KR101881580B1 - Bridge comprising monolithic structure of girder and pier and construction method for the same - Google Patents

Abstract

The present invention relates to a construction method for a bridge including: a girder-pier-integrated strong coupling structure including producing a pier, an abutment, and a plurality of PSC girders; placing the PSC girders at the abutment and the pier; temporarily fastening steel materials on the top of the end portion on the adjacent side of each of two of the PSC girders that are adjacent to each other, placing a second reinforcing bar at a beam part at which a beam is to be formed, and arranging a third reinforcing bar at a continuous part between two adjacent PSC girders; forming a bottom plate slab by placing and curing concrete on the top of the PSC girder; and completely fastening the steel materials on the top of the end portion on the adjacent side of each of two of the PSC girders that are adjacent and temporarily fastened to each other and forming a continuous portion and the beam and the pier portion bottom plate slab by placing and curing concrete at the beam part and between two adjacent PSC girders so that a first reinforcing bar, the second reinforcing bar, and the third reinforcing bar are integrated.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bridge including an integrated steel structure of a girder and a bridge,

The present invention relates to a bridge including an integrated steel structure of a girder and a bridge, and a construction method thereof.

Most of the bridges currently constructed in Korea are using bridge supports. Bridges without bridge supports are insignificant for ramen bridge or FCM bridges. In recent years, a number of one - way alternating bridges have been constructed with the intention of not installing the bridge supports and expansion joints. However, most bridge bridges are applied with bridge supports. Korean Registered Utility Model No. 20-0300023 "Raman type multi span continuous PSC type I girder bridge structure which is pierced on a pier" starts a bridge support (5). Currently, the bridges applying PSC girder to the bridge construction are constructed by applying the elastic bearing at the intermediate point, which is the middle pier. In the case of continuous bridges, two bridge supports are applied at the middle bridge pier which is the continuous point bridge. The elastic support is deformed due to the expansion and contraction due to the temperature load of the bridge, and the deformed elastic support is not recovered. There is a case in which a step is generated to cause a problem in running safety.

In addition, when the elastic bearing is eroded due to the leakage of the upper part of the bridge due to the leakage of the elastic bearing, and the elastic bearing is hardened due to the hardening of the elastic bearing over time, the elastic bearing must be replaced In this case, bridge maintenance cost is excessive after construction of bridge. In addition, since the problem of deformation of the elastic bearing continuously occurs, it is necessary to install a maintenance inspection facility in the bridge copping when constructing the PSC girder bridge, thereby increasing the cost of the initial bridge construction. As a result, there is a problem caused by the elastic support of the girder-applied bridges. Therefore, considering the integration of the girder and the bridge copping that do not apply the bridge support, the maintenance cost reduction and the bridge support inspection facility It is required to develop a technology capable of reducing the construction cost of the bridge.

KR 20-0300023 Y1

And a bridge including a structure in which a PSC girder and a bridge pier are integrated without a bridge support at an intermediate point portion of a pier.

The present invention also provides a method of constructing a bridge including a structure in which the PSC girder and a pier are integrated.

An example of the present invention relates to a structure in which a continuous portion is integrated with a girder and a pier in a PSC girder bridge. In a structure in which a girder and a pier are integrated, a plurality of continuous reinforced steel bars are arranged at a height above the neutral axis of the PSC girder The upper part of the continuous part of the PSC girder is connected to the joining steel of the continuous joining part of the continuous joint of PSC girder. Continuous continuous steel reinforcing bars of the PSC girder, continuous steel reinforcing bars and cross reinforcing bars integrally formed with the continuous steel reinforcing bars and the beam reinforcing steel bars, Integrating the girder and pier which is characterized by being integrated into the rigid-bonded structure by the concrete placed on the slab It can be tightened.

An example of the present invention relates to a structure in which a continuous portion is integrated with a girder and a pier in a PSC girder bridge. In a structure in which a girder and a pier are integrated, a plurality of continuous reinforced steel bars are arranged at a height above the neutral axis of the PSC girder The PSC girder is connected to the intersection of the PSC girder continuous section and the cross beam with the same crossing width. The upper part of the continuous part of the PSC girder has a certain length Wherein the continuous reinforcing bars and the cross bar reinforcing bars integrally formed with the continuous portion and the transverse portion of the PSC girder and the continuous reinforcing steel reinforcing bars and the bridging portion bottom plate slab reinforcing bars on the upper surface of the pier capping portion, And a concrete structure that is integrated into the steel-welded structure by the concrete placed in the beam and the bottom plate slab Integrated steel girders and piers envoys of that gong can be stretched.

The continuous part of the PSC girder may be one in which the continuous tension is added by the PS steel bar or the PS steel bar.

The connecting joint steel of the continuous part of the PSC girder may be a steel plate or a steel rod or a steel bar.

The PSC girder may be a steel girder or a steel composite girder.

One example of the present invention is a construction and construction method for integrating a girder and a pier in a rigid joint structure in a PSC girder bridge. In a first step, alternate, pier and PSC girder are manufactured at a manufacturing site. Vertically embedding a plurality of columns at regular intervals up to the height of the neutral axis of the PSC girder for continuous joining of reinforcing bars along the entire length in a direction perpendicular to the throat; In a second step, a provisional support is installed in the vicinity of both ends of the upper portion of the pier capping and the PSC girder is alternately installed on the pier. In the third step, in order to serialize the PSC girder placed on the temporary support above the pier capping, the continuous joint joining steel at the upper part of both ends of the continuous part of the PSC girder is fastened and reinforcing steel is inserted in the continuous part and the beam part ; In the fourth step, the slab concrete of the bottom plate is laid in the whole area except the continuous portion, the side beam and the bottom plate slab portion of the pier portion, and cured; In the fifth step, the PSC girder is continuously fastened to the upper part of the continuous part of the continuous joint joining steel, and the temporary support part installed at both ends of the pier capping upper part is blocked out. A step of cementing the concrete and the side beams and the piers of the bottom plate slabs in a second order; In a sixth step, a provisional support installed at both ends of the upper part of the bridge pier is removed, grouting is applied to the removed block-out part, and the PSC girder is tensioned with the continuous PS wire. And step 7 is a step of installing bridges such as bridges, waterproofing, packaging, barrier walls, and the like.

One example of the present invention relates to a structure and a construction method for integrating a girder and a bridge into a strong-joint structure in a PSC girder bridge. In the first step, alternation, pier and PSC girder are manufactured at a manufacturing site. Installing a plurality of rows vertically in the PSC girder at regular intervals up to the height of the neutral axis of the PSC girder in order to join the reinforcing bars to each other over the entire length in the direction perpendicular to the throat; In a second step, a provisional support is installed in the vicinity of both ends of the upper portion of the pier capping and the PSC girder is alternately installed on the pier. In the third step, to connect the continuous PSC girder to the temporary support at the upper part of the bridge coping, the continuous joint joint steel at both ends of the continuous part of the PSC girder is fully tightened and reinforcement is applied to the continuous part and the transverse part step; In the fourth step, the temporary support part installed at both ends of the bridge ceiling is blocked out, and all of the temporary support side parts are constructed as bulkheads, and the concrete is laid in the primary part of the continuous part of the PSC girder, step; A fifth step of removing the temporary support provided at both ends of the upper portion of the bridge coping, filling the removed block-out portion with grouting, and tightening the PSC girder at both sides of the upper portion of the continuous portion with the PS steel bar; In a sixth step, the concrete is installed in all places of the bottom plate slab, including the bottom plate slab portion of the pier portion; And step 7 is a step of installing bridges such as bridges, waterproofing, packaging, barrier walls, and the like.

An example of the present invention relates to a structure and a construction method for integrating a girder and a bridge into a strong-joint structure in a PSC girder bridge. In the first step, alternation, pier and PSC girder are manufactured at a manufacturing site. Vertically embedding a plurality of columns at regular intervals up to the height of the neutral axis of the PSC girder for continuous joining of reinforcing bars along the entire length in the perpendicular direction; In a second step, a provisional support is installed in the vicinity of both ends of the upper portion of the pier capping and the PSC girder is alternately installed on the pier. In the third step, reinforcing bars are inserted in the continuous portion and the transverse portion of the PSC girder installed at the upper part of the bridge pier, and the vertical length of the continuous reinforced concrete reinforced concrete is embedded vertically from the top of the bridge to the upper portion of the neutral shaft. Folding the hook reinforcement so that it can be embedded in the plate slab; In the fourth step, the slab concrete of the bottom plate is laid in the whole area except the continuous portion, the side beam and the bottom plate slab portion of the pier portion, and cured; In the fifth step, the entirety of the temporary support side portion is constructed as a bulkhead so that the temporary support portion installed at both ends of the pier capping upper portion can be blocked out, and the concrete is installed in the secondary portion of the PSC girder continuous portion, step; In a sixth step, the provisional support installed at the upper end of the bridge pier is removed, grouting is applied to the removed block-out part, and the PSC girder is tensioned with the continuous PS wire. And step 7 is a step of installing bridges such as bridges, waterproofing, packaging, barrier walls, and the like.

The temporary support may be a hydraulic jack or a preceding load jack or a screw jack or a sand jack.

A method of constructing a bridge including an integrated steel structure of a girder and a bridge pier according to the present invention is characterized in that a plurality of first reinforcing bars are horizontally spaced apart along a plurality of rows and columns in an upper surface of a coping of a pier, Alternately and a plurality of PSC girders including the step of embedding the bridge columns in the piers; Mounting a temporary base on the upper surface of the coping and mounting the plurality of PSC girders on the alternating and piercing angles; And a second reinforcing member is disposed on a portion of the upper portion of the upper portion of the adjacent end of each of the adjacent two PSC girders of the plurality of PSC girders, Disposing a third reinforcing bar in a continuous portion between the two PSC girders; Forming a bottom plate slab by pouring and curing concrete on the upper portion except for the crossbar portion and the continuous portion; And the adjacent two PSC girders are fastened to each other so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated with each other, And forming the continuous portion, the cross beam and the pier portion bottom plate slab by pouring and curing the concrete at the cross section portion.

A method of constructing a bridge including an integrated steel structure of a girder and a bridge pier according to the present invention is characterized in that a plurality of first reinforcing bars are horizontally spaced apart along a plurality of rows and columns in an upper surface of a coping of a pier, Alternately and a plurality of PSC girders including the step of embedding the bridge columns in the piers; Mounting a temporary base on the upper surface of the coping and mounting the plurality of PSC girders on the alternating and piercing angles; The steel material on the upper side of the adjacent end of each of the two adjacent PSC girders of the plurality of PSC girders is fully fastened to each other and a second reinforcing bar is placed on the crossing portion located on the upper side of the coping to form the beam, Disposing a third reinforcing bar in a continuous portion between the two PSC girders; Inserting and curing the concrete into the continuous portion and the crossbar portion so that the first reinforcing bar, the second reinforcing bar and the third reinforcing bar are integrated, thereby forming a continuous portion, a beam, and a bridge bottom slab; Removing the temporary base and filling the portion where the temporary base is removed with grouting, and tensing the portion of the PSC girder corresponding to the upper portion of the PSC girder with PS bar at both side portions of the beam; And forming the bottom plate slab by pouring and curing concrete on the PSC girder including the pier portion bottom slab.

A method of constructing a bridge including an integrated steel structure of a girder and a bridge pier according to the present invention is characterized in that a plurality of first reinforcing bars are horizontally spaced apart along a plurality of rows and columns in an upper surface of a coping of a pier, Alternately and a plurality of PSC girders including the step of embedding the bridge columns in the piers; Mounting a temporary base on the upper surface of the coping and mounting the plurality of PSC girders on the alternating and piercing angles; A second reinforcing bar is disposed at a portion of the upper portion of the coping where the beam is to be formed and a third reinforcing bar is placed in a continuous portion between the adjacent two PSC girders, Folding the hook reinforcement so that at least a part of the upper portion of the first reinforcing bar embedded vertically to the upper portion of the neutral axis can be embedded in the bottom plate slab to be formed later; Forming a bottom plate slab by pouring and curing concrete on the upper portion except for the crossbar portion and the continuous portion; And a step of curing and curing the concrete between the adjacent two PSC girders and the crossbar portion so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated, thereby forming a continuous portion, a cross beam and a bridge portion bottom slab . ≪ / RTI >

The method of constructing the bridge may further include the step of removing the temporary support, filling the portion where the temporary support is removed by grouting, and continuing to tense the continuous portion to the PS steel wire or the PS steel wire.

The step of pouring and curing the concrete between the adjacent two PSC girders and the crossbar portion so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated, And a step of constructing a side wall part of the bulkhead.

The continuous portion may be subjected to continuous tension by a PS steel wire or a PS steel bar.

The steel material may include at least one of a steel plate, a steel bar, and a reinforcing bar, and the PSC girder may include at least one of a steel girder and a steel composite girder.

The temporary support may include at least one of a hydraulic jack, a preceding load jack, a screw jack, and a sand jack.

The plurality of first reinforcing bars may be embedded in the bridge pier so that the height of the upper ends of the plurality of first reinforcing bars is higher than the height of the neutral axis of the PSC girder.

The method of constructing the bridge may further include, after the continuous tensioning step, performing a bridging waterproofing construction, a paving construction, and a fire wall installation on an upper surface of the bottom plate slab.

Bridges comprising an integrated steel structure of girders and piers in accordance with the present invention may alternate; A bridge including a coping; A plurality of first reinforcing bars projecting vertically from the upper surface of the copings of the bridge piers and installed on the bridge piers so as to be spaced along a plurality of rows and columns in a horizontal direction on an upper surface of the copings of the bridge piers; A plurality of PSC girders disposed in the alternation and at the pier; A plurality of PSC girders; a plurality of PSC girders each having a plurality of adjacent PSC girders; A second reinforcing bar disposed at a transverse portion of the PSC girder; A third reinforcing bar disposed between the adjacent two PSC girders; A beam formed in the second reinforcing bar at a crossing portion of the PSC girder; A continuous portion formed between two adjacent said cross beams; And a bottom plate slab disposed on the upper portion of the PSC girder, wherein the crossbeam and the continuous portion are integrally formed by collective pouring and curing of concrete to integrate the first reinforcing bar, the second reinforcing bar and the third reinforcing bar can do.

The bridge may further include a PS steel wire or a PS steel bar which tenses the continuous portion.

The method of integrating the piers and the PSC girder without the bridge support at the midpoint of the pier can eliminate the bridge support and the bridge inspection device at the piers and omit the expansion joints at the bottom slabs, The maintenance cost can be reduced.

In this way, the construction phase may be somewhat increased rather than the bridges with bridges at the bridges of the bridge, but this can be a very useful technique for the maintenance personnel who need to use the bridges for 50 to 100 years.

The bridges on bridges are being replaced on a regular basis for a period of 10 to 15 years and the expansion joints are replaced for a period of 5 years so that not only the maintenance costs but also the social costs associated with traffic interruption can be reduced, It is possible to prevent damage to the upper and lower parts of the bridge due to the impact in the part without the occurrence of noise due to the occurrence of steps in the expansion joint part and to prevent the bridge part from being damaged. It is possible to make the terminal slope more gentle and it has many merits such as the reduction of the social cost due to the traffic control because the traffic control according to the replacement of the expansion joint device and the bridge support is unnecessary.

Since the girder and bridge pier are made into a unified steel structure, the construction cost is reduced since the expansion joint and bridge support are omitted at the beginning of the construction, and the maintenance cost can be reduced because there is no replacement of the expansion joint and the bridge support during public use.

Since the bridge deck slab does not have a telescopic joint, it has good running characteristics. There is no noise due to the step difference of the expansion joint part, and there is no impact on the bridge part, so damage to the upper and lower parts of the bridge can be prevented.

Since there is no bridge support of the bridge, it is possible to secure additional space of the bridge by the height of the bridge support and to make the slope of the terminal more gentle.

It is possible to reduce the social cost due to the traffic control because it is not necessary to control the traffic according to the expansion joint of the bridge and the bridge support.

1 is a cross-sectional view of a bridge according to a first embodiment of the present invention.
FIG. 2 is a view for explaining a step of manufacturing an alternation and a pier in a method of constructing a bridge according to the first embodiment of the present invention.
3 is a cross-sectional view of the pier in Fig.
4 is a perspective view of the pier in Fig.
Fig. 5 is a plan view of the pier in Fig. 2. Fig.
FIG. 6 is a view for explaining a step of manufacturing a PSC girder of an outer lateral portion and an inner lateral PSC girder of a method of constructing a bridge according to a first embodiment of the present invention.
7 is a view for explaining a step of mounting a PSC girder to a bridge pier in a method of constructing a bridge according to the first embodiment of the present invention.
FIG. 8 is a view illustrating a step of fastening a continuous joint connecting steel material in a method of constructing a bridge according to a first embodiment of the present invention, and arranging a crossbar reinforcing bar and a continuous reinforcing bar.
9 is a view for explaining a step of forming a bottom plate slab through a concrete primary casting curing method among the method of constructing a bridge according to the first embodiment of the present invention.
10 is a perspective view illustrating a method of constructing a bridge according to a first embodiment of the present invention. FIG. 10 is a cross-sectional view illustrating a method of constructing a bridge according to a first embodiment of the present invention. A continuous section, and a bridge bottom plate slab through the through-hole, the bottom plate slab, and the bottom plate slab.
11 is a view for explaining a step of removing a temporary support from a method of constructing a bridge according to the first embodiment of the present invention, filling the part where the temporary support is removed by grouting, and tightening the PSC girder with the continuous PS wire to be.
FIG. 12 is a view for explaining a bridging waterproofing construction, a paving construction, and a fire wall installation step in a method of constructing a bridge according to the first embodiment of the present invention.
13 is a cross-sectional view of a bridge according to a second embodiment of the present invention.
FIG. 14 is a view for explaining a step of forming a beam, a continuous portion and a bridge portion bottom plate slab through a concrete primary casting curing method among the method of constructing a bridge according to the second embodiment of the present invention.
FIG. 15 illustrates a step of removing a temporary support from a method of constructing a bridge according to a second embodiment of the present invention, filling the removed portion with grouting, and tightening the PSC girder with the PS steel bar at both side portions of the upper portion of the continuous portion. Fig.
FIG. 16 is a view for explaining a step of secondarily laying and curing concrete in the entirety of the bottom plate slab including the bridge portion bottom plate slab portion of the bridge construction method according to the second embodiment of the present invention.
17 is a cross-sectional view of a bridge according to a third embodiment of the present invention.
18 is a view for explaining a step of manufacturing a PSC girder of an outer side portion and a PSC girder portion of an inner side portion of a bridge construction method according to a third embodiment of the present invention.
19 is a view for explaining a step of mounting a PSC girder to a bridge pier in a method of constructing a bridge according to a third embodiment of the present invention.
FIG. 20 is a view for explaining a step of arranging a crossbar reinforcing bar, a continuous reinforcing bar, and a hook reinforcing bar in a method of constructing a bridge according to a third embodiment of the present invention.
FIG. 21 is a view for explaining a step of forming a bottom plate slab through a concrete primary casting curing method among the construction methods of a bridge according to a third embodiment of the present invention.
FIG. 22 is a view for explaining a step of forming a beam, a continuous portion and a bridge portion bottom plate slab through concrete secondary curing in a method of constructing a bridge according to a third embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described with reference to the accompanying drawings. However, the technical spirit of the present invention is not limited to some embodiments described.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements.

When a component is described as being "connected" or "coupled" to another component, the component may be directly coupled or coupled to the other component, but another component It is to be understood that the elements may be " connected " or " coupled ".

Hereinafter, the steel-welded structure and method, which is an example of the present invention, will be described.

The steel-pipe joint structure is constructed such that the bridge portion 310 and the continuous portion 320 of the PSC girder 300 are spaced apart from each other by a plurality of rows at regular intervals to the height above the neutral axis of the PSC girder 300 (First reinforcing bars) 410 which are vertically installed and combined with each other in a mutually rigid structure to integrally join the pier 100 as a bridge substructure, the PSC girder 300 and the beam 610 as upper structures, It is a structure in which the moment due to the load of the upper structure is transmitted to the lower part and the structure of increasing the earthquake resistance ability by the multipoint fixed bridge method. The above structure can absorb the displacement of the upper girder due to the softness of the bridge pier 100. The expansion joint can be omitted in the bottom plate slab 800 and the bridge support can be omitted in the bridge portion, It is a useful structure that can reduce the maintenance cost during public use. In addition, there are no measures such as traffic interruption for public administration maintenance, and there is no social cost due to traffic control at all.

The steel-welded structure can be constructed in three ways according to its structure and construction method.

The first method is a method in which concrete is first placed and cured between the entirety of the bottom plate slab 800 excluding the portion where the bridge bottom slab 810 is to be formed and the like, and then the continuous portion 320 and the beam portion 310, And a second concrete is placed and cured in the portion where the sub floor slab 810 is to be formed. The concrete construction method of the PSC girder 300 is performed such that the remaining section of the bottom plate slab 800 excluding the part where the bridge bottom plate slab 810 is to be formed after the continuous connecting joint steel material (steel material) The concrete is first placed and cured so as to completely receive the stress of the PSC girder 300 and the bottom plate slab 800 in advance and the continuous joint connecting steel material 500 is fully tightened The pier 100 having a lower structure and the PSC girder 300 having an upper structure are integrally formed by curing the secondary concrete in a place where the continuous portion 320 and the beam portion 310 and the pier portion bottom plate slab 810 are to be formed, And the rib 610 are joined together in a steel structure later. Although the construction process is somewhat complicated, after the continuous joint connecting steel material 500 causes the PSC girder 300 and the bottom plate slab 800 to generate stress in advance, the bridge bottom plate slab 810, Thereby reducing the amount of continuous jointed steel material 500 and controlling the cracks in the continuous bottom deck in common, and a construction method thereof.

That is, in the structure in which the PSC girder 300 and the pier 100 are integrated in the continuous portion 620 in the PSC girder bridge, the continuous reinforcing steel bar 410 extends over the entire length in the direction perpendicular to the throttle from the middle portion in the throttle- A plurality of PSC girders 300 are vertically buried at a height above the neutral axis and are integrally joined to the continuous beams 620 of the PSC girder 300, The continuous joint connecting steel material 500 is positioned above the continuous portion 620 of the PSC girder 300 so that the upper surface of the continuous portion 620 of the PSC girder 300 is continuous by the joint bonded steel material 500, A continuous reinforcing bar (third reinforcing bar) 430 integrally formed with the continuous joint connecting steel material 500 and the continuous portion 320 and the beam portion 310 of the PSC girder 300 and a cross bar reinforcing bar (second reinforcing bar) And the continuous portion joining reinforcement 410 and the continuous portion 620 on the upper surface of the pier capping portion 420, the beam 610, Labrador 800 integrated in the girder and which is characterized in that the piers are integrated into ganggyeol bonded structure by the concrete to be poured in a ganggyeol structure.

The second method is a method in which the concrete is first cast on the continuous portion 320 and the beam portion 310 and the bottom plate including the portion where the pier portion bottom plate slab 810 is to be formed after the continuous PS rigid bar 340 is strained, A concrete method of collecting and curing concrete in a second place between the whole of the slab 800 and its concrete construction method is a method of fully curing the continuous portion 320 of the PSC girder 300 and the intersection portion 310 The PSC girder 300 and the beam 610 are combined and joined together in a strong structure. Then, the continuous portion 320 of the PSC girder 300, After the portion 310 is tensed with the PS steel bar 340, the concrete is placed in a second place in the whole area of the bottom plate slab 800 including the pier portion bottom plate slab 810 at the upper portion of the continuous portion 320 , Which is the same as that of the continuous joint portion 320, The requirement of the continuous joint connecting steel material 500 and the PS steel bar 340 is increased since the PS material 500 and the PS steel bar 340 bear the stresses of the PSC girder 300 and the bottom plate slab 800 after all The construction of the bottom plate slab 800 is a construction in which the convenience of the construction is prioritized by placing the concrete in a whole place and curing the whole area, and the construction method thereof.

In other words, in the PSC girder bridge structure in which the continuous portion is integrated with the girder and the pier, the continuous reinforced steel reinforcement 410 extends over the entire length in the direction perpendicular to the sagittal axis of the pier- A plurality of PSC girders 300 are vertically buried at regular intervals and are joined together with the continuous portion 620 of the PSC girder 300 to a cross beam 610 having the same width as the crossing direction crossing width, And the upper portion of the continuous portion 620 of the PSC girder 300 is continuous by the connecting joint steel 500. The PSC girder 300 has a continuous connecting joint steel 500, The continuous steel reinforcing bars 430 and the reinforcing bars 420 and the continuous reinforcing steel reinforcing bars 410 on the upper surface of the pier capping portion 410 and the continuous steel reinforcing bars 410 integrally formed with the steel material 500, the continuous portion 320, The slab 620 and the beam 610 and the cone placed in the bottom plate slab 800 The integrated structure of the girder and ganggyeol pier that is characterized in that integrated into ganggyeol junction structure by discrete.

In the third method, the bridge portion bottom plate slab claw reinforcement 440 is disposed at the portion where the continuous portion 320 and the bridge bottom plate slab 810 are to be formed, and the bridge portion bottom plate slab 810 as a continuous portion is formed The first and second concrete slabs 810 and 810 are to be formed in a portion where the continuous portion 320 and the beam portion 310 and the pier portion bottom plate slab 810 are to be formed, A concrete method of curing concrete is a method in which a pier portion bottom plate slab claw reinforcement 440 is vertically disposed on a continuous reinforced steel reinforcing bar 410 at a continuous portion 320 of the PSC girder 300 The concrete is first laid and cured in the remaining section of the bottom plate slab 800 excluding the part where the bridge bottom slab 810 as the continuous section 320 is to be formed, Sub floor plate A portion of the bottom plate slab 800 in which the bending bar reinforcement 440 is firstly inserted is formed to have a predetermined length and a portion where the continuous portion 320 and the beam portion 310 and the bridge bottom plate slab 810 are to be formed The PSC girder 300 and the beam 610 are joined to each other by a steel structure and the stress of the PSC girder 300 and the bottom plate slab 800 is increased The bottom plate slab 810 and the like at the upper portion of the continuous portion 620 can be used to reduce the amount of material required and to control cracks in the continuous bottom plate And the construction method thereof.

In other words, in the PSC girder bridge structure in which the continuous portion is integrated with the girder and the pier, the continuous reinforced steel reinforcement 410 extends over the entire length in the direction perpendicular to the sagittal axis of the pier- A plurality of PSC girders 300 are vertically buried at regular intervals and are integrally joined to the cross beams 610 having the same crossing axial crossing width as the continuous portion 620 of the PSC girder 300. The upper surface of the continuous portion 620 of the PSC girder 300 Is a structure in which a bridge portion bottom plate slab claw reinforcement 440 is overlapped with the continuous steel structure joining steel material 500 so that a certain length is embedded in the bottom plate slab 800. The continuous portion of the PSC girder 300 The continuous reinforcing bars 430 and the reinforcing bars 420 and the continuous reinforcing steel reinforcing bars 410 on the upper surface of the pier capping part and the piers of the bridge deck slab reinforcing bars 440, The continuous portion 620 and the beam 610 and the bottom plate Labrador 800 integrated in the girder and which is characterized in that the piers are integrated into ganggyeol bonded structure by the concrete to be poured in a ganggyeol structure.

The steel-welded structure and first construction method according to the present invention may include the following steps.

The first step is to manufacture the alternation 200 and the pier 100 and the PSC girder 300 at the manufacturing site. The PSC girder 300 is installed at the upper part of the coping 110 of the pier 100, A plurality of columns may be vertically buried at regular intervals up to the height of the neutral axis of the PSC girder 300 for continuous joining of reinforcing bars 410.

The second step may be to place the temporary support 710 near the opposite ends of the piercing coping 110 in the throttle direction and to mount the PSC girder 300 on the alternating 200 and pier 100.

The third step is to connect the continuous joint joining steel members 320 at the upper portions of both ends of the continuous portion 320 of the PSC girder 300 for the sequencing of the PSC girder 300 mounted on the temporary support 710 above the pier capping 110. [ The reinforcing bars may be fastened to the continuous portion 320 and the reinforcing bars 310 to the reinforcing bars 310.

In the fourth step, the concrete for forming the bottom plate slab 800 is first laid in all the sections except for the continuous portion 320 and the portion where the beam portion 310 and the bridge bottom plate slab 810 are to be formed It can be a curing step.

In the fifth step, the continuous joint connecting steel material 500 fastened to the upper portion of the continuous portion 320 of the PSC girder 300 is completely fastened, and the portion of the temporary support 710 installed at both ends of the upper portion of the pier- The PSC girder 300 is constructed such that the continuous portion 320 of the PSC girder 300 and the portion where the beam portion 310 and the pier portion bottom plate slab 810 are to be formed, It may be a step to cure by putting it in the second batch.

In the sixth step, the temporary support 710 installed at both ends of the upper portion of the pier capping 110 is removed, the grout 730 is filled in the removed block out portion, and the PSC girder 300 is connected to the continuous PS wire (PS wire) (330). ≪ / RTI >

The seventh step is to install the bridging facilities such as bridge waterproofing, pavement, and barrier wall.

The steel-welded structure and the second construction method according to the present invention may include the following steps.

The first step is to manufacture the alternation 200 and the pier 100 and the PSC girder 300 at the manufacturing site. The PSC girder 300 is installed at the upper part of the coping 110 of the pier 100, A plurality of columns may be vertically buried at regular intervals up to the height of the neutral axis of the PSC girder 300 for continuous joining of reinforcing bars 410.

The second step may be to place the temporary support 710 in the vicinity of both ends in the direction of the throttle above the bridge coping 110 and to mount the PSC girder 300 on the bridge 200 and the bridge 100.

The third step is to connect the continuous joint joining steel members 320 at the upper portions of both ends of the continuous portion 320 of the PSC girder 300 for the sequencing of the PSC girder 300 mounted on the temporary support 710 above the pier capping 110. [ Tightening the reinforcing bar 500 and fully reinforcing the continuous portion 320 and the crossbar portion 310.

In the fourth step, the entire side portion of the temporary support 710 is partitioned so that the portion of the temporary support 710 installed at both ends of the upper portion of the pier capping 110 can be blocked out, the continuous portion 320 of the PSC girder 300, The first concrete pouring and curing may be performed at the portion where the beam portion 310 and the pier portion bottom plate slab 810 are to be formed.

The fifth step is to remove the temporary support 710 installed at both ends of the upper part of the pier capping 110 and to fill the removed block out portion with the grouting 730 and to fix the PSC girder 300 to the upper portion of the continuous portion 620 To the PS steel rods 340 at both side portions of the base 610.

The sixth step may include a step of curing the concrete in the whole area of the entire floor slab 800 including the part where the bridge bottom slab 810 is to be formed.

The seventh step is to install the bridging facilities such as bridge waterproofing, pavement, and barrier wall.

The steel-welded structure and the third construction method according to the present invention may include the following steps.

The first step is to manufacture the alternation 200 and the pier 100 and the PSC girder 300 at the manufacturing site. The PSC girder 300 is installed at the upper part of the coping 110 of the pier 100, A plurality of columns may be vertically buried at regular intervals up to the height of the neutral axis of the PSC girder 300 for continuous joining of reinforcing bars 410.

The second step may be to place the temporary support 710 in the vicinity of both ends in the direction of the throttle above the bridge coping 110 and to mount the PSC girder 300 on the bridge 200 and the bridge 100.

The third step is to reinforce the reinforcing bars 410 and 420 on the continuous portion 320 and the beam portion 310 of the PSC girder 300 mounted on the pier capping 110, The reinforcing bar 440 may be folded so that a certain length of the reinforcing bars can be embedded in the bottom plate slab at the upper end of the continuous reinforcing steel bar 410 embedded vertically from the upper surface to the upper portion of the neutral shaft.

In the fourth step, the concrete for forming the bottom plate slab 800 is first laid in all the sections except for the continuous portion 320 and the portion where the beam portion 310 and the bridge bottom plate slab 810 are to be formed It can be a curing step.

In the fifth step, the entire side portion of the temporary support 710 is partitioned so that the portion of the temporary support 710 installed at both ends of the upper portion of the pier capping 110 can be blocked out, the continuous portion 320 of the PSC girder 300, And the second concrete placement and curing of concrete at the portion where the beam portion 310 and the bridge portion bottom plate slab 810 are to be formed.

The PSC girder 300 is connected to the continuous PS strand 330 by the grouting 730. The PSC girder 300 is connected to the PS strand 330 by the grouting 730, And the like.

The seventh step is to install the bridging facilities such as bridge waterproofing, pavement, and barrier wall.

At each construction stage of steel-joint structure and construction method, it is possible to further increase the efficiency or to enlarge the construction scope by applying partial modification to the following items.

In addition to steel plate connection, the PSC girder 300 may be formed of a steel bar connection or a reinforcing bar connection structure. The steel plate may be connected by bolt or welding, and the steel bar or reinforcing bar may be connected by coupling or lap joint. Therefore, it is possible to flexibly and flexibly apply continuous joint jointed steel according to economical efficiency and construction conditions. The tension of the PS steel wire 330 in the PSC girder 300 may be selectively applied to the structure using the PS steel wire or the PS steel bar depending on the girder condition or the like. The width of the cross beam 610 which is rigidly joined to the bridge portion as a substructure can be constructed in a structure having the same width as the width of the bridge crossing portion in the throttle direction. PSC girder 300 is applicable to PSC girder, steel girder, and steel composite girder. The temporary support 710 can selectively use a hydraulic jack, a selective load jack, a screw jack, and a sand jack.

The PSC girder 300 and the bridge 100 are integrally formed in a steel structure so that the bridge pier portion and the PSC girder 300, which are bridge substructures, It reduces the construction cost by omitting the device and the bridge support, and reduces the maintenance cost because there is no replacement of the expansion joint and the bridge support during public use.

Second, since the bridge deck slab (800) does not have a telescopic joint, it has good running characteristics. There is no noise due to the step difference of the expansion joint part, and there is no impact on the bridge part, so damage to the upper and lower parts of the bridge can be prevented.

Third, since there is no bridge support in the bridge, it is possible to secure the additional space of the bridge as much as the support height of the bridge and to make the slope of the end more gentle.

Fourth, it is possible to reduce the social cost due to the traffic control because there is no need to control the traffic according to the bridge expansion / contraction device and bridge restoration.

In addition, the bridge pier 100, which is a bridge substructure, has a structure that increases the earthquake resistance by a structure that resists the moment due to the load of the PSC girder 300, which is the upper structure, by a multi-point fixed bridge method.

Hereinafter, the structure of the bridge according to the first embodiment of the present invention will be described.

1 is a cross-sectional view of a bridge according to a first embodiment of the present invention.

The bridge may include a bridge 100. The bridge pier 100 can support the PSC girder 300 from below. Bridge columns 100 may be disposed between alternations 200. The bridge pillars 100 may be provided in plural and spaced apart from each other.

The bridge 100 may include a coping 110. The coping 110 may be referred to as "bridge coping ". The copings 110 may be disposed at the top of the bridge 100. The diameter of the coping 110 may be greater than the diameter of the lower portion of the bridge 100.

The bridge may include an alternating 200. Alternate 200 can be placed at both ends of the bridge. That is, alternation 200 can be placed at the beginning and end of the bridge, respectively.

The bridge may include a PSC girder (prestressed concrete girder) 300. The PSC girder 300 may be provided in plural. A plurality of PSC girders 300 may be disposed in alternation 200 and bridge 100. The PSC girder 300 is a steel girder or a steel composite girder. That is, the PSC girder 300 can be replaced with a steel girder or a steel composite girder.

The PSC girder 300 may include an outer transversal PSC girder (see FIG. 6 (a)) and an inner transversely spaced PSC girder (see FIG. 6 (b)). The outer transversal PSC girder may be disposed at one end in alternation 200 and at the other end in pier 100. In this case, the steel material 500 may be disposed only at the other end of the outer transversely PSC girder and the steel material 500 may not be disposed at one end. Both ends of the inner transversely section PSC girder may be disposed in the bridge 100. In this case, the steel material 500 may be disposed at both ends of the inner transversal PSC girder.

The PSC girder 300 may include a beam portion 310. However, the beam portion 310 may include a spacing space in the lateral direction of the PSC girder 300 (when the continuous beam portion 320 is viewed as a longitudinally spaced space of the PSC girder 300). That is, the beam portion 310 may include a space between a portion of the PSC girder 300 and a plurality of PSC girders 300 spaced laterally from the portion where the beam 610 is to be formed. The beams 610 can be formed by placing concrete in the beam portion 310. The beam portion 310 may be disposed at the distal end of the PSC girder 300. A continuous portion 320 may be disposed between two adjacent crossbar portions 310.

The PSC girder 300 may include a continuous portion 320. However, the continuous portion 320 may include a longitudinally spaced space of the PSC girder 300. That is, the continuous portion 320 may include a space between a portion of the PSC girder 300 and a plurality of PSC girders 300 arranged in the longitudinal direction, as a portion where the continuous portion 620 is to be formed. Concrete may be placed in the continuous portion 320 to form the continuous portion 620. The continuous portion 320 may be a space between two adjacent PSC girders 300.

The PSC girder 300 may include a PS steel wire 330. PS wire 330 may be referred to as "continuous PS wire." The PS wire 330 may be used to tense the continuous portion 620. The PS wire 330 can be used to tilt the beam 610. The PS wire 330 may be used to tense the PSC girder 300.

The bridge may include a first reinforcing bar 410. The first reinforcing bars 410 may be referred to as "continuous reinforcing steel bars ". The first reinforcing bars 410 may be formed such that a portion of the first reinforcing bars 410 protrude vertically from the upper surface of the copings 110 of the piers 100 and are spaced along the plurality of rows and dies in the horizontal direction on the upper surface of the copings 110 of the piers 100 And can be installed in the bridge 100.

The bridge may include a second reinforcing bar 420. The second reinforcing bars 420 may be referred to as "crossbar reinforcing bars ". The second reinforcing bars 420 may be disposed in the transverse portion 310 of the PSC girder 300.

The bridge may include a third reinforcing bar (430). The third reinforcing bars 430 may be referred to as "continuous reinforcing bars ". The third reinforcing bars 430 may be disposed between two adjacent PSC girders 300. The third reinforcing bars 430 may be disposed in the continuous portion 320 of the PSC girder 300.

The bridge may include a steel material 500. The steel material 500 may be referred to as "continuity bonded joint steel. &Quot; The steel material 500 may be disposed on the upper portion of the adjacent side of each of two adjacent PSC girders 300 of the plurality of PSC girders 300 and may be coupled to each other. The steel material 500 may include at least one of a steel sheet, a steel bar, and a reinforcing bar.

The bridge may include a cross beam 610. The beam 610 may be formed on the second reinforcing bar 420 at the transverse portion 310 of the PSC girder 300.

The bridge may include a continuous portion 620. The continuous portion 620 may be formed between two adjacent beams 610. Continuous strain can be added to the continuous portion 620 by the PS steel wire or the PS steel bar.

In the present embodiment, the beam 610 and the continuous portion 620 are integrally formed by collective pouring and curing of concrete to integrate the first reinforcing bars 410, the second reinforcing bars 420 and the third reinforcing bars 430 .

The bridge may include a temporary support 710. The temporary support 710 may include at least one of a hydraulic jack, a preceding load jack, a screw jack, and a sand jack.

The bridge may include grouting (730). The grouting 730 can be applied to the portion where the temporary support 710 is removed.

The bridge may include a bottom plate slab 800. The bottom plate slab 800 may be disposed on top of the PSC girder 300. The bottom plate slab 800 may include a bridge bottom plate slab 810. The bridge deck slab 810 may be a portion of the bottom slab 810 that overlaps the bridge 100 in the vertical direction.

Hereinafter, a structure of a bridge according to a second embodiment of the present invention will be described. Hereinafter, the structure of the bridge according to the second embodiment, which is different from that of the first embodiment, will be mainly described. That is, the structure common to the first embodiment among the structures of the bridge according to the second embodiment can be applied to the description in the first embodiment by analogy.

13 is a cross-sectional view of a bridge according to a second embodiment of the present invention.

The bridge may include a PS steel bar 340. The PS steel bar 340 may be used to tense the portions corresponding to the upper portions of the continuous portion 620 of the PSC girder 300 at both side portions of the beam 610.

Hereinafter, a structure of a bridge according to a third embodiment of the present invention will be described. The structure of the bridge according to the third embodiment is different from that of the first embodiment. In other words, a structure common to the first embodiment among the structures of the bridge according to the third embodiment can be applied to the description in the first embodiment by analogy.

17 is a cross-sectional view of a bridge according to a third embodiment of the present invention.

The bridges may include hook bars 440. The hook reinforcement 440 is formed on the upper portion of the first reinforcing bar 410 vertically buried from the upper surface of the coping 110 of the pier 100 to the upper portion of the neutral axis of the PSC girder 300, And can be folded so as to be embedded in the plate slab 800. At least a portion of the hook reinforcement 440 may be embedded in the bottom plate slab 800. The hook reinforcement 440 may be coupled to the first reinforcement 410. The hook reinforcement 440 may have a hook shape at least in part.

Further, the steel material 500 in the bridge according to the third embodiment can be omitted. 18 (a) shows an outer transversal PSC girder and (b) shows an inner transversal PSC girder. Referring to FIG. 18, it can be confirmed that the steel material 500, which is a constitution of the first embodiment and the second embodiment, is omitted from the PSC girder 300.

Hereinafter, a method of constructing a bridge according to a first embodiment of the present invention will be described.

FIG. 2 is a view for explaining a step of manufacturing an alternation and a bridge in the method of constructing a bridge according to the first embodiment of the present invention, FIG. 3 is a sectional view of the bridge in FIG. 2, FIG. 6 is a perspective view of a bridge construction method according to the first embodiment of the present invention. FIG. 6 is a perspective view illustrating a construction of a PSC girder of an outer lateral section and a PSC inner section of a bridge according to a first embodiment of the present invention. FIG.

A plurality of first reinforcing bars 410 are connected to a bridge 100 so as to be spaced along a plurality of rows and columns in a horizontal direction on the upper surface of the coping 1100 of the bridge 100, And a plurality of PSC girders 300. The plurality of first reinforcing bars 410 may include a plurality of first reinforcing bars 410, The height of the upper end of the one reinforcing bar 410 may be higher than the height of the neutral axis of the PSC girder 300.

7 is a view for explaining a step of mounting a PSC girder to a bridge pier in a method of constructing a bridge according to the first embodiment of the present invention.

The method of constructing the bridge may include installing a temporary support 710 on the upper surface of the coping 110 and mounting a plurality of PSC girders 300 on the alternate 200 and bridge 100.

FIG. 8 is a view illustrating a step of fastening a continuous joint connecting steel material in a method of constructing a bridge according to a first embodiment of the present invention, and arranging a crossbar reinforcing bar and a continuous reinforcing bar.

The method of constructing the bridge is to fasten the steel material 500 at the upper part of the adjacent end of each of the two adjacent PSC girders 300 of the plurality of PSC girders 300 to each other, The step of placing the second reinforcing bars 420 on the transverse portion 310 where the first reinforcing bars 610 are to be formed and the third reinforcing bars 430 on the continuous portion 320 between the adjacent two PSC girders 300 .

9 is a view for explaining a step of forming a bottom plate slab through a concrete primary casting curing method among the method of constructing a bridge according to the first embodiment of the present invention.

The method of constructing the bridge may include forming the bottom plate slab 800 by pouring and curing the concrete on the upper portion except for the intersection portion 310 and the continuous portion 320.

10 is a perspective view illustrating a method of constructing a bridge in accordance with a first embodiment of the present invention. FIG. 10 is a perspective view of a concrete installation method according to a first embodiment of the present invention. A continuous section, and a bridge bottom plate slab through the through-hole, the bottom plate slab, and the bottom plate slab.

The method of constructing the bridge is to completely fasten the steel material 500 on the upper end of the adjacent side of each of the adjacent two PSC girders 300 fastened together and to fasten the first reinforcing bars 410, Concrete beams are cured and cured between the adjacent two PSC girders 300 and the beam portion 310 so that the third reinforcing bars 430 are integrated so that the continuous portion 620, the beam 610 and the pier portion bottom plate slab 810, To form the second electrode.

The concrete is laid between two adjacent PSC girders 300 and the beam portion 310 so that the first reinforcing bars 410, the second reinforcing bars 420 and the third reinforcing bars 430 are integrated in the bridging method, The step may include the step of constructing the bulkhead of the side portion of the temporary support 710 so that the portion of the temporary support 710 can be removed. With this structure, the temporary support 710 can be blocked out.

And constructing a side wall of the temporary support so as to remove the temporary support portion.

11 is a view for explaining a step of removing a temporary support from a method of constructing a bridge according to the first embodiment of the present invention, filling the part where the temporary support is removed by grouting, and tightening the PSC girder with the continuous PS wire to be.

The method of constructing the bridge may include the step of removing the temporary support 710 and filling the portion where the temporary support 710 is removed with the grouting 730 and straining the PSC girder 300 with the PS steel wire 330 have.

FIG. 12 is a view for explaining a bridging waterproofing construction, a paving construction, and a fire wall installation step in a method of constructing a bridge according to the first embodiment of the present invention.

The method of constructing a bridge may include performing a cross-over waterproof construction, a pavement construction, and a barrier installation on the top surface of the bottom plate slab 800. Accordingly, a cross-linked waterproof layer 910 may be formed on the top surface of the bottom plate slab 800. The packaging layer 920 may be formed on the upper surface of the cross-linked waterproof layer 910. A barrier wall 930 may be disposed on the upper surface of the packaging layer 920.

Hereinafter, a method of constructing a bridge according to a second embodiment of the present invention will be described. However, the second embodiment of the present invention will be described focusing on differences from the first embodiment. That is, the description of the second embodiment of the present invention can be applied to the description of the first embodiment.

FIG. 14 is a view for explaining a step of forming a beam, a continuous portion and a bridge portion bottom plate slab through a concrete primary casting curing method in a method of constructing a bridge according to a second embodiment of the present invention.

The method of constructing the bridge is to completely fasten the steel material 500 at the upper part of the adjacent end of each of the adjacent two PSC girders 300 among the plurality of PSC girders 300 to each other, Placing the second reinforcing bars 420 on the beam portion 310 where the beams 610 are to be formed and disposing the third reinforcing bars 430 between the adjacent two PSC girders 300 . The difference is that the two adjacent steel materials 500 are joined together in the corresponding step of the first embodiment.

The method of constructing the bridge includes placing and curing the concrete between the adjacent two PSC girders 300 and the beam portion 310 so that the first reinforcing bars 410, the second reinforcing bars 420 and the third reinforcing bars 430 are integrated Forming a continuous portion 620, a beam 610 and a bridge bottom slab 810. This is different from the first embodiment in that the bottom plate slab 810 is formed earlier than the cross beam 610 and the continuous portion 620.

FIG. 15 illustrates a step of removing a temporary support from a method of constructing a bridge according to a second embodiment of the present invention, filling the removed portion with grouting, and tightening the PSC girder with the PS steel bar at both sides of the upper portion of the continuous portion. Fig.

The method of constructing the bridge is such that the temporary support 710 is removed and the portion where the temporary support 710 is removed is filled with the grouting 730 and the portion corresponding to the upper portion of the continuous portion 620 of the PSC girder 300 And tensioning the PS steel bar 340 at both side portions of the beam 610.

FIG. 16 is a view for explaining a step of secondarily laying and curing concrete in the entirety of the bottom plate slab including the bridge portion bottom plate slab portion of the bridge construction method according to the second embodiment of the present invention.

The method of constructing the bridge may include forming a bottom plate slab 800 by pouring and curing the concrete on top of the PSC girder 300, including the bridge bottom slab 810.

Hereinafter, a method of constructing a bridge according to a third embodiment of the present invention will be described. However, the third embodiment of the present invention will be described focusing on differences from the first embodiment. That is, the description of the second embodiment of the present invention can be applied to the description of the first embodiment.

18 is a view for explaining a step of manufacturing a PSC girder of an outer side web portion and an inner side PSC girder of a bridge construction method according to a third embodiment of the present invention. FIG. 20 is a view for explaining a step of mounting a PSC girder on a bridge pier in a method of constructing a bridge according to a third embodiment of the present invention. Fig.

The method of constructing the bridge is to install the second reinforcing bars 420 on the upper portion of the copings 110 of the PSC girder 300 and to the transverse portion 310 where the beams 610 are to be formed and to sandwich the adjacent two PSC girders 300 And the upper portion of the first reinforcing bar 410 embedded vertically from the upper surface of the coping 110 of the pier 100 to the upper portion of the neutral axis of the PSC girder 300, Folding the hook reinforcement 440 so that a part of the reinforcement can be embedded in the bottom plate slab 800 to be formed later.

FIG. 21 is a view for explaining a step of forming a bottom plate slab through a concrete primary casting curing method among the construction methods of a bridge according to a third embodiment of the present invention.

The method of constructing the bridge may include forming a bottom plate slab 800 by pouring and curing the concrete on top of the PSC girder 300 except for a portion including the crossbar portion 310.

FIG. 22 is a view for explaining a step of forming a beam, a continuous portion and a bridge portion bottom plate slab through concrete secondary curing in a method of constructing a bridge according to a third embodiment of the present invention.

The method of constructing the bridge includes placing and curing the concrete between the adjacent two PSC girders 300 and the beam portion 310 so that the first reinforcing bars 410, the second reinforcing bars 420 and the third reinforcing bars 430 are integrated Forming a continuous portion 620, a beam 610 and a bridge bottom slab 810.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. It is to be understood that the terms such as 'include', 'comprising', or 'having', as used herein, mean that a component can be implied unless specifically stated to the contrary. But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: Pier 200: Shift
300: PSC girder 410: first reinforcing bar
500: Steel 610: Rear beam
710: temporary rest 800: bottom plate slab

Claims (11)

Alternate and multiple PSCs including a plurality of first reinforcing bars embedded in the bridge piers so that a plurality of first reinforcing bars are spaced along a plurality of rows and columns in a horizontal direction on an upper surface of the coping of the pier, Fabricating a girder;
Mounting a temporary base on the upper surface of the coping and mounting the plurality of PSC girders on the alternating and piercing angles;
And a second reinforcing member is disposed on a portion of the upper portion of the upper portion of the adjacent end of each of the adjacent two PSC girders of the plurality of PSC girders, Disposing a third reinforcing bar in a continuous portion between the two PSC girders;
Forming a bottom plate slab by pouring and curing concrete on the upper portion except for the crossbar portion and the continuous portion; And
Between the two adjacent PSC girders so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated with each other, And curing and curing the concrete at the crossbar portion to form a continuous portion, a cross beam, and a bridge bottom slab,
Further comprising the steps of removing the temporary support, filling the portion where the temporary support is removed with grouting, and continuously tensioning the continuous portion to the PS steel wire or the PS steel bar,
Placing and curing the concrete between the adjacent two PSC girders and the crossbar portion so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated,
And constructing a side wall of the temporary support so that the temporary support portion can be removed.
Alternate and multiple PSCs including a plurality of first reinforcing bars embedded in the bridge piers so that a plurality of first reinforcing bars are spaced along a plurality of rows and columns in a horizontal direction on an upper surface of the coping of the pier, Fabricating a girder;
Mounting a temporary base on the upper surface of the coping and mounting the plurality of PSC girders on the alternating and piercing angles;
The steel material on the upper side of the adjacent end of each of the two adjacent PSC girders of the plurality of PSC girders is fully fastened to each other and a second reinforcing bar is placed on the crossing portion located at the upper portion of the coping and in which the crossbeam is to be formed, Disposing a third reinforcing bar in a continuous portion between the two PSC girders;
Inserting and curing the concrete into the continuous portion and the crossbar portion so that the first reinforcing bar, the second reinforcing bar and the third reinforcing bar are integrated, thereby forming a continuous portion, a beam, and a bridge bottom slab;
Removing the temporary base and filling the portion where the temporary base is removed with grouting, and tensing the portion of the PSC girder corresponding to the upper portion of the PSC girder with PS bar at both side portions of the beam; And
And forming a bottom plate slab by pouring and curing concrete on top of the PSC girder, including the bridge bottom slab,
Further comprising the steps of removing the temporary support, filling the portion where the temporary support is removed with grouting, and continuously tensioning the continuous portion to the PS steel wire or the PS steel bar,
Placing and curing the concrete between the adjacent two PSC girders and the crossbar portion so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated,
And constructing a side wall of the temporary support so that the temporary support portion can be removed.
Alternate and multiple PSCs including a plurality of first reinforcing bars embedded in the bridge piers so that a plurality of first reinforcing bars are spaced along a plurality of rows and columns in a horizontal direction on an upper surface of the coping of the pier, Fabricating a girder;
Mounting a temporary base on the upper surface of the coping and mounting the plurality of PSC girders on the alternating and piercing angles;
A second reinforcing bar is disposed at a portion of the upper portion of the coping where the beam is to be formed and a third reinforcing bar is placed in a continuous portion between the adjacent two PSC girders, Folding the hook reinforcement so that at least a part of the upper portion of the first reinforcing bar embedded vertically to the upper portion of the neutral axis can be embedded in the bottom plate slab to be formed later;
Forming a bottom plate slab by pouring and curing concrete on the upper portion except for the crossbar portion and the continuous portion; And
Placing the concrete between the adjacent two PSC girders and the crossbar portion so that the first reinforcing bar, the second reinforcing bar and the third reinforcing bar are integrated, and curing the concrete to form a continuous portion, Including,
Further comprising the steps of removing the temporary support, filling the portion where the temporary support is removed with grouting, and continuously tensioning the continuous portion to the PS steel wire or the PS steel bar,
Placing and curing the concrete between the adjacent two PSC girders and the crossbar portion so that the first reinforcing bars, the second reinforcing bars and the third reinforcing bars are integrated,
And constructing a side wall of the temporary support so that the temporary support portion can be removed.
delete delete 4. The method according to any one of claims 1 to 3,
Wherein the steel material comprises at least one of a steel sheet, a steel bar, and a reinforcing bar,
Wherein the PSC girder comprises an integrated steel structure of a girder and a pier which is a steel girder or a steel composite girder.
The method according to any one of claims 1, 2, and 3,
Wherein the temporary support includes an integral steel structure of a girder and a bridge including at least one of a hydraulic jack, a preceding load jack, a screw jack, and a sand jack. The method according to any one of claims 1, 2, and 3,
Wherein the plurality of first reinforcing bars include an integrated reinforcing structure of a girder and a bridge pier installed in the pier so that a height of an upper end of the plurality of first reinforcing bars is higher than a height of a neutral axis of the PSC girder. The method according to any one of claims 1, 2, and 3,
After the sequencing and tensioning step,
The method of claim 1, further comprising the step of: performing cross-securing waterproofing, paving, and installing a barrier wall on the top surface of the bottom slab. delete delete

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