KR102599119B1 - Fiber reinforced polymer anchor insertion device - Google Patents

Abstract

The present invention involves inserting an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber reinforced polymer (FRP) sheet, comprising: a cylindrical body portion having a length in a horizontal line; an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retreat prevention plate are supported by a spring; a handle extending from the other side of the body and held by the user with his/her hand; an insertion lever rotatably coupled to the handle portion about a hinge axis and selectively advancing the insertion rod by pressing the guide plate with a pressing member formed on an upper side; and a wiper member provided at one end of the body portion, which steals and collects the epoxy resin applied to the FRP anchor while advancing the FRP anchor through a through hole formed in the center. Including, before inserting the FRP anchor, the FRP anchor. By stealing and collecting the applied epoxy resin, waste of epoxy resin can be reduced as excessive epoxy resin is not used, and by using the perforated member provided in the front of the body, the FRP sheet is used to secure a hole into which the FRP anchor will be inserted. Provides a fiber-reinforced polymer anchor insertion device that can secure a hole into which an FRP anchor will be inserted without the need for cutting, thereby shortening the installation time of the FRP anchor.

Description

Fiber reinforced polymer anchor insertion device}

The present invention relates to a fiber reinforced polymer (FRP) anchor insertion device, and more specifically, to a fiber anchor coated with epoxy resin in a structure reinforced by attachment of a fiber reinforced polymer (FRP) sheet. It relates to a fiber-reinforced polymer anchor insertion device that is inserted into a structure.

In general, bridge girder beams, floor slabs, and column structures are mainly made of reinforced concrete, so after completion, cracks and sagging occur due to aging of the concrete. In particular, if the crack exceeds the allowable crack width, the safety of the structure is affected. Since deflection can also cause a decrease in the rigidity of the structure, various reinforcement methods have already been developed to prevent threats to safety and decrease in rigidity due to cracks and deflection of such structures.

As a method of improving the seismic performance of aging non-seismic structures, FRP (Fiber-reinforced polymer) is used to continuously attach fiber-reinforced sheets (or plates) such as carbon fiber, aramid fiber, and glass fiber to the reinforced portion of the structure. ) reinforcement method is applied.

However, the general FRP reinforcement method causes a delamination phenomenon in which the concrete and FRP sheets are separated in members such as beams, slabs and masonry walls of the structure, resulting in a decrease in reinforcement performance.

In other words, the conventional FRP reinforcement method is a problem of securing adhesion strength for the integral behavior of the fiber-reinforced sheet (or plate) and the structure, which means that if the adhesion strength is insufficient, the fiber-reinforced sheet (or plate) and the structure do not behave as one. This is because the reinforcing effect due to the attachment of the fiber-reinforced sheet (or plate) is almost lost.

In particular, when attaching a fiber-reinforced sheet (plate) to a structure using an adhesive such as epoxy resin to secure the required adhesion strength, although there are differences depending on the degree of construction quality, the adhesion is such that it bites off the concrete in the reinforced part of the structure. In the case of using a strong adhesive, no matter how high the performance of the adhesive is, the adhesion strength of the fiber-reinforced sheet (plate) is ultimately dominated by the tensile strength of the concrete, so the adhesion strength of the fiber-reinforced sheet (plate) is increased by the adhesive. There is a limit to what you can do.

Furthermore, the method of using such an adhesive requires the prerequisite of securing a sufficient length to attach a fiber-reinforced sheet (plate) having a certain width to the structure, and this attachment area is usually limited by the geometric shape of the structure, etc. In cases where it is difficult to sufficiently secure the same due to field conditions, there is a problem that the fracture of the interface between the concrete of the structure and the fiber-reinforced sheet (or plate) precedes the fracture of the fiber-reinforced sheet (or plate).

As a result, it is not easy to secure the performance of the fiber-reinforced sheet (or plate) as it was designed.

For prior art, please refer to Registered Patent No. 10-2258151 (May 24, 2021).

Additionally, as another FRP reinforcement method, the method using FRP anchors is emerging as a new alternative.

However, there are problems in that the FRP sheet must be cut to secure the FRP anchor hole, excessive epoxy resin is wasted during installation (insertion) of the FRP anchor, and installing the FRP anchor in a small hole is very cumbersome and difficult compared to the time required to attach the FRP sheet. There was a problem that anchor installation took a long time.

The present invention allows the epoxy resin applied to the FRP anchor to be stolen and collected before inserting the FRP anchor, so that excessive epoxy resin is not used, thereby reducing the waste of epoxy resin, and by using the perforated member provided in the front of the body, FRP The purpose is to provide a fiber-reinforced polymer anchor insertion device that can secure a hole into which an FRP anchor will be inserted without the need to cut the FRP sheet to secure a hole into which the anchor will be inserted, thereby shortening the FRP anchor installation time.

The fiber-reinforced polymer anchor insertion device according to the present invention is a fiber-reinforced polymer anchor insertion device for inserting an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber-reinforced polymer (FRP) sheet, A cylindrical body portion having an internal space; an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retraction prevention plate are supported by a spring; an insertion lever connected to the insertion rod and selectively advancing the insertion rod; and a wiper member provided at one end of the body, which steals and collects the epoxy resin applied to the FRP anchor while advancing the FRP anchor through a through hole formed in the center, wherein the body has an insertion rod inside the body. It is provided on the lower side and includes a stand that supports the FRP anchor inserted and fixed to the insertion rod.

At this time, it extends from the other side of the body part according to the present invention and further includes a handle part that the user holds with his hand.

And the insertion lever according to the present invention is rotatably coupled to the handle portion about a hinge axis, and presses the guide plate with a pressing member formed on the upper side.

In addition, the fiber-reinforced polymer anchor insertion device according to the present invention is a fiber-reinforced polymer anchor insertion device for inserting an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber-reinforced polymer (FRP) sheet, A cylindrical body portion having an internal space therein; an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retraction prevention plate are supported by a spring; an insertion lever connected to the insertion rod and selectively advancing the insertion rod; and a wiper member provided at one end of the body, which steals and collects the epoxy resin applied to the FRP anchor while advancing the FRP anchor through a through hole formed in the center, wherein the insertion rod is installed on one side of the FRP anchor. An anchor rod fixing hole is formed into which the rod is inserted, and a support flange supported on one end of the spring is formed at one point along the length extending in the circumferential direction.

delete

In addition, the fiber-reinforced polymer anchor insertion device according to the present invention is a fiber-reinforced polymer anchor insertion device that inserts an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber-reinforced polymer (FRP) sheet, A cylindrical body portion having an internal space; an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retraction prevention plate are supported by a spring; an insertion lever connected to the insertion rod and selectively advancing the insertion rod; and a wiper member provided at one end of the body, which steals and collects the epoxy resin applied to the FRP anchor while advancing the FRP anchor through a through hole formed in the center, wherein the body is coupled to one outer surface of the body. , when one side collides with the FRP sheet, it perforates the FRP sheet, and includes a perforation module that opens when the FRP anchor advances from the inside of the body to one side.

At this time, the perforated module according to the present invention is arranged symmetrically on one outer surface of the body part, the opposing sides are arranged so that they are in contact, and the other end is rotatably coupled to the hinge axis, a first perforated member and a second perforated member , It is provided on the other side of each of the first perforated member and the second perforated member, and includes a support spring that provides elasticity while supporting the first perforated member and the second perforated member.

In addition, the perforated module according to the present invention is coupled to the front surface of the body portion and includes a fixing bracket to which the first perforated member and the second perforated member are rotatably coupled to the hinge axis.

The effects exhibited by the fiber-reinforced polymer anchor insertion device according to the present invention are as follows.

Before inserting the FRP anchor into the hole formed in the structure, the epoxy resin applied to the FRP anchor is stolen and collected, so that excessive epoxy resin is not used, which has the effect of reducing the waste of epoxy resin.

In order to secure a hole for inserting an FRP anchor, a hole can be secured by perforating an FRP sheet by using a perforated member without the need to cut the FRP sheet.

Since an access road is secured and guided to the hole formed in the structure by the perforated member, it is easy to install the FRP anchor in a small hole.

Since FRP anchors are installed in the structure by injection, the installation time of FRP anchors is shortened compared to before.

Figure 1 is a reference diagram showing a fiber-reinforced polymer anchor insertion device according to an embodiment of the present invention.
Figure 2 is an illustrative diagram showing an example of use of a fiber-reinforced polymer anchor insertion device according to an embodiment of the present invention.
Figure 3 is an illustrative diagram showing another example of an epoxy receiving portion and a perforated member according to an embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. Based on the principle of definability, it must be interpreted with meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent the entire technical idea of the present invention, so at the time of filing this application, they can be replaced by equivalent equivalents. It should be understood that variations may exist.

The present invention allows the epoxy resin applied to the FRP anchor to be stolen and collected before inserting the FRP anchor, so that excessive epoxy resin is not used, thereby reducing the waste of epoxy resin, and by using the perforated member provided in the front of the body, FRP This relates to a fiber-reinforced polymer anchor insertion device that can secure a hole into which an FRP anchor will be inserted without the need to cut the FRP sheet to secure a hole into which the anchor will be inserted, thereby shortening the installation time of the FRP anchor. Referring to the drawings, As follows.

Referring to Figures 1 to 3, the fiber-reinforced polymer anchor insertion device according to an embodiment of the present invention is a fiber-reinforced polymer anchor insertion device that inserts an FRP anchor soaked in epoxy resin into a hole formed in a structure to which an FRP sheet is attached. It relates to and includes a body portion 100, an insertion rod 200, a handle portion 300, and an insertion lever 400.

First, the body portion 100 is cylindrical with a hollow space inside, and has a horizontal length.

At this time, an opening is formed on the side of the body 100 through which the FRP anchor 10 immersed in epoxy resin can be introduced into the internal space of the body 100.

Also, a wiper member 110 is provided at one end of the body portion 100. The wiper member 110 is made of rubber or silicone, which is an elastic material, and has a through hole 111 at its center. do.

The through hole 111 is a hole through which the FRP anchor 10 passes when the FRP anchor 10 accommodated in the inner space of the body 100 advances to the outside, and the FRP anchor 10 passes through the through hole. When passing (111). The wiper member 110 steals and collects the epoxy resin applied to the FRP anchor 10.

At this time, the through hole 111 may be formed by cutting into a '+' or '*' shape, or may be a hole formed relatively smaller than the corresponding diameter of the FRP anchor 10.

Therefore, when the FRP anchor 10 accommodated in the internal space of the body 100 passes through the through hole 111 of the wiper member 110, the inner peripheral surface of the through hole 111 is the FRP anchor 10. ), the epoxy resin applied to the surface of the FRP anchor 10 is collected, and the epoxy resin applied to the FRP anchor 10 is prevented from advancing to the outside in an excessively applied state.

And the body portion 100 is provided with an epoxy accommodating portion 120 at the lower portion of one side of the internal space where the wiper member 110 is provided. The epoxy accommodating portion 120 is formed by the wiper member 110. Accepts stolen and collected epoxy resin.

At this time, the epoxy resin contained in the epoxy receiving portion 120 is selectively taken out and reused when the FRP anchor 10 is immersed in the epoxy resin.

Here, the epoxy accommodating part 120 may be selectively and detachably provided on the outer surface of the body part 100.

In addition, an insertion rod 200 is provided to be movable along the longitudinal direction of the center of the internal space of the body portion 100, and the other side of the insertion rod 200 is connected to a spring 210 on the other side of the body portion 100. It is provided with a supported guide plate 220 and a retreat prevention plate 230.

At this time, it is preferable to form an anchor rod fixing hole 201 into which the rod of the FRP anchor 10 is inserted at one end of the insert rod 200 located in the inner space of the body 100, and the insertion The other end of the rod 200 is located outside the other side of the body portion 100.

Here, looking at the spring 210 and the guide plate 220 provided on the other side of the insertion rod 200, the spring 210 is a coil spring, and the other side of the insertion rod 200 is located at the inner center of the coil. It penetrates, and the guide plate 220 is adjacent to and supported on the other side of the spring 210.

At this time, a hole having an inner diameter relatively larger than the diameter of the insertion rod 200 is formed in the center of the guide plate 220, and the other side of the insertion rod 200 penetrates the hole.

A pressing force is selectively applied to the guide plate 220. At this time, the applied pressure presses the lower side of the guide plate 220 in one direction so that the guide plate 220 lies diagonally inclined, and the guide plate ( When 220) lies down, the inner peripheral surface of the hole of the guide plate 220 comes into contact with the surface of the insertion rod 200 to apply frictional force.

Accordingly, the lying guide plate 220 hooks the insertion rod 200 and causes the insertion rod 200 to move in one direction.

And when the pressing force applied to the guide plate 220 is released, the guide plate 220 is erected vertically by the elasticity of the spring 210 and the hole of the guide plate 220 and the insertion rod 200 The state in which the surface is flat is released, and the guide plate 220 moves to the other side along the length of the insertion rod 200 and returns to its original position.

Therefore, when the above process is continuously repeated, the insertion rod 200 gradually moves forward.

The anti-retraction plate 230 is provided at the other end of the body portion 100, and the anti-retraction plate 230 is also provided in a state supported by the spring 210.

At this time, a hole having an inner diameter relatively larger than the diameter of the insertion rod 200 is formed in the center of the anti-retraction plate 230, and the other side of the insertion rod 200 penetrates the hole.

And the upper side of the anti-retraction plate 230 is rotatably connected to the body 100, so that the anti-retraction plate 230 is provided to be tilted diagonally.

Here, the anti-retraction plate 230 is tilted in the opposite direction to the guide plate 220 by the elasticity of the spring 210, and the inner peripheral surface of the hole of the receding prevention plate 230 laid down is the insert rod. It provides frictional force by interviewing the surface of (200).

At this time, the insertion rod 200 is prevented from retracting by the frictional force of the retraction prevention plate 230 provided.

Therefore, when retracting the insertion rod 200, the user presses the bottom of the anti-retraction plate 230 to erect the anti-retraction plate 230 vertically, and then pulls the other side of the insertion rod 200. retreat.

The other side of the insert rod 200 located outside the other side of the body portion 100 is bent at a right angle to form a grip portion, so that the user pulls the grip portion by hand to insert the insert rod 200 into the body. It can be selectively moved backward along the longitudinal direction from the center of the internal space of the unit 100.

Additionally, a handle portion 300 is extended to the other side of the body portion 100, and the handle portion 300 allows the user to hold it with his or her hand.

An insertion lever 400 is rotatably coupled to the handle portion 300 about the hinge axis, and the insertion lever 400 selectively rotates about the hinge axis to press the guide plate (not shown) formed on the upper side. 220) is pressed to selectively advance the insertion rod 400.

And the body portion 100 according to an embodiment of the present invention is provided with a pedestal 140 on the lower side of the insertion rod 200, and the pedestal 140 is inserted and fixed to the insertion rod 200. Supports the FRP anchor (10).

Therefore, the pedestal prevents the FRP anchor 10 inserted and fixed to the insertion rod 200 from sagging down due to the load, so that the FRP anchor 10 can easily be inserted into the through hole 111 of the wiper member 110. ) to be inserted.

At this time, the other side of the pedestal 140 forms an inclined surface 141, and the FRP anchor 10 is guided to the through hole 111 of the wiper member 110 along the inclined surface 141.

In addition, the body portion 100 is provided with a perforation module 130 on one outer surface thereof. The perforation module 130 is cone-shaped, and when one sharp side collides with the FRP sheet, it perforates the FRP sheet, and the body portion ( When the FRP anchor 10 advances from the inside of the body 100 in one direction, the FRP anchor 10 advances from the inside of the body 100 by opening up and down or left and right.

At this time, the perforated module 130 includes a first perforated member 131, a second perforated member 132, and a support spring 134. The first perforated member 131 and the second perforated member 132 are disposed symmetrically on one outer surface of the body portion 100, so that opposing sides are in contact with each other, and the other side end is rotatably coupled to the hinge axis 133.

And a support spring 134 is provided on the other side of each of the first perforated member 131 and the second perforated member 132. The support spring 134 is connected to the first perforated member 131 and the second perforated member 132. By supporting (132) and providing an elastic repulsion force, the first perforated member 131 and the second perforated member 132 are always anastomosed.

Accordingly, the first perforated member 131 and the second perforated member 132 remain anastomosed to each other by the elastic repulsion force of the support spring 134 and are connected to the FRP anchor in one direction inside the body portion 100. When (10) advances, the first perforated member 131 and the second perforated member 132 rotate about the hinge axis to open the door due to the advancing force of the FRP anchor 10.

In addition, the perforated module 130 includes a fixing bracket 135, which is in the form of a tube with a hollow interior, and the other end of which is selectively attached to one outer surface of the body portion 100. Combine.

At this time, a coupling flange 136 is formed extending in the radial direction at the other end of the fixing bracket 135, and a coupling portion 101 corresponding to the coupling flange 136 is formed at one end of the body portion 100. form

A plurality of coupling flanges 136 are arranged radially at regular intervals with respect to the center line of the fixing bracket 135, and a plurality of coupling flanges of the body portion 100 are also formed in a plurality of the coupling flanges 136. ) are arranged radially at regular intervals from each other on one side of the center line, and the coupling portion 101 is formed so that only one side is open,

When coupling the fixing bracket 135 to the body 100, the fixing bracket 135 is positioned so that the coupling flanges 136 of the fixing bracket 135 are positioned between the coupling portions of the body 100. After interviewing one side of the body portion 100, the fixing bracket 135 is rotated toward the opening of the coupling portion 101, and the coupling flange 136 is inserted into the coupling portion 101. , the fixing bracket 135 is coupled to the body.

And one side of the fixing bracket 135 includes a first perforated member 131, a second perforated member 132, and a support spring 134. The first perforated member 131 and the second perforated member (132) is arranged symmetrically on one side of the fixing bracket (135), so that the opposing sides are in contact with each other, and the other side end is rotatably coupled to the hinge axis (133).

And a support spring 134 is provided on the other side of each of the first perforated member 131 and the second perforated member 132. The support spring 134 is connected to the first perforated member 131 and the second perforated member 132. By supporting (132) and providing an elastic repulsion force, the first perforated member 131 and the second perforated member 132 are always anastomosed.

Accordingly, the first perforated member 131 and the second perforated member 132 remain anastomosed to each other by the elastic repulsion force of the support spring 134 and are connected to the FRP anchor in one direction inside the body portion 100. When (10) advances, the first perforated member 131 and the second perforated member 132 rotate about the hinge axis to open the door due to the advancing force of the FRP anchor 10.

The perforation module 130 may be integrally provided on one side of the body 100, or may be selectively detachable. After the user holds the body, the sharp one side collides with the FRP sheet. When the FRP anchor 10 advances from the inside of the body 100 in one direction, the first perforation member 131 and the second perforation member 132 of the perforation module 130 The door is opened up and down or left and right to allow the FRP anchor 10 to advance from the inside of the body 100.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

10: FRP anchor 100: body part
101: coupling portion 110: wiper member
111: Through hole 120: Epoxy receiving portion
130: perforated member 131: first perforated member
132: Second perforated member 133: Hinge axis
134: support spring 135: fixing bracket
136: coupling flange 140: pedestal
141: slope 200: insertion rod
201: anchor rod fixing hole 210: spring
220: Guide plate 230: Retraction prevention plate
300: Handle 400: Insertion lever

Claims (9)

In the fiber reinforced polymer (FRP) anchor insertion device for inserting an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber reinforced polymer (FRP) sheet,
A cylindrical body portion having an internal space therein;
an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retreat prevention plate are supported by a spring;
an insertion lever connected to the insertion rod and selectively advancing the insertion rod; and
A wiper member provided at one end of the body portion and advancing the FRP anchor through a through hole formed in the center while stealing and collecting the epoxy resin applied to the FRP anchor;
The body part
A fiber-reinforced polymer anchor insertion device including a support provided on the lower side of the insertion rod and supporting the FRP anchor inserted and fixed to the insertion rod.
In claim 1,
A fiber-reinforced polymer anchor insertion device further comprising a handle portion extending from the other side of the body portion and held by a user with his/her hand.
In claim 2,
The insertion lever is
A fiber-reinforced polymer anchor insertion device that is rotatably coupled to the handle portion about a hinge axis and pressurizes the guide plate with a pressing member formed on the upper side.
In claim 1,
The body part
A fiber-reinforced polymer anchor insertion device that is provided at a lower portion of one side of the inner space where the wiper member is provided and includes an epoxy receiving portion that accommodates the epoxy resin stolen and collected by the wiper member.
In the fiber reinforced polymer (FRP) anchor insertion device for inserting an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber reinforced polymer (FRP) sheet,
A cylindrical body portion having an internal space therein;
an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retreat prevention plate are supported by a spring;
an insertion lever connected to the insertion rod and selectively advancing the insertion rod; and
A wiper member provided at one end of the body portion and advancing the FRP anchor through a through hole formed in the center while stealing and collecting the epoxy resin applied to the FRP anchor;
The insert rod is
An anchor rod fixing hole is formed on one side into which the rod of the fiber anchor is inserted,
A fiber-reinforced polymer anchor insertion device having a support flange supported on one end of a spring extending in the circumferential direction at one point along the length.
delete In the fiber reinforced polymer (FRP) anchor insertion device for inserting an FRP anchor coated with epoxy resin into a structure reinforced by attaching a fiber reinforced polymer (FRP) sheet,
A cylindrical body portion having an internal space therein;
an insertion rod provided along the longitudinal direction of the center of the inner space of the body portion and through which a guide plate and a retreat prevention plate are supported by a spring;
an insertion lever connected to the insertion rod and selectively advancing the insertion rod; and
A wiper member provided at one end of the body portion and advancing the FRP anchor through a through hole formed in the center while stealing and collecting the epoxy resin applied to the FRP anchor;
The body part
A fiber-reinforced polymer anchor insertion device including a perforation module that is coupled to the outer surface of one side, perforates the FRP sheet when one side collides with the FRP sheet, and opens when the FRP anchor advances from the inside of the body in one direction.
In claim 7,
The perforated module is
a first perforated member and a second perforated member arranged symmetrically on one outer surface of the body part so that opposing sides are in contact with each other and the other end is rotatably coupled to a hinge axis;
A fiber-reinforced polymer anchor insertion device comprising a support spring provided on the other side of each of the first perforated member and the second perforated member and providing elasticity while supporting the first perforated member and the second perforated member.
In claim 8,
The perforated module is
Coupled to the front surface of the body portion,
A fiber-reinforced polymer anchor insertion device including a fixing bracket to which the first perforated member and the second perforated member are rotatably coupled to a hinge axis.

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