KR20240036825A - Method for reinforcing anchor pullout strength of existing exterior panel - Google Patents

Abstract

By improving the anchor pulling performance of exterior panels already installed in curtain wall-type buildings where there is a risk of exterior materials falling off, and high-rise buildings in urban areas that must resist high wind speeds and pressures, exterior materials that may fall off due to earthquakes or building winds, etc. Damage to buildings can be minimized, and by reinforcing the pulling strength of the anchor by installing microbolts at the existing anchor location without dismantling or replacing the exterior panel, sufficient anchor reinforcement performance can be achieved without installing additional anchors. In addition, a method of reinforcing the anchor pull-out strength of an existing exterior panel is provided, which can prevent damage or cross-sectional loss of the exterior panel without compromising its aesthetics without additional installation of anchors, which may occur in the existing exterior panel reinforcement method.

Description

Method for reinforcing anchor pullout strength of existing installed exterior panels {METHOD FOR REINFORCING ANCHOR PULLOUT STRENGTH OF EXISTING EXTERIOR PANEL}

The present invention relates to reinforcing the anchor pull-out strength of an exterior panel. More specifically, when reinforcing an exterior panel already installed in a building frame, the anchor pull-out strength (pull-out strength) is reinforced using microbolts without additional installation of anchors. This relates to a method of reinforcing the anchor pull-out strength of an existing installed exterior panel.

In general, building exterior materials are carefully selected because they are related to the exterior as well as interior insulation.

These types of exterior materials include wood, brick, marble, stucco, and zinc. In addition, building exterior materials can be constructed as a single type, but they can also be constructed in combination.

Figure 1 is a diagram illustrating an exterior panel installed on a building frame.

As shown in FIG. 1, when attaching and installing the exterior panel 11 to the building frame 20, a direct-buried anchor 12 can be used as a concrete anchor.

These concrete anchors are installed before placing concrete or in hardened concrete members and are used to transfer load between structural members.

These concrete anchors are typically used for joining foundation concrete and steel, and are widely used for attaching machinery and plumbing equipment, soundproof walls, signs, and finishing materials.

In addition, it is widely used in the reinforcement work of existing structures, for joining existing concrete members and reinforcement materials, and for installing brackets for temporary structures.

Specifically, the types of anchors are divided into pre-installation anchors, which are installed before concrete is placed, and post-installation anchors, which are installed on hardened concrete, based on the time of installation.

In addition, based on the method of connection to concrete, post-installed anchors are divided into mechanical anchors that engage the concrete and steel and adhesive anchors that use adhesives such as epoxy.

At this time, because the anchor performance of attachable anchors varies greatly depending on the performance of the adhesive material used and the retention conditions, the concrete structural standards require manufacturers to propose a separate design method.

For example, in ACI 318-11, the anchor design method for seismic load, lightweight concrete coefficient, anchor diameter and burial depth limitations, method for calculating the projected area of the concrete failure surface of anchors subjected to shear, and anchor installation have been partially revised. .

Meanwhile, Figure 2 is a diagram illustrating additional pre-installation of a plate or washer to increase the anchor pulling strength of an exterior panel according to the prior art.

Typically, factors that can affect the tensile strength (N _b ) of a single anchor are the concrete strength inside the panel ( ) and concrete burial depth ( : insertion depth).

However, since the concrete strength of the existing exterior panel 11 cannot be changed, a method of securing a sufficient effective burial depth can be considered according to the following equation 1.

[Equation 1]

here, represents the basic concrete failure strength coefficient due to tension, represents the concrete coefficient, represents the concrete design standard compressive strength, represents the effective buried depth of the anchor, respectively.

However, in the case of thin exterior panels, there is a limit to the burial depth, and to overcome this, a method of expanding the projected area of the concrete failure surface that occurs when tensile force acts on the anchor 12 can be considered.

For this purpose, as shown in FIG. 2, the head of the anchor 12 or the plate 13 can be additionally installed.

Specifically, according to the prior art, as shown in FIG. 2, b ₀ is set to affect the effective area (or projected area) by additionally installing a plate or washer 13 to increase the tensile strength. By increasing b ₀ ', the first projection area can be increased to the second projection area,

Accordingly, the anchor tensile strength ( ) can be increased, and at this time, the anchor tensile strength corresponds to the anchor pull-out strength (or pull-out strength).

Meanwhile, a large-scale earthquake occurred in Pohang in 2017, causing serious damage to non-structural materials such as exterior materials, and the frequency and scale of typhoons that can cause serious damage to building exterior materials are rapidly increasing.

In addition, as the density of high-rise buildings increases in large urban centers, damage from building winds is also occurring.

Accordingly, there is a need for technology that can improve the tensile strength or pull-out strength of anchors, which are joints that connect existing exterior panels (or exterior panels) and the building frame, without dismantling or replacing them.

The tensile strength of the anchor joint connecting these exterior panels and the building against wind load or earthquake load is most affected by the embedment depth of the anchor within the exterior panel. However, in line with the lightweighting of buildings, the interior concrete of exterior panels often does not secure sufficient depth, so instead of securing sufficient depth, the number of anchors is increased.

This construction and structural design method has the problem that the constructability and productivity of exterior panels may worsen as the quantity increases.

Figure 3 is a diagram showing additional installation of anchors to reinforce the anchor pulling strength of an existing exterior panel according to the prior art.

As shown in a) and b) of Figure 3, in order to improve the tensile strength (pull-out strength) of the existing exterior panel 11, a method of embedding additional anchors 14 between the existing installed anchors 12 can be utilized. You can.

However, in this method of adding anchors, newly installed additional anchors (14) or existing anchors (12) may exist within the effective area where concrete cracks occur as the anchor is pulled out in the tensile direction.

In this case, the anchor installed on the exterior panel 11 does not reach the tensile strength calculated at the time of design due to early fracture of the concrete, so it can be said to be an inefficient reinforcement method.

In addition, there are problems such as damage to the exterior panel 11 that occurs while purchasing additional anchors 14, and deterioration in constructability and construction productivity.

In addition, this method of installing additional anchors has a problem in that the gap between anchors is reduced as additional anchors 14 are installed between existing anchors 12. This means that cracks that occur when the concrete is destroyed by the tensile force acting on the anchor may affect additionally installed anchors.

This makes it difficult to achieve the originally expected tensile performance due to the additionally installed anchor reinforcement.

In addition, damage may occur within the exterior panel 11 during the additional installation of anchors, and there is a problem in that construction productivity may be reduced due to an increase in the quantity due to the installation of additional anchors 14.

Republic of Korea Patent No. 10-2358994 (registration date: January 28, 2022), title of invention: “Concrete pre-embedded anchor anchoring device” Republic of Korea Patent No. 10-1337325 (registration date: November 29, 2013), title of invention: “Medium-insulated precast wall capable of resisting positive and negative pressure and its construction method.” Republic of Korea Patent No. 10-1638155 (registration date: July 4, 2016), title of invention: “Anchor joint using box-shaped member” Japanese Patent Publication No. 2021-92039 (publication date: June 17, 2021), title of invention: “Construction method of anchor for concrete” Japanese Patent Laid-Open No. 2009-138503 (publication date: June 25, 2009), title of invention: “Embedded anchor for panel installation and concrete-based panel”

The technical problem to be achieved by the present invention to solve the above-mentioned problems is the anchor pulling performance of exterior panels already installed in curtain wall-type buildings with a risk of exterior material falling off, and high-rise buildings in urban areas that must resist high wind speeds and wind pressures. The purpose is to provide a method of reinforcing the anchor pull-out strength of existing installed exterior panels that can improve the.

Another technical problem to be achieved by the present invention is to strengthen the pullout strength of the anchor by installing microbolts at the existing anchor location without dismantling or replacing the exterior panel, so that sufficient anchor reinforcement performance can be achieved without installing additional anchors. This is to provide a method of reinforcing the anchor pull-out strength of installed exterior panels.

Another technical problem to be achieved by the present invention is to extract anchors from existing exterior panels, which can prevent damage or cross-sectional loss of exterior panels without damaging their aesthetics without additional installation of anchors, which may occur in the existing exterior panel reinforcement method. It is intended to provide a method of strengthening strength.

As a means of achieving the above-described technical problem, the method of reinforcing the anchor pull-out strength of an existing exterior panel installed in accordance with the present invention includes: a) using a drill; forming a drilling hole through the existing installed exterior panel to a predetermined depth of the anchor: b) injecting a bonding agent into the drilling hole; c) inserting a microbolt into the drilling hole into which the bonding agent has been injected; d) bending the tip of the microbolt, which is cut into at least two pieces, and bringing it into close contact with the outer surface of the exterior panel; and e) reinforcing the anchor pull-out strength by integrating the anchor and the microbolt by hardening the binder, wherein the tip of the microbolt is inserted into the anchor to reinforce the anchor pull-out strength. It is integrated, and the tip of the microbolt is exposed and bent and attached to the outer surface of the exterior panel.

Here, in step a), a drilling hole, which is a space into which a microbolt can be inserted up to the effective depth of the anchor, can be formed using a rotary or percussion drill.

Here, the bonding agent in step b) is an epoxy adhesive, which can integrate the anchor and the microbolt to transfer the load to the outside of the exterior panel.

Here, the microbolt is a tip-cut microbolt whose tip is cut into at least two pieces and bent and attached to the outer surface of the exterior panel. The microbolt is manufactured so that the tip of the microbolt can be cut into at least two pieces and bent. and may be exposed to the outside of the exterior panel.

Here, the microbolt can secure a fixing length so that it is not pulled out of the exterior panel after being inserted into the drilled hole.

As another means of achieving the above-described technical problem, the method of reinforcing the anchor pull-out strength of an existing exterior panel installed in accordance with the present invention includes: a) a drill; Forming a drilling hole through the existing installed exterior panel to a predetermined depth of the anchor using: b) injecting a bonding agent into the drilling hole; c) placing a ring plate on the outer surface of the exterior panel; d) inserting a microbolt through the ring plate and the drilling hole; e) bending the apex of at least two microbolts and bringing them into close contact with the upper surface of the ring plate; f) welding the cut microbolts to the ring plate; and g) integrating the anchor and the microbolt by curing the binder to reinforce the anchor pulling strength, wherein the tip of the microbolt is inserted into the anchor and integrated to reinforce the anchor pulling strength, The tip of the microbolt is exposed to the outer surface of the ring plate and is bent and welded.

Here, the ring plate can increase the pullout strength of the anchor by increasing the projected area, which is the effective impact area of the concrete, when a tensile force acts on the anchor.

According to the present invention, by improving the anchor pulling performance of exterior panels already installed in curtain wall-type buildings that have a risk of exterior material falling off and high-rise buildings in urban areas that must resist high wind speeds and wind pressures, they can prevent the occurrence of earthquakes or building winds. Damage to buildings, such as possible loss of exterior materials, can be minimized.

According to the present invention, sufficient anchor reinforcement performance can be achieved without installing additional anchors by reinforcing the pulling strength of the anchor by installing microbolts at existing anchor locations without dismantling or replacing the exterior panel.

According to the present invention, it is possible to prevent damage to the exterior panel or loss of cross-section without compromising its aesthetics and without additional installation of anchors, which can occur in existing exterior panel reinforcement methods.

Figure 1 is a diagram illustrating an exterior panel installed on a building frame.
Figure 2 is a diagram illustrating additional pre-installation of a plate or washer to increase the anchor pulling strength of an exterior panel according to the prior art.
Figure 3 is a diagram showing additional installation of anchors to reinforce the anchor pulling strength of an existing exterior panel according to the prior art.
Figure 4 is a cross-sectional view showing before reinforcing the anchor pull-out strength of an existing exterior panel according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing the anchor pull-out strength of an existing installed exterior panel according to an embodiment of the present invention.
Figure 6 is an operation flowchart showing a method of reinforcing the anchor pulling strength of an existing installed exterior panel according to the first embodiment of the present invention.
Figures 7a to 7d are cross-sectional views specifically showing a method of reinforcing the anchor pulling strength of an existing installed exterior panel according to the first embodiment of the present invention.
Figure 8 is an operation flow chart showing a method of reinforcing the anchor pulling strength of an existing installed exterior panel according to a second embodiment of the present invention.
Figures 9a to 9f are cross-sectional views specifically showing a method of reinforcing the anchor pulling strength of an existing installed exterior panel according to a second 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. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to “include” a certain element, this means that it may further include other elements rather than excluding other elements, unless specifically stated to the contrary.

[First Example: Method of reinforcing anchor pull-out strength of existing installed exterior panels]

Figure 4 is a cross-sectional view showing before reinforcement of the anchor pulling strength of an existing exterior panel according to an embodiment of the present invention, and Figure 5 is a cross-sectional view showing after reinforcement of the anchor pulling strength of an existing exterior panel according to an embodiment of the present invention.

As shown in FIG. 4, an instantaneous wind speed/wind pressure increase due to unexpected building wind, etc. on the previously installed exterior panel 110 and a sudden increase in the load acting on the anchor 120 due to an earthquake ( If the pull-out strength of the anchor 120 of 110) is not reinforced, damage to the building, such as falling off of the exterior material, which may be caused by an earthquake or building wind, may occur.

Accordingly, there is a need to improve the anchor pulling performance of exterior panels already installed in curtain wall-type buildings where there is a risk of exterior material falling off, and high-rise buildings in urban areas that must resist high wind speeds and pressures.

Here, the exterior panel 110 may be an exterior concrete panel, and may be typically precast using lightweight aerated concrete, but is not limited thereto.

The method of reinforcing the anchor pull-out strength of an existing exterior panel according to an embodiment of the present invention is a method of reinforcing the pull-out strength (or pull-out strength, pull-out strength) can be improved without disassembly or replacement.

Specifically, as shown in Figure 5, the method of reinforcing the anchor pulling strength of an existing installed exterior panel according to an embodiment of the present invention is,

Adding the quantity of anchors 120 to the previously installed exterior panel 110 with a shallow depth of 10 to 20 mm, connecting the exterior panel 110 and the building frame 200 without dismantling or replacing the exterior panel 110. The pullout strength of the anchor 120 joint can be increased.

Through this, structural performance can be improved and the number of anchors installed can be reduced, thereby contributing to improving constructability and construction productivity.

As shown in FIG. 5, a sufficient projected area cannot be secured due to the shallow embedment depth of the thin exterior panel 110, so additional embedment depth within the exterior panel 110 must be secured.

To this end, drilling is carried out in the concrete of the exterior panel 110 and the anchor 120 at the location of the previously installed anchor 120 from the outside to the inside of the exterior panel 110, and the microbolts 140 are installed. Secure a space (hole) to do this.

At this time, the end of the microbolt 140 exposed to the outside of the exterior panel 110 is cut into at least two or more branches so that each can be bent, which is when the microbolt 140 is inserted. Afterwards, the anchoring length can be secured so that the microbolts 140 are not pulled out from the outside of the exterior panel 110.

Therefore, after drilling the anchor, the micro bolt 140 is inserted and connected to the previously installed anchor 120, and then the existing installed anchor 120 and the micro bolt 140 are integrated using an epoxy adhesive as a bonding agent, thereby increasing the tensile force. enable it to be transmitted.

Through this method of reinforcing the anchor pulling strength of the existing installed exterior panel, the embedment depth (hef) of the anchor 120 within the thin exterior panel 110 can be maximized, and the existing projection area shown in FIG. 4 can be reduced to FIG. 5. The projected area can be increased after reinforcement as shown in .

Meanwhile, Figure 6 is an operation flowchart showing a method of reinforcing the anchor pull-out strength of an existing exterior panel according to the first embodiment of the present invention, and Figures 7A to 7D are respectively a method of reinforcing the anchor pulling strength of an existing exterior panel according to the first embodiment of the present invention. This is a cross-sectional view specifically showing the anchor pulling strength reinforcement method.

Referring to FIGS. 6 and 7A to 7D, the method for reinforcing the anchor pull-out strength of an existing exterior panel according to the first embodiment of the present invention is a method of reinforcing the anchor pull-out strength in an exterior panel previously installed on a building frame,

First, as shown in FIG. 7A, a drill is used to form a drill hole h through the previously installed exterior panel 110 to a predetermined depth of the anchor 120 (S110).

Here, a drilling hole (h), which is a space into which the microbolt 140 can be inserted up to the effective depth of the anchor, can be formed using a rotary or percussion drill.

Next, as shown in FIG. 7B, the bonding agent 130 is injected into the drilling hole (h) (S120).

Here, the bonding agent 130 is an epoxy adhesive, and can integrate the anchor 120 and the microbolt 140 to transmit the external load of the exterior panel 110.

Next, as shown in FIG. 7C, the microbolt 140 is inserted into the drilling hole (h) into which the binder was injected (S130).

Next, the tip of the microbolt 140, which is cut into at least two pieces, is bent and brought into close contact with the outer surface of the exterior panel 110 (S140).

Specifically, as shown in FIG. 7D, the microbolt 140 is a tip-cut microbolt with the tip cut into at least two pieces and bent and attached to the outer surface of the exterior panel 110,

The tip of the microbolt can be cut into at least two pieces and bent to be exposed to the outside of the exterior panel 110.

That is, the tip of the microbolt 140 is inserted and integrated into the anchor 120 to reinforce the anchor pulling strength, and the tip of the microbolt 140 is exposed to the outer surface of the exterior panel 110 and bent. It can be attached.

In addition, the microbolts 140 can secure a fixing length so that they are not pulled out of the exterior panel 110 after being inserted into the drilling hole.

Accordingly, the anchor 120 and the microbolt 140 are integrated by hardening of the binder 130, thereby reinforcing the anchor pulling strength (S150).

According to an embodiment of the present invention, by improving the anchor pulling performance of exterior panels already installed in curtain wall-type buildings with a risk of exterior material falling off and high-rise buildings in urban areas that must resist high wind speeds and wind pressures, earthquakes or building wind Damage to buildings, such as falling off exterior materials, that may occur due to this can be minimized.

[Second Example: Method of reinforcing anchor pulling strength of existing installed exterior panels]

Figure 8 is an operation flow chart showing a method of reinforcing the anchor pulling strength of an existing exterior panel according to a second embodiment of the present invention, and Figures 9A to 9F are respectively a method of reinforcing the anchor pulling strength of an existing exterior panel according to a second embodiment of the present invention. This is a cross-sectional view specifically showing the anchor pulling strength reinforcement method.

The method of reinforcing the anchor pull-out strength of an existing installed exterior panel according to the second embodiment of the present invention maximizes the effective area of influence (b ₀ ) by adding an external ring plate to the outside of the existing installed exterior panel 110. In order to do so,

After adding the ring plate 150 to the cut-out microbolt 140 installed from the outside to the inside, the tip of the microbolt 140 is bent and then welded to form the tip of the bent microbolt 140. The head and the ring plate 150 can be integrated.

Specifically, the ring plate 150 can maximize the effective area of concrete when a tensile force is applied to the anchor 120.

As described above, the pull-out strength of the inserted anchor 120 can be improved by increasing the projected area, which is the effective area of influence, through the installation of the ring plate 150. This is a reinforcement method that responds to concrete cracks that may occur due to the existing reinforcement method described above (a method of installing additional anchors between existing installed anchors). In particular, it overcomes the problem of not meeting the tensile performance of the anchor considered during reinforcement design. You can.

Referring to FIGS. 8 and 9A to 9G, the method of reinforcing the anchor pull-out strength of an existing exterior panel according to the second embodiment of the present invention is a method of reinforcing the anchor pull-out strength of an exterior panel previously installed in a building frame,

First, as shown in FIG. 9A, a drill is used to form a drill hole h through the previously installed exterior panel 110 to a predetermined depth of the anchor 120 (S210).

For example, a drilling hole (h), which is a space into which the microbolt 140 can be inserted up to the effective depth of the anchor, can be formed using a rotary or percussion drill.

Next, as shown in FIG. 9B, the bonding agent 130 is injected into the drilling hole (h) (S220).

Here, the bonding agent 130 is an epoxy adhesive, and can integrate the anchor 120 and the microbolt 140 to transmit the external load of the exterior panel 110.

Next, as shown in FIG. 9C, the ring plate 150 is placed on the outer surface of the exterior panel 110 (S230).

Here, the ring plate 150 is a ring-shaped plate with a through hole formed, and when a tensile force acts on the anchor 120, the projected area, which is the effective impact area of the concrete, is increased to increase the pullout strength (pulled out) of the anchor 120. strength) can be increased.

Next, as shown in FIG. 9D, the microbolt 140 is inserted through the ring plate 150 and the drilling hole (h) (S240).

Here, the microbolt 140 is a tip-cut microbolt with the tip cut into at least two pieces and bent and attached to the outer surface of the exterior panel 110, and the tip of the microbolt is cut into at least two pieces. It is manufactured to be bent and exposed to the outside of the ring plate 150.

That is, the tip of the microbolt 140 is inserted and integrated into the anchor 120 to reinforce the anchor pulling strength, and the tip of the microbolt 140 is exposed to the outer surface of the ring plate 150 and bent. It is welded.

Next, as shown in FIG. 9E, the peaks of each of the microbolts 140, which are cut into at least two pieces, are bent and brought into close contact with the upper surface of the ring plate 150 (S250).

Next, as shown in FIG. 9F, the cut microbolts 140 are welded to the ring plate 150 (S260).

Accordingly, the anchor 120 and the microbolt 140 are integrated by hardening of the binder 130, thereby reinforcing the anchor pulling strength (S270).

Ultimately, according to an embodiment of the present invention, sufficient anchor reinforcement performance can be achieved without installing additional anchors by reinforcing the pulling strength of the anchor by installing microbolts at existing anchor locations without dismantling or replacing the exterior panel.

According to an embodiment of the present invention, damage to the exterior panel or loss of cross-section can be prevented without compromising aesthetics without additional installation of anchors, which can occur in existing exterior panel reinforcement methods.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

110: exterior panel
120: anchor
130: Bonding agent (epoxy adhesive)
140: microvolt
150: Ring Plate

Claims (10)

In a method of reinforcing the pull-out strength of anchors in exterior panels previously installed on a building frame,
a) Using a drill to form a drill hole (h) through the previously installed exterior panel 110 to a predetermined depth of the anchor 120:
b) injecting a bonding agent 130 into the perforation hole (h);
c) inserting a microbolt (140) into the drilling hole (h) into which the bonding agent has been injected;
d) bending the tip of the microbolt 140, which is cut into at least two pieces, and bringing it into close contact with the outer surface of the exterior panel 110; and
e) a step of integrating the anchor 120 and the microbolt 140 by hardening the binder 130 to reinforce the anchor pulling strength,
The tip of the microbolt 140 is inserted and integrated into the anchor 120 to reinforce the anchor pull-out strength, and the tip of the microbolt 140 is exposed to the outer surface of the exterior panel 110. A method of reinforcing the anchor pullout strength of an existing installed exterior panel, characterized in that it is bent and attached. According to paragraph 1,
Reinforcing the anchor pull-out strength of the existing installed exterior panel, characterized in that in step a), a drilling hole (h), which is a space for inserting the microbolt 140 to the effective depth of the anchor, is formed using a rotary or percussion drill. method. According to paragraph 1,
The bonding agent 130 in step b) is an epoxy adhesive, and is characterized in that it integrates the anchor 120 and the microbolt 140 to transmit the external load of the exterior panel 110. Method of reinforcing the anchor pull-out strength of an existing installed exterior panel. According to paragraph 1,
The microbolt 140 is a tip-cut microbolt with the tip cut into at least two pieces and bent and attached to the outer surface of the exterior panel 110. The tip of the microbolt is cut into at least two pieces and bent. A method of reinforcing the anchor pull-out strength of an existing installed exterior panel, characterized in that the anchor is manufactured to be exposed to the outside of the exterior panel 110. According to paragraph 1,
A method of reinforcing the anchor pull-out strength of an existing installed exterior panel, characterized in that the microbolts (140) secure an anchoring length so that they are not pulled out of the exterior panel (110) after being inserted into the perforated hole. In a method of reinforcing the pull-out strength of anchors in exterior panels previously installed on a building frame,
a) Using a drill to form a drill hole (h) through the previously installed exterior panel 110 to a predetermined depth of the anchor 120:
b) injecting a bonding agent 130 into the perforation hole (h);
c) placing a ring plate 150 on the outer surface of the exterior panel 110;
d) inserting a microbolt 140 through the ring plate 150 and the drilling hole (h);
e) bending the peaks of each of the microbolts 140, which are cut into at least two pieces, and bringing them into close contact with the upper surface of the ring plate 150;
f) welding the cut microbolts 140 to the ring plate 150; and
g) integrating the anchor 120 and the microbolt 140 by hardening the binder 130 to reinforce the anchor pulling strength,
The tip of the microbolt 140 is inserted and integrated into the anchor 120 to reinforce the anchor pulling strength, and the tip of the microbolt 140 is exposed to the outer surface of the ring plate 150 and is bent and welded. A method of reinforcing the anchor pullout strength of an existing installed exterior panel. According to clause 6,
The ring plate 150 increases the projected area, which is the effective impact area of the concrete, when a tensile force acts on the anchor 120, thereby increasing the pulling strength of the anchor 120. Strength reinforcement method. According to clause 6,
Reinforcing the anchor pull-out strength of the existing installed exterior panel, characterized in that in step a), a drilling hole (h), which is a space for inserting the microbolt 140 to the effective depth of the anchor, is formed using a rotary or percussion drill. method. According to clause 6,
The bonding agent 130 in step b) is an epoxy adhesive, and is characterized in that it integrates the anchor 120 and the microbolt 140 to transmit the external load of the exterior panel 110. Method of reinforcing the anchor pull-out strength of an existing installed exterior panel. According to clause 6,
The microbolt 140 is a tip-cut microbolt with the tip cut into at least two pieces and bent and attached to the outer surface of the exterior panel 110. The tip of the microbolt is cut into at least two pieces and bent. A method of reinforcing the anchor pull-out strength of an existing installed exterior panel, characterized in that it is manufactured so that it can be exposed to the outside of the ring plate (150).