KR101915960B1 - Steel and concretre bridge construction method using precast half-deck - Google Patents

Abstract

The precast half section deck made of UHPC (ultra high performance high strength concrete) is set between the abdomen of the steel girder and fixed with the horizontal fastening like the connecting bolt. Then, the slab concrete is placed in the precast half section deck, A method of constructing a composite composite girder bridge using a precast half section deck for constructing a bridge. The precast half-section deck is first synthesized by mechanical fastening between the upper ends of the abdomen of the steel girder, and is constructed to be secondarily synthesized by the final slab concrete.

Description

STEEL AND CONCRETE BRIDGE CONSTRUCTION METHOD USING PRECAST HALF-DECK BACKGROUND OF THE INVENTION [0001]

The present invention relates to a steel composite girder bridge construction method using a precast half section deck. More precisely, a precast half section deck made of UHPC (ultra high performance high strength concrete) is set between the abdomen of the steel girder and fixed with a horizontal fastening such as a connecting bolt, and then slab concrete is placed in the precast half section deck To a steel composite girder bridge construction method using a precast half section deck for constructing a steel composite girder bridge.

1A is a perspective view showing a UHPC bottom plate 1a and a UHPC bottom plate 1a according to a first embodiment of the present invention. In the steel composite girder bridge connection structure using the recess 11 formed in the steel composite girder bridge.

That is to say, on both lateral sides of the upper flange 22 of the girder 2 in the transverse direction perpendicular to the longitudinal direction of the girder 2, ultra-high performance high strength concrete having a compressive strength of 150 MPa or more is used, The end portions of the bottom plates 1a and 1b are arranged so as to span,

The end faces 11 of the UHPC bottom plates 1a and 1b of the both sides face each other with the stud type shear connection member 21 protruding from the girder 2 therebetween so that the UHPC bottom plates 1a and 1b, And the UHPC bottom plates 1a and 1b are integrated with each other,

A UHPC bottom plate 1a is provided with a UHPC bottom plate 1a and a UHPC bottom plate 1a which is provided with a UHPC bottom plate 1a and a UHPC bottom plate 1a, A plurality of recesses (11) are formed at intervals in the longitudinal direction of the girder (2);

A connecting reinforcing bar 3 is provided on the end face 11 of the UHPC bottom plate 1b on the other side so as to protrude therefrom;

When the UHPC bottom plates 1a and 1b on both sides are arranged on both lateral sides of the girder 2, the other end of the connecting reinforcing bar 3 is located in the recess 11 formed in the one side UHPC bottom plate 1a Have;

Concrete (5) is laid on top of the girder (2) between the UHPC bottom plates (1a, 1b) on both sides;

The UHPC 4 is filled in the concave portion 11 of the one side UHPC bottom plate 1a and the other end of the connecting reinforcing bar 3 located in the concave portion 11 is embedded in the UHPC 4 And UHPC bottom plates 1a and 1b on both sides and the girder 4 are integrally and tightly coupled to each other.

Therefore, the UHPC bottom plate is installed on the girder protruding from the upper surface of the shear connection member, so that the UHPC bottom plate is firmly connected to each other, and the UHPC bottom plate and the girder are solidly integrated, It is possible to provide a connection structure of a new structure and a construction method thereof that can be applied to a UHPC bottom plate requiring curing and that can easily and efficiently perform a connection between a UHPC bottom plate and a composite operation with a girder.

However, since the means for integrally combining the girder 2 and the UHPC bottom plate is formed by the shear connection member 21 and the concrete 5 in the form of a stud, in order to secure sufficient rigidity in such a connection structure, (S), it is necessary to reinforce the reinforcement more densely although it is not shown for this purpose.

As shown in FIG. 1A, the end portions of the UHPC bottom plates 1a and 1b mounted on the girders 2 are formed thicker than the body portions between the end portions to artificially increase the thickness of the connection space S .

1B is a perspective view and a connection diagram of a conventional precast bottom plate 50. As shown in FIG.

That is, the precast bottom plate 50 is formed in a horizontal plate shape, and the body 51 is formed with a front end pocket 52 so as to penetrate the body portion vertically, and a loop reinforcing bar 53 is formed to protrude from the end face .

A shear connection member 54 in the form of a stud formed on the upper surface of the girder 2 is inserted into the shear pockets 52 so as to be finished by a filling material (non-shrinkable mortar) ) Are arranged to overlap with each other and are also closed by a filler material (non-shrinkable mortar, etc.).

As a result, as shown in FIGS. 1A and 1B, the connection between the precast deck and the girder is used to connect the shear connection member in the form of a stud, the shear pocket, the shear pocket finishing by the filler, and the precast deck and the girder using the loop reinforcement ,

It is necessary to secure the connection space between the upper surface of the girder and the precast deck so as to reinforce it with the reinforcing steel and there is a limit to secure the integrity of the girder and the bottom plate by the shear connector and shear pockets in the form of a simple stud.

Further, in the composite structure of the steel girder and the concrete bottom plate, as shown in FIG. 1C, the bottom plate 63 is formed by putting the front end connection member 62 in the upper flange 61 of the steel material, In order to obtain the required bending stiffness of the girder, it is necessary to increase the height of the steel girder, to install a large number of shear connectors for composing with the bottom plate, to thicken the bottom plate section of the composite portion, And a plurality of reinforcement reinforcement is required.

To solve this problem, a technique has been proposed for lowering the girder height and increasing the stiffness by composing the upper flange of the steel girder and the concrete casing block of high strength (Patent Application No. 10-2015-0011040 / Steel composite girder and its fabrication And a method of constructing a bridge overhead structure using the steel composite girder manufactured by the method / applicant: Sam Hyun PIEF) As shown in FIG. 1D, the method comprises the steps of forming the steel girders 81, 82, 83 and the concrete casing block 85) serves as an integral girder (80), and a bottom plate is synthesized thereon. The structure includes a steel girder, a concrete casing block (85) and curing, a bottom plate concrete reinforcement, a bottom plate concrete casting and curing It is not possible to shorten the air compared with the existing type, and there is a drawback in that it is required to further manufacture the concrete casing block and curing.

Accordingly, the present invention is a method in which a steel girder is fixedly installed with a pre-cast half-deck deck and a horizontal fastener that is easy to work, and a slab concrete is installed by pouring into a steel girder and a precast half- And the precast half deck deck are not required separately, but the workability and construction workability of the precast half deck deck is very excellent. Therefore, while taking advantage of the precast half deck deck made of UHPC, The present invention aims to solve the problem of providing a composite composite girder bridge construction method using a precast semi-sectional deck capable of rapidly constructing a bridge while reliably ensuring the composite performance of a cast half section deck.

According to another aspect of the present invention, there is provided a composite composite girder bridge construction method using a precast half section deck,

(a) mounting a plurality of steel girders constructed with a lower flange and abdomen in a transverse direction to a bridge substructure; (b) setting a precast half-section deck protruding downward from the bottom of both end portions of the top plate and including both lateral connection blocks formed thicker than the top plate, between the tops of the belly portions of the steel girder; (c) a horizontal hole formed in both side connecting blocks of the precast half section deck set with the abdomen of the steel girder interposed therebetween, and a horizontal fastener passing through the fastening holes formed at the upper end of the abdomen, A step of first synthesizing a girder and a precast half section deck; And (d) secondarily synthesizing a steel girder and a precast half-section deck by arranging a transverse reinforcement on the top surface of the precast half-section deck and placing and curing the bottom plate concrete (C) wherein the steel girder of step a) is formed of a "ㅗ" -shaped section composed of an abdomen extending upward from the center of the upper flange, excluding the upper flange, and the side connecting block of step (b) UHPC is installed at the upper part of the upper part of the lower part of the steel girder so that the side connection block made of UHPC is positioned at the connection part between the upper end of the steel girder and the precast half section deck, This eliminates the need for shear connectors for composite girders and precast half deck decks.

According to the present invention, the steel composite girder bridge construction method using the precast semi-section deck is capable of precisely controlling the quality by making the constituent members precast in the factory production and greatly reducing the field production process, It is possible to obtain structural durability by applying recently developed ultra high performance high strength concrete (UHPC), and it is possible to provide a method of constructing a composite composite girder bridge using a precast semi-section deck having excellent workability and workability .

FIG. 1A is a perspective view showing a connection state of a conventional girder, a precast UHPC bottom plate,
1B is a perspective view and a connection diagram of a conventional precast deck,
1C is a construction cross-sectional view of a conventional steel composite bottom plate bridge,
1D is a perspective view of a composite steel girder in a conventional bridge superstructure,
Figs. 2A and 2B are perspective views of a steel girder and a precast half section deck according to the present invention. Fig.
FIGS. 3A, 3B, and 3C are flowcharts of a method of constructing a composite composite girder bridge using the pre-cast half section deck 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.

[Steel girder (100) of the present invention and precast semi-section deck (200)]

FIGS. 2A and 2B are perspective views illustrating a steel girder 100 and a precast half-section deck 200 according to the present invention.

As shown in FIG. 2A, the steel girder 100 is a steel girder made up of a lower flange 110 and abdomen 120, which is an "ㅗ" cross-section. Unlike a normal I-shaped plate girder, Therefore, it is possible to economically manufacture the upper flange without the upper flange.

Further, when the middle of the abdomen of the I-shaped cross-section of the steel girder is cut and used as two steel girders 100, a very economical steel girder 100 can be manufactured.

In this steel girder 100, it can be seen that two steel girders 100 are arranged apart from each other with reference to FIG.

The lower flange 110 is a flange member in the form of a horizontal plate,

The abdomen 120 extends upward from the center of the upper surface of the lower flange 110 and has an upper end in the form of a vertical plate having a length extending upward from the top surface of the precast half section deck 200 to be described later.

The upper surface of the abdomen 120 is formed with a plurality of front end grooves 130 in the longitudinal direction so that the steel girder 100 and the precast half section deck 200 And to ensure sufficient synthesis performance.

Further, a plurality of fastening holes 140 are formed at the upper end of the abdomen 120 located below the upper surface so that the horizontal fastener 300 described later can be passed therethrough.

As shown in FIG. 2B, the precast half-deck deck 200 is a UHPC bottom plate manufactured by using a high-performance high-strength concrete having a compressive strength of 150 to 180 MPa or more, 100) with a horizontal fastener 300 using bolts and nuts (primary synthesis).

The precast semi-sectional deck 200 is disposed between the upper ends of the belly 120 of the two steel girders 100 so that the side connecting blocks 210 are integrally formed with the upper plate 220.

It can be seen that the precast semi-sectional deck 200 is fabricated such that the side connecting block 210 is protruded downward at both bottom ends of the top plate 220. In the middle of the side connecting block 210, The horizontal hole 230 is formed to pass through.

The upper plate 220 basically serves as a mold when the slab concrete is laid and the side connecting block 210 is formed by first combining the steel girder 100 with the precast half section deck 200, And the lateral connection block 210 made of UHPC and having a relatively large thickness is disposed at the connecting portion of the steel girder 100 so that the upper end of the abdomen portion 120 of the steel girder 100 and the precast It is also possible to eliminate the need for a separate reinforcing member to reinforce the connection site rigidity of the half section deck 200.

It is noted that a plurality of connecting reinforcing bars 240 are formed on the upper surface of the upper plate 220 for the purpose of combining with the slab concrete.

2B, it can be seen that the both side connecting blocks 210 of the different precast semi-sectional decks 200 are disposed adjacent to both sides of the upper end of the abdomen of the two steel girders 100, It can be seen that the horizontal hole 230 formed in the lateral connecting block 210 of the precast semi-sectional deck 200 is arranged to communicate with the other horizontal hole 230.

One precast half section deck 200 is set between the steel girders 100 on the basis of the two steel girders 100,

Each of the precast half-section decks 200 is disposed adjacent to both sides of the upper portion of the abdomen of the steel girder 100,

The horizontal holes 230 formed in the respective precast half section decks 200 and the horizontal fasteners 300 passing through the fastening holes 140 formed at the upper end of the abdomen of the steel girder 100, It can be seen that it is a structure.

The steel girder 100 and the precast half section deck 200 are firstly synthesized by the horizontal fastener 300 so that the mechanical fastening of the steel girder 100 and the precast half section deck 200 The workability and the workability can be secured by the joining structure by the joining structure,

In addition, since the side connection block 210 is manufactured in the same factory as UHPC, which is the same as the upper plate 220, quality control is easy,

Separate processes for joining the steel girder 100 and the precast half section deck 200 in the field and the process of joining the joining members (such as rebar) are eliminated to provide a faster and more efficient steel girder and precast half section deck So that it is possible to perform the synthesis.

In addition, a plurality of horizontal fasteners 300 are installed at the upper part of the upper portion of the lower portion of the steel girder 100, and the steel girder and the side connecting block 210 are connected to each other by the same fastening force. (210), it is not necessary to reinforce it considering the local stress.

In order to connect the steel girder 100 to the precast half-deck deck 200, a plurality of shear connectors and connecting bars are arranged in a conventional connection area as shown in FIG. 1C, ,

Since the present invention does not include the shear connection member and the connecting portion reinforcing bars, it is possible to provide a combined structure of the economical steel girder and the precast semi-sectional deck 200.

In addition, since the precast half section deck 200 is manufactured in a factory, quality control is easy, and since the horizontal fastener 300 uses a connecting bolt, the coupling structure with the steel girder becomes very simple, It becomes very efficient.

Further, the connection bolts used as the horizontal fastener 300 are inserted into the horizontal holes formed in the both-side connection block 210 so that the head and the bolt are positioned inside the both-side connection block 210, So that it is preferable for the appearance and the like.

[Method of constructing steel composite girder bridge using precast semi-section deck of the present invention]

FIGS. 3A, 3B and 3C show a flowchart of a method of constructing a composite composite girder bridge using the precast semi-section deck of the present invention.

First, as shown in FIG. 3A, a steel girder 100 is mounted on a bridge substructure 400, and a precast half-section deck 200 is firstly synthesized between steel girders 100.

In this case, the steel girder 100 is composed of a lower flange 110 and a waist portion 120 having a "ㅗ" cross section, and a plurality of front end grooves 130 are formed continuously on the upper side of the abdomen portion, It can be seen that a plurality of fastening holes 140 are formed so that the horizontal fastening tool 300 can pass through.

The steel girder 100 is lifted and mounted on the bridge substructure 400. The steel girder 100 is extended in the longitudinal direction (diagonal direction), and a plurality of the steel girders 100 are spaced apart from each other in the lateral direction .

At this time, a bridge support (not shown) can be used to mount the girder inner side lateral distance and the length of extension of the precast semi-section deck 200 to correspond to each other.

The precast half-section deck 200 is formed by projecting downwardly a lateral connection block 210 downward at both ends of the upper plate 220. A horizontal hole 230 is formed in the middle of the lateral connection block 210 And is set to be in communication with the fastening hole 140 of the steel girder 100.

And the upper surface of the upper plate is formed such that a plurality of connection reinforcing bars 240 are formed to expose a large number of connection reinforcing bars 240 for the purpose of combining with the slab concrete (C).

Next, as shown in FIG. 3B, the precast semi-sectional decks 200 set between the steel girders 100 are fastened to each other by using the horizontal fastener 300.

The horizontal fastener 300 uses a connecting bolt and a nut and the horizontal fastener 300 is connected to the horizontal hole 230 of the connected side connecting block 210 and the fastening hole 140 of the steel girder 100 So that the upper end of the abdominal portion of the steel girder is compressed between the upper ends of the side connecting blocks 210 to be synthesized first.

The abdomen portion 120 of the stronghold 100 is set so as to protrude upward from the upper surface of the top plate 220 of the precast half section deck 200 and the upper surface of the abdomen of the strongholder 100 is set in the front end groove 130 Is exposed and is embedded in the slab concrete to be described later.

The transverse reinforcing bars 500 and the transverse reinforcing bars 500 are connected to each other so that the upper surface of the connecting reinforcing bars 240 and the steel girder 100 pass through the front end grooves 130, Thereby ensuring convenience.

At this time, the transverse reinforcing bars 500 have a function of joining the upper plate 220 of the precast semi-sectional deck 200 adjacent to the upper plate 220 to each other and a function of the inner reinforcing bars of the slab 600.

Next, as shown in FIG. 3C, the slab 600 is installed by installing a not shown lateral mold (not shown) and placing and curing the slab concrete C inside the mold.

In this regard, since the slab concrete C is laid on the upper surface of the precast half section deck 200, it can be seen that the precast half section deck 200 serves as a mold for placing the slab concrete C as a half deck have.

The slab 600 serves to synthesize the precast half deck deck 200 and the steel girder 100 so that the precast half section deck 200 and the steel girder 100 can be integrally moved ,

There is no reason to separately consider reinforcement of the connecting portion between the steel girder 100 and the precast half section deck 200,

Since the slab concrete C can be formed to have a thickness required for the slab by the slab thickness, the section of the precast half-section deck 200 can be minimized,

Since the precast half section deck 200 is manufactured by using the UHPC, its own weight is very small, which is very advantageous for setting on the steel girder 100 and for joining by the horizontal fastener.

Further, the primary synthesis of the steel girder 100 by the horizontal fastener 300 and the precast half-section deck 200 is achieved by mechanically fastening the steel girder 100 and the precast half section deck 200 in the transverse direction And the slab concrete C is secondarily synthesized both in the longitudinal direction and in the transverse direction by the primary composite steel girder 100 and the precast semi-sectional deck 200.

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: Steel girder 110: Lower flange
120: abdomen 130: shear groove
140: fastening hole 200: precast half section deck
210: side connecting block 220: upper plate
230: horizontal hole 240: connection reinforcing bar
300: horizontal fastener 400: bridge substructure
500: transverse reinforcement 600: slab
C: Slab Concrete

Claims (10)

(a) mounting a plurality of steel girders (100) comprising a lower flange (110) and abdomen (120) to a bridge substructure (400) in a transverse direction;
(b) a precast semi-sectional deck 200 protruding downward from both bottom ends of the top plate 220 and including both lateral connection blocks 210 formed thicker than the top plate 220, Setting between the abdominal upper end of the abdominal region;
(c) a horizontal hole 230 formed in both side connection blocks 210 of the precast half-deck deck 200 set with the abdomen 120 of the steel girder 100 interposed therebetween, (100) and the precast half-section deck (200) with a horizontal fastener (300) which is inserted into the side connecting block (210) And
(d) A transverse reinforcing bar 500 is placed on the upper surface of the precast half-deck deck 200 and the bottom plate concrete C is laid and cured so that the steel girder 200 and the precast half- And a second step of synthesizing,
The steel girder 100 in the step (a) uses a "ㅗ" -shaped cross section composed of the abdomen 120 extending upward from the center of the upper surface of the lower flange 110 without the upper flange,
The side connection block 210 of the step (b) may be one which is integrally fabricated in the same UHPC as the upper plate 220, and is set between the upper ends of the abdomen 120 of the steel girder 100 For the synthesis of the steel girder and the precast semi-section deck such that the side connection block 210 made of UHPC is positioned at the connection portion between the upper end of the abdomen portion 120 of the steel girder 100 and the precast half- Steel composite girder bridge construction method using precast half section deck without shear connection material. The method according to claim 1,
In step (a), the steel girder 100 is formed such that a plurality of front end grooves 130 are formed on the upper surface of the abdomen 100, and the abdomen is formed on the upper plate of the precast semi-section deck 200 set in step (b) 220) extending upward from the upper surface of the slab concrete (d) to be embedded in the slab concrete in step (d). The method according to claim 1,
The pre-cast half-deck deck 200 in the step (b) is provided with a pre-cast semi-section deck 200 on which a connecting reinforcing bar 240 is extended from the inside to protrude for the purpose of combining with the slab concrete 300, METHOD FOR CONSTRUCTION OF STEEL SYNTHETIC GARDER BRIDGE USING The method of claim 3,
In the step (d), the transverse reinforcing bar 500 is disposed to penetrate the upper surface of the connecting reinforcing bar 240 and the front end groove 130 of the steel girder 100 to serve as an inner reinforcing bar of the slab concrete. Steel composite girder bridge construction using deck. The method according to claim 1,
The precast half section deck 200 in the step (b) has a horizontal hole 230 arranged between two steel girders 200 so as to be horizontally connected to each other, and a precast half section Steel composite girder bridge construction using deck. The method according to claim 1,
In the step (c), the horizontal fastener 300 passing through the horizontal hole 230 and the fastening hole 130 and fastened to the side of the both-side connecting block 210 is fastened to the steel girder 100 and the precast half section deck 200 are mechanically fastened to form a primary composite. The method according to claim 6,
In the step (b)
The primary synthesis of the steel girder 100 by the horizontal fastener 300 and the precast half-section deck 200 synthesizes the steel girder 100 and the precast half section deck 200 transversely,
The slab concrete C in the step (d) includes a pre-cast half section deck for synthesizing the primary composite steel girder 100 and the precast half section deck 200 in the longitudinal direction and the transverse direction in the second order Steel composite girder bridge construction method. The method according to claim 6,
The connection bolts used as the horizontal fastener 300 are inserted into the horizontal holes formed in the both-side connection block 210, and the head part and the bolt part are positioned inside the both-side connection block 210 to be closed. Steel composite girder bridging method using semi - section deck. delete delete

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