KR102213860B1 - Reinforcement method and structure of reinforced concrete member using steel plates and wires - Google Patents

Abstract

The reinforcing structure of a reinforced concrete member using a steel plate and a wire according to the present invention includes a reinforced concrete member; A wire wrapped around the outer surface of the reinforced concrete member; A wire protection member through which the wire passes and is located at an edge of the reinforced concrete member; Both ends of the wire; And a reinforcing plate having a protruding insertion portion formed at a corresponding position to accommodate the wire and the wire protection member.

Description

Reinforced concrete member reinforcement method and structure using steel plate and wire{REINFORCEMENT METHOD AND STRUCTURE OF REINFORCED CONCRETE MEMBER USING STEEL PLATES AND WIRES}

The present invention relates to a reinforced concrete member reinforcement method and structure, and more particularly, to a reinforced concrete member reinforcement method and structure using a reinforced steel plate and wire.

Structures are damaged or deteriorated by various factors. Therefore, repair and reinforcement are required in order to increase the strength of damaged or aging structures to extend the physical lifespan and to exhibit the original function.

In particular, in reinforced concrete columns, the transverse reinforcing bars that properly confine the concrete are often not sufficiently used, so when an earthquake occurs, the lateral deformation of the column easily occurs, resulting in brittle fracture.

There are various reinforcement methods for reinforced concrete structures to compensate for this, but in general, a method of attaching a member having high ductility such as a steel plate to the structure by using an epoxy bonding method is widely used. This is because by attaching members with high ductility, it can play a role in delaying the damage of concrete under compressive loads and leading the ductile behavior of reinforced concrete structures. This has a great advantage in that the construction period is short and can be applied to structures in use, but there is a problem that peeling and dropping of the reinforcing material may occur because the parent body and the reinforcing material are attached rather than integrally.

As described above, in the prior art, in addition to the steel plate, a reinforcing material such as carbon fiber or fiber plate is bonded to the reinforced concrete structure to reinforce it, and a method using an epoxy resin as an adhesive is mainly used. This is because it is known in the field of repair and reinforcement technology that a sufficient reinforcing effect can be obtained simply by bonding a reinforcing material to the structure surface with an epoxy adhesive.

However, the epoxy used as an adhesive has a problem in that the coefficient of linear expansion (the degree to which the material expands and contracts according to the temperature change) is different from that of concrete, so that the phenomenon of spontaneous peeling occurs according to the temperature environment change. Accordingly, the biggest problem is that when the adhesive peeling phenomenon of the epoxy occurs before the reinforcing effect of the reinforcing material is exerted, the reinforcing effect by the reinforcing material cannot be expected at all.

In addition, the reinforcing method of bonding a reinforcement material to the surface of a reinforced concrete structure using an adhesive such as an epoxy resin requires the step of surface-treating the adhesive surface of the concrete structure to which the reinforcement material is adhered. This is to increase the adhesion of the epoxy and is carried out in more complex steps than the general surface treatment steps.Since this surface treatment is performed using a grinder and sandpaper, a lot of dust is generated, so there is a problem that it is difficult to treat dust depending on the working environment. .

In addition, in the reinforcing method of bonding a reinforcement material to the surface of a reinforced concrete structure using an adhesive such as an epoxy resin, an epoxy-based adhesive is injected at a certain thickness, cured, and compressed to integrate the concrete and the reinforcing material. However, it takes a considerable amount of time to cure the epoxy, and shrinkage occurs in the epoxy. Therefore, it is difficult to directly observe the bonding interface structure between the structure surface and the reinforcing material, so that it is difficult to determine the crack of the concrete, and there is a problem that it is not possible to accurately determine whether the reinforcing material is peeled.

In particular, it is widely known that epoxy-based adhesives contain flammable materials and thus have an environmental problem of generating toxic gases while burning when a fire occurs. In recent years, social demand for eco-friendly construction methods has continuously increased even at construction sites, and accordingly, the need for construction methods using eco-friendly adhesives or members to replace epoxy adhesives has emerged.

Korean Patent Registration No. 10-1553205

The present invention is an invention conceived to solve the problems of the prior art described above, when reinforcing reinforced concrete beams or columns, without using a large amount of adhesive such as epoxy on the entire bonding surface to attach the reinforcement to the concrete structure. It is intended to provide a construction method and a structure using the reinforcement material, which minimizes the use and allows the structure and the reinforcing material to be fastened using bolts and nuts to effectively exert the reinforcement effect by the reinforcing material without being affected by the performance and construction conditions of the adhesive epoxy. will be.

In addition, since a reinforcing structure can be formed with a simple configuration, it does not require construction expertise, and it is intended to provide a reinforcement method and a structure using the same, which are effective in reducing construction costs as well as shortening construction time.

The problems of the present invention are not limited to the problems mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

The reinforcing structure of a reinforced concrete member using a steel plate and a wire according to the present invention includes a reinforced concrete member; A wire wrapped around the outer surface of the reinforced concrete member; A wire protection member through which the wire passes and is located at an edge of the reinforced concrete member; Both ends of the wire; And a reinforcing plate having a protruding insertion portion formed at a corresponding position to accommodate the wire and the wire protection member.

In the reinforcing structure of a reinforced concrete member using a steel plate and a wire according to the present invention, the protruding insertion portion may further include an observation portion capable of confirming the wire.

In the reinforcing structure of a reinforced concrete member using a steel plate and a wire according to the present invention, the wire may be selected from a synthetic fiber wire rope, a stainless wire rope, a coated wire rope, and a shape memory alloy wire rope, and both ends of the wire are fastened. The part may be fastened using one or more of a socket, a timbre, a clip, a turnbuckle, and an eye bolt.

In the reinforcement structure of a reinforced concrete member using a steel plate and a wire according to the present invention, a through hole is additionally formed in the reinforcement plate, and a bolt connecting the outer surface of the reinforced concrete member and the reinforcement plate is fastened through the through hole. Can be.

In the reinforcing structure of a reinforced concrete member using a steel plate and a wire according to the present invention, an anchor receiving portion is formed on the outer surface of the reinforced concrete member; The through hole of the reinforcing plate is formed at a position corresponding to the position of the anchor receiving part; An anchor is embedded in the anchor receiving portion; The bolt is fastened to the anchor; In addition, in order to fix the reinforcement plate to the outer surface of the reinforced concrete member, a first nut may be fastened to the bolt penetrating through the through hole of the reinforcing plate.

The method of reinforcing a reinforced concrete member using a steel plate and a wire according to the present invention comprises the steps of: forming a protruding insert capable of receiving a wire and a wire protection member on the reinforcing plate; Wrapping a wire on the outer surface of the reinforced concrete member; Penetrating the wire through a wire protection member; Positioning the wire protection member at the edge of the reinforced concrete member; Forming fastening portions at both ends of the wire; And fixing the reinforcing plate to the outer surface of the reinforced concrete member so that the wire and the wire protection member are positioned in the protruding insertion portion.

In the method of reinforcing a reinforced concrete member using a steel plate and a wire according to the present invention, the protruding insertion portion may further include an observation portion capable of confirming the wire.

In the method of reinforcing a reinforced concrete member using a steel plate and a wire according to the present invention, the wire may be selected from synthetic fiber wire rope, stainless wire rope, coated wire rope, and shape memory alloy wire rope, and both ends of the wire are fastened. The part may be fastened using one or more of a socket, a timbre, a clip, a turnbuckle, and an eye bolt.

In the reinforcement method of a reinforced concrete member using a steel plate and a wire according to the present invention, a through hole is additionally formed in the reinforcement plate, and a bolt connecting the outer surface of the reinforced concrete member and the reinforcement plate is fastened through the through hole. Can be.

In the reinforced concrete member reinforcement method using a steel plate and wire according to the present invention, an anchor receiving portion is formed on the outer surface of the reinforced concrete member; The through hole of the reinforcing plate is formed at a position corresponding to the position of the anchor receiving part; An anchor is embedded in the anchor receiving portion; The bolt is fastened to the anchor; In addition, in order to fix the reinforcement plate to the outer surface of the reinforced concrete member, a first nut may be fastened to the bolt penetrating through the through hole of the reinforcing plate.

The method of reinforcing a reinforced concrete member using a steel plate according to the present invention comprises: forming an anchor receiving portion on the outer surface of the reinforced concrete member; Forming a through hole at a position corresponding to the position of the anchor receiving part in the reinforcing plate; Embedding an anchor in the anchor receiving portion; Fastening a bolt to the anchor; And passing the bolt through the through hole of the reinforcing plate and fastening the first nut to fix the reinforcing plate to the outer surface of the reinforced concrete member.

The method of reinforcing a reinforced concrete member using a steel plate according to the present invention further includes forming a first spring receiving part on the anchor receiving part after the step of forming an anchor receiving part on the outer surface of the reinforced concrete member And, the diameter of the first spring receiving portion may be formed to be greater than or equal to the diameter of the anchor receiving portion.

The method of reinforcing a reinforced concrete member using a steel plate according to the present invention may further include positioning a first spring in the first spring receiving portion.

The method of reinforcing a reinforced concrete member using a steel plate according to the present invention may further include installing a spring protection part in the first spring receiving part.

The method of reinforcing a reinforced concrete member using a steel plate according to the present invention includes the steps of installing a second spring on the first nut; And installing a second nut on the second spring.

In the reinforcement method of a reinforced concrete member using a steel plate according to the present invention, the first nut includes a first fixing groove, the second nut includes a second fixing groove, and one end of the second spring is It is located in the first fixing groove of the first nut, the other end of the second spring may be located in the second fixing groove of the second nut.

The method of reinforcing a reinforced concrete member using a steel plate according to the present invention may further include fastening a nut cap to the bolt so as to surround the first nut, the second spring and the second nut.

In the method of reinforcing reinforced concrete members using a steel plate according to the present invention, a washer may be installed between the reinforcing plate and the first nut.

In the method of reinforcing reinforced concrete members using a steel plate according to the present invention, the reinforcing plate may be selected from a steel plate, a section steel, and an FRP reinforcement plate.

In the method of reinforcing a reinforced concrete member using a steel plate according to the present invention, the reinforcing plate may be formed as a single layer or may be formed in a multilayer structure in which fibers or plastic sheets are laminated.

Reinforced concrete structure reinforced including a steel plate according to the present invention, a reinforced concrete member; An anchor receiving portion formed on the outer surface of the reinforced concrete member; A reinforcing plate having a through hole formed at a position corresponding to the position of the anchor receiving portion; An anchor embedded in the anchor receiving portion; A bolt fastened to the anchor; And a first nut that is fastened with the bolt penetrating the through hole of the reinforced concrete member to fix the reinforcement plate to the outer surface of the reinforced concrete member.

The reinforced concrete structure including a steel plate according to the present invention further includes a first spring receiving portion formed on the anchor receiving portion formed on the outer surface of the reinforced concrete member, and the first spring receiving portion has a diameter It may be formed to be greater than or equal to the diameter of the anchor receiving portion.

The reinforced concrete structure reinforced including the steel plate according to the present invention may further include a first spring positioned in the first spring receiving portion.

In the reinforced concrete structure including the steel plate according to the present invention, a spring protection part may be additionally installed in the first spring receiving part.

The reinforced concrete structure reinforced including a steel plate according to the present invention includes: a second spring positioned above the first nut; And a second nut positioned above the second spring.

In the reinforced concrete structure reinforced including a steel plate according to the present invention, the first nut includes a first fixing groove, the second nut includes a second fixing groove, and one end of the second spring is It is located in the first fixing groove of the first nut, the other end of the second spring may be located in the second fixing groove of the second nut.

The reinforced concrete structure reinforced including the steel plate according to the present invention may further include a nut cap fastened to the bolt so as to surround the first nut, the second spring and the second nut.

In the reinforced concrete structure including the steel plate according to the present invention, a washer may be installed between the reinforcement plate and the first nut.

In the reinforced concrete structure including the steel plate according to the present invention, the reinforcement plate may be selected from a steel plate, a section steel, and an FRP reinforcement plate.

In the reinforced concrete structure including the steel plate according to the present invention, the reinforcement plate may be formed as a single layer, or may be formed in a multilayer structure in which fibers or plastic sheets are laminated.

The method of reinforcing reinforced concrete members using the improved steel plate and/or wire of the present invention and the reinforcing structure using the same have the following effects.

First, it is possible to induce the improvement of ductility and strength performance of reinforced concrete members by appropriately restraining the concrete with insufficient ductility.

Second, by introducing external stress using a wire, it is possible to secure the weight reduction and durability improvement of the steel plate reinforcement material compared to the existing steel plate reinforcement method.

Third, compared to the conventional steel plate reinforcement method using an epoxy-based adhesive, the difficulty of work is low and construction expertise is not required, so construction is easy even for non-professionals, so economicality in terms of construction cost can be secured.

Fourth, since the epoxy-based adhesive is not used, it is possible to improve the environmental problem of generating toxic gas while the epoxy burns when a fire occurs.

Fifth, by fastening the structure and the reinforcing material using bolts and nuts, it is possible to effectively exert a reinforcing effect by the reinforcing material without being affected by or dependent on the adhesive force by the adhesive, that is, the adhesive performance, and the adhesive construction state.

The effects of the present invention are not limited to the effects mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a diagram illustrating a method in which a reinforced concrete member reinforcement method using a steel plate and a wire is applied to a structure according to an embodiment of the present invention.
Figure 2 is a reinforced concrete member reinforcement method and reinforcement structure using a steel plate and wire according to an embodiment of the present invention, a wire installed on the outer surface of the reinforced concrete member and a protruding insert for receiving the protruding wire is formed A drawing showing an exemplary reinforcement plate.
Figure 3 is a view showing an exemplary state in which a reinforced concrete member is installed on an outer surface of a reinforced concrete member in the reinforcement method and reinforcement structure of a reinforced concrete member according to an embodiment of the present invention.
4 is a view showing an exemplary method in which a reinforced concrete member reinforcement method using a steel plate is applied to a structure according to another embodiment of the present invention.
FIG. 5 is a diagram illustrating an anchor receiving portion and an anchor formed on an outer surface of a reinforced concrete member in a reinforced concrete member reinforcement method and reinforcement structure using a steel plate according to another embodiment of the present invention.
6 is a reinforced concrete member in which an anchor is embedded in an anchor receiving portion and an anchor formed on the outer surface of the reinforced concrete member in the reinforced concrete member reinforcement method and reinforcement structure using a steel plate according to another embodiment of the present invention An exemplary view showing a reinforcing plate in which a through hole is formed at a position corresponding to the position of the negative.
7 is a view showing an exemplary configuration in which an elastic member is arranged in an anchor in a reinforcement method and a reinforcing structure of a reinforced concrete member using a steel plate according to another embodiment of the present invention.
8 is an exemplary view showing a configuration in which a bolt and a nut, an elastic member, and a nut cap for preventing loosening of the nut are arranged in the reinforcement method and reinforcement structure of a reinforced concrete member using a steel plate according to another embodiment of the present invention. drawing.
9 is a view showing an exemplary method in which a reinforced concrete member reinforcement method using a steel plate is applied to a structure according to another embodiment of the present invention.
10 is a view showing an exemplary method in which the reinforcement method of a reinforced concrete member using a steel plate and a wire is applied to a structure according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be realized in detail will be described with reference to the accompanying drawings. In the description of the present embodiment, the same name and the same reference numerals are used for the same configuration, and additional descriptions thereof will be omitted.

The accompanying drawings are not shown according to the scale, but are shown partially enlarged and reduced in order to explain the technical idea of the present invention.

The present invention relates to a reinforcement method and a structure in consideration of the damaged state of concrete. As shown below, we intend to increase the efficiency in terms of structural and economic terms by applying suitable reinforcement methods and structures for each damage stage classified according to the concrete crack condition proposed by the Architectural Institute of Korea.

Concrete design standard, condition evaluation by concrete crack (2007. 12) Damage condition crack Deterioration and damage 1-way crack 2-way crack One Crack width less than 0.1 mm Reticulated crack width
Less than 0.1 mm none 2 Crack width 0.1 ~ 0.3 mm
Less than 2% crack rate Reticulated crack width
0.1 to 0.3 mm Surface damage area less than 2% 3 Crack width 0.3 ~ 0.5 mm
Crack rate 2 ~ 10% Reticulated crack width
0.3 mm or more 1. Surface damage area less than 2 ~ 10%
2. Reinforcing bar corrosion damage area less than 2%
3. Deck plate peeling and leakage 4 Crack width 0.5 ~ 1.0 mm
Crack rate 10 ~ 20% Concrete peeling occurs due to the propagation of reticulated cracks 1. Surface damage area over 10%
2. Over 2% of damaged area exposed to rebar
3. Deck plate peeling is severe and corrosion occurs due to leakage 5 Crack width 1.0 mm or more
More than 20% crack rate Possibility of punching destruction due to severe peeling due to reticulated cracking In case the safety of the floor plate is degraded due to severe reduction in the section of the reinforcing bar due to corrosion

More specifically, the present invention proposes a crimping method using bolting and a reinforcing method using a crimping method using a wire, and preferably, a crimping method using bolting in the case of damage states 1 to 3, and in the case of damage states 4 and 5 It is proposed to apply a crimping method using a wire. However, it will be well understood by those skilled in the art that the crimping method using bolting and the crimping method using wire may be widely applied as necessary, and may be applied together.

Hereinafter, an embodiment of a reinforcing method of a reinforced concrete member using a steel plate and a wire of the present invention will be described with reference to FIGS. 1 to 3.

1 is a diagram illustrating a method in which a reinforced concrete member reinforcement method using a steel plate and a wire is applied to a structure according to an embodiment of the present invention. Figure 2 is a reinforced concrete member reinforcement method and reinforcement structure using a steel plate and wire according to an embodiment of the present invention, a wire installed on the outer surface of the reinforced concrete member and a protruding insert for receiving the protruding wire is formed It is a view showing an exemplary reinforcing plate, and FIG. 3 is a view showing a reinforcing plate installed on the outer surface of the reinforced concrete member in the reinforcement method and reinforcement structure of a reinforced concrete member using a steel plate and wire according to an embodiment of the present invention This is an exemplary diagram.

As shown in Figure 1, the concrete structure 10 according to the reinforced concrete member reinforcement method using the steel plate and wire of the present invention is a wire 11 for confining the reinforced concrete member 100, a wire protection member (12), it may be configured to include a wire fastening portion 13 and reinforcing plate 200, protruding insertion portion 201.

In FIGS. 1 to 3, the reinforced concrete member 100 was described as an example as a square reinforced concrete column. However, the reinforced concrete member 100 is not limited to a column, and may include all reinforced concrete members of various types such as reinforced concrete beams or slabs.

As such, the wire 11 may be installed on the outer surface of the reinforced concrete member 100 such as a column, beam, or slab that requires repair and reinforcement according to the present invention. The wire 11 can be reinforced by restoring the deformation or stress of the existing structure, delaying the damage of the concrete by restraining the concrete and leading to a ductile behavior to induce an improvement in the bearing capacity. In addition, depending on the shape of the concrete member 100, it is possible to improve the tensile performance by installing the wire 11.

The wire 11 of the present invention may be a general wire rope, that is, a member produced by assembling a wire to form a strand and winding it around a core at a constant pitch. In addition, it may be a wire made of a shape memory alloy.

As the wire 11 is wrapped around the circumference of the reinforced concrete member 100 and fastened at both ends, the wire 11 is tensioned and a post tension is introduced into the reinforced concrete member 100.

In an embodiment of the present invention, the wire 11 may be installed to surround the circumference of the square reinforced concrete member 100 as shown in FIG. 1.

More specifically, in an example of the present invention, it may be installed to include a wire protection member 12 to prevent breakage of the wire 11 at the edge of the reinforced concrete member 100. The wire protection member 12 is formed in an L-shape, and has a shape in which the wire 11 is perforated to pass therethrough. By installing the wire protection member 12, it is possible to prevent the wire 11 from being in direct contact with the edge of the reinforced concrete member 100, thereby avoiding damage or breakage of the wire 11 due to abrasion by the edge.

Therefore, the wire 11 is passed through the inside of the wire protection member 12 and the wire 11 is wrapped around the reinforced concrete member 100 while the wire protection member 12 is installed at each corner. After that, by fastening and fixing both ends of the wire 11, the wire 11 is installed so as not to slip in a position surrounded by the reinforced concrete member 100.

In this case, the fastening portions 13 of both ends of the wire installed at both ends of the wire 11 in order to fasten both ends of the wire 11 may use a generally known terminal processing and fastening method of a wire rope. For example, it can be fastened using a device such as a socket, a thimble, a clip, a turnbuckle, an eye bolt, or the like.

Then, the reinforced concrete member 100 on which the wire 11 is installed is covered with a reinforcing plate 200. In this case, the reinforcement plate 200 may be formed in a shape corresponding to the shape of the reinforced concrete member 100. That is, the protruding insertion portion 201 at a position corresponding to the portion where the wire 11 and the wire protection member 12 are located so as to include a space for accommodating the wire 11 and the wire protection member 12 Can be formed. Since the wire 11 and the wire protection member 12 are positioned in the protruding insert 201, the reinforcing plate 200 and the wire 11 and the reinforcing plate 200 and the wire 11 are in close contact between the reinforcing plate 200 and the reinforced concrete member 100 Close contact with the wire protection member 12 can be effectively achieved at the same time.

In particular, FIG. 1 shows when the reinforcing plate 200 is positioned on the outer surface of the reinforced concrete member 100 in which the wire 11 is wrapped according to an embodiment of the present invention, the wire 11 and the wire protection member 12 ), a cross-sectional view showing the shape of the wire fastening portion 13, and the reinforcing plate 200 in detail, and more specifically, a cross-sectional view at a portion where the protruding insertion portion 201 of the reinforcing plate 200 is located. As shown in FIG. 1, the protruding insertion portion 201 may contain a wire 11, a wire protection member 12, and a fastening portion 13 at both ends of the wire.

In addition, an observation part 202 may be additionally formed in the protruding insertion part 201. The observation part 202 is made of a high-strength plastic having high light transmittance in a through hole formed in the protruding insertion part 201 or a high-strength plastic, etc., so that the inside of the reinforcing plate can be observed. Through the state of the wire 11 and the fastening state, more preferably, the fastening state at both ends of the wire 13 can be observed with the naked eye. In the conventional steel plate reinforcement method, a reinforcing structure installed on the reinforced concrete member 100 can be observed. Even if deformation, separation, peeling, etc. occur, it is difficult to determine the state of the reinforcing structure because the internal structure cannot be checked with the naked eye.In order to check the state, a part or all of the reinforcing structure, for example, the reinforcing plate 200 must be removed. There was a problem. In addition, in the conventional reinforcement method, it is difficult to form a separate through hole in the reinforcement plate 200 because the reinforcement performance is determined by the degree of adhesion and attachment between the reinforced concrete member 100 and the reinforcement plate 200.

However, in the present invention, the reinforced concrete member 100 is reinforced using the wire 11, and the reinforcing performance of the protruding insert 201 for accommodating the wire 11 is complementary, so the protruding insert 201 Even if the observation part 202 is formed on the ), it is possible to visually check the fastening state and deformation of the wire 11 without causing a significant decrease in reinforcing performance.

Therefore, in FIGS. 1 to 3, the observation portion 202 is shown to be formed on the reinforcement plate 200 coupled to one surface of the reinforced concrete member 100 on which the wire fastening portions 13 are located, but the observation portion It will be understood by those of ordinary skill in the art that the shape, size, number, location, etc. of 202 are not limited to those shown, and various modifications may be made as necessary.

As shown in FIG. 1, the reinforcement plate 200 may be installed on each side of the reinforced concrete member 100.

Therefore, in one embodiment of the present invention, the reinforcement plate 200 is fastened with the reinforced concrete member 100 corresponding to the reinforcement plate 200 in a bolting manner, so that the reinforcement plate 200 and the reinforced concrete member 100, The wire 11, the wire protection member 12, and the fastening portions 13 at both ends of the wire may be integrated.

Hereinafter, an embodiment of a reinforced concrete column reinforcing method using the bolting method of the present invention will be described with reference to FIGS. 4 to 6. Hereinafter, in order to clearly describe the configuration of the bolting fastening method, drawings and detailed descriptions of the reinforcing configuration using the wire as described above are omitted. However, it will be understood by those of ordinary skill in the art that the configuration of the bolting fastening method described below may be applied to the configuration using the wire described above.

4 is a diagram illustrating a method in which a reinforced concrete member reinforcing method using a steel plate is applied to a structure according to another embodiment of the present invention. FIG. 5 is a view exemplarily showing an anchor receiving portion and an anchor formed on an outer surface of a reinforced concrete member in a reinforced concrete member reinforcement method and reinforcement structure using a steel plate according to another embodiment of the present invention, FIG. 6 According to another embodiment of the present invention, in the reinforcement method and reinforcement structure of a reinforced concrete member using a steel plate, a reinforced concrete member in which an anchor is embedded in the anchor receiving portion and the position of the anchor receiving portion formed on the outer surface of the reinforced concrete member It is a view showing an example of a reinforcing plate in which a through hole is formed at a position corresponding to.

As shown in Figure 4, the concrete structure 20 according to the reinforcement method of a reinforced concrete member using a steel plate of the present invention is a reinforced concrete member 100, a reinforcement plate 200 and an anchor 110, a bolt ( 120) and the first nut 130 may be included.

In Figures 4 to 6, the reinforced concrete member 100 has been described as an example as a square reinforced concrete column. However, the reinforced concrete member 100 is not limited to a column, and may include all reinforced concrete members of various types such as reinforced concrete beams or slabs.

In this way, an anchor receiving portion 101 for installing by embedding the anchor 110 may be formed on the outer surface of the reinforced concrete member 100 such as a column, beam or slab that requires repair and reinforcement according to the present invention. . The anchor receiving portion 101 is formed by digging a groove on the surface of the reinforced concrete member 100. In addition, the anchor 110 is embedded in the anchor receiving portion 101 formed on the outer surface of the reinforced concrete member 100.

In general, an anchor is a device that is installed to fix a skin attachment to a concrete structure. After drilling a hole in the concrete and installing an anchor, it can be fixed by bonding the skin attachment to the exposed area outside the concrete and fastening it with a nut. Do.

The anchor of the present invention is known in the art and can be used various types of anchors, for example, chemical anchors, set anchors, all anchors, wedge anchors, frame anchors ( Frame anchor), sleeve anchor (sleeve anchor), strong anchor (strong anchor), may include a drop-in anchor (dropin anchor).

In one embodiment of the present invention, the anchor receiving part 101 may be formed on the outer surface of the rectangular reinforced concrete member 100 as shown in FIG. 4.

More specifically, in an example of the present invention, two left and right anchor receiving portions 101 may be formed on one surface of the reinforced concrete member 100. In addition, the number of the anchor receiving portions 101 formed on one side may be variously selected according to the concrete crack state and the degree of reinforcement. That is, when the surface area of the structure to be reinforced is large, the number of anchor receiving portions 101 may be sufficiently increased so that the reinforcing plate 200 attached to the reinforced concrete member 100 can be stably attached. For example, as shown in FIGS. 5 and 6, it can be installed while increasing the number of anchor receiving portions 101 in the vertical direction of the pillar on one surface of the reinforced concrete member 100 of a square pillar.

In addition, the anchor receiving portion 101 may be formed on all slopes of the reinforced concrete member 100, respectively, as shown in FIG. 4. However, depending on the crack condition and shape of the concrete to be reinforced, and the degree of reinforcement, it can be formed on only one side, can be formed on two sides facing each other, can be formed on two adjacent sides as corners, and formed on three sides. May be.

The reinforcing effect of the conventional steel plate reinforcement method using epoxy is excellent in that a steel plate is used as a reinforcing material, but there is a problem that the reinforcing effect is remarkably deteriorated when the step for epoxy injection is complicated and the epoxy is not sufficiently injected. In addition, when the thickness of the cross section of the reinforcing material is increased to improve the reinforcing effect, the epoxy injection thickness must be increased together to withstand the increased self-weight of the reinforcing material. Was.

In addition, in the conventional reinforcing method using epoxy as an adhesive, since epoxy must be injected between the structure and the reinforcing material, it is essential to prevent the epoxy from leaking. For example, a reinforcing plate must be placed on the entire slope of the column and the circumference of the reinforcing plate is sealed with a separate sealing operation, or a separate injection hole for epoxy injection must be installed while the epoxy does not leak by welding between the steel plates. It was complex and required skilled skills.

However, in the present invention, since epoxy is not injected between the reinforced concrete structure and the reinforcing plate, which is a reinforcing material, since it does not go through the frame sealing operation and welding process as in the prior art, the difficulty of the operation is low, and the unskilled person can also easily construct it. In addition, since an adhesive is not used, even when an increase in the thickness of the reinforcing material is desired, the increase in the amount of the adhesive used accordingly does not need to be considered, so a reinforcing material having a required thickness can be easily selected and constructed.

At this time, the depth of the anchor receiving portion 101 is determined according to the effective depth at which the anchor 110 and the bolt 120 used for fixing the reinforcing plate 200 can effectively act, and the anchor receiving portion 101 ) Of the diameter is also determined according to the effective diameter to which the anchor 110 and the bolt 120 can act effectively. The size, length, and thickness of the anchor 110 and the bolt 120 are determined according to the crack state of the concrete, the degree of reinforcement, and the size and weight of the reinforcing plate 200 to be attached.

In addition, the depth of the anchor receiving portion 101 may be constructed to be deeper than the length of the anchor 110 in order to cope with an external impact.

Before and after the anchor 110 is embedded in the anchor receiving part 101 to increase the fixing force and adhesion of the anchor 110 to the reinforced concrete member 100, between the anchor receiving part 101 and the anchor 110 An adhesive (for example, an epoxy adhesive) and a grouting material may be additionally injected.

For example, after forming the anchor receiving portion 101, an adhesive may be injected into the anchor receiving portion 101, and then the anchor 110 may be installed, and the bolt 120 is fastened to the anchor receiving portion 101. Before the following, the bolt 120 may be fastened after the adhesive is injected into the female threaded portion of the anchor 110. That is, between the anchor receiving portion 101 and the anchor 110 formed in the reinforced concrete member 100, the anchor 110 and the bolt 120 may be filled with an adhesive agent.

A through hole 210 is formed in the reinforcing plate 200 at a position corresponding to the position of the anchor receiving part 101. The reinforcing plate 200 is fixed to the reinforced concrete member 100 by passing the bolt 120 through the through hole 210 and tightening the first nut 130.

In the present invention, since an epoxy adhesive is not used between the concrete structure and the reinforcing material, it is not necessary to separate the reinforcing material from the concrete structure in order to inject the epoxy, so that the reinforcing material and the concrete structure can be directly and closely fixed. In addition, the problem of the prior art in which brittle fracture of a concrete structure occurs before the epoxy adhesive interface layer is peeled off and the reinforcing material exhibits reinforcing performance can be solved through the bolting compression method of the present invention.

However, in the case of using the bolting crimp method as described above, the bolt should be able to be firmly fixed to the structure without loosening. In particular, the anchor 110 embedded in the concrete structure 20 does not deviate from the anchor receiving part 101 even when vibration occurs, including earthquakes, and expansion and contraction of concrete, and the reinforcing plate 200 and the reinforced concrete member The bolt 120 and the first nut 130, which are the main roles for fixing the 100, should not be loosened. Accordingly, in the present invention, a spring, which is an elastic structure, is included in the reinforcing structure for this function.

Hereinafter, embodiments of a reinforced concrete column reinforcement method using a steel plate of the present invention including a spring will be described with reference to FIGS. 7 to 9.

7 is a diagram illustrating a configuration in which an elastic member, that is, a spring, is arranged in an anchor in a reinforcing method and a reinforcing structure of a reinforced concrete member using a steel plate according to another embodiment of the present invention. 8 is an exemplary view showing a configuration in which a bolt and a nut, an elastic member, and a nut cap for preventing loosening of the nut are arranged in the reinforcement method and reinforcement structure of a reinforced concrete member using a steel plate according to another embodiment of the present invention. It is a drawing. 9 is a view showing an exemplary method in which a reinforced concrete member reinforcement method using a steel plate is applied to a structure according to another embodiment of the present invention.

As shown in Figure 7, the concrete structure 30 by the reinforced concrete member reinforcement method using the steel plate of the present invention is a reinforced concrete member 100, a reinforcement plate 200, and an anchor 110, a bolt ( 120), the first nut 130, and the first spring 140 may be included.

7 shows an example in which an anchor having a female threaded portion formed therein is used as an example of the anchor. Therefore, it is possible to fix the reinforcing plate by fastening a separate bolt, for example, a computerized bolt to the female threaded portion. If a bolt is pre-fastened to the anchor or an anchor of a type (for example, an anchor bolt) is used, the bolt provided with the anchor can be used, or the provided bolt can be replaced. It is possible to perform the reinforcement method of the present invention by using another bolt.

Therefore, depending on the type of anchor used, a bolt 120 that is previously fastened to the anchor 110, such as an anchor bolt, may be used, and a separate bolt 120 conforming to the standard of the anchor 110, for example It will be appreciated by those skilled in the art that it is also possible to use a computerized bolt.

Hereinafter, for clarity, the direction in which the anchor 110 is buried in the anchor receiving portion 101 is referred to as an anchor or a downward direction (lower, lower) of the bolt, and the bolt 120 fastened to the anchor 110 The direction in which) is connected to the reinforcing plate 200 will be described by referring to the upward direction (top, top) of the anchor or bolt.

The first spring 140 is installed on the outer periphery of the bolt 120 from the top of the anchor 110. The first spring 140 may be installed after filling the anchor 110 or after fastening the bolt 120 to the anchor 110. That is, before fastening the reinforcing plate 200 to the bolt 120, the first spring 140 is first positioned on the reinforced concrete member 100. Then, the reinforcing plate 200 is fastened to tighten the first nut 130 so that the first spring 140 abuts the reinforcing plate 200.

The first spring 140 is a reinforcing plate that is located inside the reinforced concrete member 100 and attached to the reinforced concrete member 100 as a reinforcing material for vibration applied to the reinforced concrete member 100 and the expansion and contraction force of the concrete It can be delivered effectively to 200. As such, since the first spring 140 is in close contact with the reinforcing material inside the concrete, the force and vibration acting on the concrete structure are absorbed by the elastic member and simultaneously transmitted to the reinforcing material, thereby improving the reinforcing effect by the reinforcing material.

In addition, the first spring 140 may distribute a force received by the anchor 110 embedded in the reinforced concrete member 100. The anchor 110 and the bolt 120 buried in the reinforced concrete member 100 are continuously receiving force due to vibration, impact, expansion, contraction, etc. of the concrete, and thus the anchor 110 and the bolt 120 A phenomenon in which the bonding between the concrete members 100 becomes loose may occur. The first spring 140, which is an elastic member, has the effect of absorbing and dispersing this force. Therefore, it is possible to prevent the anchor 110 and the bolt 120 from being suddenly released or damaged by an external force such as vibration, so that the reinforcement plate 200 is separated from the reinforced concrete member 100.

In order to install the first spring 140 having such an effect, after forming the anchor receiving portion 101 on the outer surface of the reinforced concrete member 100, the first spring receiving portion ( 102) can be further formed. In this case, the diameter d _s1 of the first spring accommodating portion 102 may be formed to be greater than or equal to the diameter d _a of the anchor accommodating portion 101. Therefore, in an embodiment of the present invention, when the anchor receiving part 101 is formed, the reinforced concrete member 100 is formed by the sum of the embedded length L of the anchor 110 and the length l of the first spring 140. A groove is dug from the outer surface, but at this time, the diameter is formed to a size capable of accommodating the anchor 110 (d _a ), and the diameter (d _s1 ) of the first spring receiving part 102 is determined by the anchor receiving part 110. When the diameter (d _a ) is to be formed larger than the first spring from the outer surface of the reinforced concrete member 100 at the position where the anchor receiving part 110 is formed, the length (l) of the first spring 140 A groove having a diameter d _s1 of the receiving part 102 may be additionally formed.

The size of the first spring 140, that is, a diameter, a thickness, and a length may be appropriately selected as necessary.

In addition, since the bolt 120 is installed through the inside of the first spring 140, the bolt 120 serves as a guide to prevent the first spring 140 from being bent or bent.

In addition, a first spring protection part 170 may be added to the first spring receiving part 102. The first spring protection part 170 is to prevent foreign substances such as concrete pieces from being caught in the first spring 140, and is a cylindrical member installed in accordance with the diameter of the first spring receiving part 102 or in concrete. It may be a coating layer coated with the used paint.

The bolt 120 is installed by penetrating the inner diameter of the first spring 140, and then the bolt 120 is passed through the through hole 210 of the reinforcing plate 200 to pass the reinforcing plate 200 to the reinforcing bar. It is fixed to the concrete member 100. When there are a plurality of through holes formed in one reinforcing plate 200, the reinforcing plate is positioned so that the plurality of through holes are fastened with corresponding bolts.

The reinforcing plate 200 may be a steel plate or a steel plate used in a general steel plate reinforcement method. However, it is not limited thereto, and steels that can be attached to concrete for repair and reinforcement of concrete structures, such as section steel (H-type, L-type, etc.), FRP reinforcing plate (for example, carbon fiber plate, aramid fiber plate, glass fiber plate), etc. It may include. In addition, the self-weight, size, and thickness of the reinforcing material may be determined according to the degree of damage to the concrete structure and the degree of reinforcement thereto.

Therefore, the reinforcing plate 200 may be formed in one single layer or in one or more multi-layered structures depending on the degree of reinforcement. If necessary, a functional fiber or plastic sheet (eg, carbon fiber, aramid fiber, glass fiber, etc.) may be laminated together.

The first nut 130 is fastened to the bolt 120 so that the reinforcing plate 200 positioned on the outer surface of the reinforced concrete member 100 can be securely fastened, and the first nut 130 is fastened.

A washer (not shown) for preventing the nut from loosening may be included between the first nut 130 and the reinforcing plate 200. For example, washers such as plain washers, spring washers, rubber washers, and the like may be used.

In general, in a fastening method using a bolt and a nut, there is a possibility that elasticity is lost due to a yield phenomenon of a material, or a space is generated due to vibration of a fastening structure and a component, thereby reducing the frictional force between the bolt and the nut, thereby causing loosening. In order to prevent an accident due to this loosening phenomenon, in the prior art, a method of fixing the bolt and nut by injecting an adhesive is used, but there is a problem that the nut must be destroyed when the nut must be disassembled for maintenance. .

The reinforcing method and structure according to an embodiment of the present invention is to prevent loosening while convenient construction by additionally installing a second spring 150 and a second nut 160 on the first nut 130. It is characterized. The configuration of this embodiment will be described in detail below with reference to FIGS. 8 and 9.

As shown in Figure 8, the concrete structure 40 by the reinforcement method of a reinforced concrete member using a steel plate of the present invention is a reinforced concrete member 100, a reinforcement plate 200 and an anchor 110, a bolt ( 120), a first nut 130, a first spring 140, a second spring 150, and may include a second nut 160.

9 is an exploded perspective view illustrating a method in which the configuration of FIG. 8 is applied to a structure, and the reinforced concrete member 100, the reinforcement plate 200 and the anchors 110 and bolts for fastening them described above in FIG. 8 120), the first nut 130, the first spring 140, the second spring 150, the second nut 160, and the reinforcing method of the embodiment including the nut cap 300 is a structure as shown in FIG. Can be applied to

FIG. 8 relates to an embodiment in which a second spring 150, a second nut 160, and a nut cap 300 are added to the configuration described above in FIG. 7, and the configuration is applied in the same manner to FIGS. 7 and 8 The description of the method and the like will be omitted. Similarly, it will be appreciated that the method in which the reinforcing method and configuration of FIG. 7 is applied to the concrete structure can be applied in a manner similar to the exploded perspective view of FIG.

Fastening the first nut 130 to the bolt 120, and placing the second spring 150 and the second nut 160 on the bolt 120 protruding above the first nut 130 in order Let it. At this time, as in the first spring 140, since the bolt 120 is installed through the inside of the second spring 150, the bolt 120 prevents the second spring 150 from bending or bending. You will act as a guide.

The second spring 150 is located between the first nut 130 and the second nut 160 so that one end of the second spring 150 abuts the first nut 130 and the second spring The other end of 150 is positioned in a contact shape with the second nut 160. A first fixing groove 131 and a second fixing groove 161 are formed in the first nut 130 and the second nut 160, respectively, so that the second spring 150 is formed in the fixing grooves 131 and 161. Both ends of) are positioned in a seated shape.

In an example of the present invention, when the first nut 130 rotates in the loosening direction, the second spring 150 having one end located in the first fixing groove 131 of the first nut 130 rotates in the open direction. That is, the second spring 150 may be installed to relax. Accordingly, one end in contact with the first nut 130, that is, the lower end of the second spring 150, in the direction in which the second spring 150 is opened by the loosening energy acting in the direction in which the first nut 130 is released. When the rotation is attempted, the other end of the second nut 160 is in contact with the second fixing groove 161, that is, the upper end of the second spring 150 is between the second nut 160 and the second spring 150. As the rotation of the second nut 160 is prevented by the frictional force acting on the second spring 150, the loosening energy is generated by the restoring force of the second spring 150 that is about to rotate or partially rotated in the opening direction. ) Is transmitted in a direction in which the second spring 150 is retracted to prevent loosening of the first nut 130.

Accordingly, the second spring 150 presses the first nut 130 from the top of the first nut 130 to prevent the first nut 130 from loosening due to vibration or the like. In addition, the second spring 150 absorbs the vibration transmitted through the reinforcing plate 200, the bolt 120, and the nuts 130, 160 by the elastic member and simultaneously presses it from the top of the first nut 130. When the first nut 130 is used alone, frictional force is increased, so that rotation of the first nut 130 may be prevented.

In addition, a nut cap 300 may be additionally installed to prevent and physically fix the bolt 120 and the first and second nuts 130 and 160 from rotating. The nut cap 300 is formed to accommodate the first and second nuts 130 and 160, the second spring 150 and the bolt 120.

The nut cap 300 may also block moisture and dust from the external environment to prevent the bolt 120, the first and second nuts 130 and 160, and the second spring 150 from rusting. . In this way, it is possible to maximize the life extension effect of the bolts 120, nuts 130 and 160, and the second spring 150.

According to the reinforcing method and the reinforcing structure of the present invention, welding and the use of adhesives are minimized, so that maintenance and repair of the reinforcing structure is easy even after reinforcement. That is, since the reinforcing plate 200 is welded or the reinforcing plate 200 and the concrete member 100 are not bonded with epoxy, the nut cap 300 is separated from the reinforcing structure at any time as needed. And only some of the reinforcing structures, such as the second springs 140 and 150, the first and second nuts 130 and 160, the bolts 120, and the reinforcing plate 200, which have problems, can be repaired and replaced. Management costs can also be reduced.

In particular, bolts and nuts may expand or contract not only due to vibrations such as earthquakes, but also due to changes in ambient temperature, thereby causing screw loosening. However, according to the reinforcing method and the reinforcing structure of the present invention, since maintenance and repair are easy, bolts and nuts can be refastened without dismantling the entire reinforcing structure.

In the above, various embodiments of the crimping method using bolting and the crimping method using wires of the present invention have been described above. However, the above-described various bolting and wire crimping methods can be applied as one reinforcing method and structure, which is illustrated in FIG. 10.

10 is a combination of various embodiments of the present invention, in which the wire crimping method of FIGS. 1 to 3 and the bolting crimping method of FIGS. 8 to 9 are applied together, and the detailed description and detailed decomposition of FIG. 10 described above for each embodiment Referring to the perspective view, the configuration and reinforcement method of this embodiment will be sufficiently understood by those skilled in the art.

The reinforced concrete member 100 is formed with a protruding insertion part 201 at the position of the reinforcing plate 200 corresponding to the portion where the wire 11 is wrapped around the reinforced concrete member 100, and the wire 11 is not wrapped around the reinforced concrete member 100 ) Has an anchor insertion part 101 formed therein, and a through hole 210 is formed at the corresponding position of the reinforcing plate 200, and bolting compression is performed through it, so that the reinforced concrete member 100 ).

At this time, since each of the reinforcing plates 200 is attached using a bolt fastening method on each outer circumferential surface of the reinforced concrete member 100, an excessive amount to attach between the reinforced concrete member 100 and the reinforced concrete member 100 It is not necessary to use an epoxy adhesive or surface welding between the reinforcing plate 200 and the reinforcing plate 200 at the corners.

In the related art, when a steel plate is to be attached on each side, such as a concrete column, a method of separately welding the steel plate and the steel plate at the edge of the column without bolting the column and the steel plate is used. Surface welding between the steel plate and the steel plate has a disadvantage in that it takes a considerable amount of time, and the quality of the welding part is very large depending on the skill level of the worker. In particular, in the case of steel plate reinforcement, high-strength CO ₂ welding is performed instead of general welding to improve the reinforcement performance. Such CO ₂ gas welding has a constant welding rate and high tensile strength compared to arc welding, but skilled techniques are used. It is a major disadvantage in that the construction cost and time are increased as required.

However, in the present invention, since the concrete column and the reinforcing plate are fastened using the bolting compression method, construction convenience is improved, and the quality fluctuation according to the work skill is small, so that a certain level of strength can be expected.

As described above, preferred embodiments according to the present invention have been examined, and the fact that the present invention can be embodied in other specific forms without departing from its spirit or scope in addition to the above-described embodiments is known to those skilled in the art. This is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be modified within the scope of the appended claims and equivalents thereof.

10, 20, 30, 40, 50: concrete structures
11: wire
12: wire protection member
13: Connection at both ends of the wire
100: reinforced concrete member
101: anchor receiving portion
102: first spring receiving portion
110: anchor
120: volts
130: first nut 131: first fixing groove
140: first spring
150: second spring
160: second nut 161: second fixing groove
170: first spring protection unit
200: reinforcement plate
201: protruding insert
202: observation unit
210: through hole
300: nut cap

Claims (10)

Reinforced concrete members;
A wire wrapped around the outer surface of the reinforced concrete member;
A wire protection member through which the wire passes and is located at an edge of the reinforced concrete member;
Both ends of the wire; And
A reinforcing plate having a protruding insertion portion formed at a corresponding position to accommodate the wire and the wire protection member;
Including,
The reinforcing structure of a reinforced concrete member using a steel plate and a wire, characterized in that the protruding insertion portion further includes an observation unit capable of confirming the wire. delete The method of claim 1,
The wire is selected from a synthetic fiber wire rope, a stainless wire rope, a coated wire rope, and a shape memory alloy wire rope, and both ends of the wire are fastened using one or more of a socket, a thimble, a clip, a turnbuckle, and an eye bolt. Reinforced concrete member reinforcement structure using a steel plate and wire, characterized in that the. The method of claim 1,
The reinforcement structure of the reinforced concrete member using a steel plate and wire, characterized in that a through hole is additionally formed in the reinforcing plate, and a bolt connecting the outer surface of the reinforced concrete member and the reinforcement plate is fastened through the through hole. The method of claim 4,
An anchor receiving portion is formed on the outer surface of the reinforced concrete member;
The through hole of the reinforcing plate is formed at a position corresponding to the position of the anchor receiving portion;
An anchor is embedded in the anchor receiving portion;
The bolt is fastened to the anchor; And
A first nut is fastened to the bolt penetrating the through hole of the reinforcement plate to fix the reinforcement plate to the outer surface of the reinforced concrete member;
Reinforced concrete member reinforcement structure using a steel plate and wire, characterized in that. Forming a protruding insert capable of accommodating a wire and a wire protection member on the reinforcing plate;
Wrapping a wire on the outer surface of the reinforced concrete member;
Penetrating the wire through a wire protection member;
Positioning the wire protection member at the edge of the reinforced concrete member;
Forming fastening portions at both ends of the wire; And
Fixing a reinforcing plate to the outer surface of the reinforced concrete member so that the wire and the wire protection member are located in the protruding insertion portion;
Including,
The protrusion insertion part further comprises an observation part for confirming the wire. A method of reinforcing reinforced concrete members using a steel plate and a wire. delete The method of claim 6,
The wire is selected from a synthetic fiber wire rope, a stainless wire rope, a coated wire rope, and a shape memory alloy wire rope, and both ends of the wire are fastened using one or more of a socket, a thimble, a clip, a turnbuckle, and an eye bolt. Reinforced concrete member reinforcement method using a steel plate and wire, characterized in that the. The method of claim 6,
The reinforced concrete member reinforcement method using a steel plate and wire, characterized in that a through hole is additionally formed in the reinforcing plate, and a bolt connecting the outer surface of the reinforced concrete member and the reinforcement plate is fastened through the through hole. The method of claim 9,
An anchor receiving portion is formed on the outer surface of the reinforced concrete member;
The through hole of the reinforcing plate is formed at a position corresponding to the position of the anchor receiving part;
An anchor is embedded in the anchor receiving portion;
The bolt is fastened to the anchor; And
A first nut is fastened to the bolt penetrating the through hole of the reinforcement plate to fix the reinforcement plate to the outer surface of the reinforced concrete member;
Reinforced concrete member reinforcement method using a steel plate and wire, characterized in that.

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