KR100941437B1 - 2 arch tunnel construction method for upper girder void proofing and efficient construction - Google Patents

Abstract

PURPOSE: A construction method of two arch tunnels capable of excluding the air gap of a top girder is provided to improve stability and economical efficiency by being structurally stabilized. CONSTITUTION: A construction method of two arch tunnels capable of excluding the air gap of a top girder is constituted as follows. A short concrete is poured in a ceiling portion(A) of a middle tunnel(100). The short concrete surface of the lower part of the ceiling portion is projected to a downward curved surface and a ceiling portion short concrete(120) is formed. A top girder upper side is placed on the bottom of the short concrete. The short concrete has a fixed gap in a tunnel length direction. A guide bar is installed on the both ends.

Description

2 ARCH TUNNEL CONSTRUCTION METHOD FOR UPPER GIRDER VOID PROOFING AND EFFICIENT CONSTRUCTION}

The present invention relates to a method of constructing a two-arch tunnel that can improve the workability and can be voided the upper girder. More specifically, in order to construct an arch-shaped tunnel, first, install a central tunnel, and install an upper girder extending in the longitudinal direction on the upper side of the central column installed in the center of the central tunnel, and then, on the left and right of the central column on which the upper girder is formed. In the construction method for forming an arch tunnel (main line tunnel), that is, the two arch tunnel construction method, the invention relates to the construction method of the upper girder.

In general, the two arch tunnel first excavated the central tunnel 10 as shown in Figure 1a, and then install the central column 11 in the central tunnel, the left and right tunnels of the central tunnel 10 through the mechanical drilling or blasting method Construction will be carried out in the order of excavating the main tunnel 20, 30.

The shape of the upper girder 40 formed on the upper portion of the central column 11 is a trapezoidal shape in which the lining ends 21 and 31 of the left and right tunnels are supported on both upper sides as shown in FIG. 1B. Concrete lining connection portion) and the upper spherical shape of the spherical shape 42 formed on the upper portion of the lower sphere (upper crown).

In particular, both sides of the upper sphere 42 is made of an inclination, as shown in Figures 1c and 1d, the work required for installation of the formwork for the production and processing and assembly of reinforcing bars 43 of various thicknesses, installation of a waterproof membrane for waterproofing the tunnel There is a problem that the space is difficult to secure, the construction is difficult and the quality control is not easy.

This is because the shape of the upper girder 40 is formed in the shape of a polygonal shape, the inclined rebar processing and assembly for manufacturing the upper girder is complicated and the construction is inferior, and there is insufficient space to protect the waterproof membrane of the central tunnel and the left and right tunnels It was the cause of the leakage at the connection.

In addition, as shown in FIG. 1C, when the concrete 12 for forming the upper girder 40 is formed, the voids 12 are generated on the upper surface thereof, and thus, cement mortar filling is required for the voids generated after the construction of the upper girder.

In general, however, such filling is not performed in a tight manner, and as a result, structural integrity between shotcrete and the structure cannot be maintained, so that settlement occurs due to the loading action during the construction of the two arch tunnel, which acts as an additional load on the structure. There was a problem that the structurally weak section.

Therefore, the present invention in the construction of the two-arch tunnel upper girder, in particular, by modifying the shape of the upper sphere to enable a work space for the waterproof membrane and the upper girder construction for tunnel waterproofing, rebar processing and assembly for manufacturing the upper girder is It is easy to improve the construction and economical efficiency, and it is a technical problem to solve the problem that it is possible to maintain the structurally stable cross-section and to construct an efficient two arch tunnel by eliminating the occurrence of upper voids when constructing the upper girder.

The present invention to achieve the above technical problem,

First, the upper sphere (upper crown) of the central column, which is constructed so that the upper part is in contact with the top end of the central tunnel, is formed in the form of a simple rectangular parallelepiped (rectangular sphere) so that the workability and quality due to the formwork and concrete pouring for the construction It is easy to manage, and it is easy to process and assemble the reinforcement inside the formwork to improve the constructability of the structure.

That is, by modifying the shape of the upper sphere (upper crown) constituting the upper girder (polygon ==> square sphere), the free space of the upper girder and the central tunnel is expanded to protect the waterproof membrane for connection of the waterproof membrane to the main tunnel. It is possible to prevent damage to the waterproof membrane due to securing of space and cutting of steel retainer, so that it is possible to prevent leakage of structural connections that are likely to occur in the two arch tunnel.

Third, the finishing shotcrete, which is generally used in order to exclude the occurrence of voids in the upper part of the girder of the two arch tunnel, was cast into the surface in advance to maintain the structural integrity of the shotcrete and the structure.

In the construction of the two arch tunnel according to the present invention, the construction work of the upper girder of the center pillar is not only very easy, but also protects against damage of the waterproof membrane and can be structurally stabilized by excluding voids generated in the upper part of the girder. Therefore, it is possible to construct the two arch tunnel with excellent constructability, economical and improved stability.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

First, the central tunnel 100 for the construction of the two arch tunnel as shown in Figure 2a will be constructed first.

Such a central tunnel 100 is typically constructed by a NATM method by explosive blasting, and such a NATM method is formed immediately after a tunnel-shaped tunnel excavation surface is formed by explosive blasting, and immediately supports the primary support (110, SHOTCRETE, shotcrete). ) Is installed on the tunnel excavation surface to settle the behavior of the base rock early, and the rock bolt (not shown) is inserted radially into the base ground on the back of the tunnel excavation surface to prevent loosening of the ground around the tunnel excavation surface and to seal between the rocks. The effect can be secured.

At this time, the secondary support material such as concrete lining, which is not shown, is additionally installed on the tunnel excavation surface formed with the rock bolt and the shotcrete to complete the final tunnel.

In this case, when the shotcrete 110 is poured as shown in FIG. 2B, the shotcrete 110 casted on the top end portion A of the arched tunnel excavation surface is formed to protrude further downward.

This downwardly protruding portion will be referred to as the top end shotcrete 120, and thus the top end shotcrete 120 is later formed on the upper part of the upper girder 310, 320, the lower sphere of the concrete lining connection and the upper sphere of the upper crown. Concrete does not fill the surface tightly inside the formwork to fill the free space causing leakage into the tunnel.

Therefore, since the top end shotcrete 120 to be formed to fill the free space is naturally formed by the shotcrete 110, it may not be easy to accurately form the thickness thereof.

Therefore, in the present invention, first, at the top end portion A, there is a predetermined interval in the longitudinal direction (length direction) of the tunnel, and the center end is exposed downward from the top end portion A so that the horizontal shot is installed at both ends thereof. The guide bar 130 is first installed to be lodged in the 110.

The guide bar 130 is to be embedded in the primary shotcrete 110, the both ends of the guide bar by using a reinforcing bar, but the portion between the two ends to be exposed to the outside.

Accordingly, it can be seen that the guide bar 130 is referred to as a guide bar in that it can guide the final shape of the top end concrete according to its installation form.

That is, by placing the secondary shotcrete so that the guide bar is buried based on the guide bar 130, it protrudes below the top end A so that the curved top shotcrete 120 naturally has a predetermined thickness and curved surface. To be formed.

The guide bar 130 may be set to adjust the position setting and the thickness of the top end shotcrete 120.

Next, also the construction of the central pillar as shown in Figure 2a, in order to be installed first by the formwork and concrete pouring the pillar portion 400 in the lower portion of the top (A).

Next, the upper girder 300 is constructed by the lower sphere 310 and the upper sphere 320, which is the upper portion of the concrete lining connection.

First, the reinforcing bars according to the overall shape of the lower sphere 310 and the upper sphere 320 are first assembled and installed on the upper surface of the pillar 400.

Although not shown, while assembling and installing the reinforcing bars, drain pipes are arranged in advance in the longitudinal direction of the tunnel.

After the reinforcing bar is finally installed separately to the scaffold around the pillar 400, it is assembled and installed under the top end shotcrete 120 formed in the central tunnel 100 as a work.

When the rebars are all installed, the formwork is installed around the reinforcement according to the shape of the upper girder 310 and 320, and the final upper girder is completed by filling concrete in the formwork.

At this time, the final shape of the lower sphere 320 is gathered inwardly to be bent in a rhombus shape while being gathered inwardly from the top of the pillar part 400 so as to cover the end of the concrete lining 510 of the main line tunnel to be described later. It is formed in the cross-sectional shape.

The end of the concrete lining 510 is in contact with the bending paper surface (B) collected inward.

Next, the upper sphere 320 which is an upper crown of a rectangular sphere shape (sphere shape) is formed on the upper portion of the lower sphere 310.

At this time, in the case of the conventional lower sphere and the conventional upper sphere as a whole rhombus cross-sectional shape, there was a problem that its manufacturing is not easy, such as reinforcing assembly and formwork installation in a narrow space, but in the present invention in particular as shown in Figure 2a and 2c As the 320 is formed in the form of a simple rectangular sphere (sphere), it is very easy to work in the installation of reinforcing bars 321 and formwork installed therein, and free space (C) from the workbench installed around It can be seen that the worker's work efficiency can be expected.

In addition, the upper spherical body 320 and the top end portion A are additionally constructed with a waterproof membrane such as a waterproof sheet due to leakage problems caused by inflow of groundwater.

After the waterproof membrane is installed in advance at the top end portion A, the work is connected to the concrete lining of the main line tunnel and the waterproof membrane which will be described later. In the upper crown of the conventional rhombus cross section, such a connection space is provided. It is not easy to secure, the problem of leakage through the bar has always been pointed out in the present invention can be easily secured by changing the shape of the upper crown in the shape of the upper crown in the rectangular shape of the waterproof means, such as leakage The problem can be solved.

In the state in which the formwork according to the shape of the lower sphere 310 and the upper sphere 320 and the reinforcing bars are assembled, the concrete in the form of the upper girder (300: 310, 320) according to the present invention Completed.

That is, when the concrete is filled in the closed formwork, the concrete is filled from the bottom of the formwork, which forms a hole in the top of the formwork, and generally follows the procedure of filling the concrete through the hole.

However, concrete should be filled tightly inside the formwork, but according to the upper form of the formwork, that is, the upper part of the upper crown, the free space is formed, which is the construction of the tunnel has been a problem of leaking soon.

Therefore, in the present invention, since the top end shotcrete 120 protruding downward from the top end portion A is formed in advance, it can be seen that the concrete can be tightly filled inside the formwork without making such a spare space.

Next, when the upper girders (300: 310, 320) is finally completed, the main tunnel 500 is also formed by the NATM method as shown in FIG. 2A, and the shotcrete, which is the primary supporting material, is poured, and rock bolts are installed. Then, lining concrete, which is a secondary support, will be constructed.

At this time, the end of the concrete lining is to be supported on the upper bending surface of the lining connecting portion, so that the two arch tunnel by the central tunnel and the main tunnel can be formed.

1A, 1B, 1C, 1D and 1E are cross-sectional views, excerpts and cross-sectional views schematically showing the construction stage of a conventional two arch tunnel,

2a, 2b and 2c are cross-sectional views showing the construction step of the two arch tunnel according to the present invention.

<Simple description of the main reference signs>

100: center tunnel

110: shotcrete

120: Temple end shotcrete

121: 1st shotcrete 122: 2nd shotcrete

130: Guide bar

300: upper girder

310: lower sphere (concrete training connection) 320: upper sphere (upper crown)

400: pillar 500: main line tunnel

Claims (2)

After forming the central tunnel 100 to form the upper girder (300: 310, 320) formed on the upper portion of the central column of the central tunnel of the two arch tunnel to form the main tunnel 500 on both sides of the central tunnel. In Shotcrete is poured into the top end portion A of the central tunnel 100 to form the top end shotcrete 120 formed by protruding the shotcrete surface below the top end portion downward curved surface, An upper girder is formed on the bottom surface of the top shotcrete 120 to be in contact with the upper girder formed on the upper portion of the center pillar, wherein the upper girder is a concrete sphere connecting portion formed on the upper portion of the pillar 400 of the central pillar 310 To form an upper sphere 320 which is an upper crown in the form of a square sphere extending upwards, The shotcrete protruding downwardly from the top end of the top end has a predetermined distance in the tunnel length direction and is horizontally installed downward from the top end of the shotcrete, but both ends thereof are guided to the primary shotcrete 110. After installation, the construction of the secondary arch of the second shotcrete so that the guide bar is buried so that the construction of the shotcrete protruding to the lower surface of the top end portion according to the guide bar, the construction method of the two arch tunnel can be removed the upper girder void. delete

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