KR20130004801A - Vertical column construction method of none-excavation underground structure - Google Patents

Abstract

PURPOSE: A method for constructing a vertical column for an underground structure is provided to vertically construct concrete columns by steel pipes for guide, and to reduce a construction period. CONSTITUTION: A method for constructing a vertical column for an underground structure comprises following steps. A guide steel pipe(14) is vertically installed in a place where a column is installed from the gallery pipe(12) at an upper gallery side at a predetermined depth by using a hydraulic jack. A column form(18) is installed inside the guide steel pipe after removing soil in the guide steep pipe. Concrete is placed into the column form and cured. A reinforcement connecting sleeve(24) for a haunch and a reinforcement connecting sleeve(28) for a slab are installed at the lower side of the guide steel pipe after excavating the circumference of the guide steel pipe. A main reinforcing bar for a haunch and a main reinforcing bar for a slab are respectively connected to the reinforcement connecting sleeve for the haunch and the reinforcement connecting sleeve for a slab, and a floor slab and haunch portion(2) are constructed in order.

Description

Vertical column construction method of none-excavation underground structure

The present invention relates to a vertical pillar construction method of an unattached underground structure, and more particularly, to a vertical pillar construction method of an unattached underground structure so that concrete columns can be vertically constructed.

The Tubular Roof Construction Method (TRCM) method, one of the non-opening methods for the construction of underground structures, uses steel pipes equipped with hydraulic controls between the leading pipe and subsequent pipes to adjust the linearity according to the longitudinal and transverse gradients in the work area. After press-fitting with pressurized jack, drilling the inside of steel pipe, reinforcing reinforcement and concrete to complete the upper slab, and installing underground vertical wall using precast panel and support jack, and excavating the inside of the tunnel to build the tunnel of the structure. It is a construction method.

This method installs work tools and reaction walls, pushes and excavates gallery pipes, pushes and excavates slab pipes, girder excavation and formwork, top slab concrete pouring, wall installation and concrete pouring (wall trench excavation, precast panels and support jacks). It will be installed in the order of earth pressure support, reinforcement of concrete in wall, concrete in gallery, tunnel excavation and structure installation.

This method is excellent in coping with soil changes, and because steel pipes are used as the structure, the construction cost is low and the air can be shortened.

On the other hand, when constructing the underground structure by the non-adhesive method to achieve a wide width to support the upper slab by standing a pillar in the center. The pillars shall then be placed vertically from the upper slab towards the bottom slab. Shear reinforcement structures are to be provided at the joint between the column and the floor slab.

Conventionally, in the case of installing a pillar in the center portion, the construction was mostly performed by an underpinning method using an H-beam. In general, under pinning is a method used when constructing piles to reinforce the structure when a new pile is piled up in or adjacent to an existing structure, and the H-beam is perpendicular to the upper slab side of the non-adhesive structure. In installation, there is a problem that the construction is complicated and the air is long.

Accordingly, the present invention was made in view of the above circumstances, and an object of the present invention is to provide a vertical pillar construction method of an unattached underground structure that allows the air to be shortened and to be installed vertically with the guide of the guide steel pipe. have.

According to a suitable embodiment of the present invention,

Press-fitting the guide steel pipe vertically by a predetermined depth using a hydraulic jack at a position where the pillar is to be installed from the upper slab-side gallery tube;

Removing the internal soil of the guide steel pipe and installing pillar formwork therein;

Pouring concrete into the pillar formwork to cure;

Excavating the circumference of the guide steel pipe and installing radially connecting the haunch rebar connecting sleeve and the slab rebar connecting sleeve on the lower side of the guide steel pipe in a plurality of upper and lower stages;

After connecting the rebar connecting slab and the slab reinforcing bar to the rebar connecting sleeve and the slab rebar connecting sleeve, respectively, the floor slab and the haunting part are sequentially constructed of concrete.

According to another suitable embodiment of the present invention, in order to match the verticality of the column formwork, the spacer is installed between the guide steel pipe and the column formwork around the column formwork.

According to another suitable embodiment of the present invention, after installing the reinforcing bar connecting slab and the reinforcing bar connecting slab for slab is characterized in that the construction by cutting and removing the guide steel pipe to be exposed to the upper portion of the haunch.

According to another suitable embodiment of the present invention, the column formwork is characterized in that the composite column is constructed using a steel pipe.

In the vertical pillar construction method of the non-adhesive underground structure according to the present invention, the concrete pillars are pressed after the guide steel pipe is vertically pressed from the gallery tube constituting the upper slab, and the concrete pillar formwork is supported inside the guide steel pipe. Can improve the vertical workability.

In addition, the concrete column formwork may be configured as a steel pipe formwork, in this case, a predetermined section of the lower side of the steel pipe formwork can realize a shear bonding reinforcement structure with the floor slab.

The following drawings, which are attached in the present specification, illustrate exemplary embodiments of the present invention, and together with the detailed description of the present invention, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
Figure 1a is an exemplary view showing the upper slab before the vertical column construction of the non-adhesive underground structure.
FIG. 1B is a cross sectional view taken along line AA of FIG. 1A; FIG.
Figure 2 (a), (b) is a process of indentation of the guide pipe and the construction of the column formwork in the vertical pillar construction method of the non-adhesive underground structure according to the present invention.
Figure 3 (a), (b) is an illustration of the concrete poured into the pillar formwork in Figure 2 and the state in which the reinforcing bar connecting sleeve is installed in the guide steel pipe.
Figure 4 (a), (b) is a state in which the main reinforcing bar is connected to the reinforcing bar in Figure 3;
5 is a cross-sectional view taken along line BB of FIG. 2.
Figure 6 is a perspective view showing a state in which the reinforcing bar is installed in the guide steel pipe in the vertical column construction method of the non-opening underground structure according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

The present invention provides a construction method for constructing a column between a wall and a wall by increasing the width of the underground structure in the construction of underground structures (for example, underground tunnels) by a non-adhesive method. In particular, when constructing the upper slab 10 of the underground structure as a gallery tube 12 as shown in Figure 1a and 1b provides a method for constructing a concrete column vertically in the gallery tube (12).

First, the guide steel pipe 14 is press-fitted into a position where a pillar is to be installed from the gallery tube 12 constructed on the upper slab 10 side as shown in FIG. At this time, the guide steel pipe 14 is press-fitted through the hole drilled in the gallery tube 12. Guide steel pipe 14 is press-fitted vertically by a predetermined depth using a hydraulic jack (16). Before the guide steel pipe 14 is press-fitted after the pre-extrusion is made, the hydraulic jack 16 is supported in the gallery tube 12 is installed to press the steel pipe 14 for the guide to the basement steel. Excavation may be accomplished by attraction or other mechanical means. Guide steel pipe 14 is divided into a plurality of welded to each other sequentially. At this time, the indentation depth of the guide steel pipe 14 is up to the position where the bottom slab 1 will be constructed. The diameter of the guide steel pipe 14 is smaller than the diameter of the gallery pipe 12 is selected.

Next, after the internal soil of the guide steel pipe 14 is removed, the pillar formwork 18 is installed therein as shown in FIG. The pillar formwork 18 may be, for example, a split formwork composed of steel pipes or other materials.

At this time, it is preferable that the spacer 15 is installed between the guide steel pipe 14 and the pillar formwork 18 around the pillar formwork 18 so as to match the verticality of the pillar formwork 18. The spacer 15 is provided at regular intervals in the height direction of the column formwork 18. Therefore, the column formwork 18 is supported by the guide steel pipe 14 via the spacer 15 to maintain the vertical state.

Next, the concrete is poured into the pillar formwork 18 and cured as shown in FIG. Therefore, inside the pillar formwork 18 is a pillar that is cured with concrete is formed, when the pillar formwork 18 is composed of a steel pipe is a synthetic column is constructed.

Then, after excavating the outer periphery of the guide steel pipe 14 as shown in (b) of FIG. 3, the rebar connecting sleeve 24 for the haunch and the rebar connecting sleeve 28 for the slab are disposed on the lower side of the guide steel pipe 14. ) Are installed radially in the upper and lower stages. In this case, the excavation area is an internal area of the structure formed by the wall of the underground structure and the upper slab, and includes the area where the floor slab is constructed. Excavation can be used with excavation equipment. The reinforcing bar connecting sleeve 24 for the haunch is for constructing the haunch unit 2, and the reinforcing bar connecting slab 28 for the slab is constructed to increase the bonding strength with the bottom slab 1. Since these rebar connecting sleeves 24 and 28 are well-known in the art as accessories for connecting reinforcing bars, detailed structural description thereof will be omitted. The haunting unit 2 serves as a protective wall for increasing the acupressure area or protecting the pillar.

Then, as shown in (a) of FIG. 4, a binding operation is performed to connect the cast bar reinforcing bar 26 and the slab cast bar 30 to each of the reinforcing bar connecting sleeve 24 and the slab rebar connecting sleeve 28, respectively. . In this case, the main reinforcing bars 26 and 30 may be disposed radially according to the connecting direction of the reinforcing bar connecting sleeves 24 and 28. In addition, the reinforcing bar is additionally coupled to the radially installed main reinforcing bars (26, 30), of course.

In this method, the reinforcing bar structure for reinforcement at the lower side of the column and the joint between the column and the floor slab is not limited to a particular type.

Then, the bottom slab 1 and the haunting portion 2 are sequentially constructed into a concrete structure by a conventional method in the art.

Here, after the installation of the reinforcing bar connecting sleeve 24 and the reinforcing bar connecting slab 28 for the slab is made of cutting of the guide steel pipe 14 to be exposed to the upper portion of the haunche. Therefore, the concrete pillar 200 in which the guide steel pipe 14 is removed to the upper portion of the haunch portion 2 is constructed. In addition, when the column formwork 18 is used as a steel pipe, the steel pipe is intact and becomes a composite pillar.

The pillars 200 of the non-attached underground structures constructed and constructed as described above are constructed at regular intervals along the underground direction of the underground structures in the same manner to stably support the wide upper slab 10.

The pillar 200 constructed by such a method is improved in verticality because the pillar formwork 18 is supported by the guide steel pipe 14 at the construction stage to match the verticality.

In addition, when the column formwork 18 is used as a steel pipe, it is possible to form a shear-reinforced joint structure connected to the steel pipe to a portion where the pillar 200 and the bottom slab 1 are joined.

In addition, it provides an advantage that the construction work is simplified compared to the underpinning method using a conventional H-beam.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

12: gallery tube
14: Guide steel pipe
18: pillar formwork
24: Rebar connecting sleeve for haunches
28: Rebar connection sleeve for slab
200: pillar

Claims (5)

Pressing the guide steel pipe 14 vertically by a predetermined depth vertically using the hydraulic jack 16 at a position where the column is to be installed from the gallery tube 12 on the upper slab 10 side;
Removing the internal soil of the guide steel pipe 14 and then installing pillar formwork 18 therein;
Pouring and curing concrete into the pillar formwork 18;
After excavating the periphery of the guide steel pipe (14), the step of installing the reinforcing bar connecting sleeve 24 and the slab rebar connecting sleeve (28) on the lower side of the guide steel pipe (14) radially in each of the upper and lower stages Wow;
The floor slab (1) and the haunting section (2) are made of concrete after connecting the reinforcing bar connecting slab (24) and the slab rebar connecting sleeve (28) to the rebar connecting slab (26) and the slab casting bar (30), respectively. Vertical pillar construction method of the non-impregnated underground structure, characterized in that the construction is sequentially constructed. The method of claim 1,
Non-adhesive, characterized in that the spacer 15 is installed between the guide steel pipe 14 and the column formwork 18 around the column formwork 18 to match the verticality of the column formwork 18. Construction method of vertical column of underground structure. The method of claim 1,
After installation of the reinforcing bar connecting sleeve 24 for slab and the reinforcing bar connecting slab 28 for slab, the vertical column construction of the non-adhesive underground structure, which is constructed by cutting and removing the guide steel pipe 14 to be exposed to the upper portion of the haunch section. Way. The method of claim 1,
Column formwork (18) is a vertical pillar construction method of the non-adhesive underground structure, characterized in that the composite pillar is constructed using a steel pipe. Claims 1 to 4 vertical pillars of the non-adhesive underground structure, which is constructed through the method of any one of claims.

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