximal end of the lower hanger ring part 14A is connected to the upper end of the base anchor bolt 10. The lower hanger ring portion 14A is extended eccentrically to one side from the center line of the base anchor bolt 10 in the vertical direction. And the lower hanger ring portion 14A protrudes from the base anchor bolt 10 to one side. And the lower hangers ring part 14A is attached to the lower hook in the row reject 14.

The proximal end of the upper hanger ring part 14B is connected to the distal end of the lower hanger ring part 14A. The upper hanger ring portion 14B is disposed in a direction facing the lower hanger ring portion 14A. And the upper hanger ring portion 14B is attached to the upper ring in the row reject 14.

The hanger hole 16 includes a lower hanging hanger hole surface and an upper hanging hanger hole surface 116UH, and an insert hole surface extends to the upper hanging hanger hole surface 116UH.

An inner surface of the lower hanger ring portion 14A forms a lower hanger hanger hole and an inner surface of the upper hanger ring portion 14B forms an upper hanger hanger hole surface 116UH. A secured hole between the lower hanging hanger hole surface and the upper hanging hanger hole surface 116UH forms a hanger hole 16.

At this time, a part of the hanger hole 16 is composed of a tapered hanger hole 16 whose distance gradually becomes narrow. The inner end of the upper hanging hanger hole surface 116UH and the inner end of the lower hanging hanger hole surface are connected to each other so that the distance between the upper hanging hanger hole surface 116UH and the lower hanging hanger hole surface is outwardly eccentric from the base anchor bolt 10 side A part of the hanger hole 16 may be constituted by a tapered hanger groove.

More specifically, the lower hanging hanger hole surface is connected to the lower anchor bolt 10 and extends in the horizontal direction, and a lower horizontal hanging hanger hole surface 116LHH extending to the lower horizontal hanging hanger hole surface 116LHH, And a lower inclined hanging hanger hole surface 116LSH.

The lower inclined hanging hanger hole surface 116LSH extends upwardly inclined even though the upper hanging hanger surface extends in the horizontal direction so that the lower hanging hanging hanger hole surface 116LSH is inclined upwardly by a part of the upper hanging hanger hole surface 116UH and the lower inclined hanging hanger hole surface 116LSH, And a tapered hanger hole 16 in which a part of the hanger hole 16 is gradually narrowed in distance between the inner surfaces. Of course, the upper hanger hanger surface 116UH can also be extended upwardly and the distance between the lower hanger hanger surface and the upper hanger hanger surface 116UH can be made narrower even if the upper hanger hanger surface extends upwardly . The lower horizontal hanger hanger surface 116LHH is disposed closer to the base anchor bolt 10 than the lower inclined hanger hanger surface 116LSH and the lower inclined hanger hanger surface 116LSH is disposed at a lower horizontal hanger hanger surface (116LHH), which is located at a greater distance from the swash barb.

An inner end of the lower inclined hanging hanger hole surface 116LHH is connected to an inner end of the lower inclined hanging hanger hole surface 116LHH. A lower inclined insert hole surface 116ISH. The lower inclined insert seating surface 116ISH is formed to be inclined downward toward the extension bar 18 side.

The inner end of the upper hanging hanger hole surface 116UH is connected to the inner end of the lower hanging hanger hole surface 116UH and the inner end of the upper inclined insert hole surface 116USH is connected to the outer end of the upper hanging hanger hole surface 116UH. The outer end of the upper inclined insert seating surface 116USH is connected to the lower outer insert seating surface 116LIH which is the inner surface of the extension bar 18. [ The upper inclined insert hole surface 116USH is inclined so as to face the lower inclined insert hole surface 116ISH. The inclined insert hole is formed by the lower inclined insert hole surface 116ISH and the upper inclined insert hole surface 116USH. The space between the lower inclined insert hole surface 116ISH and the upper inclined insert hole surface 116USH is formed as an inclined insert hole.

The extension bar 18 extends downward from the upper hanger ring portion 14B and the inner surface of the extension bar 18 becomes the lower outer insert hole surface 116LIH. The lower outer insert surface 116LIH extends in the vertical direction.

A lower inner insert surface is connected to an outer end of the lower inclined insert hole surface 116ISH in the lower hanger ring portion 14A. The lower inner insert surface extends in a vertical direction parallel to the lower outer insert surface 116LIH. The space between the lower outer insert insert face (116LIH) and the lower inner insert face becomes the lower insert hole.

The lower insert hole is connected to the inclined insert hole, and the inclined insert hole is connected to the hanger hole 16 formed inside the row reject 14. Since the lower insert hole and the oblique insert hole are formed in the insert hole for insertion into the reinforcing bar 2, the insert hole is connected to the hanger hole 16 formed in the inside of the row reject 14.

Meanwhile, the upper inclined insert hole surface 116USH and the lower inclined insert hole surface 116ISH may be omitted. In this case, the spaced space between the extension bar 18 and the lower hanger ring 14A is formed as an insert hole. The insert hole extends in the vertical direction, and the hanger hole (16) is connected to the insert hole and at the same time disposed at the eccentric position at one side of the insert hole. The insert holes are arranged in the vertical direction and the hanger holes 16 can be arranged in the horizontal direction orthogonal to the insert holes. The hanger holes 16 may be arranged in an upward slanting direction intersecting the insert holes.

The rebar 2 is passed through the lower insert hole in the vertical direction and the rebar 2 is passed through the inclined insert hole in the secondary direction. The row reject 14 can be fixed to the reinforcing bar 2 and the row reject 14 can be fixed to the iron ball by fixing the row anchor bolt 10 to the reinforcing bar 2 .

Therefore, when the reinforcing bars 2 enter the hanger hole 16 formed in the row rejection 14 and the row rejection 14 is caught by the reinforcing bar 2, the extension bar 18 is located at one side of the reinforcing bar 2 And is disposed at a position facing the outer circumferential surface on one side of the reinforcing bar 2. One side of the reinforcing bar 2 is disposed at a position where it is caught by the extension bar 18 when the reinforcing bar 2 is forced to fall in the horizontal direction. That is, when the reinforcing bar 2 is to fall sideways from the hanger hole 16 in the row reject 14, the reinforcing bar 2 is prevented from being pulled out of the hangar hole 16 due to being caught by the extension bar 18. On the other hand, even if the row rejection 14 of the base anchor bolt 10 tries to fall to the upper side of the reinforcing bar 2, the lower hanging loop portion 14A is caught below the reinforcing bar 2, It is also prevented that the reinforcing bar 2 is pulled upward. Particularly, the lower horizontal hanger hanger surface 116LHH is supported on the lower surface of the reinforcing bar 2, and the upper hanger hanger surface 116UH of the upper hanger ring portion 14B supports the upper surface of the reinforcing bar 2, It is possible to reliably prevent the row reject 14 from falling in the up and down directions of the reinforcing bar 2 even if a force to pull the bar 2 in the upward direction or downward direction acts. The distance between the upper hanging hanger hole surface 116UH of the upper hanger ring part 14B and the lower horizontal hanger hanger hole surface 116LHH of the lower hanger ring part 14A is smaller than the outer diameter of the reinforcing bar 2 So that the reinforcing bars 2 are press-contacted with the upper and lower horizontal hanger hanger surfaces 116UH and 116LHH. This makes it possible to more reliably prevent the rebar 2 from being detached from the reinforcing bars 2 because the reinforcing bars 2 are tightly coupled to the hanger holes 16 in the rebar 14 .

In the meantime, according to the present invention, support pins (not shown) are inserted in the direction intersecting the hanger holes 16 so as to be disposed outside the reinforcing bars 2 in a state where the reinforcing bars 2 are inserted into the hanger holes 16 in the row reject 14 20).

The support pin 20 is inserted into the insert hole in front of the reinforcing bar 2 in a state where the reinforcing bar 2 is completely inserted into the hanger hole 16 inside the row refractory 14 and engaged.

Since the support pin 20 is sandwiched between the extension bar 18 and the reinforcing bar 2 provided in the row rejection 14, even if the reinforcing bar 2 slips sideways in the hanger hole 16 Since the support pin 20 blocks the reinforcing bars 2, it is possible to completely prevent the reinforcing bars 2 from slipping sideways in the hanger holes 16. [

The upper inclined insert hole surface 116USH is formed at the lower end of the extension bar 18 and the lower inclined insert hole surface 116ISH is formed at the lower hanger joint portion 14A so that the upper inclined insert hole surface 116USH, An insert hole is secured between the lower inclined insert hole surface 116ISH and the lower inclined insert hole surface 116ISH, and the insert hole may be configured to communicate with the hanger hole 16 inside the row rejection 14.

In this case, the row rejection 14 can be more easily coupled to the reinforcing bar 2 through the inclined insert hole, and the reinforcing bars 2 can be inserted into the hanger holes 16 in the row rejection 14, Even if the row rejection 14 of the base anchor bolt 10 tries to fall to the lower side of the reinforcing bar 2, the lower hanger ring portion 14A is caught on the upper side of the reinforcing bar 2, 14B are hooked on the upper surface of the reinforcing bar 2 to prevent the row rejection 14 from falling downward and upward of the reinforcing bar 2. [

The present invention further includes a cap 30 coupled to an outer circumferential surface of the base anchor bolt 10. The plug 30 has a screw hole communicating with the upper and lower ends thereof. And the inner circumferential surface of the screw hole of the cap 30 is made of a thread. A thread formed on the inner circumferential surface of the plug 30 is screwed into the thread of the base anchor bolt 10. The stopper (30) can be raised and lowered in the base anchor bolt (10) by turning the stopper (30).

When the plug 30 is coupled to the outer circumferential surface of the base anchor bolt 10, the through hole 3H of the mold 3 is closed by the plug 30 when the concrete mortar is poured into the mold 3 It is possible to prevent the concrete mortar being poured from coming into the through hole 3H of the formwork 3 and sticking to the thread of the outer circumferential surface of the base anchor bolt 10 to be exposed to the outside of the concrete and hardening, In the process of joining the anti-shake brace with the connection anchor such as a nut to the base anchor bolt 10 by making the bracket 3H of the die 3 not to be buried in the thread of the outer peripheral surface of the anchor bolt, It is possible to prevent the occurrence of difficulties. In other words, the stopper 30 is coupled to the outer circumferential surface of the base anchor bolt 10 and is vertically coupled to the thread of the outer circumferential surface of the base anchor bolt 10 by the threads of the inner circumferential surface, It is possible to prevent the concrete mortar from escaping through the through hole 3H of the formwork 3 to the outside after the concrete anchor bolt 10 ) Can be smoothly coupled to the anti-shake brace.

It is also possible to prevent the concrete mortar from flowing through the through holes 3H of the formwork 3 during the concrete mortar erosion so as to prevent a trouble in the construction due to the plug 30 closing the through holes of the formwork 3 There is also.

At this time, the plug 30 may be further provided with a flange portion. In the case where the flange portion is further provided in the stopper 30, since the stopper 30 is rotated by holding the flange portion, the operation of tightening the stopper 30 so as to block the through hole 3H of the die 3 from the inside easy.

Further, a stopper of the insert cap 30 may be further provided on the lower end of the cap 30. [ The outer diameter of the insert cap 30 is smaller than the outer diameter of the plug 30. The insert cap 30 having a smaller outer diameter protrudes from the lower end of the plug 30. The threaded hole extends from the upper end of the plug 30 to the lower end of the stone stopper 30. In the state where the insert cap 30 and the stone piece of the insert cap 30 are coupled to the outer circumferential surface of the base anchor bolt 10 by the screw hole, the protrusion of the insert cap 30 is inserted into the through hole 3H formed in the mold 3, As shown in FIG.

Therefore, since the protrusion of the insert cap 30 is more tightly attached to the inner circumferential surface of the through hole 3H of the formwork 3, it is possible to more reliably prevent the concrete mortar being poured from flowing through the hole of the formwork 3 .

The stopper 30 may be provided with a shield pocket 40 for covering the base anchor bolt 10 passing through the through hole 3H of the die 3. The shield pocket 40 may have a structure such as a flexible bag wherein the lower end of the shield pocket 40 is clogged and the upper end of the shield pocket 40 may be connected to the closure 30. [ The upper end of the shield pocket 40 may be directly connected to the lower end of the plug 30 if the insert cap 30 does not protrude from the lower end of the plug 30. [ The upper end of the shield pocket 40 may be connected to the lower end portion of the groove of the insert cap 30 when the end of the insert cap 30 protrudes from the lower end of the plug 30. [

Since the shield pocket 40 surrounds the outer circumferential surface of the base anchor bolt 10 from the through hole 3H of the mold 3, the through hole 3H between the plug 30 and the mold 3, Even when the concrete mortar is seized out due to the gap formed, the concrete mortar which is counted out is prevented from adhering to the portion protruding outward of the formwork 3 and hardened, so that the concrete mortar pouring inside the formwork 3 It is possible to almost completely prevent the base anchor bolt 10 from sticking out to the outside. Meanwhile, since the shield pocket 40 is made of a thin flexible material such as a plastic bag, the shield pocket 40 may be torn and removed after the form 3 is removed after completion of the concrete construction. When the shield pocket 40 is removed, the anchor bolt protruding out of the concrete may be connected to the anti-shake brace as described above.

Further, in the present invention, the inner diameter of the hanger hole 16 inside the row reject 14 is formed into a tapered shape gradually decreasing, so that even if the diameter of the reinforcing bar 2 entering the hanger hole 16 changes It is possible to apply the row rejection 14 to all kinds of reinforcing bars 2. The reinforcing bars 2 are different in diameter from each other and the reinforcing bars 2 having the largest diameters and the reinforcing rods 2 having the smallest diameter or the reinforcing rods 2 having the smallest diameters are arranged in such a manner that the inner diameter It is possible to easily hang the row rejection 14 on all kinds of reinforcing bars 2 irrespective of the diameter of the reinforcing bars 2 .

Meanwhile, another embodiment of the present invention is different from the above-described embodiments in the coupling structure of the base anchor bolt 10 and the row rejection 14. According to another embodiment of the present invention, the base anchor bolt 10 is formed in the shape of a straight bolt, and the adjustment anchor bolt 10 is fitted with an adjustment sleeve 50, A row rejection unit 14 is provided.

The adjustment sleeve (50) is provided with a screw hole which opens to the lower end thereof. A screw hole of the adjustment sleeve (50) is engaged with the threaded portion of the outer peripheral surface of the base anchor bolt (10).

The above-described row rejection 14 is provided at the upper end of the regulating sleeve 50.

The adjustment sleeve 50 is lifted and lowered in the base anchor bolt 10 by rotating the adjustment sleeve 50 and the row rejection 14 provided in the adjustment sleeve 50 is also lifted up from the upper end of the base anchor bolt 10 .

Therefore, in another embodiment of the present invention, the position of the row reject 14 is moved by the rotation of the adjusting sleeve 50 at the upper end of the base anchor bolt 10 so that the inner surface of the die 3 and the reinforcing bars 2, the row reject 14 can be conveniently hooked to the reinforcing bar 2. [ The position of the row reject 14 can be adjusted by the rotation of the adjusting sleeve 50 in accordance with the distance between the reinforcing bars 2 and the form 3, It is possible to hang it on the reinforcing bar (2).

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

4. Slabs 10. Base anchor bolts
14. Deny Rule 14A. Lower hanger ring part
14B. Upper hanger ring 16. Hanger hole
18. Extension bar 20. Support pin
30. Stopper 40. Cover pocket
116LHH. Lower horizontal hanger hanging surface 116LSH. Lower inclined hanging hanger
116ISH. Lower inclined insert surface 116UH. Top hanger hanger
116USH. Upper bevel insert insert face 116LOH. Lower outer insert
116LIH. Lower inner insert face

Claims (5)

A base anchor bolt 10 partially buried in the concrete placed and supported by the formwork 3 and a part of the base anchor bolt 10 passing through the through hole 3H formed in the formwork 3 and projecting to the outer surface of the formwork 3, ;
And a row rejection (14) provided in the base anchor bolt (10) and hooked to a reinforcing bar (2) laid for concrete construction,
When the mold 3 is removed, a part of the base anchor bolt 10 protrudes from the surface of the concrete through the through-hole 3H of the mold 3, And an anchor bolt (10) for connecting an anti-shake brace,
The row reject 14 is integrally connected to the upper end of the base anchor bolt 10,
The proximal end of the extension bar 18 is connected to the distal end of the row reject 14 and the distal end of the extension bar 18 extends downward toward the anchoring tube 10,
The hanger hole 16 includes a lower hanging hanger hole surface and an upper hanging hanger hole surface 116UH,
The lower hanger hanger has a lower horizontal hanger hanger surface 116LHH extending to the connecting bar 11 and extending in the horizontal direction and a lower horizontal hanger hanger surface 116LHH extending to the lower horizontal hanger hanger surface 116LHH, And a hanging hanger hole surface 116LSH,
The lower inclined hanger hanger surface 116LSH extends upwardly and the upper hanger hanger surface 116UH extends horizontally or slopes upwards and the distance between the lower hanger hanger surface and the upper hanger hanger surface 116UH is Wherein the hanger hole (16) is formed to be gradually narrower, and a part of the hanger hole (16) is constituted by a tapered hangar hole.
delete delete The method according to claim 1,
Wherein an anchor bolt is coupled to an upper end of the anchor bolt, and the row rejection (14) is connected to an upper end of the buried sleeve.
The method according to claim 1,
And a cap (30) coupled to an outer circumferential surface of the anchor bolt to block an outer circumferential surface of the anchor bolt and the through hole (3H) of the formwork (3). The anchor bolt Anti-seismic shrink-proof brace concrete fixture.

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