KR102598284B1 - Tendon buried concrete structure for external pre-tensioning reinforcement, and construction method for the same - Google Patents

Abstract

In the external pretension reinforcement method for reinforcing concrete structures such as concrete beams or girders, tension members can be easily embedded in the concrete matrix using anchor bolts and poured concrete, and prestress is also introduced into the tension member at the bottom of the concrete matrix. By cutting the tension material exposed at the end of the poured concrete, the anchoring device can be removed and reused, thereby reducing construction costs. Additionally, when constructing anchor bolts at the bottom of the concrete matrix, a bracket for combining anchor bolts is used. Provided is a concrete structure in which tendons for external pretension reinforcement are embedded, and a method of constructing the same, which can improve the adhesion between the concrete matrix and poured concrete by using them together, and thereby increase the prestress transmission ability of the tendons.

Description

Concrete structure in which tension members for external pretension reinforcement are embedded and its construction method {TENDON BURIED CONCRETE STRUCTURE FOR EXTERNAL PRE-TENSIONING REINFORCEMENT, AND CONSTRUCTION METHOD FOR THE SAME}

The present invention relates to a concrete structure in which tension members for external pretension reinforcement are embedded. More specifically, the present invention relates to an external pre-tensioning reinforcement method for reinforcing concrete structures using anchor bolts and poured concrete. It relates to a concrete structure in which tendons for external pretension reinforcement are embedded in a concrete matrix, and a method of constructing the same.

In general, the method of reinforcing a concrete structure by introducing prestress according to the prior art is performed by tensioning the tendon material using a fixing device protruding from the outer surface of the end of the concrete structure and then anchoring it to the anchoring device.

Figure 1 is a perspective view showing the installation of a fixing device used for a concrete beam as a method of reinforcing a concrete structure according to the prior art.

In the case of a method of reinforcing a concrete structure according to the prior art, as shown in FIG. 1, anchorage brackets 14 and 14' are installed on the concrete beam 12 of the bridge 11, for example, on both ends of the girder. ) is fixedly installed and the tension member (17) is placed. One end of the tension member 17 is fixed to the anchoring device bracket 14' on one side, and the other end of the tension member 17 is tensioned by a hydraulic jack 19 installed on the anchoring device bracket 14 on the other side.

In other words, it can be said to be a method of using the brackets (14, 14') as a fixing device and tensioning the tension member (17) using a hydraulic jack (19).

However, the method of reinforcing a concrete structure according to the prior art has the disadvantage that the appearance of the concrete structure deteriorates after reinforcement because the anchoring device protrudes outward from the outer surface of the concrete structure. In other words, the external tension reinforcement method requires an anchoring device at the end of each girder. In this case, the anchorage device is made of steel and is expensive, and the external tension reinforcement method requires reinforcement materials such as steel bars, steel wires, and strands to be exposed to the outside. There is a risk of corrosion and damage, and there are many difficulties in maintenance.

Specifically, since the anchoring device must protrude from both end surfaces of the concrete matrix and secure enough space to be installed, it must be installed on the reinforced surface of the concrete structure, such as when the reinforced surface of a concrete structure is immediately adjacent to a neighboring structure. If there is not enough space to protrude and install the fixing device, there is bound to be a limit to its application.

In particular, in the case of a concrete beam or girder of a bridge, if a tension member is installed after installing an anchoring device on the lower surface of the concrete beam or girder, the anchoring device occupies the lower space of the concrete beam or girder, thereby reducing the risk of securing height. Problems may arise.

In addition, fixing devices such as brackets are mainly made of metal, and since they are installed on the outside of the concrete structure and are continuously exposed to moisture due to rain, etc., the brackets can easily corrode, and in this case, rust can flow and damage the appearance of the concrete structure. Of course, if the fixing device is damaged, problems with the reinforcement effect are bound to occur. Damage to these anchoring devices may eventually lead to loss of reinforcing strength of the concrete structure, resulting in destruction of the concrete structure.

At this time, the tendon (PC strand, steel bar, etc.) is usually used as the tendon, but recently, a method of reinforcing a concrete structure using a FRP tendon using a surface embedding method has been introduced.

Figure 2 is a diagram schematically illustrating a surface embedding method for reinforcing a concrete structure by tensioning FRP tendons according to the prior art.

As shown in Figure 2, the method of reinforcing a concrete structure by tensioning FRP tension members according to the prior art uses a surface-embedded anchoring device embedded in a concave groove formed on the bottom of the concrete structure and a tension device for FRP tension members. Thus, a method of introducing tension to the FRP tension material and filling the concave groove with grouting material is adopted.

The surface embedding tension method according to this conventional technology forms a concave groove at a certain depth on the outer surface of the part requiring reinforcement in the concrete structure. A tension member is installed in this concave groove, and then the tension member is tensioned using a tension device installed at the end of the concrete structure. Then, the concave groove is filled with filler so that the tendon material is completely buried in the filler. When the filler is cured to a predetermined strength or higher, the tension device is dismantled from the tendon material to introduce tension into the concrete structure, and then unnecessary parts of the tendon material are removed to complete the reinforcement of the concrete structure. Therefore, the surface embedding tension method according to the conventional technology can be easily applied even in places where the space of the concrete structure is narrow, and tension can be applied to the tendon material.

However, in the case of the surface embedding tension method according to the conventional technology, the structure becomes complicated and there is a limitation in that the anchoring device cannot be removed.

Meanwhile, as a prior art related to the attachment and detachment of anchorage devices, an invention titled "Method for continuous girder construction of composite girder bridges using detachable anchorage devices" is disclosed in Republic of Korea Patent No. 10-1001443, which is shown in Figures 3a to 3a. This will be explained with reference to FIG. 3D.

Figures 3a to 3d are construction flowcharts of the main girder continuous construction method of a composite girder bridge using a detachable anchoring device according to the prior art.

The main girder continuous method of a composite girder bridge using a detachable anchoring device according to the prior art is, first, as shown in Figure 3a, the main girder 20 manufactured to match the span length is mounted on the pier or abutment, Connect both main beams (22) at the middle pier (21) to create a non-composite continuous beam structure.

Next, the anchoring device 30 is attached to the upper edge of the main body 20, as shown in Figure 3b, within the inflection point of the bending moment that occurs when the floor plate load is applied to the non-composite continuous beam, and then the anchoring device A prestressing steel material (31) is installed at (30) to introduce tension (P1).

At this time, a plurality of individually distributed strands are used as the prestressing steel material 31, and the size of the tension force introduced depends on the constituent materials of the main beam, the size of the bending moment due to the self-weight of the main beam and floor concrete, and the span configuration. It is decided through detailed structural analysis.

Next, as shown in FIG. 3C, the floor plate concrete 40 is constructed to form a composite state with the main body 20. At this time, a certain section 41 around the anchorage device 30 is the floor plate. By avoiding concrete construction, the anchoring device 30 can be dismantled later.

Next, as shown in FIG. 3D, when the curing of the floor slab concrete 40 is completed, the prestressing steel material 31 on the upper edge of the main body consisting of a plurality of individual strands is cut with a gas fire or a grinder to be used as a fixing device. The tension applied to the main deck is transmitted to the main deck through the adhesion force with the floor slab concrete (40), so that the role of the anchoring device on the upper edge of the main deck is no longer needed. Afterwards, the empty space 41 around the fixing device is filled with concrete.

In the case of the main girder continuous construction method of a composite girder bridge using a detachable anchoring device according to conventional technology, the use efficiency of prestressing steel is improved by arranging prestressing steel materials outside the main girder to introduce a pre-compressive force to the main girder near the midpoint. It can be increased, and the fixing device needed to fix the prestressing steel can be used repeatedly, reducing the cost of introducing tension.

However, in the case of the main girder continuous construction method of a composite girder bridge using a detachable anchoring device according to the conventional technology, the anchoring device required to fix the prestressing steel can be used repeatedly, but the tension applied to the anchoring device is not connected to the deck concrete. As a method of transmitting to the main beam through adhesion, there is a limitation in that the prestress transmission ability of the tendon material cannot be increased.

Republic of Korea Patent No. 10-529518 (registration date: November 11, 2005), title of invention: “Structure and method for continuous mid-point section of prestressed concrete beam using sole plate” Republic of Korea Patent No. 10-1001443 (registration date: December 8, 2010), title of invention: “Method for continuous girder construction of composite girder bridge using detachable anchorage device” Republic of Korea Registered Utility Model No. 20-268160 (registration date: March 4, 2002), designation name: “External steel wire anchorage device for reinforcing concrete structures” Republic of Korea Patent Publication No. 2002-33146 (publication date: May 4, 2002), title of invention: “Method for reinforcing external tension members of reinforced concrete structures and their structure”

The technical problem to be achieved by the present invention to solve the above-described problems is to use anchor bolts and poured concrete in the External Pre-tensioning Reinforcement method for reinforcing concrete structures such as concrete beams or girders. The purpose is to provide a concrete structure in which tension members for external pretension reinforcement can be embedded in a concrete matrix, and a method of constructing the same.

Another technical problem to be achieved by the present invention is to introduce prestress into the tension material at the bottom of the concrete matrix and then cut the tension material exposed at the end of the poured concrete, thereby embedding the tension material for external pretension reinforcement, which can be reused by removing the anchoring device. The purpose is to provide a concrete structure and its construction method.

Another technical problem to be achieved by the present invention is to provide a tension material for external pretension reinforcement that can improve the adhesion between the concrete matrix and poured concrete by using a bracket for combining anchor bolts when constructing anchor bolts at the bottom of the concrete matrix. It is intended to provide a buried concrete structure and its construction method.

As a means of achieving the above-described technical problem, the concrete structure in which the tension member for external pretension reinforcement according to the present invention is embedded is formed of concrete for external pretension reinforcement, and has an anchor bolt fastening hole (h1) into which the anchor bolt is fastened. ) a concrete matrix formed at predetermined intervals; An anchor bolt fastened to an anchor bolt fastening hole (h1) formed in the concrete matrix; Anchoring devices installed on both ends of the lower portion or sides of the concrete matrix to anchor the tendons; Tension material disposed on the lower or side of the concrete matrix and fixed to the anchoring device using a tension introducing device; and poured concrete poured under the concrete matrix so that the tension member is buried, wherein the tension member 140 is such that the exposed end is cut after curing of the poured concrete 150, and the anchor bolt is connected to the concrete matrix. It is fastened to the concrete matrix in order to attach the poured concrete and transmit the prestress transmission force of the tendon to the concrete matrix, is coupled with the anchor bolt, and is fastened to the lower portion or side of the concrete matrix together with the anchor bolt. It includes a bracket for coupling anchor bolts, wherein the bracket for coupling anchor bolts is a steel plate on which an anchor bolt through hole (h2) is formed so that the anchor bolt can penetrate, and the anchor is connected through the anchor bolt through hole (h2). A bracket body into which a bolt is inserted and which is constructed under the concrete matrix together with the anchor bolt; and a steel plate, which includes bracket bends formed by bending both sides of the bracket body.

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Meanwhile, as another means for achieving the above-described technical problem, the method of constructing a concrete structure in which the tension member for external pretension reinforcement according to the present invention is embedded is: a) anchors at predetermined intervals at the bottom of the concrete matrix for external pretension reinforcement; Forming a bolt fastening hole (h1); b) fastening an anchor bolt to an anchor bolt fastening hole (h1) formed in the lower part of the concrete matrix; c) arranging anchoring devices at both ends of the lower part of the concrete matrix: d) arranging tension materials at both ends of the anchoring devices and tensioning them to a predetermined tension; e) applying and curing poured concrete to the lower part of the concrete matrix so that the tendon material is buried; f) cutting each end of the tendon exposed to the side of the poured concrete; and g) removing the anchoring device from the concrete base for reuse of the anchoring device, wherein the tension member 140 is such that the exposed end is cut after curing of the poured concrete, and the anchor bolt is connected to the concrete base. It is fastened to the concrete matrix in order to attach the concrete matrix and the poured concrete and transmit the prestress transmission force of the tendon to the concrete matrix, is coupled with the anchor bolt, and is attached to the lower or side of the concrete matrix together with the anchor bolt. It includes a bracket for coupling anchor bolts, wherein the bracket for coupling anchor bolts is a steel plate on which an anchor bolt through hole (h2) is formed so that the anchor bolt can penetrate, and the anchor bolt through hole (h2) is formed. a bracket body through which the anchor bolt is inserted, and which is constructed under the concrete matrix together with the anchor bolt; and a steel plate, which includes bracket bends formed by bending both sides of the bracket body.

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According to the present invention, in an external pretension reinforcement method for reinforcing concrete structures such as concrete beams or girders, tension members can be easily embedded in the concrete matrix using anchor bolts and poured concrete.

According to the present invention, by introducing prestress to the tension member at the bottom of the concrete matrix and then cutting the tension member exposed at the end of the poured concrete, the anchoring device can be removed and reused, thereby reducing construction costs.

According to the present invention, when constructing anchor bolts at the bottom of the concrete matrix, the adhesion between the concrete matrix and poured concrete can be improved by using a bracket for combining anchor bolts, and thus the pre-stress transmission ability of the tendon can be increased.

Figure 1 is a perspective view showing the installation of a fixing device used for a concrete beam as a method of reinforcing a concrete structure according to the prior art.
Figure 2 is a diagram schematically illustrating a surface embedding method for reinforcing a concrete structure by tensioning FRP tendons according to the prior art.
Figures 3a to 3d are construction flowcharts of the main girder continuous construction method of a composite girder bridge using a detachable anchoring device according to the prior art.
Figure 4 is a cross-sectional view showing a concrete structure in which a tension member for external pretension reinforcement is embedded according to an embodiment of the present invention.
Figure 5 is a diagram specifically showing a bracket for coupling anchor bolts in a concrete structure in which a tension member for external pretension reinforcement is embedded according to an embodiment of the present invention.
Figures 6a to 6c are a side view, a front view, and a plan view of a fixing device in a concrete structure in which a tension member for external pretension reinforcement is embedded according to an embodiment of the present invention, respectively.
Figure 7 is an operation flowchart showing a construction method of a concrete structure in which tension members for external pretension reinforcement are embedded according to an embodiment of the present invention.
Figures 8a to 8f are cross-sectional views for specifically explaining the construction method of a concrete structure in which the tension member for external pretension reinforcement is embedded according to an embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

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

[Concrete structure in which tension material for external pretension reinforcement is embedded]

Figure 4 is a cross-sectional view showing a concrete structure in which a tension member for external pretension reinforcement is embedded according to an embodiment of the present invention.

Referring to Figure 4, the concrete structure in which the tension member for external pretension reinforcement according to an embodiment of the present invention is embedded includes a concrete matrix 230, an anchor bolt 110, a bracket for combining anchor bolts 120, and an anchoring device ( 130), tension material 140, and poured concrete 150.

The concrete matrix 230 is a matrix formed of concrete for external pretension reinforcement. For example, the concrete matrix 230 is a concrete beam or girder mounted on the abutment or pier 210 and the bridge support 220. It may be possible, but it is not limited to this. In addition, anchor bolt fastening holes h1 are formed at predetermined intervals so that the anchor bolts 110 can be fastened to the lower part or side of the concrete matrix 230.

The anchor bolt 110 is fastened to the anchor bolt fastening hole h1 formed in the concrete matrix 230. At this time, in order to attach the concrete matrix 230 and the poured concrete 150 and transmit the pre-stress transmission force of the tendon 140 to the concrete matrix 230, the anchor bolt 110 is attached to the concrete matrix 230. Fasten construction.

The anchor bolt coupling bracket 120 is coupled to the anchor bolt 110 and is fastened to the lower portion or side of the concrete matrix 230 together with the anchor bolt 110.

The anchoring device 130 is installed at both ends of the lower portion or side of the concrete matrix 230 to anchor the tendon 140. At this time, the fixing device 130 can be removed after cutting the tendon 140 and thus can be reused.

The tension material 140 is a reinforcing material, which is disposed on the lower part or side of the concrete matrix 230 and is fixed to the anchoring device 130 using a tension introducing device. For example, the tension member 140 may be a steel wire, strand, or steel bar. At this time, the exposed end of the tendon 140 is cut after curing the poured concrete 150. That is, after pretension reinforcement of the concrete matrix 230, the tension member 140 is embedded in the poured concrete 150, and then the anchoring device 130 is removed to form a concrete structure, for example, a concrete beam or girder. Excellent aesthetics can be maintained, and construction costs can be reduced by reusing the fixing device.

Poured concrete 150 is poured into the lower part of the concrete base body 230 so that the tendon 140 is buried. Specifically, the poured concrete 150 is placed in the lower part of the concrete matrix 230 so that the tension material 140 is embedded after introducing tension to the tension material 140 and anchoring it to the anchoring device 130. At this time, the poured concrete 150 may be shotcrete.

Accordingly, in the case of a concrete structure in which a tendon for external pretension reinforcement according to an embodiment of the present invention is embedded, the adhesion performance of the poured concrete 150 to the concrete matrix 230 is increased and the pre-stress transmission capacity of the tendon 140 is increased. The anchor bolt 110 is fastened to transmit the anchor bolt 110 to the concrete matrix 230, and the anchor bolt coupling bracket 120 coupled to the anchor bolt 110 is constructed together with the anchor bolt 110, thereby forming the poured concrete. It is possible to improve the adhesion with the material and to improve the pre-stress transfer ability of the material.

In other words, a detachable anchoring device is placed on the concrete structure, tension material is placed, and tension is introduced. After pouring and curing the concrete, the tendon material is cut, and the anchoring device is removed to apply the pretension method to the concrete structure. By introducing it, damaged and deteriorated parts of concrete structures can be rapidly reinforced.

Meanwhile, Figure 5 is a diagram specifically showing a bracket for coupling anchor bolts in a concrete structure in which a tension member for external pretension reinforcement is embedded according to an embodiment of the present invention.

Referring to FIG. 5, in a concrete structure in which a tension member for external pretension reinforcement according to an embodiment of the present invention is embedded, the anchor bolt coupling bracket 120 includes a bracket body 121 and bracket bent portions 122 and 123. It can be done, but it is not limited to this.

The bracket body 121 is a steel plate with an anchor bolt through hole (h2) formed so that the anchor bolt 110 can penetrate, and the anchor bolt 110 is inserted through the anchor bolt through hole (h2), It is constructed at the bottom of the concrete matrix 230 together with the anchor bolt 110.

The bracket bending portions 122 and 123 are steel plates bent on both sides of the bracket body 121, and a plurality of poured concrete coupling holes h3 are formed in each to improve the adhesion of the poured concrete 150. That is, the poured concrete 150 is poured into the poured concrete coupling hole (h3).

Meanwhile, Figures 6a to 6c are a side view, a front view, and a plan view of a fixing device in a concrete structure in which a tension member for external pretension reinforcement is embedded according to an embodiment of the present invention, respectively.

As shown in FIGS. 6A to 6C, in a concrete structure in which a tension member for external pretension reinforcement according to an embodiment of the present invention is embedded, the anchoring device 130 includes a horizontal plate 131, a vertical plate 132, and a anchoring device 130. It may include a plate 133, an end plate 134, a first reinforcement plate 135, a second reinforcement plate 136, and a chemical anchor 137.

The horizontal plate 131 is a steel plate arranged horizontally, with a fixing plate 133 connected to one upper side and an end plate 134 connected to the other upper side.

The vertical plate 132 is a steel plate vertically connected to the lower part of the horizontal plate 131, and a chemical anchor bolt fastening hole (h4) is formed to allow the chemical anchor 137 to pass through.

The anchoring plate 133 is disposed on one upper side of the horizontal plate 131, and a tendon through-hole (h5) is formed so that the tendon 140 can penetrate and be anchored.

The end plate 134 is formed on the other upper side of the horizontal plate 131 opposite the fixing plate 133.

The first reinforcement plate 135 is a steel plate for horizontal reinforcement of the fixing device 130 and is disposed between the fixing plate 133 and the end plate 134.

The second reinforcement plate 136 is a steel plate for vertical reinforcement of the fixing device 130 and is disposed between the horizontal plate 131 and the vertical plate 132.

The chemical anchor 137 is an anchor bolt that secures the vertical plate 132 of the anchoring device 130 to the concrete matrix 230, and is formed through a chemical anchor bolt fastening hole (h4) formed in the vertical plate 132. It penetrates and is fastened to the concrete matrix 230.

Ultimately, according to the concrete structure in which the tension member for external pretension reinforcement according to an embodiment of the present invention is embedded, the anchoring device is removed by introducing prestress to the tension member at the bottom of the concrete matrix and then cutting the tension member exposed at the end of the poured concrete. It can be reused, thereby reducing construction costs. In addition, when constructing anchor bolts at the bottom of the concrete matrix, the adhesion between the concrete matrix and poured concrete can be improved by using a bracket for combining anchor bolts. Accordingly, the prestress transmission ability of the tendon material can be increased.

[Construction method of concrete structures in which tension members for external pretension reinforcement are embedded]

Figure 7 is an operation flow chart showing a construction method of a concrete structure in which tension members for external pretension reinforcement are embedded according to an embodiment of the present invention, and Figures 8a to 8f are according to an embodiment of the present invention according to an embodiment of the present invention. These are cross-sectional drawings to specifically explain the construction method of a concrete structure in which tension members for external pretension reinforcement are embedded.

Referring to FIGS. 7 and 8A to 8F, the method of constructing a concrete structure in which the tension member for external pretension reinforcement according to an embodiment of the present invention is embedded is, first, at the bottom of the concrete matrix 230 for external pretension reinforcement. At predetermined intervals, anchor bolt fastening holes h1 are formed as shown in FIG. 5 (S110). Here, the concrete matrix 230 may be a concrete beam or girder mounted on an abutment or pier 210 and bridge support 220.

Next, as shown in FIG. 8A, the anchor bolt 110 is fastened to the anchor bolt fastening hole h1 formed in the lower part of the concrete matrix 230 (S120). At this time, the anchor bolt 110 can be fastened together with the anchor bolt coupling bracket 120. Specifically, the anchor bolt coupling bracket 120 is composed of a bracket body 121 and bracket bent portions 122 and 123, as shown in FIG. 5, and the bracket body 121 includes the anchor bolt. An anchor bolt penetration hole (h2) through which (110) penetrates is formed, and a plurality of poured concrete coupling holes (h3) are formed in the bracket bent portions (122, 123), making it easy to connect the poured concrete (150). can be combined easily. Specifically, the bracket body 121 is a steel plate with an anchor bolt through hole (h2) formed so that the anchor bolt 110 can penetrate, and the anchor bolt 110 passes through the anchor bolt through hole (h2). It is inserted and constructed under the concrete matrix 230 together with the anchor bolt 110. In addition, the bracket bent portions 122 and 123 are steel plates bent on both sides of the bracket body 121, and each has a plurality of poured concrete coupling holes h3 to improve the adhesion of the poured concrete 150. is formed

Next, as shown in FIG. 8B, fixing devices 130 are placed at both ends of the lower part of the concrete matrix 230 (S130). Here, the fixing device 130 includes a horizontal plate 131, a vertical plate 132, a fixing plate 133, an end plate 134, and a first reinforcement plate ( 135), a second reinforcement plate 136, and a chemical anchor 137.

Next, as shown in FIG. 8C, tension members 140 are placed on both ends of the fixing device 130 and tensioned to a predetermined tension force using a tension force introduction device (S140). Here, the tension member 140 is a reinforcing material and may be a steel wire, strand, or steel bar.

Next, as shown in FIG. 8D, poured concrete 150 is applied and cured to the lower part of the concrete matrix 230 so that the tendon 140 is buried (S150). Here, shotcrete can be applied as the poured concrete 150.

Next, as shown in FIG. 8E, the ends of the tendons 140 exposed to the side of the poured concrete 150 are cut (S160). At this time, since the end cut surface of the tendon 140 is exposed and corrosion may occur, both sides of the poured concrete 150 can be finished by surface treatment.

Next, as shown in FIG. 8F, the fixing device 130 is removed from the concrete matrix 230 in order to reuse the fixing device 130 (S170). That is, the fixing device 130 is not fixed to the concrete matrix 230. As the tendon 140 is cut, it can be removed from the concrete matrix 230 and reused, thereby reducing construction costs.

Ultimately, according to an embodiment of the present invention, in an external pretension reinforcement method for reinforcing concrete structures such as concrete beams or girders, tension members can be easily embedded in the concrete matrix using anchor bolts and poured concrete.

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

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

210: Pier or abutment 220: Bridge support (bridge device)
230: concrete matrix 110: anchor bolt
120: Bracket for combining anchor bolts 130: Anchoring device
140: Tension material 150: Poured concrete
121: Bracket body 122. 123: Bracket bent portion
131: horizontal plate 132: vertical plate
133: fixing plate 134: end plate
135 first reinforcement plate 136: second reinforcement plate
137: Chemical anchor h1: Anchor bolt fastening hole
h2: Anchor bolt through hole h3: Poured concrete joining hole
h4: Chemical anchor bolt fastening hole h5: Tension material through hole

Claims (16)

A concrete matrix 230 made of concrete for external pretension reinforcement and having anchor bolt fastening holes h1 where the anchor bolts 110 are fastened at predetermined intervals;
An anchor bolt (110) fastened to an anchor bolt fastening hole (h1) formed in the concrete matrix 230;
A fixing device 130 installed on both ends of the lower or side surfaces of the concrete matrix 230 to fix the tendon 140;
Tension material 140 disposed on the lower or side of the concrete matrix 230 and fixed to the anchoring device 130 using a tension introducing device; and
It includes poured concrete 150 poured under the concrete matrix 230 so that the tendon 140 is buried,
The tension member 140 allows the exposed end to be cut after curing the poured concrete 150,
The anchor bolt 110 is attached to the concrete matrix 230 in order to attach the concrete matrix 230 and the poured concrete 150 and transmit the prestress transmission force of the tendon 140 to the concrete matrix 230. Fastening construction is carried out,
It is coupled to the anchor bolt 110 and includes an anchor bolt coupling bracket 120 fastened to the lower part or side of the concrete matrix 230 together with the anchor bolt 110,
The anchor bolt coupling bracket 120 is a steel plate with an anchor bolt through hole (h2) formed so that the anchor bolt 110 can penetrate, and the anchor bolt 110 is connected through the anchor bolt through hole (h2). ) is inserted and a bracket body 121 constructed under the concrete matrix 230 together with the anchor bolt 110; and a concrete structure in which a tension member for external pretension reinforcement is embedded as a steel plate, including bracket bent portions (122, 123) formed by bending on both sides of the bracket body (121). According to paragraph 1,
According to the external pretension reinforcement of the concrete matrix 230, the tension member 140 is cut and embedded at both ends in the poured concrete 150, and the anchoring device 130 is installed in the poured concrete 150 so that it can be reused. ) A concrete structure in which tension members for external pretension reinforcement are embedded, characterized in that they are removed after curing. delete delete delete According to paragraph 1,
The bracket bending portions 122 and 123 are external pretensioners, characterized in that a plurality of poured concrete coupling holes (h3) are formed through which the poured concrete 150 is connected to improve adhesion to the poured concrete 150. A concrete structure in which reinforcing tension members are embedded. The method of claim 1, wherein the fixing device 130 is:
A horizontal plate 131, which is a steel plate disposed horizontally and has a fixing plate 133 connected to one upper side and an end plate 134 connected to the other upper side;
A vertical plate 132, which is a steel plate vertically connected to the lower part of the horizontal plate 131 and has a chemical anchor bolt fastening hole (h4) so that the chemical anchor 137 can pass through;
A fixing plate 133 disposed on one upper side of the horizontal plate 131 and having a tension material through-hole (h5) so that the tension material 140 can penetrate and be anchored thereto;
an end plate 134 formed on the other upper side of the horizontal plate 131 opposite the fixing plate 133;
A first reinforcement plate 135 disposed between the fixing plate 133 and the end plate 134 as a steel plate for horizontal reinforcement of the fixing device 130;
A second reinforcement plate 136 disposed between the horizontal plate 131 and the vertical plate 132 as a steel plate for vertical reinforcement of the fixing device 130; and
As an anchor bolt for fixing the vertical plate 132 of the fixing device 130 on the concrete matrix 230, the concrete matrix ( 230) A concrete structure in which a tension member for external pretension reinforcement including a chemical anchor 137 fastened to the top is embedded. According to paragraph 1,
A concrete structure in which a tension member for external pretension reinforcement is embedded, characterized in that the tension member is formed of a steel wire, strand, or steel bar as a reinforcing material. a) forming anchor bolt fastening holes (h1) at predetermined intervals in the lower part of the concrete matrix 230 for external pretension reinforcement;
b) fastening the anchor bolt 110 to the anchor bolt fastening hole (h1) formed in the lower part of the concrete matrix 230;
c) Step of arranging fixing devices 130 at both ends of the lower part of the concrete matrix 230:
d) placing tension members 140 on both ends of the fixing device 130 and tensioning them with a predetermined tension force;
e) applying and curing poured concrete 150 to the lower part of the concrete matrix 230 so that the tendon 140 is buried;
f) cutting each end of the tendon 140 exposed to the side of the poured concrete 150; and
g) including the step of removing the fixing device 130 from the concrete matrix 230 for reuse of the fixing device 130,
The tension member 140 allows the exposed end to be cut after curing the poured concrete 150,
The anchor bolt 110 is attached to the concrete matrix 230 in order to attach the concrete matrix 230 and the poured concrete 150 and transmit the prestress transmission force of the tendon 140 to the concrete matrix 230. Fastening construction is carried out,
It is coupled to the anchor bolt 110 and includes an anchor bolt coupling bracket 120 fastened to the lower part or side of the concrete matrix 230 together with the anchor bolt 110,
The anchor bolt coupling bracket 120 is a steel plate with an anchor bolt through hole (h2) formed so that the anchor bolt 110 can penetrate, and the anchor bolt 110 is connected through the anchor bolt through hole (h2). ) is inserted and a bracket body 121 constructed under the concrete matrix 230 together with the anchor bolt 110; and a method of constructing a concrete structure in which a tension member for external pretension reinforcement, which is a steel plate and includes bracket bent portions (122, 123) formed by bending on both sides of the bracket body (121), is embedded. According to clause 9,
According to the external pretension reinforcement of the concrete matrix 230, the tension member 140 is cut and embedded at both ends in the poured concrete 150, and the anchoring device 130 is installed in the poured concrete 150 so that it can be reused. ) A method of constructing a concrete structure in which tension members for external pretension reinforcement are embedded, characterized in that they are removed after curing. delete delete delete According to clause 9,
The bracket bending portions 122 and 123 are external pretensioners, characterized in that a plurality of poured concrete coupling holes (h3) are formed through which the poured concrete 150 is connected to improve adhesion to the poured concrete 150. A method of constructing a concrete structure in which reinforcing tendons are embedded. The method of claim 9, wherein the fixing device 130 is:
A horizontal plate 131, which is a steel plate disposed horizontally and has a fixing plate 133 connected to one upper side and an end plate 134 connected to the other upper side;
A vertical plate 132, which is a steel plate vertically connected to the lower part of the horizontal plate 131 and has a chemical anchor bolt fastening hole (h4) so that the chemical anchor 137 can pass through;
A fixing plate 133 disposed on one upper side of the horizontal plate 131 and having a tension material through-hole (h5) so that the tension material 140 can penetrate and be anchored thereto;
an end plate 134 formed on the other upper side of the horizontal plate 131 opposite the fixing plate 133;
A first reinforcement plate 135 disposed between the fixing plate 133 and the end plate 134 as a steel plate for horizontal reinforcement of the fixing device 130;
A second reinforcement plate 136 disposed between the horizontal plate 131 and the vertical plate 132 as a steel plate for vertical reinforcement of the fixing device 130; and
As an anchor bolt for fixing the vertical plate 132 of the fixing device 130 on the concrete matrix 230, the concrete matrix ( 230) A method of constructing a concrete structure in which a tension member for external pretension reinforcement including a chemical anchor 137 fastened thereto is embedded. delete