KR102108622B1 - Support structure of temporary strut for construction period reduction - Google Patents

Abstract

The present invention relates to an air shortened hypothesis strut support structure, a pillar steel frame forming a pillar of an underground structure of a building; A temporary bracket provided on a flange of a section steel constituting the pillar steel frame; Supported by the hypothetical bracket, one end supports a first mud wall provided for forming the underground structure, and the other end supports a second mud wall provided on a surface facing the first mud wall. Hypothetical struts; Supported by the transverse hypothesis strut, one end is disposed to be orthogonal to the transverse hypothesis strut to support a third retaining wall provided for forming an underground structure, and the other end faces the third retaining wall A longitudinal hypothetical strut supporting a fourth retaining wall provided in the; A section steel having an L-shaped cross-section, wherein one end is coupled to a lower surface of the upper flange of the transverse hypothetical strut; a first buckling prevention angle; And an L-shaped cross-section, wherein one end includes a second buckling-prevention angle that engages the upper side of the lower flange of the longitudinal hypothesis strut.

Description

SUPPORT STRUCTURE OF TEMPORARY STRUT FOR CONSTRUCTION PERIOD REDUCTION

The present invention relates to a hypothetical strut support structure supporting a retaining wall, and specifically, to a structure capable of significantly reducing air compared to a conventional strut method by reconfiguring a hypothetical strut and a center file supporting the hypothetical strut.

In a typical construction site, when constructing a ground for construction (civil engineering / construction site), a temporary mud construction is carried out in a conventional way to prevent soil collapse at the back of the excavation and to suppress displacement. The construction method or earth anchor construction method will be used.

Particularly, in the conventional strut construction method, the struts are orthogonal to the horizontal direction to abut at regular intervals to support the retaining wall, and a center file for preventing sagging or buckling of the stud is constructed together. At this time, it is common to determine the position of the center pile so that it does not interfere with the pillars or walls of the structure being constructed later.

However, according to such a conventional method, there is an advantage of reducing the construction period and cost of the retaining structure, but the structure is inevitably constructed in the order of foundation → basement frame → ground layer frame, that is, netting. It has a problem that the construction period is significantly increased compared to the top-down method, which can first construct the ground floor frame before the foundation is constructed.

Patent Document 1: Republic of Korea Patent Registration No. 10-1628264 Date of Publication June 8, 2016 Patent Document 2: Republic of Korea Patent Publication No. 10-2011-0018581 Publication Date February 24, 2011

The present invention has been disclosed in order to solve the disadvantages of the conventional construction method of the hypothetical strut, even before the foundation is constructed as in the top-down construction method by supporting the hypothetical strut after installing the center file directly on the pillar or wall position of the building structure The goal is to provide a structure that significantly shortens the construction period (approximately 3 to 6 months) by allowing the ground floor frame to be advanced.

An air shortened hypothesis strut support structure according to one feature for realizing the above object of the present invention includes a pillar steel frame that plays a role of a center pile while forming a pillar of an underground structure of a building; A temporary bracket provided on a flange of a section steel constituting the pillar steel frame; Supported by the hypothetical bracket, one end supports a first mud wall provided for forming the underground structure, and the other end supports a second mud wall provided on a surface facing the first mud wall. Hypothetical struts; Supported by the transverse hypothesis strut, one end is disposed to be orthogonal to the transverse hypothesis strut to support a third retaining wall provided for forming an underground structure, and the other end faces the third retaining wall A longitudinal hypothetical strut supporting a fourth retaining wall provided in the; A section steel having an L-shaped cross-section, wherein one end is coupled to a lower surface of the upper flange of the transverse hypothetical strut; a first buckling prevention angle; And a section steel having an L-shaped cross-section, wherein one end includes a second buckling-prevention angle coupled to the upper side of the lower flange of the longitudinal hypothesis strut.

At this time, the other end of the first buckling prevention angle and the other end of the second buckling prevention angle are combined, so that the lateral hypothesis strut, the longitudinal hypothesis strut, the first buckling prevention angle and the second buckling prevention An angle may be arranged in a form surrounding the pillar steel frame.

At this time, the transverse hypothesis strut and the longitudinal hypothesis strut are preferably formed of H-beams of the same standard.

In this case, the transverse hypothesis strut and the longitudinal hypothesis strut may have through holes formed at regular intervals on both sides of the upper flange and the lower flange.

On the other hand, the first buckling-prevention angle is arranged in a form so that the upper surface of the one end can be coupled to the lower surface of the upper flange of the transverse hypothetical strut.

In addition, the second buckling prevention angle) is disposed in a b shape so that the lower surface of the one end can be coupled to the upper surface of the lower flange of the longitudinal hypothetical strut.

In addition, the other end of the first buckling prevention angle and the other end of the second buckling prevention angle further includes a coupling auxiliary member disposed between the coupling surfaces, and the coupling auxiliary member includes an upper flange of the transverse hypothetical strut. And a thickness corresponding to the sum of the thicknesses of the lower flanges of the longitudinal hypothesis struts.

According to the air shortening hypothesis strut support structure according to an embodiment of the present invention,

First, the installation and excavation of the transverse temporary strut and the longitudinal temporary strut are repeated for each floor of the underground structure, and during this time, the ground structure can be preceded and constructed even before the foundation is constructed according to the design history of the column steel frame. have.

Second, it is possible to secure economic feasibility by manufacturing the transverse hypothesis strut and the longitudinal hypothesis strut in advance with the same specifications.

Third, it is possible to reuse all the temporary members (transverse hypothesis struts, longitudinal hypothesis struts, hypothesis brackets, first buckling prevention angle and second buckling prevention angle), thereby significantly reducing construction cost.

1 illustrates the concept of simultaneously performing a ground floor construction and a basement construction using the hypothetical strut support structure of the present invention.
2 is a plan view of a hypothetical strut support structure according to an embodiment of the present invention.
3 is an elevation view of a hypothetical strut support structure according to an embodiment of the present invention.
4 is a perspective view of a transverse hypothesis strut and a longitudinal hypothesis strut according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the accompanying drawings, the same components are denoted by the same reference numerals as possible. In addition, detailed descriptions of well-known functions and configurations that may obscure the subject matter of the present invention will be omitted. For the same reason, some components in the accompanying drawings are exaggerated, omitted, or schematically illustrated.

1 illustrates the concept of simultaneously performing a ground floor construction and a basement construction using the hypothetical strut support structure of the present invention.

In the construction sequence, the first step is to construct a pillar steel frame that serves as the center pile supporting the temporary struts while performing the earthwork and forming the pillars of the underground structure of the building. Construction of pillar steel frame is done by PRD method (Percussion Rotary Drill).

The pillar steel frame used may be selected from H-beams or prefabricated square steel pipe pillars.

Subsequently, excavation of the basement is carried out by installing the transverse hypothesis strut and the longitudinal hypothesis strut in support of the column steel frame.

When excavation proceeds more than a certain depth, a perforated plate is installed in some sections of the lower floor to secure a yard, work table, and so on.

Unlike the top-down method, since the floor slab on the first floor is not constructed first, a temporary steel frame beam for supporting a round frame for installation of the ground structure should be placed at the location (A) where the above-ground structure is installed. And a longitudinal hypothetical strut.

The installation and excavation of the transverse temporary struts and the longitudinal temporary struts for each floor of the underground structure are repeatedly performed, while the ground structure is preceded even before the foundation is constructed according to the design history of the column steel frame constructed by the PRD method. It can be constructed.

Subsequently, when the excavation is completed, the foundation is laid and the framed structures of the underground structure are proceeded with net smashing, and the installed longitudinal hypothesis struts and transverse hypothesis struts are dismantled.

The construction of the ground structure can be carried out in a sequential stroke together with the pouring and curing of the structure of the underground structure (that is, by strengthening the strength with the SRC pillar that combines concrete and reinforcement with the pillar steel frame).

Finally, on the first floor above the ground, the construction of the structure of the underground structure and the structure of the sagittal structure are connected to each other, and the remaining construction of the ground structure is completed.

2 is a plan view of a hypothetical strut support structure according to an embodiment of the present invention, FIG. 3 is an elevation view of a hypothetical strut support structure according to an embodiment of the present invention, and FIG. 4 is a transverse view according to an embodiment of the present invention It is a perspective view of a directional hypothesis strut and a longitudinal hypothesis strut.

2 to 4, the temporary strut support structure 1000 according to the present invention includes a pillar steel frame 100, a longitudinal temporary strut 200, a transverse temporary strut 300, and a second buckling prevention angle 400 ), A first buckling prevention angle 500, a temporary bracket 600 and a coupling auxiliary member 700.

The pillar steel frame 100 is also called a center pile and is a steel frame forming a pillar of an underground structure of a building. Depending on the design of the building, the pillar steel frame 100 may be implemented to be connected to the pillar of the ground structure.

Column steel frame 100 is constructed by the PRD method (Percussion Rotary Drill). The pillar steel frame 100 may be selected from H-beams or prefabricated square steel pipe pillars.

The hypothetical bracket 600 is provided on the pillar steel frame 100 to directly or indirectly support the longitudinal hypothetical strut 200 and the transverse hypothetical strut 300.

In the illustrated example, the hypothetical bracket 600 is formed of H-shaped steel having the same shape as the pillar steel frame 100, but this is only for obtaining cost savings by using the same member, and the shape of the hypothetical bracket 600 is It is not limited to the illustrated example.

When the pillar steel frame 100 is formed of H-shaped steel, the temporary bracket 600 is provided on the flange of the pillar steel frame 100. The method of fixing the hypothetical bracket 600 is not limited, but it is preferable to fix it with a bolt / nut method for demolition and reuse.

The transverse hypothesis strut 300 is supported by the hypothetical bracket 600, one end supporting a first mud wall (not shown) provided for forming an underground structure, and the other end facing a first mud wall The second mud wall (not shown) provided in the support.

The longitudinal hypothesis strut 200 is supported by the transverse hypothesis strut 300, and is arranged to be orthogonal to the transverse hypothesis strut 300, one end of which is a third retaining wall (not shown) provided for forming an underground structure , And the other end supports a fourth retaining wall (not shown) provided on a surface facing the third retaining wall.

At this time, the column steel frame 100 does not merely support the weight of the longitudinal hypothetical strut 200 and the transverse hypothetical strut 300, but must support the load of the upper structure, so the longitudinal hypothetical strut 200 and the transverse It is preferable to install the lateral hypothetical strut 300 in close contact with the pillar steel frame 100 as much as possible.

On the other hand, the transverse hypothesis strut 300 and the longitudinal hypothesis strut 200 are preferably formed of H-beams of the same standard.

In addition, as illustrated in FIG. 4, the transverse hypothesis strut 300 and the longitudinal hypothesis strut 200 preferably include through holes H formed at regular intervals on both sides of the upper flange and the lower flange. . With this configuration, it is possible to exclude welding and drilling operations in the field.

That is, the transverse hypothesis strut 300 and the longitudinal hypothesis strut 200 may be manufactured in advance with the same standard to secure economic efficiency. After installation, the part with insufficient length can be adjusted by installing a separate hydraulic jack.

The first buckling prevention angle 500 is a section steel having an L-shaped cross section, one end of which is coupled to the lower surface of the upper flange of the transverse hypothetical strut 300.

The second buckling-prevention angle 400 is a section steel having an L-shaped cross section that is the same shape as the first buckling-prevention angle 500, one end of which is coupled to the upper side of the lower flange of the longitudinal hypothetical strut 200.

At this time, the other end of the first buckling prevention angle 500 and the other end of the second buckling prevention angle 400 are combined, the transverse hypothesis strut 300, the longitudinal hypothesis strut 200, and the first buckling prevention angle The 500 and the second buckling prevention angle 400 are disposed in a form surrounding the pillar steel frame 100. Therefore, it is possible to prevent the transverse hypothesis strut 300 and the longitudinal hypothesis strut 200 from buckling by the lateral pressure applied to the transverse hypothesis strut 300 and the longitudinal hypothesis strut 200.

Specifically, the first buckling-prevention angle 500 is disposed in the form of a and the upper surface of one end is coupled to the lower surface of the upper flange of the transverse hypothetical strut 300,

The second buckling-prevention angle 400 is disposed in the form of b and is fixed in a form that surrounds the column steel frame 100 by coupling one lower surface to the upper surface of the lower flange of the longitudinal hypothetical strut 200.

The first buckling prevention angle 500 and the second buckling prevention angle 400 are preferably combined by bolt / nut coupling.

Depending on the practitioner, the second buckling prevention angle 400 can be further fixed to the flange of the pillar steel frame 100 by bolt / nut coupling.

In the coupling auxiliary member 700, the other end of the first buckling-prevention angle 500 and the other end of the second buckling-prevention angle 400 are disposed between the coupling surfaces.

At this time, the coupling auxiliary member 700 is preferably formed to have a thickness corresponding to the sum of the thickness of the upper flange of the transverse hypothetical strut 300 and the thickness of the lower flange of the longitudinal hypothetical strut 200. .

As described above, according to the hypothetical strut support structure 1000 according to the present invention, it is possible to construct a frame of the ground structure before the underground frame is completed.

At this time, a reinforced concrete structure such as an RC plateless plate or an RC ramen structure may be applied to the frame of the underground structure.

Although described with reference to the above embodiments, those skilled in the art understand that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Will be able to.

1000: temporary strut support structure
100: pillar steel frame
200: longitudinal hypothesis strut
300: transverse hypothesis strut
400: second buckling prevention angle
500: first buckling prevention angle
600: temporary bracket
700: joining auxiliary member
H: Through hole

Claims (7)

Pillar steel frame forming the pillar of the underground structure of the building;
A temporary bracket provided on a flange of a section steel constituting the pillar steel frame;
Supported by the hypothetical bracket, one end supports a first retaining wall provided for forming the underground structure, and the other end supports a second retaining wall provided on a surface facing the first retaining wall. Hypothetical struts;
Supported by the transverse hypothetical strut, one end is disposed to be orthogonal to the transverse hypothetical strut to support a third retaining wall provided for forming an underground structure, and the other end faces the third retaining wall A longitudinal hypothetical strut supporting a fourth retaining wall provided in the;
A section steel having an L-shaped cross-section, wherein one end is coupled to a lower surface of the upper flange of the transverse hypothetical strut; a first buckling-prevention angle; And
As a section steel having an L-shaped cross section, one end includes a second buckling prevention angle which is coupled to the upper side of the lower flange of the longitudinal hypothesis strut,
The other end of the first buckling-prevention angle and the other end of the second buckling-prevention angle are combined to form the lateral transverse hypothesis strut, the longitudinal hypothesis strut, the first buckling prevention angle, and the second buckling prevention angle. Air shortening hypothesis strut support structure, characterized in that arranged in a form surrounding the pillar steel frame. delete The method according to claim 1,
The transverse hypothesis strut and the longitudinal hypothesis strut,
Air shortened hypothesis strut support structure characterized by being formed of H-beams of the same standard. The method according to claim 3,
The transverse hypothesis strut and the longitudinal hypothesis strut,
Air shortened hypothesis strut support structure, characterized in that it has through holes formed at regular intervals on both sides of the upper flange and the lower flange. The method according to claim 3,
The first buckling prevention angle,
Air shortened hypothesis strut support structure is arranged in a form, characterized in that the upper surface of the one end is coupled to the lower surface of the upper flange of the transverse hypothesis strut. The method according to claim 5,
The second buckling prevention angle,
Arranged in the form of b, the air shortened hypothesis strut support structure, characterized in that the lower surface of the one end is coupled to the upper surface of the lower flange of the longitudinal hypothetical strut. The method according to claim 6,
The other end of the first buckling prevention angle and the other end of the second buckling prevention angle further includes a coupling auxiliary member disposed between the coupling surfaces,
The coupling auxiliary member,
And a thickness corresponding to a sum of the thickness of the upper flange of the transverse hypothesis strut and the thickness of the lower flange of the longitudinal hypothesis strut.

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