KR200307124Y1 - Apparatus for reinforcing load force resistance in continuous slab bridge using steel twisted wire - Google Patents

Abstract

The present invention relates to a load bearing reinforcement device for continuous slab bridges using a stranded wire, which is installed in the longitudinal direction of the continuous slab bridges, which surrounds three sides of both sides of the slab mounted on the alternating edges, and is attached to both sides of the slab with anchor bolts. Anchors on the side of the slab on the pier and the birds installed with anchor bolts on the side of the slab to mount the main tension bracket and the strand extending from the main tension bracket integrally formed with the through hole and the anchorage to install the Longitudinal load-bearing reinforcement device made of bolt-mounted divider

Auxiliary tension bracket with through hole and anchorage is formed on the H beam with anchor bolts so that the H beam that is raised below the slab is fixed to the anchor bolt and a strand can be installed at both ends of the H beam. It is installed, but the load-bearing reinforcement of the continuous slab bridge consisting of a transverse load-bearing reinforcement device is installed in the lower slab of the portion where the birds of the longitudinal load-bearing reinforcement is installed and welded.

Tensile force reinforcement device of longitudinal slab bridge load reinforcement device is installed on main tension bracket installed on side of slab, saddle and aviator mounted on main tension bracket installed on side tension side of slab on opposite side, After the introduction of the anchorage using a fixing fixture

The auxiliary tension bracket of the transverse load-bearing device is installed at both ends of the H-beam which is processed at the bottom of the slab and is fixed with anchor bolts, and penetrates the stranded wire and is fixed to the anchorage after reinforcing the load capacity of the continuous slab bridge.

Description

Load-bearing device for continuous slab bridge using steel strands {Apparatus for reinforcing load force resistance in continuous slab bridge using steel twisted wire}

The present invention relates to a load bearing reinforcement device for continuous slab bridges using a stranded wire, which is installed in the longitudinal direction of the continuous slab bridges, which surrounds three sides of both sides of the slab mounted on the alternating edges, and is attached to both sides of the slab with anchor bolts. Anchors on the side of the slab on the pier and the birds installed with anchor bolts on the side of the slab to mount the main tension bracket and the strand extending from the main tension bracket integrally formed with the through hole and the anchorage to install the Longitudinal load-bearing reinforcement device made of bolt-mounted divider

Auxiliary tension bracket with through hole and anchorage is formed on the H beam with anchor bolts so that the H-beams raised on the bottom of the slab can be fixed and anchored with anchor bolts. Is installed in the lower slab of the part where the birds of the longitudinal load reinforcement device is installed is a load-bearing reinforcement device of the continuous slab bridge consisting of a transverse load-bearing reinforcement device is welded to integrate with the saddle.

Tensile force reinforcement device of longitudinal slab bridge load reinforcement device is installed on main tension bracket installed on side of slab, saddle and aviator mounted on main tension bracket installed on side tension side of slab on opposite side, After the introduction of the anchorage using a fixing fixture

The auxiliary tension bracket of the transverse load-bearing reinforcement device is provided with anchor bolts at both ends of the H beam installed with anchor bolts and is fixed to the bottom of the slab. It is to reinforce the load capacity of slab bridge.

The saddle and the navigator of the longitudinal load-bearing reinforcement device is installed to cross tension between the piers to guide the strand wire to the main tension bracket installed on both ends to tension settle. In addition, the transverse load-bearing reinforcement device is applied to the both ends of the H beam fixed to the bottom surface of the slab and the auxiliary tension bracket of the transverse load-bearing reinforcement device is raised to the portion where the birds of the longitudinal load-bearing device is installed After welding is installed to integrate, the stranded wire is tensioned. Therefore, the transverse load-bearing reinforcement is eventually installed in the center of the slab where the piers and piers are installed.

The purpose of the present invention is to apply to severely affect the collapse or safety of the bridge due to the aging of the slab due to the aging of the continuous slab bridge or to increase the design load of the bridge. Reinforcement device and transverse load capacity reinforcement device are installed to introduce tensile force to the strand to transfer the upward force of the strand to the slab to prevent the slab from falling down and to extend the durability of the bridge at the most economical cost. The purpose is to provide a load-bearing reinforcement device for continuous slab bridges to improve the.

Generally, a support is installed at the lower part of the slab where the slab sags downward due to the aging of the slab to prevent the slab from sagging or the lower part of the slab is coated with the epoxy resin, which is a synthetic resin adhesive, to bond the synthetic fibers at the same time. It has been used as a way to prevent corrosion and deflection, but this is only a temporary method. It is necessary to maintain and maintain the slab under the slab by applying epoxy due to the effects such as uneven settlement or corrosion of the support supporting the slab. The method to protect is also very sensitive to the outside temperature, and a certain problem has been raised such that the adhesive strength of the epoxy decreases rapidly after a certain period of time.

The present invention has been proposed in view of the above matters. The longitudinal load reinforcement device and the transverse load capacity reinforcement device which can fix and stretch the stranded wire at the bottom of the slab of the continuous slab bridge are installed in a certain place, After connecting and fixing to each other and introducing a tension force to fix the main tension bracket and the auxiliary tension bracket of the respective devices by using the anchorage to transfer the force acting upwards to the slab to prevent the slab from sagging, It provides an economical and structural load-bearing device that increases the durability of the bridge and increases the safety while preventing the risk of collapse of the slab by increasing the load capacity on the slab for reinforcement of aging or supporting load. have.

1 is a view showing the load-bearing reinforcement device of the present invention installed in the longitudinal direction of the continuous slab bridge from the side.

Figure 2 is a view showing three-dimensionally the main tension bracket of the load bearing reinforcement device of the present invention.

Figure 3 is a view showing the side installed in the slab side end of the main tension bracket of the present invention.

4 is a front view showing that the main tension bracket of Figure 3 is installed on the slab side end.

Figure 5 is a view showing the side installed on the slab side of the deviser of the present invention.

FIG. 6 is a front view showing that the aviator of FIG. 5 is installed on the slab side; FIG.

Figure 7 is a side view showing the installation of the birds of the present invention on the slab side.

FIG. 8 is a front view of the birds of FIG. 7 installed at the slab side; FIG.

9 is a view showing the lower surface of the load bearing reinforcement device of the present invention installed in the width direction of the continuous slab bridge.

Figure 10 is a front view showing the installation of the auxiliary tension bracket of the load bearing reinforcement device of the present invention in the lower slab.

<Explanation of symbols for the main parts of the drawings>

A ... load bearing reinforcement

10 ... continuous slab bridge 11 ... slab

12 Bridge top curb 13 Slab bottom

20 ... Main tension bracket 21 ... Side wall

22 ... through hole 23 ... anchorage

24 ... anchor bolt hole 25 ... anchor bolt

30.Deviator 40 ... Saddles

50 ... strand 60 ... piers

70 ... alternately 80 ... auxiliary tension bracket

90 ... H beam 100 ... longitudinal load reinforcement

200 ... lateral load reinforcement

The present invention relates to a load-bearing reinforcement device for a continuous slab bridge using a stranded wire, which is installed in the longitudinal direction of the continuous slab bridge (10), and wraps three sides of both sides of the slab (11) to be placed on the shift 70 The main tension bracket 20 and the main tension bracket 20 in which the through-hole 22 and the fixing member 23 are integrally formed so as to be attached to both side portions of the 11 by anchor bolts 25 and to install the strand 50. Anchor bolts on the side of the slab 11 side mounted on the saddle 40 and the pier 60 is installed as an anchor bolt 25 on the side of the slab 11 so as to mount the strand 50 is extended from the Longitudinal load-bearing reinforcement device 100 consisting of a divider 30 is installed as 25

An auxiliary tension bracket having a through hole and a fixing hole formed therein is installed to fix the H-beam 90 processed upward on the slab lower part 13 with anchor bolts and to install a strand that can tension the H-beam at both ends of the H-beam. The transverse load-bearing reinforcement is installed integrally with an anchor bolt to the H beam, but is installed on the lower slab 13 of the portion where the saddle 40 of the longitudinal load-bearing reinforcement device 100 is installed and welded to integrate with the saddle. It is a load-bearing reinforcement device (A) of the continuous slab bridge (10) consisting of (200).

The main tension bracket 20, the saddle 40, and the divider 30 installed on the side of the slab 11 using the longitudinal load bearing reinforcement device 100 of the continuous slab bridge 10 load bearing reinforcement device A are provided. After fixing the stranded wire 50 to the main tension bracket 20 mounted on the side end of the slab 11 of the opposite side and introduced the tensile force, and then tension-fixed using the anchorage 23,

The auxiliary tension bracket 80 of the transverse load-bearing reinforcement device 200 is installed at both ends of the H beam 90 installed by rising below the slab 11, and passes through the strand 50, followed by the strand 50. After tensioning, the anchoring unit 23 is fixed to reinforce the load capacity of the continuous slab bridge 10.

The saddle 40 and the divider 30 of the longitudinal load bearing reinforcement device 100 are installed alternately between the piers 60 to guide the strand 50 to the main tension bracket 20 installed at both ends. It is to make the tensile fixation. In addition, the transverse load-bearing reinforcement device 200 is the slab 11 to the auxiliary tension bracket 80 of the transverse load-bearing reinforcement device 200 in the portion where the saddle 40 of the longitudinal load-bearing reinforcement device 100 is installed After installation on both ends of the H-beams which are provided at the bottom of the bottom), the stranded wire 50 is tension-fixed. Therefore, the transverse load-bearing reinforcement device 200 is characterized in that it is installed in the center of the slab 11 in which the pier 60 and the pier 60 is installed.

Hereinafter, the technical configuration and operation of the present invention by the accompanying drawings in detail.

1 is a side view showing that the load-bearing reinforcement device of the present invention is installed in the longitudinal direction of the continuous slab bridge in the longitudinal direction of the continuous slab bridge 10, but both sides end of the slab 11 to be placed on the alternating 70 The main tension bracket 20 is formed to integrally cover the three sides of the slab 11 with the anchor bolts 25 attached to both sides of the slab 11, and the through hole 22 and the process fitting 23 are installed to install the strand 50. ) And the portion to be mounted on the saddle 40 and the pier 60 which are installed as anchor bolts 25 on the sides of the slab 11 so as to mount the strand 50 extending from the main tension bracket 20. The longitudinal load-bearing reinforcement device 100 made of a divider 30 is installed on the side of the slab (11) anchor bolt 25 is installed.

At this time, the saddle 40 is installed in the center between the pier 60 and the pier 60 or between the alternating 70 and the pier 60 to transfer the force to act upward of the strand 50 to the slab (11). It is installed in order to, and the divider 30 is installed on the side of the slab 11 mounted on the pier 60 is installed to change the direction of movement of the strand 50. Therefore, since the distributor 30 is installed on the side of the slab 11, the strand 50 is installed on the side of the slab 11 in the shape of the "S" Slab 11 to force the upward force of the strand 50 (slab 11) By transmitting to the slab 11 to reduce the amount of the moment acting to act to prevent the sag of the slab (11).

2, 3 and 4 are views showing the cross section and the slab side end of the main tension bracket of the load bearing reinforcement device of the present invention as shown in Figure 2 the side wall portion 21 is perpendicular to each other over three sides It is attached so that the side end of the slab 11 is enclosed in the space portion of the center, anchored to the two sides of the side of the slab by anchor bolt holes formed in the side wall of the two sides, and fixed to the anchor bolt on the side of the slab 11 A through hole 22 and a fixing hole 23 are provided in the side wall portion 21 of the main tension bracket 20 to tension-fix the strand 50. When the side end of the slab 11 is installed so as to be wrapped, the tensile force acting on the strand 50 is evenly transmitted to the side end of the slab 11 can prevent the destruction of the slab (11). 3 shows that the anchor bolt 25 is fixed to the slab 11 using the main tension bracket 20, and the anchor wire 25 penetrates the anchor wire 25 to fix it using the anchorage 23 from the side of the slab 11. 4 is a front view showing that the main tension bracket 20 is installed at the slab 11 side end.

5 and 6 is a view showing the installation of the device of the present invention on the slab side from the side and the front side of the longitudinal load bearing reinforcement device 100 of the above-mentioned slab 30 on the pier 60 11) is installed on the side of the installation to change the direction of the strand 50. Therefore, the divider 30 is installed on the side of the slab 11, so that the strand 50 is installed on the side of the slab 11 in the shape of the "S" to raise the upward force of the strand 50, the slab 11 ) To reduce the amount of government moment acting on the slab 11 to prevent the slab 11 from sagging. In addition, the divider 30 is fixedly installed using the anchor bolt 25 on the side of the slab 11 integrally with the bridge upper curb 12 installed on both sides of the bridge upper portion.

7 and 8 is a view showing the installation of the birds of the present invention on the side of the slab from the side and front, the saddle 40 between the pier 60 and pier 60 or between the alternating 70 and pier 60 It is installed in the center of the wire to install the force to act the upward of the strand 50 to the slab as the upper force of the strand 50 is transmitted to the slab 11 the government moment acting on the slab 11 It is to reduce the amount of to serve to prevent the sag of the slab (11).

3 to 8 are installed on the side of the slab in order to transmit the upward force of the strand in the longitudinal direction of the slab.

9 is a view showing the load-bearing reinforcement device of the present invention installed in the width direction of the continuous slab bridge as seen from the bottom surface is installed on both ends of the H beam (90) installed in the anchor bolt bolted to the bottom of the slab (13) An auxiliary tension bracket 80 formed with a through hole 22 and a fixing member 23 is fixedly installed in the H beam so that the 50 can be installed therebetween, and thus, between the piers 60 and the piers 60 of the lower slab 13. Or installed in the center between the alternating 70 and the piers 60 to transmit the upward force of the H-beam 90 and the strand 50 of the upward rise installed in the lower slab in the width direction of the slab (11). It is installed.

10 is a view showing the installation of the auxiliary tension bracket of the load bearing reinforcement device of the present invention in the lower slab from the front as the auxiliary tension brackets 80 are installed on both ends of the H-beam of the upward rise installed in the lower slab (13) It also shows that after the passage 50 through the anchoring fixture 23 is settled by using the anchorage, the saddle 40 of the longitudinal load-bearing reinforcement device 100 is installed integrally with the saddle at the portion where it is installed have.

As described above, the present invention relates to a reinforcing device for extending the durability of the bridge and ensuring the safety of the bridge while preventing the deflection of the slab of the continuous slab bridge to increase the load capacity of the bridge, using the apparatus It is installed at the bottom of the slab to introduce the tensile force to the strand to transfer the upward force of the strand to the slab to extend the life of the bridge. By using the reinforcement method as described above, it is possible to prevent unnecessary construction of new bridges and the removal and construction of existing bridges, thereby reducing the budget associated with the installation of the bridges and also simplifying the installation work of the device. This is a very useful reinforcement device in the most economical and structural way in which the savings are achieved.

Claims (5)

It is installed in the longitudinal direction of the continuous slab bridge, but is installed at both ends of the slab on the alternating side, and it is installed on the both sides of the slab with anchor bolts. Longitudinal load-bearing reinforcement device which consists of saddle and aviator installed on the side of slab and anchor for mounting the extended strand, As a transverse load-bearing reinforcement device consisting of an H-beam mounted on the lower part of the slab and anchored with anchor bolts, and integrated with anchor bolts at both ends of the H-beam, with an auxiliary tension bracket having through holes and anchorages to install the strand. Load bearing reinforcement device of continuous slab bridge using a stranded wire, characterized in that made. The method of claim 1, The main tension brackets installed at both ends of the slab mounted on the alternating side wall of the slab are perpendicular to each other at three sides to surround the three sides of both sides of the slab, and the anchor bolt holes formed at the side walls of the two sides of the slab A load bearing reinforcement device for a continuous slab bridge using a stranded wire, wherein two sides of the side end portion are attached with anchor bolts and a through hole and a fixing unit are integrally formed to install the stranded wire. The method of claim 1, The auxiliary tension bracket of the transverse load-bearing reinforcement device is installed with anchor bolts at both ends of the H-beams installed on the bottom of the slab, and integrated with the saddle at the slab bottom of the slab side where the birds of the longitudinal load-bearing device are installed. A load bearing reinforcement device for continuous slab bridges using a stranded steel wire, characterized in that the transverse load capacity reinforcement device is installed between the bridge piers and the piers as the through holes and the fixing holes are formed to install the strand wires. The method of claim 1, The birds are installed in the center of the bridge between the piers and the bridge or between the bridges and piers to transfer the force to act upward of the strands to the slab, the divider installed on the side of the slab mounted on the piers is a strand The stranded wire installed on the side of the slab by changing the direction of travel is installed on the side of the slab in the shape of "S" to transmit the upward force of the stranded wire to the slab to reduce the static moment. Load bearing reinforcement device of continuous slab bridge. The method of claim 1, The divider is fixed by using an anchor bolt on the side of the slab while surrounding the upper curb bridge installed in both sides of the bridge to give a downward force to the inner point to reduce the parent Load bearing reinforcement device of continuous slab bridge using stranded wire.