KR100271228B1 - Structure reinforcement method by edge disposal of reinf orcement member end-portion and notch installation - Google Patents

Abstract

PURPOSE: Method for processing a corner of an end portion and reinforcing a structure is provided to control a crack of the corner by dispersing stress concentrated on the corner and to improve road resistance of the structure and attaching strength of an end portion in a stiffener by preventing attachment breakage through the crack. CONSTITUTION: A reinforced concrete structure(120) attaches a reinforcing plate(124) straight cutting process(A) to a corner portion of an end unit(122). If a load(B) is applied to the concrete structure, tensile force is applied to the reinforcing plate to generate shearing stress on a boundary unit of the reinforcing plate. The shearing stress is concentrated on the end unit and then, is removed by cut processing(A) to the corner portion of the end unit to disperse the searing stress. Thereby, the crack of the corner portion is reduced and the shearing force of the concrete structure is improved by preventing attachment breakage on the end unit.

Description

Structure reinforcement method by edge disposal of reinf orcement member end-portion and notch installation

According to the present invention, in a structure such as a concrete structure, a steel sheet or other suitable reinforcement material is used in a part of a beam or slab in which a collapse phenomenon or collapse is expected due to cracking or deterioration of a beam, or a load or slab that needs to increase load capacity. It relates to a reinforcement method to reinforce the structure by attaching.

Usually, the destruction of a member reinforced with steel sheets, carbon fibers, glass fibers, etc. is caused by 1) the sinusoidal failure of the raw concrete starting at the end of the reinforcing member, and 2) the shear failure occurring in the original concrete running parallel to the reinforcement. 3) adhesion failure at the interface of epoxy and raw concrete starting at the end of the reinforcement member, 4) shear failure of the epoxy layer, 5) adhesion failure between the epoxy layer and the reinforcement, and 6) reinforcement resulting from the lack of reinforcement It is divided into six types of flexural tensile failure including

In the case of reinforcing members, the failure of 3), 4) and 5) types of epoxy falling off or cracking of epoxy is rarely generated when proper quality epoxy is applied. In addition, 6) type of fracture that occurs when the amount of reinforcement is insufficient rarely occurs in the case of steel sheet, and other reinforcement can be solved by increasing the amount of reinforcement through proper design. However, the failure type of 2) is caused by the decrease of the surface strength of the original concrete and the concentration of shear stress at the end of the reinforcing member, which is caused by cracking at the end before the reinforcing member exerts its design load. Will be. The occurrence of adhesion failure at this end means that the reinforcement is not functioning properly, and therefore, a solution that can solve or alleviate this problem must be taken. If attachment failure at the end of such stiffeners can be prevented through appropriate methods, ultimately, destruction of 1) occurs. Even when the shear reinforcement is combined, the fracture along the edge at the end of the shear reinforcement is the most representative failure, and since the shear reinforcement itself has a short attachment length, the failure starts from the attachment failure at the end. In the case of the construction method, the development of a reinforcement method that can prevent end fracture is the most important problem that must be solved urgently.

The most typical of the reinforcement method is the reinforcement method of steel plate attachment, which is injection method and compression method. For carbon fiber or glass fiber, the crimping method is the representative reinforcement method, and the injection method is used for reinforcing steel plate. It is a method of injecting epoxy resin therebetween at intervals of about 2 to 5 millimeters (mm) from existing structures. The injection method is widely used in Korea. This is a construction method that is often used because it is difficult to use the crimping method because the spacing between the reinforcement and the existing structure is not constant because the construction state of the existing structure is often poor. Steel plate crimping is a method of directly attaching reinforcement to the structure by applying epoxy between the surface of the structure and the adhesive surface of the reinforcement, which is widely used in advanced foreign countries. Because of this, it is possible to attach the reinforcing member directly to the structure. In addition, the crimped reinforcement method using carbon fiber or glass fiber is similar to the crimping method of steel sheet, but since the reinforcement itself is not rigid, construction is being conducted in a similar way to wallpaper wallpaper.

All of these adhesive reinforcement methods are appropriately cut and processed to reinforce the construction. Since the existing methods show various problems and brittle fractures mentioned above, the present invention solves or at least mitigates these problems. A new concept of end reinforcement is proposed. In the case of attachment reinforcement, it is suggested to propose a method to disperse and weaken the stress generated in the raw concrete at the end of the reinforcement, to prevent the occurrence of breakage at the end of the reinforcement, and to show the design performance of the reinforcement. It is an object of the invention.

The reinforcement method for reinforcing the structure is mainly used reinforcement method using a steel plate and reinforcement method using a special fiber material, the reinforcement method using a steel plate is difficult to work due to the heavy weight of the steel sheet, but the material cost is relatively low, special fiber material The reinforcing method using the method has a disadvantage that it takes a lot of material cost because the price of the special fiber material is higher than that of the steel sheet, but it is easy to work because it is lighter than the steel sheet. Recently, a reinforcing method using such a special fiber material as a reinforcing material has been widely used. In addition to carbon fiber, there are various kinds of special fiber materials with excellent engineering performance, such as glass fiber, boron fiber, Keveler fiber, aramid fiber, etc. Carbon fiber is the most representative type of fiber used in construction sites.

In connection with the repair and reinforcement of the structure, a patent application has been published or published in Korea. First of all, the Korean Patent Publication No. 95-9058 attaches a reinforcement plate to the bottom of an existing beam and can double shear reinforcement at its end. A method of reinforcing the slab floor with a carbon fiber sheet is proposed in the reinforcing method of the form in which several reinforcing plates are attached, and Korean Patent Publication No. 96-23523 filed by Shobond, a Japanese reinforcing company . Korean Patent Publication No. 96-14559, filed by Tonen, a Japanese carbon fiber producer, shows how to reinforce concrete slabs using carbon fiber sheets. It shows how to divide the area into reinforcements. Another Korean Patent Publication No. 96-23520 filed by Showbond discloses a method for reinforcing the cement of the slab top plate.

1 illustrates a concrete structure reinforced using a conventional reinforcement method. Referring to Figure 1, the concrete structure 110 is reinforced by using a conventional reinforcement method, at the bottom of the concrete structure 110, for example, the reinforcement 112, such as a reinforcement plate or carbon fiber sheet at a slight gap. After placing and placing, the epoxy layer 114 is hardened by injecting epoxy between the concrete structure 110 and the reinforcing material 112 and is reinforced by attaching the reinforcing material 112.

When the load (A) acts on the concrete structure 110 reinforced by the reinforcement method above, the action of the force as shown in the enlarged illustration (B) occurs on the interface, cross-sectional view (B) of the interface for the purpose of understanding For reference, tensile forces (T ₁ , T ₂ ) act on both ends of the microelement of the reinforcing member 112 attached to the lower end by the load (A), and the tensile forces (T ₁ , T ₂ ) is a shear force (V) is a force of the same magnitude and opposite direction between the parallel planes adjacent to each other. This shear force reaches a maximum value at the end of the reinforcement. If the attachment of the reinforcement by the external load is not broken, the sinusoidal tension is generated in combination with the tensile stress acting on the bottom of the structure. In this case, when the sinusoidal tension acting on the concrete becomes larger than the tensile strength of the concrete, cracks occur in the concrete, and the cracks cause adhesion failure or sinusoidal fracture at the end (D). This breakdown proceeds abruptly throughout the reinforcement 112 so that the reinforcement 112 is no longer acting to increase the load capacity of the structure as the reinforcement 112 is separated from the concrete structure 110. As described above, the conventional reinforcement method using the reinforcing material has a disadvantage in that the drop-off easily occurs at the end (D) by the shear force acting on the concrete.

The technical problem to be achieved by the present invention is to focus on the phenomenon that the stress is concentrated in the cut edge of the end, to disperse the stress concentrated on the edge, to suppress the occurrence of cracking at the edge, the end by the crack To prevent adhesion failure at the end, increasing the adhesion strength at the end of the stiffener, thus enhancing the load capacity of the structure. In addition, it is noted that when the steel sheet is used as the reinforcing material, it is common that the breakage of the end is preceded, so that the load capacity of the reinforcing material can be determined engineeringally by relatively reducing the load capacity of the center portion relative to the attachment force of the end.

1 is a perspective view of a concrete structure reinforced using a conventional reinforcement method.

2 is a perspective view of a concrete structure reinforced by a reinforcing method according to an embodiment of the present invention.

3 is a bottom view of FIG. 2.

4 is a side view of FIG. 2.

5 to 10 is a perspective view of a concrete structure reinforced by a reinforcement method according to other embodiments of the present invention.

<Description of the code | symbol about the principal part of drawing>

120, 130, 140, 150, 160, 170, 180 ... concrete structures,

124, 134, 144, 154, 164, 174, 184 ...

122, 132, 142, 152, 162, 172, 182 ...

A, F, Q ... straight edge cutting,

D, E, K, O ... Curved edges

H, M, Q, S, U ... Notch,

146, 176 ... epoxy layer.

Reinforcement method by the reinforcing material attachment according to the present invention for achieving the above object is characterized in that it comprises a step of attaching the reinforcing material processed by straight or curved cutting the corner portion of the end of the reinforcing material in order to disperse the stress acting on the end It is done.

In addition, it is preferable that the reinforcement including one or more notches formed by straight cutting or curved cutting both sides of the reinforcing material to have a predetermined depth and width.

Hereinafter, with reference to the accompanying drawings will be described preferred embodiments of the reinforcing method by the reinforcing material attached according to the present invention.

Figure 2 is a perspective view of a concrete structure reinforced by a reinforcement method according to an embodiment of the present invention, Figure 3 and Figure 4 is a bottom view and a side view of Figure 2 respectively. 2, the concrete structure 120 reinforced by the reinforcement method according to an embodiment of the present invention is a reinforcing plate 124 having a straight cutting (A) of the corner portion of the end portion 122 at the bottom by the crimping process Attached. Referring to FIG. 3, it is easily identified that the angled portion at the corner of the end 122 of the concrete structure 120 is straight cut (A). Referring to FIG. 4, the concrete structure 120 is referred to. The direction in which the load B is applied to and the position where the reinforcing plate 124 is attached are easily identified. In addition, it is shown as a circle to indicate the point portion (C) for supporting the concrete structure for reference.

When a load B is applied to the reinforced concrete structure 120 as described above, a tensile force is applied to the reinforcement plate 124, and a shear stress is generated at the boundary of the reinforcement plate 124 by the tensile force. The shear stress is concentrated in the end 122, in the present invention, since the angular portion of the edge portion 122 of the end portion where the stress is concentrated is removed by the straight cutting (A), the reinforcing plate 124 The shear stresses acting on the edges of the ends 122 are dispersed. Accordingly, the stress concentration at the end is alleviated, thereby making it possible to suppress the occurrence of cracking at the corners, and to prevent adhesion failure at the end 122 due to the cracking, thereby improving the load capacity of the concrete structure 120. do.

5 is a perspective view of a concrete structure reinforced by a reinforcement method according to another embodiment of the present invention. Referring to Figure 5, the concrete structure 130 is reinforced by the reinforcement method according to an embodiment of the present invention is a reinforcing plate 134 curved cutting process (D) of the edge portion of the end 132 at the bottom by the compression treatment Attached.

As the concrete structure 130 is reinforced as described above, since the corner portion is curved and cut (D), there is no angled portion, so that the stress dispersion effect described in the embodiment of FIG. 2 is further enhanced, so that the load capacity of the concrete structure 130 is increased. Is increased. Such curved cutting is preferably applied in consideration of the workability of the reinforcing material.

6 is a perspective view of a concrete structure reinforced by a reinforcement method according to another embodiment of the present invention. Referring to Figure 6, the concrete structure 140 is reinforced by the reinforcement method according to an embodiment of the present invention is a reinforcement plate 144 curved curve (D) of the edge portion of the end 142, the concrete structure ( The epoxy layer 146 is formed by injecting epoxy between the 140 and the reinforcing plate 144.

As described above, the reinforced concrete structure 140 may achieve the same stress dispersion effect as described in the embodiment of FIG. 5, and the spacing between the reinforcing material and the structure is not constant, thus making it difficult to use the crimping method. May be optionally applied.

7 is a perspective view of a concrete structure reinforced by a reinforcement method according to another embodiment of the present invention. Referring to Figure 7, the concrete structure 150 is reinforced by the reinforcement method according to an embodiment of the present invention is a straight line cutting (F) of the edge portion of the end 152 at the bottom and reinforced at a predetermined distance (G) from the end A reinforcing plate 154 provided with a so-called notch H formed by linearly cutting both sides of the plate 154 to have a predetermined depth and width is attached by a pressing method.

The concrete structure 150 reinforced as described above may achieve the same stress dispersion effect as described in the embodiment of FIG. 5 by attaching the edge portion of the end portion 152 by straight cutting (F). In addition, the concrete structure 150 reinforced as described above is notched by installing the notch (H) formed by cutting the side of the reinforcement at a predetermined distance (G) in consideration of the point of the load-bearing force and the attachment force of the end 152. The first part I corresponding to the depth of H) acts to increase the adhesive force, and the second part J acts as a part for transmitting a load. Here, if the depth and width of the notch (H) is appropriately adjusted, the adhesion of the end 152 can be made relatively larger than the load capacity of the central portion of the reinforcing plate 154. By increasing the attachment force of the end portion 152 in this manner, it is possible to prevent the attachment failure from being preceded at the end portion 152 and to precede the breakdown in the notch portion. At this time, the breakage of the notch is determined according to the tensile force of the reinforcement, so that the design load of the center of the reinforcement can be determined through engineering calculation.

8 is a perspective view of a concrete structure reinforced by a reinforcement method according to another embodiment of the present invention. Referring to FIG. 8, the concrete structure 160 reinforced by the reinforcement method according to the embodiment of the present invention is curved at the lower end of the end portion 152 by cutting (K) and notched at a predetermined distance (L) from the end. A reinforcing plate 164, which is formed by curving a semicircle or trapezoid (M), is attached by a crimping method.

The concrete structure 160 reinforced as described above can achieve the effect described in the embodiment of FIG. 7 more efficiently by cutting and attaching the corner portion of the end portion 162 in a curved line, and the corner portion is curved. As the cutting is performed, there is no angled portion, thereby improving the stress dispersion effect described in the embodiment of FIG. 2. It is preferable to selectively apply the trapezoidal curved cutting process in consideration of the workability of the reinforcing material.

9 is a perspective view of a concrete structure reinforced by a reinforcing method according to another embodiment of the present invention. 9, the concrete structure 170 reinforced by the reinforcement method according to an embodiment of the present invention is curved at the edge of the end portion 172 at the bottom (N) and notched at a predetermined distance (O) from the end An epoxy layer 176 is formed and adhered by injecting epoxy to the reinforcing plate 174 provided by curving (P).

The concrete structure 170 reinforced as described above can achieve the same effect as described in the embodiment of FIG. 8 and can be effectively used when it is difficult to use the crimping method because the distance between the reinforcement and the structure is not constant. Can be.

10 is a perspective view of a concrete structure reinforced by a reinforcement method according to another embodiment of the present invention. Referring to FIG. 10, the concrete structure 180 reinforced by the reinforcement method according to the embodiment of the present invention has a straight cut (Q) at the edge of the end portion 182 and a first notch at a predetermined distance R from the end. It is reinforced by attaching the reinforcing plate 184 which provided (S) and provided the 2nd notch U at another predetermined distance T which is a center part of a reinforcing material by the crimping | bonding method.

In the embodiment of FIG. 7, the concrete structure 180 reinforced as described above has a straight cut Q at an edge of the end 182 and a first notch S is installed at a predetermined distance R from the end. The above described effects can be achieved in the same manner, and the second notch U is provided at a predetermined distance T selected at a suitable position in consideration of the characteristics of the applied load and the end attachment force to sufficiently secure the attachment area at the end. In addition, it is possible to relatively reduce the transfer amount of the tensile load at the center of the reinforcement, so that it is always possible to cause the destruction of the reinforced structure to start from the center of the reinforcement. In addition, when such a failure is caused, it is possible to design the reinforcement by engineering calculation.

As described above, the reinforcement method by the reinforcing material attachment according to the present invention, by dispersing the stress acting on the end of the structure to prevent the adhesion failure at the end by the crack to enhance the load capacity of the structure, the adhesion of the end Relatively increased to prevent the attachment failure of the end preceded to enable the engineering design of the reinforcement amount in the center of the reinforcement.

Claims (3)

A reinforcing method for reinforcing the structure by attaching a reinforcing material to a concrete structure, the reinforcing method comprising the step of attaching a reinforcing material including one or more notches formed by straight cutting or curved cutting of both sides to have a predetermined depth and width. The method of claim 1, wherein the reinforcing material is a reinforcing method, characterized in that the reinforcing material processed by straight cutting or curved cutting the corner portion of the end. The method of claim 1, wherein the notch is installed in the center of the reinforcing material.

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