KR200358799Y1 - The infrastructure for the matrix support of the bridge - Google Patents

Abstract

The present invention relates to the structure for supporting the formwork of bridge slabs, and more specifically, the structure for supporting the formwork of the bridge slab, which can be provided with high quality bridges by securing the original stability and work efficiency and providing a beautiful appearance. will be.

That is, in the step of fixing the flat iron 15, the plywood 19, the girder 12 to the flange 13a, the girder 12 and the stud bolt 17 are fixed to the flat iron 15 on the flange 13a. The reinforcement 16 is seated on the upper side of the flat iron 15, and the stud bolt 17 provided above the reinforcement 16 and the flange 13a is fixed to the weld 21 and at the same time While the 15 is fixed, the plywood 19 and the girder 12 are integrally fixed to the fixed flat iron 15 by bolts 14 and nuts 14a.

Description

Structure for the formwork of bridge slab {The infrastructure for the matrix support of the bridge}

The present invention relates to the structure for supporting the formwork of bridge slabs, and more specifically, to the structure for supporting the formwork of the bridge slab, which can be provided with high quality bridges by securing the original stability and work efficiency and providing a beautiful appearance. It is about.

In general, bridges are divided into upper and lower structures. The upper structure refers to the structure on the alternating or pier, and is generally composed of mold, slab, etc. Determining the type of bridge depends on the shape of the main member, which is the member that receives the most force from the bridge. Girder bridges are used for castings (girders), arch bridges and trusses for truss bridges, and kale bridges (cables and suspension bridges) for cables.

In addition, the substructure refers to the shifts and bridges that safely transfer the loads acting on the superstructure to the ground, and the shift refers to the bearing of the starting point of the bridge, and the bridge refers to the intermediate bearings other than the starting point.

When forming the slab of the steel box girder bridge of the upper structure of the bridge configured as described above, first to form and install the formwork in the conventional steel box 13 on the upper side of the pier as shown in Figure 3 After the installation is stable, the flat iron 15 is seated on one side of the side flange 13a of the steel box 13 above the flange 13a, and the bottom surface of the flange 13a is provided with a plywood 19 and at the same time an angle ( 18) and the welded girders 12 are fixed with bolts 14 nuts 14a and then formwork 20 can be installed on top of the girders 12.

Such a structure is not only highly likely to cause a safety accident due to the load of reinforcement and concrete after installing the formwork 20, but also easily causes voids between the components for fixing and externally exposed components. Due to various risk factors such as corrosion of the contact with the concrete, there is a problem that the work delay is caused and the quality is reduced even after installation.

In this invention, as designed to eliminate the problems described above, by constructing the reinforcement (16), the strong binding with the stud bolt 17, so as to have a sufficient bearing capacity when binding the components with bolts, It provides the structure and the installation method of the structure which can reduce the check loss due to the work delay by improving the work efficiency when installing the structure that can support the formwork and preventing safety accidents by securing the original stability. The main focus is on the technical task.

1 is a structure installation process diagram for supporting the formwork of the bridge slab

2 is a side configuration diagram of a bridge to which the technical gist of the present invention is applied.

3 is an enlarged structural diagram of a part of a structure A installed by a conventional method;

4 is an enlarged structural diagram of a part of the structure (A) proposed in the present invention

Figure 5 is a partially enlarged perspective view of the main portion of the structure (A) proposed in the present invention

Figure 6 is a partially enlarged perspective view showing another embodiment of the main portion of the structure (A) proposed in the present invention

■ Explanation of symbols used in main part of drawing ■

A: structure 10: pier

11: Slab 12: girder

13: Steel box 13a: Flange

14: Bolt 14a: Nut

15: flat iron 16: reinforcement

17: Stud bolt 18: Angle

19: plywood 20: formwork

21: Welding part 21a: U bolt

In order to achieve the above technical problem, the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a structure installation process diagram for supporting formwork of a bridge slab, and FIG. 2 is a side configuration diagram of a bridge to which the technical gist of the present invention is applied. 3 is an enlarged structural view of a part of the structure A proposed in the present invention, FIG. 4 is a partially enlarged perspective view illustrating an essential part of the structure A presented in the present invention, and FIG. 5 is presented in the present invention. As a partial enlarged perspective view showing another embodiment of the main portion of the structure (A), the structure (A) for supporting the formwork of the bridge slab proposed in the present invention will be described in detail as follows.

Referring to the installation process with reference to Figures 1, 4, 5, 6,

In the installation method of the structure (A) for supporting the formwork of the bridge slab using the girder 12 and the steel box 13,

Fixing the flat iron 15, plywood 19, girder 12 to the flange (13a) of the steel box,

Placing the flat iron 15 on the flange 13a in a position to be fixed together with the girder 12 and the stud bolt 17,

The reinforcing material 16 is seated and provided on the upper side of the flat iron 15 disposed, and then the flat iron 15 is fixed while welding 21 to fix the stud bolt 17 provided on the reinforcing material 16 and the flange 13a. To be fixed,

The plywood 19 and the girder 12 are integrally fixed to the fixed flat iron 15 by bolts 14 and nuts 14a.

When the plywood formwork is fixed in the structure as described above, the welding force is coupled to the reinforcement 16 so that the stud bolts of the rear part rather than the front part are supported by the bolt fastening, and the reinforcement 16 is flat iron 15 to increase the supporting force. The stud bolt 17 is in contact with each other to form a straight pipe. In order to improve the work efficiency, it may be composed of various sections such as b-shaped steel or angular pipe, and it is preferable to use b-shaped steel in order to increase weight and increase bearing capacity, and it is preferred to use a steel strip provided on the reinforcing material 16 and the flange 13a. Fixing the bolt 17 is possible by welding or the like which is a conventional fixing method. Conventionally, U bolts and the like are commonly used to bind fixed elements in the construction of formwork for bridge slab construction. However, in the present invention, when U bolts are used, welding is used to minimize play and defects. Conventional coupling method that can increase the binding force, that is, welding, pin, bolt coupling, etc. may be applied.

The reinforcing material (16), which plays a key role in the present invention, is to restrain the generation of voids that may have occurred due to the faulty coupling and the defect of the flat iron itself by increasing the bearing capacity of the flat iron. That is, the plywood formwork 20 is adapted to meet the slab cross-sectional specification by pulling up the clamping force of the structures constructed between the girders 12 fixed between the bolts 14 and the nuts 14a to perfect fixing force of the flat iron. The concrete will be poured by installing and reinforcing the rebar.

After the concrete is laid and the concrete 20 is completely hardened after the dismantling period, the girder 12 and the mold 20 and the bolt 14 connected to the flat iron 15 are separated by rotating with a tool.

At this time, if the bolt 14 is removed from the nut 14a, the girder 12 and the plywood 19 can be easily separated from the bottom, and the stud bolt 17 provided on the upper flange 13a of the steel box 13 can be separated. The welded reinforcement and the flat iron 15 and the nut 14a are embedded in the concrete, and after dismantling the formwork 20, the lower concrete surface is shown as a very clean shape, and the concrete exposed surface bolt hole (not shown) uses a finishing material. It can be easily filled so that no structure other than the crete surface is exposed to the outer surface, so there is no need to worry about voids caused by corrosion afterwards.

Therefore, the exposure of the spacers, which had been reinforced in the front part due to the change in thickness of the upper flange 13a of the steel box 13 of the conventional method, is eliminated as time passes, so as not only to solve the safety problem but also directly to the flange 13a. It is possible to eliminate secondary defects due to coating damage to prevent rusting of steel by welding, thereby improving workability and improving quality.

The structure and the method of installing the structure for supporting the formwork of the bridge slab of the present invention as described in detail above, by fixing the stud bolt and reinforcement attached to the upper flange of the steel box to perfect the fixing of the flat iron, play between the structures It does not occur, and there is no damage to the steel box itself, so there is no need for further surface treatment work.When the concrete is hardened and the bolts are rotated to dismantle the formwork, the reinforcement of the concrete surface is not exposed, and concrete pouring It is a devised design with great anticipated effects such as preventing mortar flow in the city and ensuring no work, economic feasibility, safety and quality.

Claims (3)

In the structure (A) for supporting the formwork 20 formed by fastening the steel box 13 and the girder 12 installed on the upper side of the pier, The structure (A) is a flat iron (15) configured in a position where the girder 12 and the stud bolt 17 is fixed to the flange (13a), The reinforcing member 16 is in contact with the flat iron 15 and the stud bolt 17 to the upper side of the flat iron 15 to form a straight pipe shape and welded to the stud bolt 17, A girder 12 formed below the flange 13a, Consists of plywood 19 formed between the bottom of the flange (13a) and the girder (12) Structure for supporting the formwork of the bridge slab comprising a fastening and fixing with a bolt (14), a nut (14a) to be integrally coupled. The method of claim 1, The reinforcement (16) and the stud bolt (17) fixing is a structure for supporting the formwork of the bridge slab including a conventional coupling method that can increase the binding force, that is, welding, pin, bolt coupling. The method of claim 1, The reinforcement (16) is a structure for supporting the formwork of the bridge slab comprising any one of the straight b-shaped steel, angular pipe, angle.