KR101965303B1 - Parapet direct connecting girder type bridge - Google Patents

Abstract

The present invention relates to a half-length bridge in which a chute wall block 20 at an upper end of an alternation 10 and an alternate side 10 side end of a girder 30 are integrated to omit a bridge entrance stretch joint, The concrete is filled between the ends of the girder 30 and the front wall of the chute block 20 so that the girder 30 and the chute block 20 are joined to each other.
The present invention allows the chest wall block 20 and the girder 30 to be formed without any complicated process of preforming the concave portion 29 in the chest wall block 20 of the half- It is possible to achieve a simple, tight, and rigid connection between the components 30 and 30, thereby simplifying the manufacturing process of each member including the chest wall block 20 and the joining process between the members.

Description

{PARAPET DIRECT CONNECTING GIRDER TYPE BRIDGE}

The present invention relates to a half-length bridge in which a chute wall block 20 at an upper end of an alternation 10 and an alternate side 10 side end of a girder 30 are integrated to omit a bridge entrance stretch joint, The concrete is filled between the ends of the girder 30 and the front wall of the chute block 20 so that the girder 30 and the chute block 20 are joined to each other.

The half-body bridge is constructed by integrating the girder 30 supported by the interlocking device 11 at the upper end of the shift 10 and the chute block 20 installed at the upper rear side of the shift 10, A connecting slab 12 of a bridge entrance road is connected to the upper rear portion of the girder 30 so as to omit the expansion joint between the upper plate slab 13 on the upper surface of the girder 30 and the chute wall block 20 and the connecting slab 12, A deformation backfill section is formed in the back ground of the block 20 to absorb the deformation of the girder 30 and the slab 13 of the upper plate.

By omitting the expansion joint of the entrance part of the bridge, it is possible to improve the feeling of driving and reduce the noise, to prevent the structural transformation of the impact applied to the expansion joint device when passing through the vehicle, It is possible to prevent the corrosion of the calibration apparatus 11 due to a snow remover or the like. In the prior art related to such a semi-solid bridge, Patent No. 1389285 can be mentioned.

FIG. 1 schematically shows a basic structure of a conventional half-girder bridge including the patent No. 1389285. As shown in the drawings, in the conventional half-girder bridge, the girder 30 for supporting the slab 13 of the upper plate, I.e. the end of the alternating 10 side of the girder 30 is supported by the co-ordinate apparatus 11 at the top of the alternator 10 with the chute wall block 20 fixed and joined.

The integral connection between the end of the girder 30 on the alternate 10 side and the chest wall block 20 is achieved by the enlarged portion in the ellipse of Fig. 1 and the end portion of the girder 30 formed on the chest wall block 20 The concrete is inserted and filled in the concave portion 29 so that the end portion of the girder 30 is embedded in the chest wall block 20. In such a conventional half- 20 and the girder 30 have the following problems.

2, in the conventional half-piece type bridge, the girder 30 and the chest wall block 20 are basically joined to the front surface of the chest wall block 20 by the same number It is necessary to form the concave portions 29 of the girder 30 and the chute wall block 20 before the filling concrete is poured, which is a practical bonding process between the girder 30 and the chute block 20, There has been a problem in that it is necessary to accurately insert or combine the two.

That is, it is necessary to precede the step of putting the end portion of the girder 30 in the correct position and posture into the recessed portion 29 formed in the chest wall in a state in which the chest wall is installed in the alternation 10, The girder 30 has a large span of the span of the girder 30. This allows the girder 30 to have both end portions of the girder 30 at a predetermined distance in the recessed portion 29 formed in each of the chest wall blocks 20 on both sides of the girder 30. [ It is due to the fact that it must be correctly injected.

If one end of the girder 30 is temporarily fixed to the shift 10, the bridge underground or other hypothetical situation and only the other end of the girder 30 is bound, the girder 30 is moved to the chute block 30 20, it is possible to easily perform the installation work of the girder 30. However, in the conventional half-girder bridge, since the end portion of the girder 30 needs to be accurately inserted into the recessed portion 29 at a time, Temporary mounting and position adjustment work was practically impossible.

When the size of the girder 30 is slightly adjusted or the number of the girders 30 is increased or decreased as the planning specifications of the bridges are changed, the chute block 20, in which the girders 30 are formed, There was also a problem that must be produced separately every time.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems and it is an object of the present invention to provide an apparatus and a method for connecting a chute block 20 at an upper end of an alternator 10 and an end of a girder 30, A plurality of girders 30 are provided on the front wall of the chest wall block 20 so that the girder 30 is provided between the end portions of the girder 30, The concrete is inserted and cured in the space between the front wall surfaces of the chest wall block 20 so that the girder 30 and the chest wall block 20 are bonded to each other.

A plurality of fixing bars 21 are provided on the front wall of the chest block 20 and the fixing bars 21 are positioned between the girders 30 joined to the front wall of the chest block 20, (21) is embedded in a concrete placed in a space between the end portions of the chest wall block (20) and the front wall surface of the chest wall block (20). The chest wall block (20) 25 of the chest wall block 20 are formed by being recessed toward the other side of the girder 30 and the inner lower end of the binding concave portion 25 is formed on the front wall surface of the chest wall block 20 And the widening recessed portion 25 is formed at its inner core portion with a widened portion 26 having a widened planar width.

The fixation bar 21 is a U-shaped reinforcing bar and the fillet nut 22 is embedded in the front wall of the chest wall block 20. One end of the fusion splice 23 is coupled to the fillet 22, And the other end of the spindle 23 is fastened to the distal end of the fixing steel bar 21 by a coupler 24.

The present invention allows the chest wall block 20 and the girder 30 to be formed without any complicated process of preforming the concave portion 29 in the chest wall block 20 of the half- It is possible to achieve a simple, tight, and rigid connection between the components 30 and 30, thereby simplifying the manufacturing process of each member including the chest wall block 20 and the joining process between the members.

In particular, the cost of manufacturing the chest wall block 20 made of precast concrete can be drastically reduced, and the chest wall block 20 having the same structure can be applied to the girders 30 of various types and sizes, It is possible to provide compatibility with the chest wall block 20, thereby ensuring ease of installation, shortening the air, and reducing the construction cost.

FIG. 1 is a cross-sectional view of a conventional half-
2 is an exploded perspective view of a conventional half-
3 is a schematic view of the structure of the present invention
4 is an exploded perspective view of the present invention under construction
5 is an explanatory view
FIG. 6 is an illustration of a formwork installation state for joining the girder and the chest wall block of the present invention
Fig. 7 is a partially cutaway perspective view of the present invention chest wall block,
8 is a partially cutaway perspective view of a chute wall block according to the present invention to which a detachable fixing bar is applied.
Fig. 9 is a partially cutaway perspective view of the chest wall block of the present invention,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A detailed configuration of the present invention will be described with reference to the accompanying drawings.

3 is a schematic view of a basic structure of a half-body bridge to which the present invention is applied. As shown in FIG. 3, a chute block 20 is installed at an end portion of the girder 30 constituting the present invention, As shown in the excerpt of the same figure, the wall surface of the chest wall block 20 facing the front side wall surface of the chest wall block 20, that is, the side of the girder 30, 29 are not integrally formed but form a flat wall surface.

The chute block 20 according to the present invention is prefabricated with precast concrete or the like and is installed in the alternation 10 as shown in FIG. 4, and the front wall surface of the chute block 20 on the side of the girder 30 is formed flat A plurality of girders 30 are provided on the front wall of the chest wall block 20 so that the space between the ends of the adjacent girders 30 and the front wall of the chest wall block 20, Concrete is poured and cured, so that the girder 30 and the chest wall block 20 are bonded to each other.

As described above, in the present invention, the concave portion 29, in which the end portion of the girder 30 is accommodated or coupled, is not formed integrally with the chest wall block 20, so that the girder 30 can be freely and easily mounted It is possible to slightly move the girder 30 in a state in which the girder 30 is temporarily held, and the ease of installation in the installation of the half-girder bridge girder 30 can be remarkably improved.

Concrete for joining the girder 30 and the chute block 20 together is cured by being poured between the end surface of the adjacent girder 30 and the front wall surface of the chute block 20. The concrete pouring and curing are shown in FIG. It is possible through the same die 40.

That is, as shown in FIG. 6, the form 40 is formed of a horizontal plate and a vertical plate so that the upper surface of the horizontal plate is brought into close contact with the bottom surface of both sides of the curved device at the bottom surface of the end of the girder 30, And the distal end of the chest wall block 20 is in close contact with the lower end of the front wall of the chest block 20 so that the vertical plate is parallel to the front wall of the chest block 20 and spaced toward the center of the girder 30, And both side ends are brought into close contact with the side surface of the girder 30. [

6, the end surface of the girder 30, the vertical plate of the mold 40, the horizontal plate of the mold 40 and the front wall of the chest wall block 20 are surrounded Curing after pouring the concrete into the space enables tight and firm bonding between the girder 30 and the chest wall block 20 without forming the concave portion 29 as in the conventional chest wall block 20. [

7 and 8 are views for maximizing the effect of joining or integrating concrete between the girder 30 and the front wall surface of the chest wall block 20 and between the concrete and the chest wall block 20. As shown in Fig. 7, the chest wall block A plurality of fixing bars 21 are provided on the front wall of the chest wall block 20 and the fixing bars 21 are positioned between the girders 30 joined to the front wall of the chest block 20.

As shown in FIGS. 7 and 8, a U-shaped bent reinforcing bar is applied to the fixing reinforcing bar 21 embedded in the front wall of the chest wall block 20, and both ends of the fixing reinforcing bar 21 are connected to the chest wall block The fixing rib 21 of the portion of the chest wall block 20 exposed outside the front wall surface of the chest wall block 20 is positioned between the ends of the girder 30 and the front wall surface of the chest wall block 20, It is embedded in the concrete poured into the space.

8 shows a state in which the fixing steel bar 21 is detachably mounted and the fixing steel bar 21 is not embedded in the chest wall block 20 but the fixing steel bar 21 is once detached, The U-shaped fixing steel bar 21 can be installed in the recessed nut 22 embedded in the front wall surface of the chest wall block 20 by using the spindle 23 and the coupler 24. [

That is, as in the excerpted enlarged portion of FIG. 8, the fixing reinforcing bar 21 is formed by applying a U-shaped bent reinforcing bar so that both ends of the fixing reinforcing bar 21 are fixed to the front wall surface of the chute block 20, One end of a threaded rod 23 having a male thread on both ends is engaged with the other end of the threaded nut 22 and the other end of the threaded rod 23 is engaged with the other end of the threaded rod 23. [ Is also fastened to the end of the fixing reinforcing bar 21 on which the male thread is formed and the coupler 24.

By applying the mechanical reinforcing means such as the arm, male screw and threaded coupler 24 to the mounting of the fixing reinforcing bar 21, it is possible to mount and fix the fixing reinforcing bar 21 smoothly and stably, 7 and 8, when the U-shaped bending steel bar is used as the fixing steel bar 21, the problem that the end portion of the fixing steel bar 21 can not be directly fastened to the embedding nut 22 Is generated.

That is, the rod-like male thread can be directly connected to the female threaded nail 22 fixed to the front wall surface of the chest wall block 20, but in the case of the U-shaped bent steel rod, only one end can be screwed It is not.

8, one ends of the spiral rods 23 are fastened to the recessed nuts 22, temporarily fastened to the male threads at both ends of the U-shaped fixing rods 21, The coupler 24 is reversely rotated in a state in which the end of the exposed spiral bar 23 and the end of the fixing barrel 21 are in close contact with each other after the coupler 24 is retracted to the bending portion side of the fixing bar 21 as much as possible So that the U-shaped fixing steel bar 21 can be mechanically installed.

9 shows a state in which the binding concave portion 25 recessed inwardly of the chest wall block 20 is formed between the girder 30 and the girder 30 so that the concave filling portion 25 So that the concrete can act as a key for performing an anti-activity or anti-departure prevention function.

9, the fastening concave portion 25 is formed on the front wall surface of the chest wall block 20 so that the front wall surface of the chest wall block 20 is recessed toward the other side of the girder 30 And an inner lower portion of the coupling recess 25 is formed spaced upward from a lower end of the front wall surface of the chest wall block 20 and a wider portion 26 having a larger planar width is formed in the inner core portion of the coupling recess 25 As concrete is inserted into the thus formed coupling recess 25, a close coupling effect between the chest wall block 20 and the concrete is achieved.

The binding concave portion 25 can be easily formed without a major modification of the mold in a manner that inserts are inserted into the mold when the chest wall block 20 is pre-casted. As shown in FIG. 9, By forming the widened portion 26 whose width is enlarged in the plane on the inner core portion in the other direction of the girder 30, a tight and solid coupling structure can be constructed.

9, the lower end of the coupling concave portion 25 does not penetrate the chest wall block 20 completely but the lower end of the coupling concave portion 25 does not penetrate the chest wall block 20 completely, It is possible to effectively resist the shear force exerted on the joint surface between the packed concrete and the chest wall block 20 and to effectively prevent the shear force acting on the joint recess 40 between the packed concrete and the chest wall block 20, It is possible to omit the mold 40 for closing the lower portion of the mold 25, thereby enabling easy construction.

10: Shift
11:
12: connecting slab
13: Slab of roof slab
20: chest wall block
21: Settling bars
22: Recessed nut
23: Sun Bae
24: Coupler
25: binding lamb
26:
29:
30: Girder
40: Form

Claims (4)

Wherein the girder 30 of the chute block 20 is a half-length bridge in which the chute block 20 at the upper end of the shift 10 and the alternate 10 side end of the girder 30 are integrated, A plurality of girders 30 are provided on the front wall of the chest wall block 20 so that the concrete is placed in a space between the ends of the girder 30 and the front wall of the chest block 20, In the chest wall-facing girder bridges which are cured and in which the girder 30 and the chest wall block 20 are joined to each other,
A plurality of fixing bars 21 are provided on the front wall of the chest wall block 20 and the fixing bars 21 are positioned between the girders 30 joined to the front wall of the chest wall block 20;
The fixing bar 21 is embedded in the concrete placed between the ends of the girder 30 and the front wall of the chest block 20, wherein the fixing bar 21 is a U-shaped bent bar;
A fillet nut 22 is embedded in the front wall of the chest wall block 20;
Wherein one end of the spiral bar is coupled to the embedding nut and the other end of the spiral bar is coupled to the end of the fixing barrel with the coupler.
Wherein the girder 30 of the chute block 20 is a half-length bridge in which the chute block 20 at the upper end of the shift 10 and the alternate 10 side end of the girder 30 are integrated, A plurality of girders 30 are provided on the front wall of the chest wall block 20 so that the concrete is placed in a space between the ends of the girder 30 and the front wall of the chest block 20, In the chest wall-facing girder bridges which are cured and in which the girder 30 and the chest wall block 20 are joined to each other,
A binding concave portion 25 is formed on the front wall surface of the chest wall block 20 so that the binding concave portion 25 is formed by recessing the front wall face of the chest wall block 20 to the other side of the girder 30;
The inner lower end of the binding recess 25 is formed upwardly spaced from the lower end of the front wall surface of the chest wall block 20;
And a widened portion (26) having an enlarged planar width is formed in an inner core portion of the coupling recessed portion (25). delete delete

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