KR100691664B1 - Method of construction for girder bridge - Google Patents

Abstract

The present invention provides a method for constructing a girder bridge which can increase the span of the bridge girder and reduce the height of the girder.

In the method for constructing the girder bridge of the present invention, a plurality of beam material units (3) having support pressure flanges (7) at both ends are joined to each other via a joining plate (11) in the longitudinal direction, and wired in the longitudinal direction. The inner cable 5 is tensioned with a predetermined force to form a principal beam 1 to which prestress is applied, and between the fixing plates 12 at both ends of the main beam 1. After passing through the support pressure flange 7 of the beam material unit to wire the external cable 14, the main beam 1 is alternately arranged between the bridges 2 in the widthwise direction 16. And a plurality of plural and the gap portion 16 is blocked by cast-in-place concrete 17 or precast concrete member 18 to form a bridge girder 21, and the bridge After binding the main beam 1 with the horizontal cable 20 wired in the width direction of the girder 21, the external cable 14 is disconnected. Positive tension is applied to prestress the entire bridge girder 21.

Girder bridge, prestress, beam ash unit, main beam, bridge girder

Description

How to Build a Girder Bridge {METHOD OF CONSTRUCTION FOR GIRDER BRIDGE}

1 is a cross-sectional view in the horizontal direction of the main beam.

2 is a front view of the main beam in which the internal cable is wired.

3 is a cross-sectional view of the beam material unit.

4: (1) is a front view of the junction part of a beam material unit, (2) is a top view.

5 is a front view of the main beam in which the external cable is wired, 2 is a sectional view in the horizontal direction of the junction of the beam material unit, and 3 is a front view of the junction of the beam material unit.

6 is a cross-sectional view of the beam material unit in which the end of the external cable is fixed.

FIG. 7: (1) is a front view which installed the beam material unit between turns, (2) is a cross section of the same horizontal direction.

8 is a cross-sectional view of the bridge girder.

9 is an enlarged view of FIG. 8.

(1) is a front view of a continuous girder bridge, (2) is sectional drawing in the same horizontal direction.

11 is a front view of the main beam in which the internal cable is wired, and (2) a front view of the main beam in which the external cable is wired.

12 is a sectional view of the junction of the main beam.

Fig. 13 is a front view of the main beam in which one external cable is wired, and Fig. 2 is a sectional view of the junction of the main beam.

14 is a front view of a conventional girder bridge.

The present invention relates to a method for constructing a girder bridge.

As a conventional girder bridge, there exists invention of Unexamined-Japanese-Patent No. 2003-213622, for example. As shown in Fig. 14, a bridge girder 31 formed by binding a principal beam 30 in the width direction is provided between the abutments 32, the center portion of which is a bridge ( There is a girder bridge 34 supported by pier 33.

The main beam 30 is formed by connecting a beam material unit 35 made of concrete in the longitudinal direction.

However, the span of the girder bridge as described above has a limit of 30 to 40 m because the bending moment due to the weight of the bridge girder increases. In addition, since the limit of the girder height span ratio (height of the girder: the width of the girder) was 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 method for constructing a girder bridge which can increase the span of the bridge girder and reduce the height of the girder.

According to the construction method of the girder bridge of the present invention, a plurality of beam material units having support pressure flanges at both ends are joined to each other via a joining plate in the longitudinal direction, and the inner cable wired in the longitudinal direction is tensioned with a predetermined force ( After forming the main beam to give prestress, and through the supporting pressure flange of the beam material unit between the fixing plates in the both ends of the said main beam, and wiring an external cable, the said main beam is alternately widened. Transverse cables provided with a plurality of suitable gaps in the direction, the bridges being covered with cast-in-place concrete or precast concrete members to form bridge girders, and wired in the width direction of the bridge girders. After binding the main beams, the external cables are tensioned with a predetermined force to impart prestress to the entire bridge girder. The features.

The girder bridge construction method includes joining a plurality of beam material units having support pressure flanges at both ends via a joining plate in the longitudinal direction, and tensioning the internal cable wired in the longitudinal direction with a predetermined force to reduce prestress. After forming the provided main beam, and passing the support pressure flange of the beam material unit between the fixing plates at both ends of the main beam to wire an external cable, a plurality of the main beams are provided with appropriate gaps in the width direction between the shifts. Bridge gaps are formed by blocking the gaps with the field-cut concrete or precast concrete members, and the main beams are bound by the transverse cables wired in the width direction of the bridge girders, and the external cables are tensioned with a predetermined force. Are installed between the piers in turn, and then these bridge girders are connected. Shall be.

Girder bridge with a span of 70m and a span ratio of girder height of about 1/30 can be constructed, and a tensioning chord beam is introduced by introducing tension by an external cable. There is no integral buckling, and it becomes a girder bridge with high toughness.

A plurality of beam materials formed by joining a plurality of beam material units provided with supporting pressure flanges at both ends by internal cables are alternately provided in the width direction between shifts to form a bridge girder, and the wires are wired in the width direction of the bridge girder. After the beam material is bound by the cable, the external cable is tensioned with a predetermined force to impart prestress to the entire bridge girder, thereby increasing the span of the bridge girder and constructing a girder bridge having a smaller girder height.

The construction method of the girder bridge of this invention is demonstrated based on a single girder bridge. The construction method of this girder bridge is performed by providing the main beam 1 shown in FIG. 1 between the shifts 2, and manufactures this main beam 1 first. As shown in Fig. 2, the main beam 1 is produced by being bound by the inner cable 5 in which the five beam material units 3 joined in the longitudinal direction are wired in the longitudinal direction, and the inner cable 5 Predetermined prestress is given by.

In addition, as shown in FIGS. 2 and 3, six internal cables 5 are wired over the entire length of the main beam 1 over the entire length, and two wires over the three beam material units 3 in the center portion. It is. In this way, the load suspended on the main beam 1 by the tension of the inner cable 5 wired to the upper and lower parts of the main beam 1 and the steel frame (hereinafter referred to as steel frame) 6 embedded in the upper portion Generated and canceled out by the stress of the dead load.

Moreover, the beam material unit 3 is a concrete block of cross section I type | mold provided with the support pressure flange 7 at both ends, and the steel frame 6 which consists of two L-shaped steel plates 8 is embedded in the upper part, A stud bolt 10 protrudes from the lower surface of the steel frame 6 so as to be integrated with the concrete 9. Moreover, as shown in FIG. 4, the joining plate 11 is provided in both end surfaces of the steel frame 6, and at the other end surface of the steel frame 6 in the beam material unit 3 of both ends, a fixing plate ( 12) is installed. When the joining plate 11 is joined by a shear key 13 to connect the steel frames 6 of each beam material unit 3 to each other, it is as if one main beam 1 is embedded with one steel frame. )

Next, as shown in FIG. 5, two sets of external cables 14 are wired over the entire length of both sides of the main beam 1. This external cable 14 is routed through the through hole 4 of the support pressure flange 7 of the beam material unit 3, and both ends thereof are fixed to the fixing plate 12 of the beam material unit (FIG. 6). Reference). In addition, this external cable 14 is only wiring, and is not still tense.

Thus, after the main beam 1 which the inner cable 5 and the outer cable 14 were wired was completed, as shown in FIG. 7, it hangs with a crane and installs between the shifts 2, and so on. Then, six of the main beams 1 are provided with appropriate gaps 16 in the width direction of the alternate 2.

Next, the gap 16 between these main beams is blocked by the field-stretched concrete 17 or the precast concrete member 18 to form a top plate 19 having a predetermined width.

Next, as shown in FIG. 8, the bridge girder 21 is formed by binding these six main beams 1 by the horizontal cable 20 wired in the horizontal direction. The bridge girder 21 is provided with a predetermined prestress in the transverse direction with the transverse cable 20.

When the bridge girder 21 is completed, when the external cable 14 of each main beam 1 is tensioned with a predetermined force to impart prestress, the bridge girder 21 becomes a tensioned cord beam and a suspended load is given. Corresponds to the live load. Thus, if the whole bridge girder 21 (live load part) can be lifted integrally, the girder bridge 22 without buckling and with high toughness will be provided.

Next, a method of constructing a continuous girder bridge will be described. The method of constructing the continuous girder bridge is also substantially the same as the method of constructing the single girder bridge. As shown in Fig. 10, six main beams 1 are provided between the alternating portions 2 and the pier 26 to form a bridge girder. After forming 21 (as shown in FIG. 7), the same bridge girders 21 are formed between the following piers 26 in the same manner as described above. The bridge girders 21 are sequentially formed between the bridge piers 26, and then the bridge girders 21 are joined to each other to form a continuous girder bridge 23.

As shown in FIG. 11, the main beam 1 is the same as that shown in FIG. 2 above, and the inner cable 5 corresponding to the dead load and the outer cable 14 corresponding to the live load are wired.

Bonding of the bridge girders 21 is a joint between the respective main beams 1, and as shown in FIG. 12, the steel frame 6 of the main beam 1 provided on the bridge 26 is connected to the connecting member 28. And the ends of the main beam 1 are joined to the PC steel bar 29 or the PC cable 29, and then the field-stretched concrete 27 is poured between the main beams 1.

In addition, in FIG. 13, the external cable of the upper side is made into one massive external cable 24, and after joining the bridge girder 21 together as mentioned above, the pole is extended over the full length of this bonded bridge girder 21. As shown in FIG. One external cable 24 is wired and tensioned by a predetermined force to impart prestress to correspond to the live load of the girder bridge 22.

In this way, a buckling-free, high-tough girder bridge can be constructed, and thus a girder bridge can be constructed that traverses rivers, roads, and railways of 45 m or more, and whose girder height is limited.

Claims (2)

delete A main beam which is bonded to a plurality of beam material units having supporting pressure flanges at both ends via a joining plate in the longitudinal direction, and is prestressed by tensioning the inner cable wired in the longitudinal direction with a predetermined force. (principal beam) is formed, the steel frame embedded in the upper part of the beam material unit is connected to each other by a connecting material, and the external cable is wired through the supporting pressure flange of the beam material unit between the fixing plates at both ends of the main beam, After repeating the above process a plurality of times to produce a plurality of main beams, the plurality of main beams are provided between alternating bridges with appropriate gaps in the width direction, and cast-in-place the gaps of the main beams. ) Bridge girder formed by concrete or precast concrete member, and wired in the width direction of the bridge girder. After binding the main beam by the cable, the external cable in the formed bridge girder is tensioned with a predetermined force to impart prestress to the main beam, The process is repeated between the following shifts to form the next bridge girder, which then connects the steel frame of each main beam with a connecting material, and joins the ends of the main beam with a PC steel bar or PC cable to bridge bridging. Are bonded to each other, and then cast the field-stroke concrete between the main beams, wiring the grand external cable over the entire length of the continuous bridge girder bonded, and give the prestress by tensioning the grand external cable. How to build a continuous girder bridge.

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