KR101762148B1 - Bridge using precast psc deck type girder and construction method therefor - Google Patents

Abstract

The present invention relates to a bridge using a precast PSC girder which is constructed so as to facilitate the dismantling of a concrete hollow box girder in a longitudinal direction and a transverse direction after temporarily installing a file and a coping portion in a coping portion unlike a conventional bridge, A pile portion including a precast coping portion extending in the transverse direction on the pipe head portion of the steel pipe and spaced apart from each other in the longitudinal direction and an end portion vertically adjacent to the upper surface of the precast coping portion, And a precast PSC girder to which the transversely adjacent upper side surfaces are connected by the transverse connecting means.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bridge using a precast PSC girder,

The present invention relates to a bridge using a precast PSC girder and a construction method thereof. More specifically, the present invention relates to a bridge using a precast PSC girder which is constructed by installing a steel pipe file and a precast copping portion, connecting a precast PSC girder to a precast PSC girder in a longitudinal direction and a transverse direction, .

FIG. 1A shows an attempt to construct a conventional hypothetical bridge.

That is, the temporary vent 2 is first installed on the ground in consideration of the later dismantling, and the girder 3 is placed in the vertical direction on the upper surface and the upper plate 4 is installed on the upper surface of the girder 3.

When the bridge is completed, the bridge 4 is dismantled and the girder 3 and the temporary vent 2 are removed.

Therefore, the laminates, girders, and temporary vents are usually made of steel for later reuse and treatment.

FIG. 1B illustrates a conventional attempt to construct a hollow girder with a permanent bridge.

That is, after the bridge girder 30 is mounted on the bridge underground structure so that the hollow box girder 10 is substantially in contact with the bridge girder 10 in the transverse direction, the hollow box girder transverse spacing space is subjected to no shrinkage It is possible to connect the hollow box girders 10 by using the concrete 40 and then form a slab or a packing layer on the upper surface of the hollow box girder 10.

As a result, it can be seen that the hollow box girders 10 made of concrete are integrated with each other by using the non-shrinkable mortar 40 in the transverse direction.

FIG. 1C is a perspective view of a conventional concrete slab 50 and a concrete slab 50. The concrete slab 50 is spaced apart from each other with a backup material 60 interposed therebetween in order to absorb the expansion and contraction of the concrete slab in the construction of the concrete slab and the packing layer 80 It can be seen that the elastic asphalt 70 is filled in the upper space.

In other words, the conventional bridges are mainly constructed of steel bridges and upper structures, and permanent bridges use economical concrete girders. In actual bridges or pedestrians, Since the vent and the girder are made of expensive steel, they are inevitably required to incur a large initial cost, generate vibration and noise, have poor running feeling, and require repair due to defects.

Korean Patent No. 10-1120163 (Name of the invention: Method of constructing a hypothetical bridge, publication date: March 20, 2012) Korean Patent No. 10-1071115 (Title of the Invention: Method of constructing a hollow girder bridge and method of constructing a hollow girder, publication date: October 10, 2011) Korean Patent No. 10-1002741 (title of the invention: joint of slab, publication date: December 21, 2010)

Accordingly, in the bridges such as bridges or pedestrian bridges, the bridge substructure is assembled with a minimum of pile and precast copings, and the precast PSC girder is used as a precast PSC girder which is economical and can reduce its own weight However, it is a technical problem to solve the problem of providing a bridge using a precast PSC girder which is more efficient and economical, and a construction method thereof, because it can be simply connected in the longitudinal direction and the lateral direction and can be disassembled later.

Therefore, the bridge using the precast PSC girder of the present invention and the construction method thereof,

A pile portion including a precast coping portion provided to extend in the transverse direction on the head portion of the steel pipe and spaced apart from each other in the longitudinal direction and an end portion vertically adjacent to the upper surface of the precast coping portion are connected to each other And a precast PSC girder to which transversely adjacent upper side surfaces are connected by means of transverse connecting means,

The longitudinal connecting means uses an elastic packaging material forming space which is continuous with the longitudinal end surface of the precast PSC girder so that the upper and lower steel members are stepped to each other so that the upper steel members are larger than the lower steel members , The transverse connecting means is provided to use a bolt working space exposed to the upper side of the precast PSC girder so that the upper and lower steel members are stepped to each other so that the upper steel members are larger than the lower steel members, Wherein the transverse connecting means is a bolt fastening and the lower section steel members spaced transversely from each other are connected to each other with fastening bolts in a working space between the upper section steel members; And an L-shaped connecting bolt connected to the upper damper plate by using a vertical connecting plate connecting upper and lower transverse steel members to each other, wherein a lower end of the L-shaped connecting bolt extends toward the bottom of the upper damper plate Respectively.

Since the present invention uses a precast PSC girder made of a concrete material, it is economical to manufacture it, and it is possible to secure economical efficiency and constructability of a bridge or a pedestrian bridge by using a buried steel for later disassembly.

In addition, the upper surface of the bridge can prevent the slip phenomenon of the bridge through the anti-slip coating, so that the precast PSC girder is optimized for the bridge.

FIG. 1A is a perspective view of a hypothetical bridge made of a conventional steel material,
1B is a view showing a bridge construction using a conventional hollow hollow box girder,
1C is a sectional view of a conventional concrete slab,
FIG. 2 is a perspective view of a bridge using a precast PSC girder according to the present invention,
FIGS. 3A, 3B, 3C and 3D are pile, longitudinal and transverse connections of the bridge A using the precast PSC girder according to the present invention,
4 is a bridge construction flowchart using the precast PSC girder 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.

[Bridge (A) Using Precast PSC Girder 200 of the Present Invention]

FIG. 2 is a perspective view of a bridge A using the precast PSC girder 200 according to the present invention, and FIGS. 3a, 3b, 3c and 3d are cross-sectional views of a bridge A using the precast PSC girder according to the present invention, Of the pile of FIG.

The bridge A using the precast PSC girder 200 includes a pile 100 and a precast PSC girder 200 as shown in FIG.

As shown in FIG. 2, the pile unit 100 includes a plurality of steel pipe piles 110 installed in a row in a horizontal direction, and a precast coping unit 120 is assembled at an upper end thereof.

Since the steel pipe pile 110 is relatively fast in construction speed and does not require a foundation to be built so as to be buried in the ground, it is constructed so as to function as piers and alternately.

The precast coping unit 120 is a concrete member that is connected to the upper and lower surfaces of the steel pipe 110 by a steel bracket 130 and extends in the lateral direction and is manufactured at a factory. They can be fixed to each other by welding or the like using the steel bracket 130 and can be disassembled later.

2, the steel bracket 130 is inserted into the exposed bottom connecting plate 131 formed on the bottom surface of the precast coping portion 120 and the head of the steel pipe 110, and has a reinforcing rib In a case where the lower connection plate 131 and the upper connection plate 132 are side-welded to each other and only the welded portion is dismantled in the pile cap 133 formed with the upper connection plate 132 formed in the horizontal direction, And reuse becomes possible.

At this time, it is preferable that the pile cap 133 is welded and fixed to the head of the steel pipe pile 110. The pile pile portion 100 can be manufactured by assembling the steel pipe pile 110 and the precast coping portion 120 quickly It can be seen that

The precast coping portion 120 is a portion where the precast PSC girder 200 described below is mounted. In the case where the bridge is installed in a continuous bridge form, the bridge portions between the alternating portion and the alternating portion are respectively connected to the pre- (120) is laterally extended.

2, 3B and 3D, the precast PSC girder 200 has a concrete hollow box cross-section which is mounted on the upper surface of the precasted coping portion 120 extending in the transverse direction so as to support both ends in the longitudinal direction Or made of a solid box girder.

When the weight of the precast PSC girder 200 is increased, much effort and cost are incurred for manufacturing, transporting and mounting. Therefore, the hollow portion is formed inside and the prestress is introduced by reducing the weight of the pre- So that it can be used for long-distance bridges. In the case of only a short diameter, a box made of a solid box girder can be used.

Since the precast PSC girder 200 can also serve as a laminating board for a temporary bridge, the precast PSC girder 200 is constructed so as to be in contact with each other in the lateral direction. Therefore, it is necessary to provide a separate transverse connecting means 400 for connecting the precast PSC girder 200 in the transverse direction.

Also, since the precast PSC girder 200 is connected to the longitudinal direction on the upper surface of the precast coping portion 120, the precast PSC girder 200 needs to compensate the longitudinal stretching according to the temperature. Therefore, A longitudinal connecting means 300 for the elastic packaging material construction is required.

Further, a support pad 121 (rubber material) is provided on the upper surface of the precast coping portion 120 to stably support the precast PSC girder 200 to prevent breakage or the like.

3A, upper and lower steel members 310 and 320, which are spaced apart from each other and opposed to each other, are formed on the longitudinal end surface of the precast PSC girder 200, It can be seen that the step is exposed.

At this time, the upper and lower steel members 310 and 320 are continuously formed in the transverse direction over the entire longitudinal end surface of the precast PSC girder 200.

A backup material 330 which is a styrofoam is inserted and supported between the upper and lower steel members 320 and 320 and between the upper and lower steel members 310 is filled with an elastic packing material 340 to absorb deformation due to longitudinal expansion and contraction .

At this time, since the longitudinal end faces of the precast PSC girder 200 are disposed at a minimum longitudinal separation distance (approximately 20 mm), such longitudinal separation distances (referred to as longitudinally adjacent ends in claim 1) It is not possible to secure a sufficient space for forming the elastic packaging material.

As shown in FIG. 3A, the upper and lower steel members 310 and 320 facing each other are formed with stepped portions such that spaces between the upper steel members 310 are further spaced apart from each other in the longitudinal direction than between the lower steel members 320 The elastic member 340 is closed on the upper steel member 310 and the leakage of the elastic member 340 is prevented by the backup member 330.

Further, the upper and lower steel members 310 and 320 may be integrally formed on the longitudinal end surface of the precast PSC girder 200 together with the vertical stiffener and the anchor bolt for reinforcement using the C-type channel member. So that the longitudinal connecting portion can be reinforced.

The starter 350 exposed as a steel member is exposed to the corresponding position on the bottom surface of the precast PSC girder 200 so that the precast PSC girder 200 can be fixed to the precast coping portion 120 in the longitudinal direction. And is fastened to the starter 122 of the precast coping portion 120 by bolts or the like so as not to fall down or the like.

Next, referring to the transverse connecting means 400, it can be seen that the precast PSC girder 200 can be connected to each other in the transverse direction by bolting or welding, respectively, as shown in FIGS. 3b, 3c and 3d.

As shown in FIGS. 3B and 3C, the transverse connecting means 400 by bolt connection is installed to be spaced apart from the upper side of the precast PSC girder 200 in the transverse direction. In the transverse direction, So that the lateral spacing space (about 10 mm) of the girder 200 is covered (referred to as the upper side adjacent laterally in claim 1).

At this time, it is also seen that the upper and lower steel members 450 and 460 are exposed to the side of the lateral side of the precast PSC girder 200 as well.

At this time, since the transverse upper side surfaces of the precast PSC girder 200 are also arranged at the minimum lateral distance (approximately 10 mm), the transverse distance may be a connection It becomes very difficult to secure a work space for the user.

As shown in FIG. 3B and FIG. 3C, the upper and lower steel members 450 and 460 facing each other have a stepped portion such that the gap between the upper steel members 450 is longer than that between the lower steel members 460 So that it is possible to secure a work space for bolt connection work.

Further, the upper and lower steel members 450 and 460 are integrally formed with the vertical upper side of the precast PSC girder 200 together with the vertical stiffener and the anchor bolt for high strength by using the C channel member. So that the longitudinal connecting parts can be reinforced.

The lower shaped steel members 460 spaced from each other in the transverse direction are connected to each other by the fastening bolts 420 using the upper damper plate 410 in the working space between the upper steel members 450,

The upper shaped steel member 450 spaced apart from each other in the transverse direction is connected to the upper wrapping plate 440 by the L connecting bolt 440 by using the vertical connecting plate 430 which is a C- 410, respectively.

3B and 3C, since the lower end of the L-shaped connecting bolt 440 has no portion to be fixed, the lower bent portion of the L-shaped connecting bolt 340 is extended toward the bottom of the upper wrapping plate 410,

The upper and lower steel members 450 and 460 are laterally connected to the fastening bolts 420 and the L-shaped connecting bolts 440. These bolted connections are particularly advantageous in dismantling. As shown in FIG. 3C, the L-shaped connecting bolt 340 is formed with a hole H on an upper surface of a vertical connecting plate 430, which is a U-shaped channel member, to form a vertical support plate 441 .

Next, as shown in FIG. 3D, the lateral connection means 400 by welding is installed so as to be spaced apart from the lateral sides of the precast PSC girder 200 in a lateral direction. In the transverse direction, the precast PSC girder 200, (About 10 mm) of the transverse spacing space,

Shaped channel member 470 in the upper and lower steel members 450 and 460, which are exposed to the side of the lateral side of the precast PSC girder 200, And the upper outer side of the upper end portion of the upper end portion of the lower end portion are welded together.

The upper surface of the precast PSC girder 200, which is connected to the longitudinal and transverse directions by the minimum spacing distance (about 10-20 mm), is subjected to a top surface finish for pedestrians and vehicles, Or an additional steel plate may be additionally fixed on the upper surface of the precast PSC girder 200.

[Construction method of the bridge (A) using the precast PSC girder of the present invention]

Fig. 4 shows a flowchart of a method of constructing a bridge (A) using the precast PSC girder of the present invention.

First, the steel pipe file 110 and the steel bracket 130 are provided to construct the pile 100, and the precast coping part 120 is also manufactured separately.

In addition, the precast PSC girder 200 is divided into a hollow box girder and a solid box girder by dividing the girder into a long shear girder and a short span girder. In the present invention, .

In this case, the precast PSC girder 200 is formed with a lower connecting plate 131 to be connected to the upper connecting plate 132 of the steel bracket 130 in advance, and as the longitudinal connecting means 300, The upper and lower steel members 450 and 460 are preliminarily formed in a stepped shape so that the lower steel members 310 and 320 are formed in advance and the lateral connection means 400 is used.

4,

The pile section 100 and the precast coping section 120 using the steel pipe file 110 and the steel bracket 130 are constructed.

That is, to construct a multi-span bridge, the steel pipe pile 110 is constructed as a pillar between the two alternating piles and the two alternating piles in a one-row transverse direction structure. At this time, it can be seen that the steel pipe file 110 is not installed separately.

The steel bracket 130 is fixed to the head of the steel pipe 110 and the steel bracket 130 and the precast coping portion 120 are lifted to connect the lower connecting plate 131 of the steel bracket 130 to the lower end of the steel bracket 130, Thereby connecting the upper connecting plates 132 of the upper plate 130 to each other.

Next, as shown in FIG. 4,

The precast PSC girder 200 is connected to the precast coping portion 120 in the longitudinal direction and the transverse direction. (S120)

In other words, the precast PSC girder 200 is mounted on the upper surface of the precast coping portion 120, which are laterally extended from each other and spaced apart from each other in the longitudinal direction, so that both ends are supported by the supporting pads 121 in the longitudinal direction ,

The ends of the precast PSC girder 200 are spaced slightly from the top surface of the precast coping portion 120.

The precast PSC girder 200 is arranged to be slightly spaced even in the lateral direction.

Once the longitudinal and transverse installation of the final precast PSC girder 200 is completed, they are connected to one another by means of the longitudinal and transverse connecting means 300, 400.

The longitudinal connecting means 300 is for installing the backup material 330 and the elastic packaging material 340,

The transverse connection means 400 will be constructed using bolting or welding.

As a result, a barrier or the like is installed as a bridge on the outermost side surface of the precast PSC girder 200 in which the longitudinal and transverse connections are completed.

Since the pre-cast PSC girder 200 is used, the amount of deflection is not greatly increased in comparison with the use of a steel material using a bridge, so that the vibration is reduced, So that noise can be hardly generated and driving safety can be ensured. Thus, the present invention is particularly advantageous for a temporary bridge and a pedestrian bridge.

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.

100: pile portion
110: steel pipe file 120: precast coping portion
121: Supporting pad 122:
130: steel bracket 131: lower connecting plate
132: upper connection plate 133: pile cap
200: Precast PSC girder
300: longitudinal connecting means 310: upper section steel member
320: lower section steel member 330: backup material
340: elastic packing material 350:
400: transversal connecting means 410: upper folding plate
420: fastening bolt 430: vertical connecting plate
440: L-shaped connecting bolt 450: Upper section steel member
460: Lower section steel member 470: U-shaped channel member
A: Bridges using precast PSC girder

Claims (10)

A pile (100) comprising a precast coping portion (120) extending transversely to a head of a steel pipe (110) and spaced apart from each other in a longitudinal direction:
The longitudinally adjacent ends of the precast coping portion 120 are connected to each other by the longitudinal connecting means 300 and the transversely adjacent upper end side is connected by the transverse connecting means 400, And a girder (200)
The longitudinal connecting means 300 is connected to the longitudinal end face of the precast PSC girder 200 so that the upper and lower steel members 310 and 320 are stepped to each other, The elastic packaging material forming space exposed to a larger size is used,
The transverse connecting means 400 is formed so that the upper and lower steel members 450 and 460 are continuously staggered from the upper side of the precast PSC girder 200 so that the upper steel members are larger than the lower steel members. Using exposed bolt work space,
The transverse connecting means 400 is bolted and the lower shaped steel members 460 spaced transversely from each other are connected to each other by upper bolts 420 connected to each other in the working space between the upper steel members 450 410); And an L-shaped connecting bolt 440 connected to the upper damper plate 410 by using a vertical connecting plate 430 connecting upper and lower steel members 450 spaced apart from each other, And the lower end of the connecting bolt 440 is extended to the bottom of the upper wrapping plate 410. [ The method according to claim 1,
The steel pipe file 110 is installed without a base part, and is fixed to the head part by the steel bracket 130 and the precast coping part 120,
The steel bracket (130)
An exposed lower connecting plate 131 formed on the bottom surface of the precast coping portion 120; And a pile cap 133 inserted into the top of the pipe tube 110 and having an upper connecting plate 132 formed on the upper surface thereof as a reinforcing rib horizontally,
A bridge using a precast PSC girder which is made by side-welding the lower connection plate 131 and the upper connection plate 132 to each other and disassembling only the welded portion so that it can be separated and reused. The method according to claim 1,
The precast PSC girder 200 is lifted and mounted on the upper surface of the precast coping portion 120 by a supporting pad, and a precast concrete box girder or a concrete solid box girder is used, Bridge using PSC girder. The method according to claim 1,
The longitudinal connecting means (300)
A backup material 330 inserted and supported between the lower-shaped steel members 320 exposed stepwise on the longitudinal end surface of the precast PSC girder 200; And a resilient packing material (340) finished between the upper structural member (310) and the upper structural member (310) so as to absorb deformation due to the longitudinal expansion and contraction of the precast PSC girder (200). delete delete (a) a pile portion 100 including a precast coping portion 120 provided to extend in the lateral direction on the head portion of the steel pipe 110 after installing the steel pipe pile 110 and spaced apart from each other in the longitudinal direction, A step of constructing; And
(b) ends vertically adjacent to the top surface of the precast coping portion 120 are connected to each other by the longitudinal connecting means 300, and the laterally adjacent upper side surfaces are connected by the transverse connecting means 400 Constructing the precast PSC girder (200)
The longitudinal connecting means 300 of the step (b) continues to the longitudinal end surface of the precast PSC girder 200 such that the upper and lower steel members 310 and 320 are stepped to each other, Is formed to be larger than the space between the upper and lower steel members,
The transverse connecting means 400 of the step (b) is constructed such that the upper section steel member 450 and the lower section steel member 460 are continuously staggered from the upper side surface of the precast PSC girder 200, A bolt working space is used which is exposed so as to be larger than between the members,
The transverse connecting means 400 of the step (b) is connected to the bolts 420 by fastening bolts 420 in the work space between the upper steel members 450, An upper collapse plate 410; And an L-shaped connecting bolt 440 connected to the upper damper plate 410 by using a vertical connecting plate 430 connecting upper and lower steel members 450 spaced apart from each other, And the lower end of the connecting bolt (440) is extended to the bottom surface of the upper wrapping plate (410). 8. The method of claim 7,
The longitudinal connecting means 300 of the step (b)
A backup material 330 inserted and supported between the lower-shaped steel members 320 exposed stepwise on the longitudinal end surface of the precast PSC girder 200; Cast PSC girder that can absorb deformation due to the longitudinal expansion and contraction of the precast PSC girder 200, including an elastic wrapping material 340 finished between the upper and lower steel members 310, . delete delete

Images