KR101641583B1 - Apparatus for reinforcing a girder section force for bridge and method manufacturing the same - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for reinforcing a girder section force of a bridge and a method of manufacturing the same. Cross beams connecting the girders horizontally; A slab connecting upper portions of the girders; First and second fixing ports provided on the beams arranged on both sides of the reference line relative to the longitudinal center of the girder; And a stranded wire having one end fixed to the first fixing port, the other end fixed to the second fixing port, and a middle portion positioned inside the lower portion of the girder, and giving a tension to the girder. According to the present invention, after the girders are installed between the alternations (the lower structures of the bridge), the transverse beams and the slab are formed in the girders, and the weakening force of the girder is strengthened by the weight of the transverse beams and the slab.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a girder bridge reinforcement apparatus for a bridge,

The present invention relates to an apparatus for reinforcing a girder section force of a bridge and a method of manufacturing the same.

A bridge includes a plurality of alternations, and a top plate connecting the alternations and alternations. If there is a pier between the alternation and the alternation, the top is located between the alternation and the pier. Bridges using concrete girders (or steel composite girders) can increase the span, which is the distance between alternating and alternating (or between alternating and piercing, or piercing and piercing) bridges compared to a reinforced concrete bridge. The alternation and pier are also referred to as the bridge's lower structure.

The general procedure for manufacturing the top plate using the concrete girder is as follows.

First, concrete girders are installed between alternating and alternating so that they are arranged in alternating transverse directions. The formwork is installed so that a slab connecting the upper side of the concrete girders and the transverse beam connecting the concrete girders in the transverse direction is formed. Reinforced concrete is placed on the formwork, then concrete is cured and cured to form a beam and a slab.

On the other hand, the concrete structure has excellent resistance to compressive force, but has a very weak resistance to tensile strength. Therefore, when constructing a concrete girder for installing a bridge top plate, a plurality of strands are arranged inside a concrete girder to produce a concrete girder, and the strands are tensed to introduce a prestress into the concrete girder.

Korean Patent Laid-Open Publication No. 2001-0000430 (published on May 1, 2001) (hereinafter referred to as Prior Art 1) discloses "a method for constructing a continuous bridge using an exposed fixation device and a prestressed concrete girder having the same. In the prior art 1, a girder is manufactured so that stranded wires are provided in the girder, and then a prestress is introduced into the girder by tensioning the strand, thereby securing a sectioning force capable of resisting the fixed load or live load acting on the girder. However, in the prior art 1, when the girders are installed alternately after introducing the prestresses into the girders respectively and the girders are formed with the transverse beams and slabs, there is a disadvantage in that the sectional force of the girders is lowered by the loads of the transverse beams and the slabs.

It is an object of the present invention to provide a bridge girder section reinforcement apparatus for installing girders between bridge substructures, forming transverse beams and slabs in the girders, reinforcing the weakening of the section force of the girders by the weight of the girders and slabs, And a manufacturing method thereof.

In order to achieve the object of the present invention as described above, girders installed between alternating and alternating positions; Cross beams connecting the girders horizontally; A slab connecting upper portions of the girders; First and second fixing ports provided on the beams arranged on both sides of the reference line relative to the longitudinal center of the girder; And a stranded wire which is fixed at one end to the first fixing port and the other end is fixed to the second fixing port and the middle portion is located inside the lower portion of the girder and which gives tension to the girder. Is provided.

It is preferable that the first fixing port is located at a beam closest to the longitudinal center line of the girder and the second fixing port is located at a beam closest to the longitudinal center line of the girder.

The girder is preferably a PSC girder including a reinforced steel structure and a concrete body surrounding the reinforced steel structure.

The girder may be a steel composite girder including an I-section steel and a concrete body surrounding the I-section steel.

It is preferable that the first fixing port is mounted on a beam positioned on one side of the girder and the second fixing port is mounted on a beam positioned on the other side of the girder and the strand is located in a diagonal direction of the girder Do.

Placing a reinforcing bar in a first die for constructing a girder to install a reinforcing steel structure; The first and second sheath pipes are installed in the first die, and the first sheath pipe is installed over the entire longitudinal direction of the first die, and the second sheath pipe extends over the middle portion in the longitudinal direction of the first die Installing; Placing and curing concrete in the first mold; Inserting a first strand into the first sheath tube and introducing a first prestress into the girder by tensing; Installing a plurality of girders between alternating and alternating; Installing a second formwork for making a slab connecting upper side of girders and transverse beams connecting the girders in a lateral direction; Placing a reinforcing steel structure in the second die; Fixing the both end portions of the second sheath pipe to protrude outwardly of the beam portion through the portion corresponding to the beam of the second die; Placing and curing concrete in the second die to form transverse beams and slabs; And introducing a second prestress into the girder by inserting a second stranded wire into the second sheath tube and tensing the girder.

Forming two opening grooves in an intermediate portion of a lower flange of the I-shaped steel for a girder; Installing a first die for forming a concrete lower casing on a lower flange of the I-beam steel; Placing reinforcing bars in the first die; Installing a sheath pipe through two portions of the lower flange of the I-shaped steel so that both end portions project out of the first formwork; Forming a steel composite girder by forming a lower casing by pouring and curing concrete in the first formwork so as to surround an intermediate portion of the lower flange of the I-shaped steel and an intermediate portion of the sheath pipe; Installing a plurality of steel composite girders between alternating and alternating; Installing a second formwork for making slabs connecting the transverse beams connecting the steel composite girders in the transverse direction and the upper surface of the steel composite girders; Placing a reinforcing steel structure in the second die; Fixing the both end portions of the sheath tube to protrude outwardly of the beam portion through portions corresponding to the beam portions of the second die; Placing and curing concrete in the second die to form transverse beams and slabs; And introducing a prestress into the steel composite girder by inserting a stranded wire into the sheath pipe and tensing it to provide a girder reinforcement apparatus for a bridge.

In the present invention, the transverse beams and the slab are formed in the girders into which the prestress is introduced, and the sectional force of the girder is weakened by its own weight. Secondary tension unit introduces compressive force to the girder secondarily to increase the sectional force of the girder. In addition, a compressive force is introduced into the slab to increase the sectional force of the slab.

In addition, since the strand of the secondary tension unit for introducing the secondary compression force to the girder is located only in the middle portion of the girder, the effect of introducing the compressive force into the girder is increased, Thereby eliminating unnecessary stress distribution.

In addition, since the present invention introduces a compressive force to the girder secondarily, the sectional force of the girder decreased by its own weight is increased, so that the amount of material required for the girder can be reduced compared with the case where only the first prestress is introduced. That is, in the case of the steel composite girder, the height of the I-shaped steel can be reduced or the length of the steel composite girder can be made longer, and in the case of the PSC girder, the sectional area of the PSC girder can be reduced or the length of the PSC girder can be made longer.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view showing an embodiment of a girder section strength reinforcing apparatus for a bridge according to the present invention;
2 is a front view showing an embodiment of a girder section strength reinforcing apparatus for a bridge according to the present invention,
3 is a plan view showing an example of a state of installation of a tension unit constituting an embodiment of a girder section strength reinforcement of a bridge according to the present invention,
Fig. 4 is a front view showing a steel composite girder constituting an embodiment of a girder section strength reinforcement of a bridge according to the present invention, Fig.
Fig. 5 is a sectional view taken along the line AA of Fig. 4,
Fig. 6 is a cross-sectional view taken along line BB of Fig. 4,
FIG. 7 is a cross-sectional view taken along the line CC of FIG. 4,
8 is a flowchart showing a first embodiment of a method for manufacturing a girder section strength reinforcement apparatus for a bridge according to the present invention,
9 is a flowchart showing a second embodiment of a method for manufacturing a girder section strength reinforcement apparatus of a bridge according to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a girder section strengthening apparatus and a method of manufacturing the same according to the present invention will be described with reference to the accompanying drawings.

1 is a plan view showing an embodiment of a girder section strength reinforcing apparatus for a bridge according to the present invention. 2 is a front view showing an embodiment of a girder section strength reinforcement apparatus for a bridge according to the present invention.

An embodiment of a girder section strengthening apparatus for a bridge according to the present invention will be described with reference to Figs. 1 and 2. Fig. First, a plurality of girders 200 are provided between the alternating station 100 and the alternating station 100, and the transverse beams 300 connecting the girders 200 in the transverse direction are installed on the girder 200 at predetermined intervals in the longitudinal direction And a slab 400 is provided on the upper part of the girders 200. [ The girders 200 are each a PSC (pre-stress concreate) girder 200. Also, a plurality of girders 200 may be provided between the bridge piers and the bridge piers, or alternately between the bridge piers. Alternates and piers are collectively referred to as bridge substructures.

The girders 200 each have a concrete body 210 having a length and a designed sectional shape corresponding to a distance between the alternation 100 and the alternation 100 and a reinforcing structure provided inside the concrete body 210 A primary tension unit 220 disposed over the entire length of the concrete body 210 to introduce a prestress to the concrete body 210 in a first place, And a secondary tension unit 230 for introducing a prestress into the concrete body 210 in a second order.

The first tension unit 220 includes a first sheath pipe 221 located over the entire longitudinal direction of the concrete body 210 and having both ends positioned on both longitudinal sides of the concrete body 210, A first strand 222 inserted into the concrete body 210 and fixing holes 223 provided on both longitudinal sides of the concrete body 210. The first sheath tube 221 and the first strand 222 are positioned in a downwardly curved shape. The first strand 222 is tensioned and exerts a compressive force on the concrete body 210 of the girder 200. It is preferable that a plurality of primary tension units 220 are provided.

The secondary tension unit 230 includes a first fixing hole 231 provided on the beam 300 located at one side of the reference line with respect to the longitudinal center of the girder 200, The center portion of the second fixing port 232 is located inside the concrete body 210 of the girder 200 and one end is connected to the first fixing port 231 and the other end is connected to the second fixing port 232, And a second strand 234 which is inserted into the second sheath pipe 233 and has both ends fixedly connected to the first and second fixing ports 231 and 232, respectively. The second sheath pipe 233 and the second strand 234 are positioned in a curved shape downward and a portion excluding both ends is located inside the girder 200. Thus, the middle portion of the second sheath pipe 233 and the second strand 234 is positioned at the lower portion inside the girder 200. The second strand 234 is tensioned and applies a compressive force to the intermediate portion of the concrete body 210 of the girder 200 and a tensile force to the slab. The first fixture 231 is preferably located on the beam 300 closest to the longitudinal centerline of the girder 200. In addition, it is preferable that the second fixing port 232 is located at the beam 300 closest to the longitudinal center line of the girder 200. In the meantime, when the girder 200 is divided into eight equal parts in the longitudinal direction, the beam 300 is positioned in the second and third areas, the first fixing hole 231 is positioned in the beam 300, 300 are positioned and the second mounting hole 232 is positioned on the beam 300. The first fixing port 231 is located on a side of one side surface of the cross beam 300 that is closer to one end surface than the other side surface of the cross beam 300. The second mounting portion 232 is also located on the side surface of the cross beam 300 near the other end surface of the cross beam 300. A filling part 211 filled with concrete is provided at the corner between the beam 300 and the girder 200 where the first fixing port 231 is located and the one end of the second sheath pipe 233 is inserted into the filling part 211 And a filler 211 filled with concrete is provided at a corner between the girder 200 and the cross beam 300 where the second fixture port 232 is located. Inside the filler 211, It is preferable that the other end portion of the second sheath tube 233 be positioned.

It is preferable that the secondary tension units 230 are positioned on both sides of the reference line with respect to the center in the width direction of the girder 200. [

Meanwhile, the secondary tension unit 230 may be provided in the diagonal direction of the girder 200 as seen in plan view of the girder 200, as shown in Fig. That is, the first fixing port 231 of the second tension unit 230 is provided on the side beam 300 located on one side of the girder 200 and the second fixing port 232 is provided on the other side of the side opposite to the girder 200 And the second end of the second sheath pipe 233 is connected to the first and second fixing ports 231 and 232 and the second strand 234 is inserted into the second sheath pipe 233, Both ends are fixedly coupled to the first and second fixing ports 231 and 232. In addition, two secondary tension units 230 are provided on the girder 200, and the girders 200 may be staggered from each other when viewed in a plan view. That is, a first fixing hole 231 of one secondary tension unit 230 is provided on the beam 300 located on one side of the girder 200 and a second fixing hole 232 is provided on the other side of the girder 200 The second sheath pipe 233 is connected to the first and second fixing ports 231 and 232 and the second strand 234 is connected to the second sheath pipe 233 Both ends are fixedly coupled to the first and second fixing ports 231 and 232 in the inserted state. And the first fixing hole 231 of the second tension unit 230 is provided on the beam 300 located on the other side of the girder 200 and the second fixing hole 232 is provided on the opposite side of the girder 200 The second sheath pipe 233 is connected to the first and second fixing ports 231 and 232 and the second strand 234 is inserted into the second sheath pipe 2330, Both ends are fixedly coupled to the first and second fixing ports 231 and 232.

The girder 200 constituting one embodiment of the girder section strength reinforcement of a bridge according to the present invention can be applied also to the case of the composite girder 200 '. Hereinafter, the case where the girder 200 is a steel composite girder 200 'will be described.

As shown in FIGS. 4, 5, 6 and 7, the girders 200 'have an I-section steel 240 having a length corresponding to the distance between the alternations 100 and 100, And a tension unit 260 installed on the center portion of the concrete body 250 in the longitudinal direction to introduce a prestress into the concrete body 250. The I-shaped portion 240 is formed so as to be curved convexly upward, but in a state where it is installed between the turns, the I-shaped portion 240 is substantially horizontal due to deflection due to its own weight. The I-form steel 240 includes an upper flange 241 as an upper horizontal portion, a lower flange 242 as a lower horizontal portion, and an abdomen portion 243 as a vertical portion connecting the upper and lower flanges 242. Two opening grooves are provided in the middle portion of the lower flange 242 of the I-shaped steel 240 at intervals. The concrete body 250 includes an upper slab 251 covering the upper flange 241 of the I-shaped steel 240, a lower casing 252 covering the lower flange 242, And a concrete 253.

The tension unit 260 includes a first fixing hole 261 provided on the beam 300 located at one side of the reference line with respect to the longitudinal center of the girder 200 ' A center portion of which is inserted into the two opening grooves 244 of the lower flange 242 while being positioned inside the lower casing 252 and one end of which is connected to the first fixing port 261 And a strand 264 inserted into the sheath pipe 263 and fixed at both ends to the first and second fixing ports 261 and 262. The sheath pipe 263 is connected to the second fixing hole 262, . The rest of the sheath pipe 263 is located inside the abdominal concrete 253 and both ends are connected to the first and second fixing ports 261 and 262, respectively. The strand 264 is in a tense state and applies a compressive force to the intermediate portion of the concrete body 210 of the girder 200 '. (Not shown) in which concrete is filled in corners between the beam 300 and the girder 200 'where the first fixing port 261 is located and one end portion of the sheath pipe 263 is inserted into the filling portion (Not shown) filled with concrete at corners between the beam 300 and the girder 200 'where the second fixing port 262 is located and a sheath tube 263 Is positioned at the other end portion.

The tension unit 260 is preferably positioned on both sides of the reference line with respect to the widthwise center of the girder 200 '.

Also, as described in the PCS girder 200, the two tension units 260 may be offset from each other.

8 is a flowchart showing a first embodiment of a method for manufacturing a girder section strength reinforcement apparatus of a bridge according to the present invention.

As shown in FIG. 8 and FIGS. 1 and 2, a first embodiment of a method of manufacturing a girder 200 reinforcement apparatus for a bridge according to the present invention comprises a first formwork (not shown) The first and second sheath pipes 221 and 233 are installed in the first die, and the first sheath pipe 221 is connected to the first die And the second sheath pipe 233 is installed over the central portion in the longitudinal direction of the first die. The first sheath pipe 221 is installed to be fixed to the reinforcing steel structure in the form of a curve curved downward. Both ends of the first sheath pipe 221 protrude to the outside of the first die part forming both end faces of the girder 200 It is preferable to install it. The second sheath pipe 233 is installed to be fixed to the reinforcing steel structure in a curved shape and the both ends of the second sheath pipe 233 protrude to the outside of the first die part forming the side surface of the girder 200 And both end portions of the second sheath pipe 233 are positioned at positions where the beam 300 connected to the girder 200 is located.

Then, concrete pouring and curing steps are performed in the first die. When the curing of the concrete placed in the first die is completed, the first die is separated to form the girder 200. At this time, both end portions of the first sheath tube 221 protrude outward from both longitudinal ends of the girder 200, and both end portions of the second sheath tube 233 protrude outside the side surface of the girder 200 .

The first strand 222 is inserted into the first sheath tube 221 and the prestress is introduced to the girder 200 in a first stage. Both ends of the first strand 222 are connected to the fixing hole 223 provided on one end surface of the girder 200 and the fixing hole 223 provided on the other end surface of the girder 200, Lt; / RTI >

A plurality of girders 200 having a prestress introduced therein are installed between the alternating station 100 and the alternating station 100 in a first step. The girders 200 are installed at regular intervals in the transverse direction of the alternation 100.

A second die for making the slabs 400 connecting the upper surfaces of the girders 200 with the transverse beams 300 connecting the girders 200 arranged alternately between the alternation 100 and the alternation 100 The installation step proceeds.

A reinforcing structure (not shown) for forming the beam 300 and the slab 400 is disposed in the second die after the second die is installed. The reinforcing bar structure is disposed so that the beam 300 is positioned at a predetermined interval.

The both ends of the second sheath tube 233 are fixed to protrude to the outside of the beam 300 through the portion corresponding to the beam 300 of the second die.

Then, the concrete is laid and cured inside the second formwork to form the beams 300 and the slabs 400. At this time, one end of the second sheath tube 233 protrudes from one side of the beam 300, and the other end of the second sheath tube 233 protrudes from one side of the other beam 300. The two beams 300 where the both ends of the second sheath tube 233 are respectively positioned symmetrically with respect to the center line of the longitudinal direction of the girder 200.

The second strand 234 is inserted into the second sheath pipe 233 after the transverse beams 300 and the slab 400 are completed and the second prestress is introduced into the girder 200 in a tense manner. Both ends of the second strand 234 are respectively fixed by a fixing hole 231 provided on one side of the side beam 300 where one end of the second strand 234 is located, And is fixed to a fixing port 232 provided on one side of the cross beam 300 where the other end of the two stranded wire 234 is located. The fixing ports 231 and 232 are installed after reinforcing the reinforcing bars to the second formwork.

The second sheath pipe 233 and the second strand 234 are installed on both sides of the center line in the width direction of the girder 200.

9 is a flowchart showing a second embodiment of a method for manufacturing a girder section strength reinforcement apparatus for a bridge according to the present invention.

9 and Figs. 4, 5, 6 and 7, a second embodiment of a method for manufacturing a girder section strength reinforcing apparatus for a bridge according to the present invention is characterized in that first, the lower flange 242 of the I- The step of forming two opening grooves 244 in the middle portion proceeds and a step of installing a first die for forming a concrete lower casing in the lower flange 242 of the I-shaped steel 240 proceeds. The I-shaped steel pipe 240 is bent upward in a curved convex shape and has an upper flange 241 as an upper horizontal portion, a lower flange 242 as a lower horizontal portion, and a connection between upper and lower flanges 241 and 242 And the abdomen 243, which is a vertical portion that is a vertical portion. Two opening grooves 244 are formed symmetrically with a gap in the center portion of the lower flange 242 of the I-shaped steel 240.

The step of arranging the reinforcing bars in the first die proceeds and the step of installing the sheath pipe 263 through the two portions of the lower flange of the I-shaped steel 240 so that both end portions protrude out of the first die. The center portion of the sheath tube 263 is inserted into the two opening grooves 244 of the lower flange 242 of the I-shaped steel 240.

The lower casing 252 is formed by pouring and curing concrete in the first formwork so as to surround the intermediate portion of the lower flange 242 of the I-shaped steel 240 and the middle portion of the sheath pipe 263, ').

And a plurality of steel composite girders 200 'are installed between the alternation 100 and the alternation 100. At this time, the steel composite girder 200 'is installed in the alternation 100 so that the convex curve portion of the I-shaped steel 240 is positioned upward. The steel composite girders 200 'are installed at regular intervals in the transverse direction of the alternation 100.

A second mold for making a slab 400 connecting the upper surfaces of the steel composite girders 200 'and the cross beams 300 connecting the steel composite girders 200' installed between the alternations 100 in the transverse direction, As shown in FIG. The second formwork is installed so as to enclose the upper flange 241 and the abdomen 243 of the I-shaped steel 240 of the steel composite girder 200 'with concrete.

A step of arranging a reinforcing structure (not shown) for forming the beams 300 and the slabs 400 is performed in the second die after the second die is installed. The I-section steel 240 and the I-section steel 240 of the steel composite girder 200 'adjacent to each other by the steel material may be connected instead of the steel structure for forming the cross beams 300. (Not shown) so that the beam 300 is positioned at a predetermined interval.

The step of fixing both ends of the sheath pipe 263 to the outside of the portion of the cross beam 300 through the portion corresponding to the cross beam 300 of the second formwork is proceeded.

Then, the concrete is laid and cured inside the second formwork to form the beams 300 and the slabs 400. At this time, one end of the sheath tube 263 protrudes from one side of the cross beam 300, and the other end of the sheath tube 263 protrudes from one side of the other cross beam 300. The two beams 300 where the both ends of the sheath tube 263 are respectively positioned symmetrically with respect to the center line of the longitudinal direction of the steel composite girder 200 '.

After the beams 300 and the slabs 400 are completed, a strand 264 is inserted into the sheath pipe 263, and the strand 264 is strained to introduce a prestress into the steel composite girder 200 '. At both ends of the strand 264 in the tensioned state of the strand 264, a fixing hole 261 provided on one side of the cross beam 300 where one end of the strand 264 is located and a cross beam 261 having the other end of the strand 264 300 to one side of the fixing member 262, The fixtures 261 and 262 are fixed to a reinforcing bar or a second die laid on the second die before the concrete is laid.

The sheath pipe 263 and the stranded wire 264 are installed on both sides of the center line in the middle of the width direction of the girder 200 '.

Hereinafter, the operation and effect of the apparatus for reinforcing a girder section force of a bridge according to the present invention will be described.

The present invention is characterized in that the girders 200 and 200 'installed between the alternations 100 in a state where the girders 200 and 200' having the first prestress introduced therein are disposed between the alternation 100 and the alternation 100, A slab 400 connecting the transverse beams 300 and the upper portions of the girders 200 and 200 'is manufactured and then the girder 200 and the secondary tension unit A second compressive force is introduced into the girders 200 and 200 'by means of a fixing device 230 (fixing holes, a sheath pipe, a stranded wire), and tensile force is introduced to the beam 300 and the slab 400. Particularly, since the stranded wire is installed in the beam 300 and the strand connected to the fixing unit is curved in the lower part of the beam 300 and the lower end of the girder 200, the prestress acting on the beam 300 is uniformly and evenly distributed The stress concentration acting on the sides of the girders 200 and 200 'can be relieved as compared with a method of directly applying the prestress to the sides of the girders 200 and 200' And the prestress effectively acts on the composite structure of the girders 200, 200 'and the slabs 400. As a result, the cross beams 300 and the slabs 400 are formed on the girders 200 and 200 'into which the first prestress is introduced, and the strength of the girders 200 and 200' The compressive force is secondarily introduced into the girders 200 and 200 'by the secondary tension unit 230 to increase the sectional force of the girders 200 and 200'. In addition, a tensile force is introduced into the slab 400 to increase the cross-sectional force that can resist the load to which the slab 400 is added.

The present invention is also characterized in that the strands 234 and 264 of the secondary tension unit 230 that secondarily compresses the girders 200 and 200 'are located only in the middle portion of the girders 200 and 200' The length of the stranded wires 234 and 264 is shortened in the girders 200 and 200 'so that the effect of introducing the compressive force is increased and the compressive force is introduced only to the necessary portions, The stress distribution is excluded.

In addition, since the present invention introduces a compressive force to the second girders 200 and 200 ', the sectional forces of the girders 200 and 200' are increased, and when the designed sectional forces are required for the girders 200 and 200 ' It is possible to reduce the amount of material used for the girders 200 and 200 ', compared with the case where only the first prestress is introduced. That is, in the case of the steel composite girder 200 ', the height of the I-shaped steel 240 can be reduced, the amount of steel used can be reduced, the length of the steel composite girder 200' The cross-sectional area of the PCS girder 200 can be reduced or the length of the PCS girder 200 can be increased.

100: shift 200; PSC girder
200 '; A steel composite girder 300; Crossbow
400; Slab

Claims (7)

An I-shaped steel including an upper flange as an upper horizontal portion, a lower flange as a lower horizontal portion, and a belly portion vertically connecting the upper and lower flanges, and a concrete body surrounding the I-shaped steel, ;
Cross beams connecting the girders horizontally;
A slab connecting upper portions of the girders;
A primary tension unit provided over the entire length of the girder to primarily tension the girder;
And a secondary tension unit which is provided over a middle portion in the longitudinal direction of the girder and tensions the center portion in the longitudinal direction of the girder secondarily,
Wherein the two secondary tension units are two,
First and second fixing ports provided on the beams positioned nearest to the reference line on both sides of the reference line based on the longitudinal center of the girder;
And a stranded wire having one end fixed to the first fixing port, the other end fixed to the second fixing port, and a center portion positioned inside the lower portion of the girder to give compressive force to the girder,
Wherein the first and second fixing ports, at which both end portions of the strand are fixed, are provided on the transverse beams so as to be positioned in the abdomen portion of the I-
Wherein the first secondary fixing unit is mounted on a beam positioned on one side of the girder and the second fixing member is mounted on a beam positioned on the other side of the girder, Is positioned diagonally of the girder,
The second fixing unit is mounted on a beam positioned on the other side surface of the girder and the second fixing port is mounted on a beam positioned on one side of the girder, A plurality of girders arranged in a diagonal direction of the girders,
Shaped steel is formed with opening grooves whose sides are opened at the lower flange of the I-shaped steel on both sides of the longitudinal direction center of the I-shaped steel, and the strand is inserted into the opening grooves so that a center portion is formed below the lower flange of the I- Of the girder of the bridge. delete delete delete delete delete delete

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