KR101538757B1 - Rahmen bridge construction method using psc beam - Google Patents

Abstract

The present invention relates to a rahmen bridge construction method using a PSC beam, and a rahmen bridge manufactured thereof. The present invention enables a PSC beam capable of installing the rahmen bridge have a long span, and minimizes a negative moment of a corner portion to be integrated with both walls after the PSC beam is manufactured. Therefore, the present invention easily secures an overhead clearance and reduces a construction period so as to have excellent economic efficiency. The PSC beam is capable of introducing tensile stress by a compression steel material, and a pressing fixture is buried in an upper circumference to enable an inside of a fixture to be exposed, and both end parts of the compression steel material is fixated to a fixing plate by a fixing nut.

Description

{RAHMEN BRIDGE CONSTRUCTION METHOD USING PSC BEAM}

The present invention relates to a ramen bridge construction method using a PSC beam. More specifically, it is possible to construct the PSC beam that minimizes the construction of the long span of the ramen bridge and minimize the momentum of the right corner, and then integrate the PSC beam with the two wall parts, thereby securing the mold space and shortening the construction period. The present invention relates to a method of constructing a ramen bridge.

In general, raymen bridge is constructed by in-situ casting method, and the upper and lower wall structures are integrated with each other. In order to integrate the upper and lower wall structures, It is a method of integrating structure and superstructure. At this time, there is a problem that large legend is generated in the right part of the existing raymen bridge, and it has been applied only to a short span bridge between middle and small size.

Therefore, a method of constructing a ramen bridge by a precast method is also introduced in the conventional ramen bridge construction.

That is, FIG. 1A shows a perspective view of a raymen structure constructed in a conventional precast method. That is, the bottom plate segments 10 are provided on the ground, the two wall segments 20 are provided so as to extend upward in the bottom plate segment, and the top plate segments 30 are arranged in the lateral direction So as to construct a ramen structure.

The upper plate segment 30 is connected to the precast upper plate 32 in the longitudinal direction and the upper plate concrete 33 is installed on the upper surface of the precast upper plate 32. [ And the prestress is introduced by using the tension member 31 in the transverse direction.

At this time, the bottom plate concrete between the top plate concrete 33 and the bottom plate segment 10 is adopted as a spot installation method, so that the workability can be ensured and the integrity of the segments can be ensured.

The prestress is introduced in the transverse direction by using the prestressing material 31 so that it is possible to construct the upper plate segment with a longer diameter. However, the introduction of the prestress into the entire upper plate segment has a problem that the introduction efficiency of the prestress can be lowered somewhat.

1B is a perspective view of a conventional alternate integral ramen bridge.

That is, the continuous slab 40 including the bottom slab 41 extending in the throttle direction to be disposed between the alternate upper surfaces and the connecting slab 42 extending in the throttle direction by the concrete pushed integrally with the bottom slab, ; (50) hingedly connected to the ground while supporting the continuous slab (40) and installed on the ground by a pile (60), wherein the integrated bottom plate slab (41) and the connecting slab So that the connecting slabs 42 are formed in the cantilever structure with respect to the alternation 50 with reference to the alternation 50 located at the inner bottom from both ends thereof.

It can be seen that the size of the cross section of the alternation 50 can be reduced by constructing the alternation 50 by using the pile 60, which is advantageous for the related construction and alternate construction.

However, since the alternation 50 is made to be hinged to the continuous slab 40, virtually no load acting on the continuous slab 40 is transferred to the alternation 50, so that the cross-sectional optimization of the continuous slab 40 It is difficult to make a composite bottom plate method.

As a result, the conventional ramen bridge construction method is able to utilize the upper structure (top plate segment, upper slab) and the lower wall structure and file more effectively so that the ramming bridge can be constructed by reducing the vertical momentum of ramen bridge. However, there is no description about the technique of the ramen bridge construction using the PSC beam capable of decreasing the vertical momentum of the ramen bridge and the long span construction.

Therefore, the present invention can prevent the PSC beam from increasing the flexural moment of the right corner during the construction process by using the PSC beam with a minimum span length, which can be constructed with a long span, and thus, a more efficient and economical PSC beam It is a technical problem to solve the provision of the ramen bridge construction method.

According to an aspect of the present invention,

First, the both wall portions and the PSC beam are installed in a simple support form at the right corner, so that the bending moments due to the weight of the PSC beam are not increased. For this purpose, a fixing bar is provided on the upper surface of the wall, The both ends of the beam are inserted and supported so that the PSC beam can be installed in a simple supporting state free from both end rotations.

Secondly, the PSC beam used in the present invention is formed so that the PC strand for the introduction of the prestress and the compression steel material buried in the upper part are formed. After the compression stress is introduced, the compression steel material is subjected to tensile stress The PSC beam cross section is optimized by canceling the compressive stress accumulated on the center axis of the PSC beam, so that the long span construction can be performed.

Next, the PSC beam using the compression steel is installed so that the upper and lower flanges are in contact with each other in the transverse direction, so that the upper plate of the ramen bridge can be formed directly by the hollow top plate, thereby minimizing its own weight, Respectively.

Third, in the both wall portions, the extended inner reinforcing bars drawn upwards are bound to the U-shaped end finishing reinforcing bars formed on both end faces of the PSC beam, so that it is possible to simply reinforce the right corner portions, and the PSC beam and the two wall portions .

Fourth, the top plate concrete can be installed separately on top of the PSC beam or the top flange of the PSC beam can be used as the top plate, so that the top plate can be efficiently installed. The PSC beams constructed so as to contact each other in the lateral direction, The transverse tensions installed in the transverse beams were used to integrate them.

The ramp bridge according to the present invention can be installed in a simple supporting state in which the end rotations of the PSC beam and both wall portions can be freely freely moved, thereby preventing the increase of the right angular bending moment due to the self weight of the PSC beam.

This rudder part connects the inner reinforcing bars drawn upward of the two wall sections to the end reinforcing bars to facilitate the reinforcement of the right angles.

In addition, the PSC beam used in the ramen bridge of the present invention can be made to be capable of minimizing its own weight while using the one manufactured to reduce the length of the ramp, thereby enabling a more efficient and economical rammen bridge construction.

That is, due to the live load, the bending moment occurs in the PSC beam and the accumulation of the compressive stress of the PSC beam is sufficiently canceled by the tensile stress due to the compression steel, thereby reducing the height of the cross section of the PSC beam, It is possible to construct the ramen bridge between the long and short sides.

In addition, since the PSC beam according to the present invention can be constructed with a hollow top plate, the weight of the top plate can be minimized, and thus a more economical rammen bridge construction becomes possible.

1A is a perspective view of a conventional raymen structure,
1B is a construction cross-sectional view of a conventional alternate integral ramen bridge,
FIGS. 2A, 2B and 2C are views showing the construction of a PSC beam used in the present invention,
FIGS. 3A, 3B and 3C are flowcharts of a ramen bridge construction method using a PSC beam according to Embodiment 1 of the present invention,
4A, 4B, and 4C are flowcharts of a method of performing a ramen bridge using a PSC beam according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Ramen bridge using the PSC beam of the present invention]

FIGS. 2A and 2B are views showing the fabrication of the PSC beam 200 (prestressed concrete beam) used in the ramen bridge of the present invention, and FIG. 2C are views showing the construction of the ramen bridge using the manufactured PSC beam.

First, the PSC beam 200 is basically constructed such that a longitudinal tensional element 290 such as a PC stranded wire is disposed in advance in a parabolic shape, and a prestress is introduced by the longitudinal torsion element 290. That is, a compressive stress is introduced. In the case of a PSC beam having a low profile height, that is, a compressive stress is introduced into the PSC beam having a small sectional height, compression fracture may occur due to introduction of compressive stress. ) Is installed separately to generate tensile stress that can offset the accumulated compressive stress during manufacture and construction, thereby enabling a more efficient and economical rammen bridge construction using a PSC beam having a low profile and a long length. .

First, as shown in FIG. 2A, a bed (150, floor) is installed so as to ensure flatness on the floor of a factory or the like, a PSC beam (200) is formed on the upper surface of the bed, A fixing nuts 220a, a pressure fixing member 270, and a longitudinal tension member 290 are installed in advance in order to fix the cushion 250, the compression steel member 210, the fixing plate 220, the fixing nut 220a, do.

In this case, the PSC beam 200 is formed on an I-shaped cross section, and in FIG. 2A, the upper flange, the abdomen, and the lower flange are not shown.

First, the U-shaped end finishing steel bar 230 is a reinforcing bar to be embedded in concrete laid by pouring concrete into a mold for manufacturing an I-shaped section PSC beam 200. In particular, in the present invention, the amount of the PSC beam 200 So as to be projected from the end face and finished in a C shape.

The reason for closing the end face in the U shape is that the PSC beam 200 and the both wall portions 110 are integrated with each other by overlapping with the inner reinforcement 120 drawn out from the wall portion in the right corner of the rammen bridge, .

Next, the sheath 250 is used to insert the longitudinal torsion springs 290. In order to introduce a prestress into the PSC beam 200, the sheath 250 is formed in a parabolic shape so as to be fixed after both ends of the PSC beam 200 are tensed. The deployed longitudinal torsion members 290 are installed to be inserted. Thus, it can be seen that the fixing port is embedded in both end surfaces of the PSC beam 200, and that the sheath 250 is installed between the fixing ports. A longitudinal torsion spring 290 is inserted into the sheath 250.

Next, the compression steel member 210 uses a steel bar, which is intended to introduce a tensile stress to the upper side of the PSC beam 200.

That is, the prestress introduced by the longitudinal prestressing material 290 causes compressive stress to be introduced into the upper side of the PSC beam 200, and tensile stress to be introduced into the lower side of the PSC beam 200.

At this time, as the cross-sectional height of the PSC beam 200 becomes smaller, the mold space of the ramp bridge becomes smaller. Therefore, the PSC beam 200 is manufactured by increasing the amount of the pre-stress introduced and reducing the height of the cross section of the PSC beam 200 The PSC beam 200 having a small cross-sectional height is installed to introduce tensile stress that can resist the accumulated compressive stress because compressive stresses can be generated as the compressive stress accumulates on the center axis.

In order to introduce such a tensile stress, the steel material 210 for compression, which is a steel rod, is disposed inside the upper edge of the PSC beam 200 so as to be horizontally extended inside.

In this manner, the compression steel member 210 can be disposed inside the PSC beam 200 in advance, thereby making it possible to secure the convenience of PSC beam production.

Next, the pressurizing fixture 270 is a steel box body which is installed such that the inside is exposed on both upper ends of the PSC beam 200 so that both ends of the compression steel member 210 are exposed.

That is, a steel box body with an open top is installed in the formwork in advance so that the steel box body is buried as the concrete is laid, while the inside is exposed (open top).

As shown in FIG. 2B, the pressurizing fixture 270 has a fixing plate 220 (see FIG. 2) having both end portions of the compression-use steel member 210 extended inward, Both end portions of the compression-use steel member 210 are formed with threaded portions so that the fixing nut 220a is pre-clamped.

Both ends of the compression-use steel member 210 are arranged to pass through the fixing plate 220 of the pressure fixing member 270, and are arranged in a state before fixing.

The sheath 250, the compression steel member 210, the fixing plate 220, the fixing nut 220a, and the pressure fixing member 270 are installed in advance in the form of the C-shaped end finishing steel bar 230, The PSC beam 200 is fabricated by demolding the mold.

In the PSC beam 200, a prestress by the longitudinal torsion member 290 is introduced, and a tensile stress by the compression-use steel member 210 is introduced into the upper torsion.

2b, the longitudinal tension member 290 is inserted into the sheath 250 and the longitudinal tension member 290 is tensioned by using the hydraulic jack 260. The longitudinal tension member 290 is fixed to the fixation port to introduce a prestress into the PSC beam 200 .

In this prestress, a compressive stress is applied to the upper side of the PSC beam 200, and a tensile stress is introduced to the lower side of the PSC beam 200. Since the compressive stress is accumulated and the concrete of the upper side can be compressively fractured, So that tensile stress in the form of reaction force is generated.

That is, a compression hydraulic jack 260a is disposed between the fixing plate 220 and the end face of the pressurizing fixture 270 having the inside exposed, and is operated to compress the compression steel 210.

When the compression steel member 210 is fixed and fixed to the fixing plate 220 by using the fixing nut 220a after compressing the compression steel member 210, Tensile stress is generated.

Upon completion of the fixing of the compression steel member 210, the compression hydraulic jack 260a is disassembled.

The pressurizing fixture 270 is installed so as to be embedded in the upper part of the PSC beam 200. By using the pressurizing fixture 270 made of a steel material, it is possible to reinforce the upper edge of the PSC beam 200, So that it can effectively resist local stress and the like due to fixing and fixing of the steel material 210.

FIG. 2C is a view showing the production of a ramen bridge using the PSC beam 200 manufactured as described above.

In other words, it can be seen that both wall portions 110 are installed first. On the upper surface, the inner reinforcing bars 120 are drawn upward. On the inner upper surface, the wall supporting rods 140 are installed. A plate such as a steel plate may be used, and a fixing bar 130 may be installed so as to penetrate the wall part support 140.

The PSC beam 200 is inserted into the insertion hole formed at the bottom of both end portions of the PSC beam 200 so that the PSC beam 200 is inserted into the both wall portions 110 So that it is simply supported.

Even if the PSC beam 200 is mounted on the wall part 110 by the simple support, the bending moment due to the weight of the PSC beam 200 is not transmitted to the wall part 110, It is possible to have a technical effect of not increasing the power consumption. Accordingly, it is possible to reduce the cost due to the construction of the wall portions 110 and the like.

After the PSC beam 200 is simply supported on both wall portions 110, the U-shaped end finishing bar 230 and the inner reinforcing bar 120 exposed on both end faces of the PSC beam 200 are connected to each other And then the right PSC beam 200 and the two wall portions 110 are integrated with each other by installing the right square concrete 240a.

As a result, it can be seen that a right angle portion is formed by the right corner concrete 240a at the connection portion between the wall portion 110 and the PSC beam 200. [

When the final rake bridge is completed, a flexural moment is generated in the PSC beam 200 due to the live load, and the bending moment is generated in the PSC beam 200 due to the live load. The compressive stress of the PSC beam according to the present invention is sufficiently canceled by the tensile stress caused by the compressive steel material 210 so that the sectional height of the PSC beam 200 is reduced and the mold space is sufficiently secured. It can be understood that there is a great significance in using the PSC beam capable of introducing the tensile stress due to the steel material.

[Method of constructing rammen bridge using PSC beam of the present invention]

FIGS. 3A, 3B and 3C illustrate a ramen bridge construction method using the PSC beam according to the first embodiment of the present invention, FIGS. 4A, 4B and 4C show a PSC beam according to the second embodiment of the present invention, And a method of using the ramen bridge.

The first and second embodiments are based on the construction method of the upper plate of the ramen bridge. In the first embodiment, the upper plate concrete is not separately installed. In the second embodiment, the upper plate concrete is separately constructed. The first and second embodiments use the PSC beam 200 in which the steel material 210 is installed. Thus, the indication of the compression steel member 210 is omitted in the drawing.

[Method of constructing the ramen bridge using the PSC beam according to the first embodiment]

First, as shown in FIG. 3A, both wall portions 110 are installed on the ground.

The wall portion 110 extends upward from the ground surface and is made of reinforced concrete.

An inner reinforcing bar 120 is drawn upward from an outer upper surface of the wall part 110 and a wall part support 140 installed through the fixing bar 130 on an inner upper surface.

Next, as shown in FIG. 3B, the PSC beam 200 manufactured first is mounted on the fixing bar 130 of the wall unit 110 so that both ends are simply supported. That is, the fixing bar 130 is inserted into the insertion holes formed at the bottoms of both end portions of the PSC beam 200, so that the PSC beam 200 is simply supported on the both wall portions 110.

3C, it can be seen that the PSC beam 200 is made of an I-shaped section composed of the upper flange, the abdomen, and the lower flange, and the lateral sides of the upper and lower flanges are held in contact with each other, ) Is formed naturally.

At this time, a plurality of beams 280 are provided in the transverse direction of the PSC beam 200 in the longitudinal direction of the PSC beam, and the transverse holes are formed in the beam 280 in advance, Transverse torsion members 250a penetrate and constrain the PSC beams 200 in the transverse direction with respect to each other.

As shown in FIG. 3C, it can be seen that the upper plate can be constructed as a hollow upper plate (slab) by mounting the PSC beam 200 in the ramen bridge of the present invention.

In this case, the upper flange of the PSC beam 200 is directly used as a raymen bridge plate, so that no top plate concrete is laid separately. In the right corner portion, a U-shaped end portion exposed at both ends of the inner reinforcing bar and the PSC beam The final reinforcing bar 230 is bound and the final PSC beam 200 and the two wall portions 110 are integrated with each other through the pouring of the right corner concrete.

As a result, it can be seen that Embodiment 1 maximizes the efficiency and economical efficiency of the ramen bridge construction as a construction method in which the upper plate is formed as a hollow upper plate and the upper plate concrete is not laid separately in the ramen bridge.

[Method of constructing the ramen bridge using the PSC beam according to the second embodiment]

First, as shown in FIG. 4A, the two wall portions 110 are installed on the ground.

Also, the wall part 110 extends upward from the ground surface and is made of reinforced concrete.

The inner reinforcing bars 120 are drawn upward on the upper side of the wall part 110 and the wall part supports 140 installed on the upper side of the inner side so that the fixing bars 130 pass through.

Next, as shown in FIG. 4B, the manufactured PSC beam 200 is mounted on the fixing bar 130 of the wall unit 110 so that both ends of the PSC beam 200 are simply supported. That is, the fixing bar 130 is inserted into the insertion holes formed at the bottoms of both end portions of the PSC beam 200, so that the PSC beam 200 is simply supported on the both wall portions 110.

4C, it can be seen that the PSC beam 200 is made of an I-shaped section composed of an upper flange, an abdomen, and a lower flange, and that the side faces of the upper and lower flanges are horizontally spaced apart from each other in the lateral direction have.

At this time, a plurality of beams 280 are provided in the transverse direction of the PSC beam 200 in the longitudinal direction of the PSC beam, and the transverse holes are formed in the beam 280 in advance, Transverse torsion members 250a penetrate and constrain the PSC beams 200 in the transverse direction with respect to each other.

As shown in FIG. 4C, the upper flange of the PSC beam 200 follows the top plate concrete 200a in a top-up manner. In this case, the U-shaped end finishing steel bars 230 exposed at both ends of the inner steel reinforcing bars and the PSC beams are bound to the inner steel reinforcing bars, and the inner steel reinforcing bars are bent to the upper part of the PSC beams to be embedded in the upper plate concrete, So that the concrete can be integrated.

The second embodiment is a construction method according to a method of separately installing an upper plate in a ramen bridge. In this embodiment, it is possible to reduce the number of PSC beams to be installed and to easily secure a transverse gradient of the upper plate. Can be contrasted.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

110: double wall part 120: inner reinforcing bar
130: Fixing bar 140: Wall support
150: Bed
200: PSC beam 210: Steel for compression
220: Fixing plate 220a: Fixing nut
230: C-shaped end finishing steel
240a: Right Angle Concrete
250: Sheath 250a: Transverse tension member
260: Hydraulic jack 260a: Hydraulic jack for compression
270: pressure-fixing body 280:
290: longitudinal tension

Claims (5)

the inner reinforcing bars 120 are drawn upward on the upper surface and the fixing bars 130 are protruded and formed on the inner upper surface so that a wall part support 140 which is Teflon or a steel plate is installed to penetrate the wall part support 140 Installing two wall portions 110 provided with the fixing bars 130;
(b) placing a PSC beam inserted into the insertion holes formed at the bottoms of both end portions of the fixing bar 130 and being supported so as to expose the U-shaped end finishing bars 230 on both end faces; And
(c) After connecting the inner reinforcing bars 120 and the U-shaped end finishing reinforcing bars 230, the reinforcing concrete 270a is attached to the right corner of the PSC beam 200 and the two wall portions 110, And integrating the PSC beam (200) and both wall portions (110)
The PSC beam 200 is a prestressed concrete beam fabricated to support the bottom surface of the PSC beam 200. The PSC beam 200 is installed to be embedded in the upper surface of the PSC beam 200 with respect to the central axis, And a fixing plate 220 formed on the inner bottom surface of the PSC beam 200 so that both ends of the pressing steel member 210 are embedded in the upper edge of the PSC beam 200 and extend inwardly of the pressure fixing body 270, And a compressive hydraulic jack 260a provided in the pressurizing fixture 270 introduces a compressive stress into the compressive steel material 210. The compressive stressed jacket 260 is inserted into the compressive steel material 210, And the fixing steel plate 210 is fixed to the fixing plate 220 by using the nut 220a. The method according to claim 1,
The PSC beam (200)
Shaped cross section constituting the upper flange, the abdomen and the lower flange, and the upper and lower flanges are abutted on the upper surface of the wall portions 110 so that the inner hollow S formed by the abdomen of the PSC beam interferes with the ram Wherein the upper plate of the bridge is formed as a hollow upper plate and the upper flange of the PSC beam is exposed to the upper plate so that the upper plate concrete is not laid separately. The method according to claim 1,
The PSC beam (200)
The upper flange, the upper flange, the lower flange, and the upper flange, the upper flange, the lower flange, the upper flange, the lower flange, the upper flange, the lower flange, And the inner reinforcing steel is formed so as to extend horizontally in the upper plate concrete. delete delete

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