KR102632675B1 - Spacers for installing building reinforcement - Google Patents

Abstract

The present invention relates to a spacer for installing building reinforcement,
A fixing part that is fixed to one side of the reinforcing steel plate (B) and has a lower opening (101) communicating with the through hole (b1) formed in the reinforcing steel plate (B) attached to the reinforcement object (A) requiring reinforcement in a building structure. (10); A close contact portion (20) that is in close contact with the surface of the reinforcement target portion (A) and has an upper opening 201 through which a drill is inserted to form an anchor installation hole (a1) in the reinforcement target portion (A); A main wall portion 30 formed in a cylindrical shape between the fixing portion 10 and the contact portion 20; Includes.
According to the present invention, it is installed in the through hole of the reinforcement steel plate and is interposed between the reinforcement target portion and the reinforcement steel plate, so that dust, concrete fragments, etc. generated in the process of forming an anchor installation hole in the reinforcement target portion using a drill are prevented from the reinforcement target portion and the installed reinforcement. By blocking the inflow between the steel plates, the adhesive strength of the adhesive injected into the space between the reinforced steel plate and the steel plate is prevented from deteriorating, and the reinforced steel plate is more firmly attached to the reinforced steel plate.

Description

Spacers for installing building reinforcement {Spacers for installing building reinforcement}

The present invention relates to a spacer for installing reinforcement in a building. More specifically, the present invention relates to a spacer for installing reinforcement in a building. More specifically, the present invention relates to a spacer for installing reinforcement in a building, and more specifically, it is interposed between the reinforcement target and the reinforcing steel plate so that dust, concrete fragments, etc. generated in the process of forming an anchor installation hole in the reinforcement target using a drill are removed from the reinforcement target and the reinforcing steel plate. It relates to a spacer for installing building reinforcement that prevents deterioration of the adhesive strength of the adhesive injected into the space by blocking the inflow into the space between them.

As the forms of buildings become more diverse and complex, there are cases where more loads are applied than the original design load, so it is often necessary to improve the strength of the building.

In addition, as a building ages, its structural performance decreases and its safety deteriorates, so in order to prevent this, the strength of the building may need to be improved.

Therefore, various structural reinforcement methods are used to reinforce the concrete slab or beam of a building, and these structural reinforcement methods largely include the cross-sectional expansion method and the attachment method.

The cross-section expansion method is a method of reinforcing a concrete structure by increasing the cross-section in addition to the concrete structure. There are methods such as the expansion method, the reinforcing material embedding method, and the concrete increase method. The concrete increase method is mainly used.

Concrete reinforcement method is a method commonly used for flexural or shear reinforcement. It is a method of grouting the base material or spraying and bonding with shotcrete, and is a method of reinforcing by placing a mold and pouring or spraying high-performance concrete mortar with good fluidity and adhesion. am.

However, depending on site conditions, there are frequent cases of peeling due to problems with adhesion between the concrete structure and the expanded mortar. Not only is it difficult to obtain sufficient reinforcing effect during peeling, but it is also difficult to apply to the interior of a building due to space constraints. There is a difficult downside.

Attachment methods include the steel plate attachment method, fiber sheet reinforcement method, and fiber plate reinforcement method. Among them, the steel plate attachment method involves placing a reinforcing steel plate on the reinforcement target area of a building and then inserting a pre-formed hole (anchor bolt insertion hole) into the reinforcing steel plate. A drill is inserted through the hole to form an anchor installation hole in the area to be reinforced, and an anchor bolt is installed in the anchor installation hole to fix the reinforcement steel plate. Then, adhesive is injected into the space between the area to be reinforced and the reinforcement steel plate and then cured to secure the reinforcement steel plate. Reinforcement work using is completed.

However, in the conventional steel plate attachment method, dust and concrete fragments generated in the process of forming an anchor installation hole in the reinforcement target area using a drill scatter and remain between the reinforcement target area and the erected reinforcing steel plate, thereby causing the reinforcement target area and the reinforced steel plate. This has the disadvantage of causing a decrease in the adhesion of the adhesive injected into the space between the steel plates, and as a result, the reinforcing performance of the reinforcing steel plates is reduced.

In addition, the gap between the space to be reinforced and the reinforcing steel plate must be appropriate for the adhesive injected into the area to be reinforced to exhibit the best adhesion. In the process of installing the steel plate to the area to be reinforced, the gap between the space between the area to be reinforced and the steel plate is determined by the operator. Since it is difficult to check with the naked eye, the gap in the space is too wide, resulting in excessive use of adhesive, or the gap is too narrow, resulting in insufficient use of adhesive, which reduces the adhesion of the reinforcing steel plate and reduces reinforcing performance. there is.

In addition, holes are formed in advance in the reinforcing steel plate for the installation of anchor bolts, but since the holes are not completely sealed even after the installation of the anchor bolts is completed, the adhesive may be Not only does it have the disadvantage of frequently occurring leaks through holes, but it also has the disadvantage of lowering work efficiency due to unnecessary additional work as adhesive leaks must be cleaned and removed one by one.

Registered Patent No. 10-0426257

In order to solve the conventional shortcomings as described above, the present invention is installed in the through hole of the reinforced steel plate and is interposed between the reinforced steel plate and the reinforced steel plate, thereby generating dust and concrete debris generated in the process of forming an anchor installation hole in the reinforced steel plate using a drill. The purpose is to provide a spacer for installing building reinforcement that can block the flow of light between the reinforcement target and the installed reinforcement steel plate.

Another object of the present invention is to provide a spacer for installing building reinforcement that ensures that the space between the reinforcement target and the reinforcement steel plate is appropriately maintained during the process of installing the reinforcing steel plate in the reinforcement target.

Another object of the present invention is to provide a spacer for installing building reinforcement that completely seals the through hole formed in the reinforcement steel plate and prevents leakage of the adhesive injected into the space between the reinforcement object and the reinforcement steel plate.

In order to achieve the above-mentioned purpose, the spacer for installing building reinforcement of the present invention,

A fixing part that is fixed to one side of the reinforcing steel plate (B) and has a lower opening (101) communicating with the through hole (b1) formed in the reinforcing steel plate (B) attached to the reinforcement object (A) requiring reinforcement in a building structure. (10);

A close contact portion 20 that is in close contact with the surface of the reinforcement target portion (A) and has an upper opening 201 through which a drill is inserted to form an anchor installation hole (a1) in the reinforcement target portion (A);

A main wall portion 30 formed in a cylindrical shape between the fixing portion 10 and the close contact portion 20; It is composed including.

In one embodiment, the fixing part 10 is provided with an adhesive means 102 on its bottom and is adhesively fixed to the surface of the reinforcing steel plate B.

In one embodiment, the main wall portion 30 is characterized in that its inner peripheral surface has a cross-sectional shape of upper and lower beams.

In one embodiment, the main wall portion 30 is formed of a material having elasticity and flexibility.

In one embodiment, the main wall portion 30 is formed in a cone shape and has a thickness that increases toward the bottom.

In one embodiment, the fixing part 10 includes an annular coupling groove 103 fitted into the through hole b1; It is characterized by being further provided.

In one embodiment, the main wall portion 30 is further provided with a transparent window 301 on one side, and the adhesive (C) is injected into the space (S) between the reinforcement target portion (A) and the reinforcing steel plate (B). It is characterized by allowing the status to be checked.

In one embodiment, the fixing part 10 is formed to protrude downward in a tubular shape from its bottom, and a plurality of cut grooves 104a are formed on the main wall, and the engaging protrusion 104 is coupled to the through hole b1 in an interference fit manner. ; It is characterized in that it is further provided.

The spacer for installing building reinforcement of the present invention is installed in the through hole of the reinforced steel plate and is interposed between the reinforced steel plate and the reinforced steel plate, thereby preventing dust, concrete fragments, etc. generated in the process of forming the anchor installation hole in the reinforced steel plate using a drill from the reinforced steel plate and the reinforced steel plate. By blocking the inflow between installed reinforcing steel plates, the adhesive strength of the adhesive injected into the space between the reinforced steel plate is prevented from deteriorating, and the reinforcing steel plate is more firmly attached to the reinforced steel plate.

In addition, the spacer for installing building reinforcement of the present invention is installed in the through hole of the reinforcing steel plate and interposed between the reinforcement target portion and the reinforcing steel plate, so that the space between the reinforcement target portion and the reinforcing steel plate is maintained uniformly, allowing adhesive to be injected into the space. This has the effect of making the injection of adhesive smoother.

In addition, the spacer for installing building reinforcement of the present invention seals the through hole formed in the reinforcing steel plate, thereby preventing the injected adhesive from leaking through the hole when injecting the adhesive into the space between the reinforcement target part and the reinforcing steel plate. there is.

Figure 1 is a cross-sectional example showing a state in which an anchor installation hole is formed in the reinforcement target area using a drill while a reinforcing steel plate is installed in the reinforcement target area of an old building structure.
Figure 2 is a cross-sectional example showing the state of forming an anchor installation hole in the reinforcement target area using a drill while a reinforcing steel plate is installed in the reinforcement target area of an old building structure.
Figure 3 is a perspective view according to the first embodiment of the present invention.
Figure 4 is an illustration of a state of use according to the first embodiment of the present invention.
Figure 5 is an illustration of a state of use according to a second embodiment of the present invention.
Figure 6 is an illustration of a state of use according to a third embodiment of the present invention.
Figure 7 is an illustration of a usage state according to a fourth embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text.

In other words, since the embodiments can be modified in various ways and can take various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea.

In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment must include all or only such effects, so the scope of the present invention should not be understood as limited thereby.

All terms used in the description of the present invention have the same meaning as generally understood by a person of ordinary skill in the field to which the present invention pertains, unless otherwise defined.

Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present invention.

In addition, terms such as “first” and “second” are only used to distinguish different components, and are not limited by the order of manufacture, and the scope of rights should not be limited by these terms.

Figure 3 is a perspective view according to the first embodiment of the present invention, and Figure 4 is an illustrative view of a use state according to the first embodiment of the present invention.

This will be described with reference to FIGS. 3 and 4.

Before explaining in detail the spacer for installing building reinforcement of the present invention according to the first embodiment, when explaining the reinforcing steel plate (B) used to reinforce a concrete slab or beam, the reinforcing steel plate (B) corresponds to the slab. It can be formed in a flat shape or a bent shape corresponding to a beam. It is preferable to use a high-strength steel plate, and the reinforcing steel plate (B) is fixed to the reinforcement target portion (A) such as a slab or beam with anchor bolts (D). For installation, it is preferable that a certain number of through holes (b1) or more are formed per unit area.

In addition, after fixed installation using the anchor bolt (D), adhesive is attached to one side of the reinforcing steel plate (B) to facilitate injection of the adhesive (C) into the space (S) between the reinforcement target portion (A) and the reinforcing steel plate (B). (C) It is preferable that an injection hole is formed and an air discharge hole is formed on the other side of the reinforcing steel plate (B).

The spacer for installing building reinforcement of the present invention according to the first embodiment is installed in the through hole (b1) of the reinforcement steel plate (B) when attaching a reinforcing steel plate (B) to reinforce the concrete slab or beam of an aged building structure. It includes a fixing part 10, a close contact part 20, and a main wall part 30 so as to be interposed between the reinforcement target part (A) and the reinforcing steel plate (B).

The fixing part 10 is fixed to one side of the reinforcing steel plate (B) by having a lower opening 101 that communicates with the through hole (b1) formed in the reinforcing steel plate (B).

The diameter of the lower opening 101 is preferably the same as or smaller than the diameter of the through hole b1 formed in the reinforcing steel plate B.

Meanwhile, various methods may be used to secure the fixing part 10 to one side of the reinforcing steel plate (B).

As an example, the fixing part 10 is further provided with an adhesive means 102 on its bottom so that it can be adhesively fixed to the surface of the reinforcing steel plate (B).

The close contact portion 20 is in close contact with the surface of the reinforcement target portion A, and has an upper opening 201 through which a drill is inserted to form an anchor installation hole a1 in the reinforcement target portion A.

The main wall portion 30 is formed in a cylindrical shape between the fixing portion 10 and the close contact portion 20.

In one embodiment, the main wall portion 30 is characterized in that its inner peripheral surface has a cross-sectional shape of upper and lower beams.

Therefore, the fixing part 10 is fixed to one side of the reinforcing steel plate (B), and the close contact part 20 is drilled through the through hole (b1) of the reinforcing steel plate (B) while being in close contact with the surface of the reinforcement target portion (A). When inserting or inserting the anchor bolt (D), the inner peripheral surface of the main wall portion 30 has a cross-sectional shape of upper and lower beams, making it easy to insert the drill or anchor bolt (D).

The spacer for installing building reinforcement of the present invention according to the first embodiment configured as described above is used to first install a reinforcing steel plate (B) to reinforce the reinforcement target part (A) that needs reinforcement in an old building structure such as a concrete slab or beam, After installing the reinforcing steel plate (B) with the fixing part (10) glued and fixed to one side formed on the reinforcing steel plate (B), a drill is inserted through the through hole (b1) of the reinforcing steel plate (B) to form a close contact portion (20). ), when the anchor installation hole (a1) is formed in the reinforcement target portion (A) through the upper opening 201 of Dust or concrete debris generated in the process of forming (a1) does not flow into the space (S) between the reinforcement target portion (A) and the reinforcing steel plate (B), but flows down the inner peripheral surface of the main wall portion (30). It is quickly discharged through the hole (b1) of the reinforcing steel plate (B).

Therefore, the spacer for installing building reinforcement of the present invention according to the first embodiment is designed to prevent dust, concrete fragments, etc. generated in the process of forming the anchor installation hole (a1) in the reinforcement target portion (A) from the reinforced portion (A) and the erected spacer. By blocking the inflow between the reinforcing steel plates (B), the adhesive strength of the adhesive (C) injected into the space (S) between the reinforcement target area (A) and the reinforcing steel plate (B) is prevented from deteriorating and the reinforcing steel plate (B) is further strengthened. It has the effect of being firmly attached and fixed to the reinforcement target part (A).

In addition, the spacer for installing building reinforcement of the present invention is installed in the through hole (b1) of the reinforcing steel plate (B) and is interposed between the reinforcement target portion (A) and the reinforcing steel plate (B), thereby creating a gap between the reinforcement target portion (A) and the reinforcing steel plate (B). As the spacing of the space (S) is maintained uniformly throughout, when injecting the adhesive (C) into the space (S), not only is the injection of the adhesive (C) smooth, but the adhesive (C) is also of uniform thickness. By curing after injection, the adhesive force of the reinforcing steel plate (B) by the adhesive (C) becomes uniform throughout, resulting in stable reinforcing performance.

In addition, the spacer for installing building reinforcement of the present invention is installed in a form that covers and seals the through hole (b1) formed in the reinforcement steel plate (B) on the inner surface of the reinforcement steel plate (B), so that after installation of the anchor bolt (D), the reinforcement target portion (A) When the adhesive (C) is injected into the space (S) between the ) and the reinforcing steel plate (B), there is an effect of preventing the injected adhesive (C) from leaking through the hole (b1).

Figure 5 is an illustrative diagram according to a second embodiment of the present invention.

The description will be made with reference to FIG. 5, but detailed descriptions of components overlapping with the above-described embodiments and components having the same reference numerals will be omitted.

The spacer for installing building reinforcement of the present invention according to the second embodiment is made of a material having elasticity and flexibility, such as urethane or rubber, and the main wall portion 30 is formed in a cone shape, and the thickness becomes thicker toward the bottom.

That is, the spacer for installing building reinforcement of the present invention is installed in the through hole (b1) of the reinforcing steel plate (B) and is interposed between the reinforcement target portion (A) and the reinforcing steel plate (B), and between the fixing portion (10) and the close contact portion (20). The main wall portion 30, which is formed in a cylindrical shape, becomes smaller in diameter and thickness toward the close contact portion 20, and becomes wider in diameter and thickness toward the fixing portion 10.

Therefore, as the thickness of the main wall 30 increases and the strength increases as it moves from the close contact portion 20 formed on the upper side to the fixing portion 10 formed on the lower side, the fixing portion 10 is formed on one side of the reinforcing steel plate B. In the process of erecting the reinforcing steel plate (B) with the adhesive fixed, the distance between the reinforcement target portion (A) and the reinforcing steel plate (B) is narrower than the total height of the main wall portion (30), and even if the reinforcing steel plate (B) is installed, the elasticity and As the main wall portion 30 made of a flexible material is compressed, it corresponds to the gap between the reinforcement target portion (A) and the reinforcing steel plate (B), and at the same time, a stable installation state can be maintained due to the strength increasing toward the bottom.

Figure 6 is an illustrative diagram according to a third embodiment of the present invention.

The description will be made with reference to FIG. 6, but detailed descriptions of components overlapping with the above-described embodiments and components having the same reference numerals will be omitted.

The spacer for installing building reinforcement of the present invention according to the third embodiment may further include an annular coupling groove (103).

The annular coupling groove 103 is formed in the fixing part 10 and is inserted into the through hole b1 of the reinforcing steel plate B.

That is, when installing the spacer for installing building reinforcement of the present invention according to the third embodiment on the reinforcing steel plate (B), it is forcibly inserted into the through hole (b1) of the reinforcing steel plate (B) in an interference fit method instead of the adhesive means (102). The annular coupling groove 103 formed in the top 10 is fixed by being inserted into the through hole b1 of the reinforcing steel plate B, so that the spacer for installing building reinforcement according to the third embodiment can be installed more quickly and easily.

In addition, as it is closely coupled to the through hole (b1) of the reinforcement steel plate (B) by the annular coupling groove (103), the sealing force for the through hole (b1) is further improved, so that the reinforcement target portion (A) after installation of the anchor bolt (D) When the adhesive (C) is injected into the space (S) between the and the reinforcing steel plate (B), it is possible to more effectively prevent the injected adhesive (C) from leaking through the through hole (b1).

The spacer for installing building reinforcement of the present invention according to the third embodiment may further include a transparent window 301.

The transparent window 301 is formed on one side of the main wall portion 30 and is integral with the main wall.

Therefore, the spacer for installing building reinforcement of the present invention according to the third embodiment is installed on the reinforcing steel plate (B), and the anchor bolt (D) is installed to fix the reinforcing steel plate (B), and then the reinforcement target portion (A) and the reinforcing steel plate ( When injecting the adhesive (C) into the space (S) between B), the injection state of the adhesive (C) can be directly checked through the transparent window 301, so that the width or length of the space (S) can be reduced. Even if it is formed long, it is possible to prevent insufficient injection of the adhesive (C) inside the space (S) or uneven injection of the adhesive (C).

Figure 7 is an illustrative diagram according to a fourth embodiment of the present invention.

The description will be made with reference to FIG. 7, but detailed descriptions of components overlapping with the above-described embodiments and components having the same reference numerals will be omitted.

The spacer for installing building reinforcement of the present invention according to the fourth embodiment is made of a high-strength material such as metal, and may further include a coupling protrusion 104 on the fixing part 10.

The engaging protrusion 104 is formed to protrude downward in a tubular shape from the bottom of the fixing part 10, and has a plurality of cut grooves 104a formed on the main wall, so that it is coupled to the through hole b1 in an interference fit manner.

Therefore, even if the spacer for installing building reinforcement of the present invention according to the fourth embodiment is formed of a high-strength material such as a metal material, the close contact portion 20 is formed with the coupling protrusion 104 in close contact with the through hole b1 of the reinforcing steel plate B. Not only can the coupling protrusion 104 be installed quickly, easily, and firmly by press fitting it into the through hole b1 by pressing or striking, but also reinforcing the spacer for installing the building reinforcement of the present invention according to the fourth embodiment. After being installed in the through hole (b1) of the steel plate (B), the reinforcing steel plate is installed with the close contact portion (20) in contact with the reinforcement target portion (A) during the process of installing the reinforcing steel plate (B) on the reinforcement target portion (A). Even if pressure is applied to (B), the spacer for installing building reinforcement of the present invention according to the fourth embodiment is made of a high-strength material and maintains its shape firmly, thereby forming the space (S) between the reinforcement target portion (A) and the reinforcing steel plate (B). The spacing can be maintained accurately.

Although the present invention has been described above with respect to limited embodiments, the scope of the present invention is not limited thereto, and the technical idea of the present invention and the claims below are understood by those skilled in the art in the technical field to which the present invention pertains. Various modifications and improvements made within the scope of equivalent scope will also fall within the scope of the present invention.

A: Part to be strengthened a1: Anchor installation hole
B: Reinforced steel plate b1: Through hole
C: Adhesive S: Space
D: Anchor bolt 10: Fixing part
101: lower opening 102: adhesive means
103: annular coupling groove 104: coupling protrusion
104a: Cut groove 20: Close contact portion
201: upper opening 30: main wall part
301: transparent window

Claims (5)

A fixing part that is fixed to one side of the reinforcing steel plate (B) and has a lower opening (101) communicating with the through hole (b1) formed in the reinforcing steel plate (B) attached to the reinforcement object (A) requiring reinforcement in a building structure. (10);
A close contact portion 20 that is in close contact with the surface of the reinforcement target portion (A) and has an upper opening 201 through which a drill is inserted to form an anchor installation hole (a1) in the reinforcement target portion (A);
A main wall portion 30 formed in a cylindrical shape between the fixing portion 10 and the close contact portion 20; It is composed including,
The fixing part 10 is provided with an adhesive means 102 on its bottom and is adhesively fixed to the surface of the reinforcing steel plate B, and is formed to protrude downward in a tubular shape from its bottom, and has a plurality of cut grooves 104a on the main wall. A coupling protrusion 104 is formed that is coupled to the through hole b1 in an interference fit manner,
The main wall portion 30 is formed in a cone shape whose thickness increases toward the bottom, and is further provided with a transparent window 301 on one side and is injected into the space S between the reinforcement target portion A and the reinforcing steel plate B. A spacer for installing building reinforcement, characterized in that it allows checking the injection state of the adhesive (C).
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