KR100927952B1 - Girder and method bridge building using the same - Google Patents

Abstract

PURPOSE: A tension-adjustable girder and a bridge construction method using the same are provided to facilitate maintenance of a bridge by loosening and tightening a secondary strand easily. CONSTITUTION: A tension-adjustable girder(100) comprises a sheath pipe, a primary strand, a secondary strand, a fixing plate, a setting wedge, and a sealing anchorage. The sheath pipe is inserted in the longitudinal direction inside a girder main body. The primary strand is settled on the end part of the girder which is inserted in the sheath pipe without coating and integrated by a grout material. The secondary strand is settled on the side of the girder which is put on the sheath pipe after coating and integrated by a grout material. The fixing plate is installed on both ends of the girder main body and secures both ends of the primary strand and the secondary strand. The setting wedge secures the primary strand and the secondary strand with tension. The sealing anchorage is installed on both ends of the sheath pipe in which the secondary strand is installed, and has an insertion hole in which the coated secondary strand is inserted airtightly and a sealing is installed.

Description

Girder with adjustable tension and construction method for bridges using it {Girder and method bridge building using the same}

The present invention relates to a girder and a method of constructing a bridge using the same, the tension force can be adjusted, in order to repair the sag or crack of the bridge by the use of the loosen the strands (strand) installed during construction again after repair and repair A girder having an airtight anchorage to prevent the end of the strand which has been stripped from being clad so as to be tensioned again by concrete, and having a strong carbon fiber plate integrated therein, which is strong in tensile strength and bending; Installing the integrated girder on the piers, tensioning the secondary strand settled on the side or the top of the girder, and installing a sealed anchor at both ends, both ends The present invention relates to a method for constructing a bridge using the girder, including the step of filling concrete, etc., between the sealed anchorages of the closed anchorages, that is, the secondary strand from which the covering is removed.

[Document 1] Korean Patent Registration No. 10-0734169, 2007.06.26
The invention of Document 1 relates to a prestressed concrete girder and a construction method thereof provided with a maintenance anchorage capable of adjusting tension. A girder comprising upper and lower flanges and an abdomen; A fixing block protruding from both sides of the girder with a predetermined width and width; It is composed of a fixing fixture for maintenance so as to introduce a tension force for tensioning the strand at a predetermined position on both end sides of the fixing block. In addition, the construction method is provided with a protruding fixing block on both sides of the PSC girder, and a maintenance fixing unit in which a wedge, an additional tension ring nut and a tension release bracket are mixed on the protruding fixing block, respectively, Strands are installed across the management anchorage, and when the main tension of the strands is tensioned using the wedges of the maintenance anchorages, the additional tension is used to tension the strands using the additional tension ring nuts of the maintenance anchorages. And, if the replacement insertion of the strand is necessary to remove the tension release bracket to completely remove the existing tension to remove the existing strand and to insert a new strand to be tension.

The girder is installed on the upper part of the pier so that the load capacity of the bridge can be adjusted, the upper plate is installed on the upper part, and concrete slabs and the like are installed on the upper part of the upper part. The girder is manufactured to adjust the tension to increase the load capacity of the bridge, to compensate for sagging or cracking caused by overload or use.

A plurality of sheath tubes are installed in a longitudinal direction inside a conventional prestressed girder (PSC) girder, and a plurality of strands are inserted into the respective sheath tubes.

The strands are divided into primary strands settled at the end of the girder and secondary strands settled at the side of the girder according to the construction stage.The primary strands are tensioned in advance and grouted to the sheath tube to be integrated with the girder. Install on the piers. The secondary strands are installed with a coating so that the secondary strands do not come into direct contact with the concrete girder and seize to relieve tension during the renovation work. And in order to pull both ends to tension the tension in the state in which both ends of the coating is peeled off, and the sheath pipe is filled with grout to install the outer surface and the girders integrally. Therefore, when renovation is required, the secondary strands that are not held by the grout are released to work, and then pulled again.

In the conventional case, the secondary strands were pulled by peeling the sheaths at both ends in order to pull the secondary strands to tension, and the tensioning device was pressed against the stripped secondary strands. The sheath tube was filled with grouting.

The secondary strand settled on the side of the girder as described above is a component that needs to be relaxed and retensioned later to repair the bridge, and the grout material is removed when the grout material is filled in the sheath tube into which the secondary strand is inserted. By sticking to the secondary strand, there was a problem that can not relax or re-tension the secondary strand for the bridge repair.

Therefore, in the present invention, even when the grout material is filled inside the sheath tube into which the secondary strands are fixed on the side of the girder, both ends of the stripped secondary strands are not in contact with the grout material and the grout material is in contact only with the secondary strands. It is aimed at providing a structure which facilitates when the secondary strand is relaxed or retensioned.

In order to achieve the above object, the present invention is to provide a girder provided with sealed anchors at both ends of the sheath tube. The sealing anchorage is formed with a plurality of insertion holes for inserting the secondary strand is fixed to the side of the girders in the coated state, the insertion hole is provided with a sealing in hermetic contact with the coating, filled in the sheath tube The grout material is prevented from leaking to the outside of the sealing anchorage, so that the coating is not in contact with both ends of the stripped secondary strand.

According to the present invention, the grout material of the sheath pipe inserted with the secondary strand settled on the side of the girder does not come into contact with both ends of the stripped secondary strand, thereby easily tensioning the secondary strand for the bridge repair work. By being able to release and tension again after repair, maintenance of the bridge using the girder becomes very easy.

Girder according to the present invention is characterized in that the structure to be able to relax and re-tension of the secondary strand (1) is fixed to the side of the girder. That is, a plurality of sheath tubes (3) inserted into the arc shape in the longitudinal direction inside the girder body (2); A primary strand 5 which is inserted into the sheath tube 3 without coating and is tensioned and then integrated with the grout material 4; A secondary strand (1) fixed to the side of the girder integrated with the grout material (4) after the sheath (6) is covered and tensioned by the sheath pipe (3); Fixing plates (7) provided at both ends of the girder body to fix both ends of the primary strand (5) and the secondary strand (1); In the girder 100, comprising: a fixing wedge 8 for holding the primary strand 5 and the secondary strand 1 drawn out through the holes of the fixing plate 7 and fixing the secondary strand 1 in a tensioned state. It is characterized in that the sealing anchorage (10) formed with the insertion hole (9) through which the secondary strand (1) covered with the sheath (6) is hermetically inserted at both ends of the sheath pipe (3) on which the primary strand (1) is installed. . The insertion hole 9 is provided with a seal 11 in close contact with the sheath 6 so as to prevent the internal grout material 4 of the sheath pipe 3 from leaking to the outside.

And the present invention has another feature in that the carbon fiber plate 12 is inserted into the girder body 2 in the longitudinal direction of the girder body (2) to be integrated. The carbon fiber plate 12 may be manufactured by using PAN-based carbon fibers of about 5 mm in thickness and having a width of 2 to 5 cm, or distributed in the form of a plate or round bar. Round bar is formed by twisting a plurality of strands of carbon fiber yarn having a diameter of about 12 mm. In the present invention, the carbon fiber plate 12 refers to all of various forms such as the carbon fiber plate and the round bar in circulation, and the carbon fiber plate in circulation, which is attached in a "TT" shape and the like and has a form of a section steel. .

And the carbon fiber plate 12 is installed inside the sheath tube (3), may be installed to be integrated by the grout material (4).

In the present invention having such a structure, the girder 100 is installed on a pier in FIG. 1, the cross section of the girder 100 is illustrated in FIGS. 2 and 3, and the secondary strand 1 is illustrated in FIG. 4. Both ends of the airtight structure are shown.

The method of installing the carbon fiber plate 12 may vary. That is, after the sheath pipe 3 is installed and cured in the girder main body 2, the carbon fiber plate 12 is inserted into the girder body 4 to be integrated with the grout material 4, and the girder main body 2 can be manufactured in a reinforced concrete structure. When the carbon fiber plate (12) without the sheath tube (3) or the carbon fiber plate (12) attached to the iron plate with an epoxy or the like on the side reinforcement with the reinforcement, and curing the girder body (2) after the main body (2) The groove is formed on one side of the carbon fiber plate 12, and the like.

Of course, the girder 100 is provided with a primary strand 5 and a secondary strand 1, and a sheath pipe 3 is installed for each of them.

When the girder 100 is cured, the weight of the girder 100 and the weight of the slab are pulled to tension the primary strands 5, and both ends thereof are inserted into the holes of the fixing plate 7, and then the fixing wedges 8 To be fixed. Then, a high-strength mortar or epoxy grout material 4 is injected into the sheath tube 3 into which the primary strands 5 are inserted to integrate the primary strands 5 into the main body 2. Its method and structure are common.

Next, the girder 100 is installed on the pier, and the secondary strand 1 is tensioned and fixed by the incident load and the live load. At this time, the present invention uses the secondary strand (1) coated (6) for the repair of the bridge after. Therefore, when the secondary strand 1 is tensioned, the cover 6 is removed at both ends by a predetermined length so that the tension device can be pressed and pulled.

And the secondary strand 1 fixed to the side of the girder is inserted into each insertion hole 9 of the sealing anchorage 10, and the sealing anchorage 10 is inserted in the edge part of the sheath pipe 3. As shown in FIG. The insertion hole 9 is provided with a seal 11, and the sheath 6 of the secondary strand 1 is positioned in the seal 11 so as to be in an airtight state. Therefore, the sheath 6 only needs to exist outside the place where the seal 11 is located.

Therefore, when the secondary strand 1 is squeezed and tensioned by the tension device, it is necessary to use the portion where the coating 6 is removed and to maintain the tension state using the fixing plate 7 and the fixing wedge 8 to maintain the tension state. It is a general well-known technique like (5).

And the grout material 4 is filled in the sheath pipe 3, the grout material 4 is not leaked to the outside of the sheath pipe 3 by the sealing (11). Therefore, the grout material 4 does not contact the secondary strand 1 from which the coating 6 located at the outer side of the sealing anchorage 10 is peeled off.

The secondary strand 1 fixed to the side of the girder is not integrally fixed to the main body 2 by the sheath 6 so that it can flow in the sheath 6, and the part where the sheath 6 is peeled off is a closed anchorage. Since the contact with the grout material 4 is prevented by (10), integration with the main body 2 is prevented.

Therefore, it is very easy to relax and re-tension the secondary strand 1 for reasons such as repair of the bridge.

In addition, since the carbon fiber plate 12 used in the present invention has a tensile strength greater than that of steel, the primary strand 5 is fixed at the end of the girder and the secondary strand 1 is fixed at the side of the girder. Of course, there is an advantage of preventing excessively bulging upward or lowering the height of the girder by the tension of the primary strand (5) and the secondary strand (1).

As described above, when constructing a continuous bridge by installing the girder 100 on the piers, a plurality of girders 100 must be connected. Both ends of the girder 100 are mounted on the pier, respectively, and are installed while maintaining a predetermined distance from other adjacent girders 100. As such, a structure in which a plurality of girders 100 are connected is illustrated in FIG. 5.

If a plurality of girders 100 are installed, the slab concrete 13 is poured on the girder 100.

A feature of the invention at this stage is that the interior of the slab concrete 13, ie the interior of the slab concrete 13 that is poured over the adjacent part of the girder 100, crosses the gap between the adjacent girders 100. It is characterized by embedding the connecting table 14.

Therefore, before placing the concrete 13 on the top of the girder 100, the connecting table 14 is installed across the space between the girder 100 and the girder 100. The connecting table 14 is a structure in which the grout material 4 is filled and integrated with the carbon fiber plate 12 inserted into the sheath tube 3 as shown in FIG. 7, or a plurality of carbon fiber plate 12. Alternatively, the carbon fiber plate 12 having the iron plate attached to the side may be installed side by side, and the epoxy 17 may be filled therebetween. Of course, any structure other than the above structure is possible, and a single structure of rebar or carbon fiber board is also possible.

After the connecting rod 14 is installed as described above, the concrete 13 is poured to cure. Therefore, the connecting table 14 prevents the occurrence of cracks that are likely to occur in the connection between the girders (100).

The next step is to pour a pavement 15, such as asphalt, on top of the cured concrete 13.

1 is a state diagram installed in the girder of the present invention pier

FIG. 2 is a sectional view taken along the line “A-A” of FIG. 1.

3 is a cross-sectional view of the "B-B" in FIG.

4 is an installation state of the sealed anchorage

5 is a detailed view of the girder connection

FIG. 6 is a cross-sectional view of the portion “C-C” of FIG. 5.

FIG. 7 is a sectional view taken along the line “D-D” of FIG. 5; FIG.

※ Explanation of codes for main parts of drawing

1: 2nd strand 2: main body

3: sheath pipe 4: grout ash

5: primary strand 6: sheath

7: fixing plate 8: fixing wedge

9: insertion hole 10: sealed anchor

11 sealing 12 carbon fiber board

13: slab concrete 14: connecting rod

15: packaging material 16: iron plate

17: epoxy 100: girder

Claims (5)

A plurality of sheath pipes 3 inserted into the girder body 2 in a longitudinal arc shape; A primary strand (5) inserted into the sheath tube (3) without covering and tensioned and then fixed to the end of the girder integrated with the grout material (4); A secondary strand (1) fixed to the side of the girder integrated with the grout material (4) after the sheath (6) is covered and tensioned by the sheath pipe (3); Fixing plates (7) provided at both ends of the girder body (2) to fix both ends of the primary strand (5) and the secondary strand (1); In the girder 100, comprising: a fixing wedge 8 for holding the primary strand 5 and the secondary strand 1 drawn out through the holes of the fixing plate 7 and fixing the secondary strand 1 in a tensioned state. An airtight anchorage 10 having an insertion hole 9 provided with a seal 11 at both ends of the sheath pipe 3 provided with the car strand 1 is provided, and the cover 6 is provided inside the seal 11. Tension-adjustable girder, characterized in that the covered secondary strand 1 is hermetically inserted. The girder according to claim 1, wherein a carbon fiber plate (12) is inserted into the girder main body (2) so as to be integrally installed in the longitudinal direction of the girder main body (2). When the girder 100 is cured, a load equal to the weight of the girder 100 or the weight of the girder 100 and the weight of the slab is pulled to tension the primary strand 5 fixed at the end of the girder, and then both ends of the fixing plate 7 are fixed. After inserting into the hole, it is fixed by the fixing wedge (8), and the grout material (4) is injected into the sheath pipe (3) into which the primary strand (5), which is fixed at the end of the girder, is inserted into the primary strand (5). Integrating the main body 2; The girders 100 are installed on the pier, the sealing anchorages 10 are installed at both ends of the sheath pipe 3 provided with the secondary strand 1 fixed to the side of the girder, and the respective insertions of the sealing anchorages 10 are inserted. Inserting the secondary strand 1 into the hole 9 so that the sealing 11 of the insertion hole 9 is hermetically adhered to the sheath 6; Pressing and pulling the stripped portion of the secondary strand 1 with the tensioning device and maintaining the tension state using the fixing plate 7 and the fixing wedge 8; Filling the grout material 4 into the sheath pipe 3 provided with the secondary strand 1 such that the grout material 4 does not leak to the outside of the sheath pipe 3 by the sealing 11; and Construction method of the bridge using a girder capable of adjusting the tension, characterized in that configured. delete Assembling the carbon fiber plate 12 when the reinforcement when the girder 100 is manufactured; When the girder 100 is cured, a load equal to the weight of the girder 100 or the weight of the girder 100 and the weight of the slab is pulled to tension the primary strands 5 fixed at the ends of the girder 100, and both ends thereof. Is inserted into the hole of the fixing plate (7) and then fixed with the fixing wedge (8), the grout material (4) inside the sheath tube (3) in which the primary strand (5) fixed to the end of the girder (100) is inserted. Injecting the primary strand 5 into the body 2; The girders 100 are installed on the pier, the sealing anchorages 10 are installed at both ends of the sheath pipe 3 provided with the secondary strand 1 fixed to the side of the girder, and the respective insertions of the sealing anchorages 10 are inserted. Inserting the secondary strand 1 into the hole 9 so that the sealing 11 of the insertion hole 9 is hermetically adhered to the sheath 6; Pressing and pulling the stripped portion of the secondary strand 1 with the tension device, and maintaining the tension state using the fixing plate 7 and the fixing wedge 8; Filling the grout material 4 into the sheath pipe 3 provided with the secondary strand 1 such that the grout material 4 does not leak to the outside of the sheath pipe 3 by the sealing 11; and Construction method of the bridge using a girder capable of adjusting the tension, characterized in that configured.

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