KR100550241B1 - Girder bridge - Google Patents

Abstract

It is to provide a girder bridge which can increase the span of the bridge girder and reduce the height of the girder.

The girder bridge 1 is formed with a bridge girder 3 in which a main girder 5 provided over alternating bridges 2 is bound in a width direction, and the main girder 5 has a steel frame 13 embedded therein. The girder material 9 made of concrete is continuously joined in the longitudinal direction, and an initial stress is applied by the inner cable 12, and the steel 13 has an outer cable 4 Initial stress is given by this.

Bridge girder, girder height, shift, main girder, steel frame.

Description

Girder Bridge {GIRDER BRIDGE}

(1) is a front view of a girder bridge, (2) is a partially omitted side view.

2 is a conceptual diagram of the girder bridge, (2) is a sectional view of the girder bridge, and (3) is a sectional view of the recess.

(1) is sectional drawing of the main girder end part, (2) is AA sectional drawing of (1), (3) is one side view of the main girder of an end part, (4) is a Another side view.

(1) is sectional drawing of the center part of a main girder, (2) is sectional drawing along the B-B line of (1), (3) is sectional drawing along the C-C line of (1).

5 is a front view of a conventional girder bridge.

<Explanation of symbols for the main parts of the drawings>

1, 23: girder bridge, 2, 26: shift, 3, 25: bridge girder, 4: outer cable, 5, 24: main girder, 6: transverse cable, 7: between main girder, 8: site Concrete slab, 9, 28: girder, 10: laminate, 11: collar, 12, 29: inner cable, 13: steel, 14: fixing plate, 15: bonding plate, 16: connecting plate, 17: steel plate, 18: concrete, 19: stud bolt, 20: flange, 21: collar portion, 22: shear key, 27: pier.

The present invention relates to a girder bridge.

As shown in FIG. 5, in the conventional girder bridge 23, a bridge girder 25, in which a main girder 24 is bundled in the width direction, is provided between the alternating bridges 26, and a central portion thereof is a pier ( 27). In addition, the main girder 24 is formed by connecting the girder material 28 made of concrete in the longitudinal direction, and is provided with an initial stress to the inner cable 29.

However, the span of the girder bridge as described above has been limited to 30 to 40 m because the bending moment due to the self weight of the bridge girder is increased. Moreover, since the limit of the girder height span ratio (the height of the girder: the width of the girder) is 1 / 17.5, it was difficult to construct at the point where the girder height was limited.

The present invention has been made in view of the above problems, and an object thereof is to provide a girder bridge which can increase the span of the bridge girder and reduce the height of the girder.

The gist of the girder bridge of the present invention for solving the above problems, the main girders provided over the alternation is tied in the width direction to form a bridge girder, the main girder is made of concrete girder built in steel frame continuous in the longitudinal direction It is bonded to the initial stress is given by the inner cable, the steel frame is characterized in that the initial stress is given by the outer cable. In addition, the girder material has a cross-sectional I shape, and includes an end plate having a joining plate having the same width as the flange in the collar portion protruding on both sides of the web. In addition, the outer cable includes wired through the collar portion of the girder material. In addition, the main girder is to be joined by a horizontal cable wired to the joining plate, it is to include that the site concrete is poured between the main girder wired by this horizontal cable.

The hoisting load is applied to the bridge girder by the initial stress applied to the steel frame of the main girder, so that the live load is mainly eliminated. In addition, since the self-weight of the bridge girder is reduced, the span can be increased (50 to 70 m), and a conventional bridge can be omitted. In addition, the limit of the girder height span ratio (height of the girder: the width of the girder) can be 1/30, and the height of the girder can be reduced. Horizontal cables are wired to the joint plates formed at the same width as the flanges at the collar, and field concrete is poured between the main girders to which the horizontal cables are wired, thereby forming a horizontal girder at the joint plates in which the initial stress is applied. can do. Moreover, since the collar part which penetrated the outer cable becomes a bundle material, a main girder can be used as a long suspension. In addition, the steel frame of the main girders made of long suspension is not buckled because it is integrated with concrete.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the girder bridge of this invention is described with reference to drawings. As shown in FIG. 1, the gerber bridge 1 is provided with a hoisting load by the external cable 4 such as a PC steel wire and a PC stranded wire to the bridge girder 3 between the shifts 2. It is composed.

As shown in Figs. 2 to 4, the bridge girder 3 is configured by binding the six main girders 5 in the width direction with lateral cables 6 such as PC steel wires and PC stranded wires. The main girder 5 is formed by joining the joining plate 10 with a girder material 9 formed of steel frame 13 and concrete 18 in a cross-sectional shape of I, and an initial stress is applied by the inner cable 12. have. This bonding plate 10 is formed in the same width | variety as the flange 20 by the collar part 11 which protruded on the both sides of the web of the girder material 9, in order to prevent the damage of the junction part by a cyclic load. Moreover, between the adjacent joining plates 7, the site concrete 8 is poured to form a lateral girder 21, and an initial stress is applied to the lateral girder 21 by the lateral cable 6.

On the other hand, the steel frame 13 embedded in the flange 20 of the girder material 10 is formed of two L-shaped steel sheets 17 joined by a connecting plate 16, and this L-shaped steel sheet 17 The stud bolts 19 protruding from the lower surface of the lower surface are integrated with the concrete 18. In addition, at one end of the steel frame 13, a fixing plate 14 on which an end of the outer cable 4 is fixed is provided, and a joining plate 15 is provided at the other end, and these are overlapped and joined together by a shear key 22. It is. Therefore, the steel frame 13 of each girder material is integrally joined, and is like one steel frame. The steel frame 13 may be embedded not only in the upper flange but also in the entire girder material 9, that is, the upper and lower flanges 20.

Moreover, the said outer cable 4 is wired through the collar part 11 of both sides of the main girder 5, and both ends are tension-fixed to the fixing plate 14 of the steel frame 13, and the main The girder 5 has a long suspension with the collar 11 as a bundle material, and a hoisting load is applied to the entire bridge girder 1.

The hoisting load is given to the bridge girder by the initial stress applied to the steel frame of the main girder, so that the live load can be mainly eliminated.

Since the self weight of the bridge girder is reduced, the span can be increased (50 to 70 m), and a conventional bridge can be omitted.

Girder height The limit of span ratio (height of girder: width) can be set to 1/30, and the height of girder can be made small.

Lateral girders given initial stress to the joining plate may be formed as bridge girders.

Since the collar part through which the outer cable penetrates becomes a bundle material, the main girder can be made into the long suspension amount.

The steel frame of the long beam main girder is not buckled because it is integrated with concrete.

Claims (4)

The main girders installed over the bridges are tied in the width direction to form a bridge girder, and the main girder is joined to the longitudinal girders of steel in which concrete is embedded An initial stress is imparted by an inner cable, and an initial stress is imparted to the steel frame by an external cable. The method of claim 1, The girder material has a cross section I-shape, and a girder bridge is formed at an end portion with a joining plate having a width equal to the flange at collar portions protruding on both sides of the web. The method of claim 2, And the outer cable is wired through the collar of the girder material. The method according to any one of claims 1 to 3, And the main girder is joined by a horizontal cable wired to a joining plate, and field concrete is poured between the main girders to which the horizontal cable is wired.

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