KR20150021328A - Construction method for supporting structure of temporary bridge tayp - Google Patents

Abstract

The present invention relates to a construction method for a temporary bridge type supporting structure which can stably support a structure without subsidence or deformation of an existing underground structure when another structure is newly constructed by being intercrossed in the lower part of the installed underground structure. More specifically, the construction method for the temporary bridge type supporting structure comprises: a step of embedding a pair of steel piles in a row from the ground to the planned depth to be adjacent to each of both side surfaces of the underground structure; a step of excavating surrounding ground to a lower level of the underground structure; a step of cutting the steel piles at a lower level than the lower surface of the underground structure; a step of excavating the lower part of the underground structure and supporting the underground structure by combining and inserting a supporting girder into the upper part of the steel piles; and a step of repeatedly performing a process of interconnecting the exposed steel piles which are excavated up to the planned depth with a reinforcing member.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of constructing a bridge structure,

The present invention relates to a method of constructing a bridge type supporting structure that is capable of stably supporting an existing underground structure without deforming or deforming when another structure is crossed under a previously installed underground structure.

The underpinning construction method is a construction that puts the foundation under the existing structure, temporarily supporting the structure, then putting the foundation and supporting the structure after the new foundation is over. For example, when a new structure such as a subway is constructed at the lower part of an existing structure, the existing structure may be temporarily supported and the lower part may be partially constructed.

In addition to this, it is also applied to the reinforcement of designations and foundations to increase depth or bearing capacity of existing structures.

In other words, the under-pinning method is a construction method that is currently being applied at various construction sites because it can temporarily support the structure or reinforce the foundation if there is a fear that the new structure will affect the existing structure.

This under-pinning method is a series of reinforcement works to prevent deformation of adjacent ground and designation due to excavation when deep excavation is performed adjacent to a high-rise building in US subway construction in the 1930s, The case that the load was transferred by using the reaction force pile for the excavation of the concrete was the prototype of the present method.

In Korea, underpinning method is mainly applied to intersection and close construction of railway, bridge, road, underpass, and underground of river, and when new structure is required under existing structure, This is applied in a comprehensive sense to excavation, lack of bearing capacity of existing structure, uneven settlement, or temporary or permanent relocation of existing structures.

The construction method of the under pinning method is briefly described. The surrounding ground is excavated to expose the lower part of the existing structure. At this time, a certain area under the existing structure is reinforced through grouting. The supporting piles are sequentially installed to support the existing structure while performing a stepwise excavation from outside to inside of the predetermined area reinforced by the ground.

When the first stage of the support pile for supporting the lower portion of the existing structure is completed, the lower stages are constructed to the depth of plan by repeating the above-mentioned construction method. At this time, So that it joins together.

However, in the conventional under pinning method, as described above, since the excavation and the joining of the support pile are repeatedly performed from the lower side to the inside side of the existing structure, the space becomes narrower toward the inner side, It is not easy and the workability is lowered and the construction period is increased accordingly.

Also, in this case, since the lower portion of the existing structure can not be supported at a time, deflection of the structure frequently occurs, and stability can not be secured.

Korean Patent No. 355513

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a bridge structure capable of stably supporting an existing underground structure without deforming when another structure is crossed under the existing underground structure. And an object of the present invention is to provide a method of constructing a building.

In order to accomplish the above object, the present invention provides a method of constructing a bridging type bridging structure, comprising the steps of: a) providing a pair of steel piles adjacent to both sides of an underground structure from a ground level to a planned depth level; b) excavating the surrounding ground to a lower level of the underground structure; c) cutting the steel pile to a lower level than the lower surface of the underground structure; d) excavating the lower part of the underground structure and supporting the underground structure by pulling and connecting the support girder to the upper part of the pair of steel piles; And e) repeatedly constructing a steel pile excavated and exposed up to a planned depth by interconnecting the pile with a reinforcing material.

As an example, in the step e), joining the intermediate supporting file to the planning depth to support the intermediate portion of the supporting girder between the pair of steel piles, And is characterized in that it opposes the bending moment of the girder.

As an example, in the step (e), coupling H-shaped steel in a vertical direction or a horizontal direction so as to couple exposed steel piles and adjacent steel piles to each other; And joining the L-shaped steel in an oblique direction so as to join the H-shaped steel, the steel pile and the H-shaped steel.

As an example, in step c), grouting and reinforcing the lower ground of the underground structure is performed to prevent the ground under the underground structure from collapsing when excavating for the support girder.

As an example, the step d) includes the steps of: coupling the girder supporting beam to the upper portion of the cut steel pile; Connecting the upper portion of the girder supporting beams of the other steel piles adjacent to each other along the longitudinal direction of the underground structure to the girder supporting beams; Installing a screw jack on the upper surface of the girder supporting beam; Placing the backing girder on top of the screw jack orthogonal to the girder supporting beams; And adjusting the screw jack so that the supporting girder contacts the lower surface of the underground structure.

As an example, in the step of placing the support girder on the upper portion of the screw jack orthogonal to the support beam, the lower bracket connecting the inner surface of the girder support beam and the lower surface of the support girder; And an upper bracket connecting the upper surface of the supporting girder and the side surface of the underground structure.

The method of constructing a bridge-type bearing structure according to the present invention is characterized in that a sufficient supporting force is secured by the structure of a supporting girder supporting the load of the underground structure by being coupled to the steel pile perpendicularly to the steel pile And minimizes the deflection of the structure, which is advantageous in that it can support the underground structure in a stable manner.

Also, it is advantageous to secure the work space in the lower part by the support structure for the support structure dedicated to the underground structure, thereby improving the workability of the new structure and thus shortening the construction period.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front sectional view showing a cross-linked support structure of the present invention. Fig.
Fig. 2 and Fig. 3 are perspective views showing the main part of the crosslinkable support structure of the present invention. Fig.
4A to 4H are schematic views showing a method of constructing a crosslinkable support structure of the present invention.
5 is a block diagram for explaining a method of constructing a crosslinkable support structure of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a front sectional view showing a crosslinkable supporting structure of the present invention, and FIGS. 2 and 3 are perspective views showing a backward supporting structure of the present invention.

The bridging type supporting structure is used as a temporary structure for supporting the load of the installed underground structure 10 when constructing a new structure crossing the lower portion of the underground structure 10.

As shown in FIG. 1, the crosslinkable supporting structure of the present invention comprises a pair of steel piles 100 inserted from the ground, and a support (not shown) which is coupled between the pair of steel piles 100 to support the underground structure 10 And a stiffener 300 for connecting the girder 200 and the adjacent steel piles 100 together.

The steel pile 100 is installed at a planned depth from the surrounding ground where the underground structure 100 is located, that is, a new structure to be constructed at the lower portion of the underground structure 10, to the depth of the underground of the expected location.

As shown in FIGS. 2 and 3, the steel piles 10 are arranged in a pair in the longitudinal direction of the underground structure 10 so as to be adjacent to both sides of the underground structure 10, Spaced apart from each other.

The steel pile 100 is cut at a distance from the bottom of the underground structure 10 prior to the process of joining the support girder 200 described below. The distance may be set to a distance such that the support girder 200 can sufficiently pass between the upper portion of the steel pile 100 and the lower portion of the underground structure 10. [

Further, the steel pile 100 is preferably composed of at least one steel material so as to secure a sufficient supporting force. In FIG. 2, the steel material pile is composed of four steel materials, but the number is not limited thereto.

The support girder 200 is laterally coupled to a pair of steel piles 100 so as to contact the lower surface of the underground structure 100 to support the load of the underground structure. The support girder 200 makes it possible to minimize the deflection of the structure by using a steel having a high rigidity.

The support girder 200 is installed by drilling a region of the unexplored ground remaining on the lower surface of the underground structure 10 in the lateral direction to form a through hole and the support girder 200 is inserted in the lateral direction So as to be seated on both steel piles 100.

As described above, one supporting girder 200 is seated and coupled on a pair of steel piles 100 installed on both sides of the underground structure 10, and the supporting girder 200 is also shown in FIG. 3 As shown in the drawing, the load of the underground structure 10 is collectively supported by being arranged along the longitudinal direction of the underground structure 10 so as to correspond to the arrangement structure of the steel piles 100.

1, a girder supporting beam 400, a girder supporting beam 500 and a height adjusting unit are provided between the pile 100 and the supporting girder 200 So that the position of the support girder 200 can be adjusted with stable support.

The girder support beam 400 is coupled to the upper portion of each steel pile 100 by a plate-like member so that the girder support beam 500 can be seated.

The girder supporting beam 500 is coupled to the upper portion of the girder supporting beam 400 so as to be horizontal with the underground structure 10, and is formed of a plurality of unit modules as shown in FIGS. 2 and 3, So that one joint is seated and coupled to the upper portion of the adjacent tether supporting and supporting beam 400 from above the support beam 400, thereby facilitating the joining operation.

The height adjusting means is provided between the girder supporting beam 500 and the supporting girder 200 to adjust the height of the supporting girder 200. For example, the present invention proposes a screw jack 600 have.

In this screw jack 600, the height of the support side and the support side are adjusted by the rotation action, and the height is adjusted upward or downward according to the rotation direction.

As described above, the elevation adjusting means is provided to closely adhere the supporting girder 200 to the lower surface of the underground structure 10, thereby finely adjusting the level of the supporting girder 200 through fine adjustment.

The reinforcing member 300 reinforces the steel piles 100 to be exposed so that the piles 100 are excavated to a planned depth so as to more firmly cope with vibrations and loads of the underground structure 10.

As shown in FIG. 1, the stiffener 300 is connected to a pair of steel piles 100 exposed by the excavation, or when the stiffener 300 is inserted adjacent to the adjacent steel piles 100, And the upper H-shaped steel 310 and the lower H-shaped steel 310 which are exposed in the next excavation are interconnected in an oblique direction or adjacent steel piles 310 100) connected to each other by an oblique line.

A reinforcing bracket 710 connecting both side surfaces of the upper portion of the steel pile 100 and the lower surface of the girder supporting beam 400 and an inner surface of the girder supporting beam 500 and the supporting girder 200, And an upper bracket 730 connecting the upper surface of the support girder 200 and the side surface of the underground structure 10 to allow mutual stable load transfer between the respective components .

The bridge supporting structure according to the present invention includes a pair of steel piles 100 for supporting both ends of the support girder 200 and an intermediate support pile 100 for preventing the support girder 200 from being warped. 800).

As the excavation process is performed stepwise up to the planned depth, the intermediate assisting file 800 is coupled to the intermediate ground of the supporting girder 200 and the other is coupled to the lower ground where excavation is completed. 800 are composed of a plurality of unit modules and are jointed in the process of excavation according to each step and installed parallel to the steel pile 100.

As shown in FIG. 1, the intermediate auxiliary file 800 includes a screw jack at a portion of the intermediate auxiliary file 800 that is in contact with the ground, So that the connection with the support girder (200) can be adjusted.

FIGS. 4A to 4G are schematic views showing a method of applying the crosslinkable support structure of the present invention, and FIG. 5 is a block diagram illustrating a construction method of the crosslinkable support structure of the present invention.

As shown in FIG. 4A, a pair of steel piles 100 are placed adjacent to both sides of an underground structure 10 from a ground level to a planned depth (S100)

In the penetration construction, a perforation hole is formed by using the perforation equipment 20 from the ground to the planned depth around the underground structure 10, and the steel pile 100 is inserted into the perforation hole.

The supporting girder 200 is then allowed to enter the lower part of the underground structure 10 by digging the surrounding ground where the underground structure 10 is located to a level where the lower part of the underground structure 10 appears. )

At this time, in the ground excavation process, although not shown in the drawings, excavation surfaces of slopes are generated by excavating the surrounding grounds. In order to prevent the excavation surfaces from collapsing, the earth retaining processes such as the soil wall construction surrounding the excavation surfaces .

When the excavation process is completed to the lower level of the underground structure 10, a part of the steel pile 100 inserted in the above process is exposed. As shown in FIG. 4B, And the steel pile 100 is cut at a spaced level (S300)

In the lower part of the underground structure 10, there is an unexplored ground area A that is not excavated in the excavation process. The ground is grouted in the unexplored ground area A to reinforce the ground. This is because the unfolded ground A is reinforced when the unfolded ground A at the entry position of the supporting girder 200 is excavated in drawing the supporting girder 200 to the lower face of the underground structure 10 So that the ground outside the inlet position is not collapsed.

The grouting method can be variously performed by a known technique, and a detailed description thereof will be omitted.

Thereafter, the reinforced undoped ground A of the lower part of the underground structure 10 is excavated to form a through hole, and the supporting girder 200 is inserted into and coupled to the upper part of the pair of steel piles 100 through the through- Thereby supporting the underground structure 10 (S400)

According to a preferred embodiment of the present invention, a girder supporting beam 400, a girder supporting beam 500 and a screw jack 600 are installed between a steel pile 100 and a supporting girder 200. First, The girder support beams 400 are coupled to the upper portions of the cut steel piles 100 as shown in FIG.

At this time, the girder supporting sail beam 400 is stably supported from the steel pile 100 by joining the both sides of the upper portion of the steel pile 100 and the reinforcing bracket 710 connected to the lower surface of the girder supporting beam 400 .

The girder supporting beam 500 is coupled to the girder supporting beam 400 of the other steel pile 100 adjacent to the girder supporting beam 400. The girder supporting beam 500 includes a plurality of unit modules So as to be connected to the upper portion of the girder support beam 400 in the longitudinal direction of the underground structure 10.

Thereafter, a screw jack 600 is installed on the upper surface of the girder supporting beam 500. As described above, the screw jack 600 adjusts the height of the support girder 200 by the rotation action so that the support girder 200 is brought into close contact with the lower surface of the underground structure 10.

The screw jacks 600 are provided corresponding to the number of the supporting girders 200 which are inserted in the lateral direction through the through holes and can be installed side by side in the longitudinal direction of the girder supporting beams 500.

The bottom of the screw jack 600 installed on the girder support beam 500 is finally positioned so that the support girder 200 is orthogonal to the girder support beam 500 and the screw jack 600 is rotated, (200) is brought into close contact with the lower surface of the underground structure (10).

The upper bracket 730 connecting the upper surface of the supporting girder 200 and the side surface of the underground structure 10 is coupled to the lower surface of the underground structure 10, By supporting the side surface of the underground structure 10 in an integrated manner with the girder 200, it is possible to reduce the shaking of the underground structure 10.

The lower bracket 720 connecting the inner surface of the girder supporting beam 500 and the bottom surface of the supporting girder 200 is coupled to stably support the load of the supporting girder 200.

After completion of the construction of the supporting girder 200 with respect to the underground structure 10 as described above, excavation is carried out step by step to the planned depth. As the stepwise excavation is performed, the steel piles 100, which are gradually exposed, are interconnected by the reinforcement 300 to bind the steel piles 100 together.

The mutual connection of the stiffeners 300 is performed by vertically or horizontally coupling the H-shaped beams 310 to bond the exposed pair of steel piles 100 and adjacent adjacent piles 100, The L-shaped steel pipe 320 is joined in the diagonal direction so as to connect between the H-shaped steel pipe 310 and the steel pile 100 and the H-shaped steel pipe 310.

As described above, the stepwise excavation and the interconnection of the stiffener 300 are repeatedly performed to the planned depth, and when the excavation is completed up to the planned depth, the connection of the stiffener 300 is also completed.

According to a preferred embodiment of the present invention, the intermediate supporting file 800 is further installed to oppose the bending moment of the supporting girder 200 supporting the load of the underground structure 10.

The intermediate support file 800 is joined to the planned depth so as to support an intermediate portion of the support girder 200 between the pair of steel piles 100, And the other side is brought into close contact with the excavated ground.

That is, as described above, the intermediate assisting file 800 is composed of a plurality of unit modules, and is installed up to the planning depth through joint failures between unit modules. When the stepping excavation is completed, Thereby supporting the intermediate portion of the supporting girder 200 in accordance with the excavation level.

Finally, when the bridge type supporting structure is completed through the above-mentioned method, a new structure is constructed at the lower part of the underground structure 10, and the new structure is stably supported at the time of construction, The workability of the new structure can be improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

10: Underground structure 20: Perforation equipment
100: Steel pile 200: Foundation girder
300: stiffener 400: girder support beam
500: girder support beam 600: screw jack

Claims (6)

a) providing a pair of steel piles adjacent to both sides of an underground structure in parallel from the ground to the planned depth;
b) excavating the surrounding ground to a lower level of the underground structure;
c) cutting the steel pile to a lower level than the lower surface of the underground structure;
d) excavating the lower part of the underground structure and supporting the underground structure by pulling and connecting the support girder to the upper part of the pair of steel piles; And
e) repeating the step of interconnecting the piles of the steel material excavated and exposed up to the planned depth with a reinforcing material.
The method according to claim 1,
In the step e)
And joining the intermediate support pile to the planned depth to support an intermediate portion of the support girder between the pair of steel piles.
The method according to claim 1,
In the step e)
Joining the H-shaped steel in a vertical direction or a horizontal direction so as to bind a pair of exposed steel piles and adjacent steel piles to each other; And
And joining the L-shaped steel in an oblique direction so as to bond the H-shaped steel and the steel pile to the H-shaped steel.
The method according to claim 1,
In the step c)
And grouting and reinforcing the lower ground of the underground structure. ≪ RTI ID = 0.0 > 11. < / RTI >
The method according to claim 1,
The step d)
Coupling the girder support beam to the upper portion of the cut steel pile;
Connecting the upper portion of the girder supporting beams of the other steel piles adjacent to each other along the longitudinal direction of the underground structure to the girder supporting beams;
Installing a screw jack on the upper surface of the girder supporting beam;
Placing the backing girder on top of the screw jack orthogonal to the girder supporting beams; And
And adjusting the screw jack so that the support girder contacts the lower surface of the underground structure.
6. The method of claim 5,
In the step of placing the support girder on the upper portion of the screw jack so as to be orthogonal to the support support beam,
Coupling a lower bracket connecting an inner surface of the girder supporting beam and a bottom surface of the supporting girder; And
And joining an upper bracket connecting the upper surface of the supporting girder and the side surface of the underground structure.

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