KR101077242B1 - Construction method of basement structure using retaining wall and steel column - Google Patents

Abstract

The present invention comprises the steps of constructing the retaining wall (100) along the boundary line of the underground structure; Installing the internal steel column 110 at a location where the column should be installed; Installing the outer steel frame pillars 120 at predetermined intervals inside the earth wall 100; Performing a first digging to expose a portion of the retaining wall (100), the inner steel column (110), and the outer steel column (120); Connecting the outer cheolgolbo 130 between the outer steel pillars 120; Connecting the inner steel beams 140 between the inner steel pillars 110 and the outer steel pillars 120 and between the inner steel pillars 110; Constructing a slab by placing concrete on the steel gimbal of the remaining portion except for the portion where the outer steel pillar 120 and the outer steel gimbal 130 are located; Repeating the above steps to build the slab (S1) (S2) (S3) and the bottom layer (B) to the construction depth of the underground structure; And continuously constructing the basement outer wall 150 upwards from the bottom layer (B) to the ground.

Underground structures, retaining walls

Description

Construction method of basement structure using retaining wall and steel column {Construction method of basement structure using retaining wall and steel column}

The present invention relates to a method for constructing an underground structure, and more particularly, in the top-down method of digging down an underground structure while digging, it does not need to install a steel pillar in the retaining wall, and also in the retaining wall. It is possible to construct the structure simply and easily by using the earth wall and the minimum number of steel poles installed in close proximity to the earth wall without the need to install a temporary support means such as a steel frame for supporting the steel frame to be connected to the steel column. It is about a method of constructing underground structures.

The method of constructing underground structures can be largely divided into net and reverse methods, which can be excavated to the depth of underground construction while supporting the wall of walls formed on the outside of the underground structure by means of temporary support such as struts. Dismantling the temporary support means by constructing the structure sequentially from the floor to the ground.

On the other hand, the reverse drilling method, called Top-Down method, performs the underground excavation and at the same time casts the slab and builds the slab structure sequentially from the ground to the ground while acting as a support for the transverse pressure. It is a way.

As an example of such a top-down method, Patent Registration No. 0531385 discloses a method for constructing an underground structure that enables continuous construction of an underground outer wall by using a buried steel band and slab film forming action.

According to the above method, the retaining wall 1 is constructed in a conventional manner, and the steel frame 2 is usually installed in the retaining wall 1 to about 1.6 m. Then, as shown in Figures 1a and 1b, after the excavation work to break the concrete wall to connect to the steel column (2) embedded in the retaining wall (1) to expose the steel column (2) and then the steel frame The steel frame base 3 is attached to the side surface of the pillar 2.

Subsequently, the steel frame strip 4 is horizontally installed on the upper portion of the steel frame base 300, and an inner horizontal beam 5 is installed between the steel frame strip 4 and the column steel frame.

Finally, concrete is poured on top of the inner horizontal beam 5 to form a concrete slab. While further digging, the above process is repeated to build an underground structure.

However, in the above process, since the steel frame base must be installed on the side of the steel pillars embedded in the earthen wall to support the steel strips, construction materials and processes are very complicated and cumbersome, and thus, air extension is inevitable. In particular, in order to install the steel frame base to expose the steel frame embedded in the wall of the earthquake, the inconvenience of having to remove the concrete wall forcibly follows.

In addition, in order to install the steel frame, the earthenware wall requires much earthen material, because the earthenware is secured only by the earthenware wall and the rigidity is guaranteed.

The present invention is to solve the above problems, there is no need to install a separate member, such as steel frame strip without installing a separate steel frame pillar and installation and installation of a separate steel pillar inside the earth wall wall structure of the earth wall It is an object of the present invention to provide a method of constructing an underground structure, which can be constructed by a simple and easy top-down method regardless of the type.
In addition, the present invention, since the slab (S1) (S2) (S3) of each layer is pre-installed only to the boundary line of the basement outer wall can be constructed continuously from the bottom layer (B) to the ground without breaking the basement outer wall 150 and It is an object of the present invention to provide a method for constructing an underground structure in which the outer steel column 120 and the outer steel frame 130 are embedded in the basement outer wall 150.

Underground structure construction method according to a preferred embodiment of the present invention in order to achieve the above object, the step of building a wall along the boundary of the underground structure; Installing an internal steel column at a location where the column is to be installed; Installing outer steel pillars at predetermined intervals inside the retaining wall; Performing a first trench to expose a portion of the retaining wall, the inner steel pillar, and the outer steel pillar; Connecting an outer cheolgolbo between the outer steel pillars; Connecting an inner steel beam between the inner steel pillars and the outer steel pillars and between the inner steel pillars; Constructing a slab by pouring concrete on the steel gimbal of the remaining portion except for the portion where the outer steel pillar and the outer steel gimbal are located; Repeating the above steps to build the slab and the bottom layer to the construction depth of the underground structure; And continuously constructing an underground outer wall upward from the bottom layer to the ground.

Preferably, the underground structure construction method of the present invention comprises the steps of installing the steel casing at intervals to be installed the outer steel pillars; Inserting and installing the outer steel column inside the steel casing; And removing and removing the steel casing to expose a portion of the outer steel pillar.

More preferably, the empty space inside the steel casing in which the outer steel column is inserted is filled with sand or soil.

In addition, it is also possible to build a concrete stake in the lower end of the outer steel pillars.

Preferably, the space between the earth wall and the outer cheolgolbo may be filled with a filling material.

According to the method of construction of underground structures of the present invention, it is possible to secure the safety and rigidity only by the wall of the earth during the construction stage, so there is no need to install a steel column separately inside the wall of the earth, and also install a temporary member such as a steel frame to support the steel band. Since there is no need, the material required for construction is not only reduced, but also the construction period is relatively simple and easy, which shortens the construction period.

In addition, in the method of constructing the underground structure of the present invention, since the structure of the earthquake wall is not attached or installed to the earthenware wall or structurally independent behavior, it is not limited to the structure or type, so it is possible to prevent the earth and earth collapse. There is an advantage that different types of retaining walls can be employed.

Furthermore, in the present invention, unnecessary processes such as forcibly removing a part of the concrete of the retaining wall to attach the steel frame or the steel frame are eliminated, thereby improving construction efficiency.
In addition, since the slab (S1) (S2) (S3) of each layer is pre-installed only to the boundary line of the basement outer wall, the basement outer wall 150 can be continuously constructed from the bottom layer (B) to the ground without being cut off, the outer steel frame The pillar 120 and the outer cheolgolbo 130 provides a construction method for underground structures embedded in the basement outer wall 150.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Underground structure construction method according to the present invention is largely, the process of installing the wall of the earth along the building boundary line and the inner steel pillars in the position to be the pillar of the building, the process of installing the steel steel casing and the outer steel pillars therein, 1 Removing the steel casing after exposing the car and exposing the outer steel pillars and the inner steel pillars, installing the outer steel beams between the exposed outer steel pillars, and installing the inner steel beams between the outer steel pillars and the inner steel pillars; and It includes a step of building a slab by pouring concrete on the inner cheolgolbo.

Then, the processes will be described in more detail.

Construction of wall

According to the method for constructing an underground structure of the present invention, first, as shown in FIG. 2, the wall wall 100 is constructed along the boundary line of the underground structure to be constructed. According to the characteristics of the present invention, since the steel frame base or the band is not installed on the wall 100, there is no restriction in the structure or type of the wall to be constructed. Thus, the retaining wall 100 may be constructed by various methods already known in the art.

As an example of such a wall construction, pile pile plate wall wall, which inserts piles such as H-beams at regular intervals (about 1.6n) and inserts soil plates between piles while carrying out excavation, and concrete at the construction site For example, cast-in-place piles (CIPs), which are used to cast soil walls, are also typical, including Soil Cement Wall (SCW) and Diaphragm Wall.

The retaining wall 100 according to the present invention does not need to be provided with steel pillars for the installation of steel frame bases or steel strips, and may be composed of only concrete and steel bars. In addition, even when provided with steel pillars can be spaced apart in about 12m.

By constructing the soil wall 100 by the above-described method, it is possible to prevent the collapse of the earth and sand even if the underground trench in the subsequent process.

Internal steel column installation

When the construction of the earth wall 100 is completed, as shown in Figure 3, according to the design of the building to be built in accordance with the design of the column to install the inner steel pillars 110 in the position to be installed.

The inner steel column 110 may be installed in a required position using an existing anti-punching method or a landfill method after drilling the ground as an H-beam.

Preferably, the lower portion of the internal steel pillar 110 is a foundation of the foundation 112 by a known reverse circulation drill (RCD) method or percussion rotary drill (PRD) method, etc. to properly load the load transmitted from the upper structure to the ground Allow for distributed delivery.

Outer steel column installation

According to a feature of the present invention, the outer steel wall pillars 120 are installed at predetermined intervals independently of the retaining wall 100, and the outer steel steel beams 130 and the inner steel steel beams 140 are installed on the basis thereof.

For this purpose, as shown in Figures 4 to 6, the outer steel pillars 120 are installed by driving the steel casing 122 in the ground at appropriate intervals to be installed. The steel casing 122 is a cylindrical member with a hollow formed therein, the soil is removed to be empty, the outer steel column 120 is inserted therein (see FIG. 5).

By supplying concrete to the lower end of the outer steel pillars 120 to build the concrete pile 124 in place to fix the outer steel pillars 120 and at the same time to distribute the load applied from the structure to the ground function. Preferably, the upper surface of the in-situ concrete pile 124 is formed to the final depth of pit of the basement layer.

In addition, the empty space inside the steel casing 122 in which the outer steel pillars 120 are inserted is filled with sand or soil 126.

Primary Dig

Subsequently, when the installation of the inner steel pillars 110, the steel casing 122 and the outer steel pillars 120 is completed, as shown in FIG. Here, the depth of the primary trench is preferably at least corresponding to the depth of basement 1, but is not necessarily limited thereto.

As the trench proceeds as described above, a portion of the upper end of the retaining wall 100 and the inner steel pillar 110 is exposed.

Then, by removing the steel casing 122 to remove a portion of the upper end of the outer steel pillars 120. As described above, since the empty space inside the steel casing 122 is filled with sand or soil 126, the steel casing 122 may be relatively easily removed. Although the present embodiment has been described as removing the steel casing 122 after the first burst, it is not necessary to be limited to this order, and the steel casing 122 may be removed before proceeding with the primary trench. It should be understood as possible.

Cheolgolbo installation

When the primary demolition is finished to a predetermined depth as described above, the cheolgolbo is connected between the exposed outer steel pillars 120 and the inner steel pillars (110).

First, as shown in Figures 8 and 9, the outer steel cheolbo 130 is connected between the outer steel pillars 120. The outer cheolgolbo 130 may be a conventional H-beam or steel-concrete composite beam is attached to the precast concrete member to the H-beam. In this example, a typical H-beam is shown.

The outer steel cheolgolbo 130 may be connected by fixing the end to the outer steel frame pillar 120 by high-strength bolt or welding. If necessary, the outer steel frame pillar 120 may be further provided with a connecting bracket (not shown) and thereby mutually fastened.

Preferably, the space 128 between the retaining wall 100 and the outer cheolgolbo 130 is filled with a filler material 128 for the continuous transmission of the earth pressure and structural balance. The filler 128 may be made of a concrete or metal material.

In addition, as shown in FIG. 7, the inner steel beams 140 are connected between the inner steel frame pillars 110 and the outer steel frame pillars 120. Since the slab is poured on the upper part of the internal cheolgolbo 140 serves as a strut to support the earth pressure applied from the earth wall 100 during the construction of the basement layer and functions as a permanent structure after construction.

The inner cheolgolbo 140 may also be composed of a conventional H-beam or steel-concrete composite beam. Of course, the inner steel frame 140 will also be connected between the inner steel column 110 and the inner steel column (110).

The inner steel beams 140 may be fixed by fastening or welding the ends of the inner steel frame (110, 120) with high-strength bolt, preferably, the outer steel frame (120) or the inner steel column (110) The side flange is installed so that the connecting bracket (132 of FIG. 8) is protruded, the matching hole 134 formed in the connecting bracket 132 and the coupling hole 136 formed at the end of the inner cheolgolbo 140 After fastening bolts and nuts can be fixed.

Although embodiments of the present specification have been described in detail with respect to the connection method of the steel column and cheolgolbo, the present invention is not limited to such embodiments, it should be understood that can be interconnected by a variety of methods known in the art in addition to that do.

Slab construction

As described above, when the connection of the cheolgolbo 130, 140 is completed, the concrete is poured on the cheolgolbo 130, 140 to build a basement 1 floor slab (S1) as shown in FIG.

Specifically, after mounting the deck plate (not shown) on the cheolgolbo (130, 140) or install the formwork, the slab reinforcement (not shown) to reinforce the slab (S1) by pouring concrete to build the slab (S1) Can be.

Preferably, the slab (S1) is formed only for the remaining portion (that is, up to the construction scheduled line of the basement outer wall to be described later) except for the portion where the outer steel column 120 and the outer steel column 130 is located.

Lower floor continuous construction

When the first basement slab S1 is completed according to the above process, the above-described process is repeated repeatedly to build an additional basement structure.

That is, the secondary demolition is performed to a predetermined depth and connects the outer steel steel beams 130 and the inner steel steel beams 140 to the exposed outer steel pillars 120 and the inner steel pillars 110. Then, by placing concrete on the upper surface of the cheolgolbo 130, 140 to build a two-story underground slab (S2).

10 is a cross-sectional view of the underground structure in which the slabs S1, S2, and S3 are constructed to the construction depth by repeating the above process.

As described above, when the construction of the slab (S1), S2 (S3) and the bottom layer (B) of the underground structure to the construction depth of the building is completed, the basement outer wall 150 shown in Figure 11 from the bottom layer (B) It will be constructed smoothly upwards to the ground. Along with the construction of the underground outer wall 150, the core retaining wall, the SRC construction of the pillar portion, etc. are performed in parallel.

When the underground outer wall 150 is constructed, the outer steel column 120 and the outer steel column 130 are buried in the underground outer wall 150, and as described above, the slab S1, S2, and S3 of each floor are underground outer walls. Since only the boundary line of the pre-installed state, the basement outer wall 150 can be continuously installed to the ground without being cut off.

Although the present invention will be described in detail with reference to the following drawings, these drawings illustrate preferred embodiments of the present invention, and the technical concept of the present invention is not limited to the drawings and should not be interpreted.

1A and 1B are a partial perspective view and a plan view for explaining a method for constructing an underground structure according to the prior art.

Figure 2 is a cross-sectional view showing a state in which the construction of the retaining wall in accordance with the construction method of the underground structure according to an embodiment of the present invention.

3 is a cross-sectional view showing a state in which the internal steel pillars are installed in accordance with the method for constructing an underground structure according to a preferred embodiment of the present invention.

Figure 4 is a cross-sectional view showing a state in which the steel casing in accordance with the construction method of the underground structure according to a preferred embodiment of the present invention.

5 is a cross-sectional view showing a state in which the outer steel pillars are installed inside the steel casing according to the method for constructing an underground structure according to a preferred embodiment of the present invention.

6 is a plan view showing a state in which the outer steel pillars are installed inside the steel casing according to the method for constructing an underground structure according to a preferred embodiment of the present invention.

Figure 7 is a cross-sectional view showing a state connecting the cheolgolbo to the pillar in accordance with the construction method for underground structures according to an embodiment of the present invention.

8 is a cross-sectional view showing a state in which the outer cheolgolbo and the inner cheolgolbo connected to the outer steel frame pillar according to the method of construction of underground structures according to the preferred embodiment of the present invention.

FIG. 9 is a plan view illustrating a state in which an outer steel frame beam and an inner steel frame beam are connected to an outer steel frame column according to a method for constructing an underground structure according to a preferred embodiment of the present invention.

10 is a cross-sectional view illustrating a state in which a slab is sequentially constructed according to the method for constructing an underground structure according to a preferred embodiment of the present invention.

11 is a cross-sectional view showing a state of constructing the basement outer wall according to the method for constructing an underground structure according to a preferred embodiment of the present invention.

<Description of Major Reference Numbers in Drawing>

100: retaining wall 110: internal steel pillars

120: outer steel pillars 122: steel casing

128: Filler 130: Outer Cheolgolbo

140: inner steel frame 150: underground outer wall

S1, S2, S3: Slab B: Bottom Layer

Claims (5)

Constructing a retaining wall 100 along a boundary line of the underground structure; Installing the internal steel column 110 at a location where the column should be installed; Installing the outer steel frame pillars 120 at predetermined intervals inside the earth wall 100; Performing a first digging to expose a portion of the retaining wall (100), the inner steel column (110), and the outer steel column (120); Connecting the outer cheolgolbo 130 between the outer steel pillars 120; Connecting the inner steel beams 140 between the inner steel pillars 110 and the outer steel pillars 120 and between the inner steel pillars 110; Constructing a slab by placing concrete on the steel gimbal of the remaining portion except for the portion where the outer steel pillar 120 and the outer steel gimbal 130 are located; Repeating the above steps to build the slab (S1) (S2) (S3) and the bottom layer (B) to the construction depth of the underground structure; And And constructing the basement outer wall 150 continuously from the bottom layer (B) upwards to the ground. The method of claim 1, Driving the steel casing 122 at intervals at which the outer steel pillars 120 are installed; Inserting and installing the outer steel column (120) inside the steel casing (122); And And removing the steel casing (122) to expose a portion of the outer steel column (120). 3. The method of claim 2, The construction method of the underground structure, characterized in that the empty space inside the steel casing 122, the outer steel pillars 120 is inserted to fill the sand or soil (126). 3. The method of claim 2, Underground structure construction method, characterized in that to build the concrete pile 124 in place on the bottom of the outer steel pillars (120). 3. The method of claim 2, The underground structure construction method, characterized in that the filling space (128) to fill the space between the earth wall and the outer cheolgolbo 130.

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