KR100556975B1 - New Messer Shield engineering method - Google Patents

Abstract

The present invention relates to an improved Messer Shield (New Messer Shield) method for excavating a tunnel, and in particular, to perform tunnel excavation through a Dividered Messer Plate (DMP), which is applied to the Messer Shield method. Designed to be included in the structure of the support material to be installed on the upper and left and right sides of the structure to minimize the excavation cross-section to significantly reduce the construction cost, through the improved method of the shield method with a minimum excavation section that also significantly improved water tightness It is about.

In the present invention, when the tunnel excavation is made through the Messer plate, the waterproofing paper attached to one surface of the earth plate is in close contact with the wedge clip, as well as the installation of the wedge clip to the filler to prevent the separation of the waterproofing paper By placing in the space formed by the, to improve the efficiency and stability of the construction, and also to provide a construction method of the tunnel structure to minimize the excavation cross-section and to improve the structural performance by constructing the support material space.

Method shield method, method plate, excavation

Description

New Messer Shield engineering method with minimum digging section

1 is an exemplary view of a conventional method of shield method.

Figure 2 is a partial schematic view showing the construction cross section of a conventional tunnel structure.

Figure 3 is an excavation cross-sectional view of the tunnel formed by a conventional shield method.

Figure 4 is a structural diagram of the wedge clip applied to the construction of the tunnel structure of the present invention.

Figure 5 is an excavation cross-sectional view of the tunnel formed by the method of the mesmer shield method of the present invention.

6 to 12 is a tunnel structure construction process diagram of the present invention.

 Explanation of symbols on the main parts of the drawings

10,30; Waterproof paper, 20; Wedge clip, 40; Structural concrete, 41; Rebar, 50; Filling

The present invention relates to an improved Messer Shield (New Messer Shield) method for excavating a tunnel, and in particular, to perform tunnel excavation through a Dividered Messer Plate (DMP), which is applied to the Messer Shield method. Designed to be included in the structure of the support material installed on the upper and left and right sides of the structure when the excavation section is minimized, the construction cost is greatly reduced, thereby improving the Messier Shield method with a minimum excavation section that also significantly improved watertightness It is about.

Messer means MESS, or KNIFE, and the origin is found in the pointed part of the shape of the board used in this method. In this method of the shield method, the tunnel construction is schematically illustrated in FIG. 1, which will be briefly described as follows.

First, after assembling the rigid retainer 100 according to the shape of the tunnel to be excavated at the shaft entrance, and then to the outside of the retainer 100 to arrange a steel plate called a mesmer plate 200 in parallel to build a strong oscillation base. And when the excavation of the tunnel from the oscillation base proceeds the locking pin 301 protruding from the body of the hydraulic propeller 300 in the hydraulic propeller insertion hole 202 of the inner surface of the Messer plate 200 is densely arranged to the outside of the support material 100 ), And then install the hydraulic cylinder 302 of the front end to be supported by the adjacent support member 100, and then supplying the hydraulic pressure to the hydraulic propeller 300, the messer plate 200 one by one Penetration of the membrane proceeds as it penetrates into the membrane.

At this time, only one support material 100 is excavated, and as soon as excavation, the newly formed film surface is stabilized with the support membrane 500 using a shoring, and then a new support material 100 is installed here, where the first step of excavation is completed. This process is repeated to complete the tunnel excavation.

In addition, when pushing the mesa plate 200, the excavation surface between the support member 100 is exposed at the rear of the mesa plate 200 in accordance with the forward movement of the mesa plate 200, this portion is supported by the earth plate 600, especially the earth plate 600 ) Insert the wedge into the bottom portion to close the earth plate 600 to the excavation surface as close as possible.

Such a method can be called a very safe method compared to other methods because it can be safely installed in the mesa plate 200 in parallel, such as membrane drilling, earth plate 600 installation and support material 100 installation in parallel Therefore, this method of shield construction has been applied in various fields such as highway crossing tunnel construction, subway tunnel construction, power and communication zone construction, and various culvert construction works.

However, in the conventional mesa shield method, the earth plate 600 is installed between the support member 100 so as to prevent the groundwater from entering the construction site during the tunnel excavation by oscillating the mesmer plate 200 While installing the waterproof paper (1) on one side of, while the waterproof paper (1) installation of a predetermined section is made, the waterproof paper (1) by placing a lightweight filled concrete (2) of relatively small strength between the support material 100 After the construction of the preliminary structure in the working section by the fixed method, the formwork is installed therein, the reinforcing bar (3) is reinforced, and the structural concrete (4) having a relatively high strength is placed therein to complete the structure. .

That is, when tunnel excavation is made through the Messer plate 200, the earth plate 600 positioned between the support material 100, which is not attached to the waterproof paper 1, on one surface of the earth plate 600 closely contacted with the support material 100. Only the exposed surface of the cover is covered with a waterproof paper (1), which is when the waterproof paper (1) is attached to the support material 100, the attached waterproof paper (1) is torn by the messer plate 200 proceeds for tunnel excavation This can cause damage to the back, which is why it loses its waterproof function.

In other words, in the conventional Messier shield method, the filled concrete that is placed on the support material is relatively low strength, which is limited to the purpose of attaching waterproof paper only without considering the resistance against external working load. Therefore, the tunnel excavation cross section is enlarged due to securing the separate installation space of the filled concrete (2) and structural concrete (4), as shown in FIG. Therefore, it was necessary to excavate additional space for installing the preliminary structure separately from the present structure that forms the design section of the tunnel, and this was to act as a main reason for increasing the construction cost.

In addition, according to the conventional method of the shield method, the construction has been accompanied by ground subsidence due to groundwater flowing out of the tunnel wall during tunnel excavation.

The present invention has been made to solve the conventional problems as described above, by minimizing the excavation cross-section by designing to be included in the structure of the support material installed on the upper and left and right sides of the structure when the tunnel excavation using the method plate Its main purpose is to provide an economically efficient method for shielding the construction cost.

Another object of the present invention is to install a waterproof paper on the outer surface of the support material for guiding the mesmer plate, but also to maintain the contact with the earth plate installed on the outside so that the waterproof paper is not damaged by the mesmer plate, dry operation While providing space and minimizing groundwater outflow, it is intended to provide a method and shielding method with improved construction and watertightness that can effectively prevent ground subsidence.

Another object of the present invention is to reduce the area of ground relaxation through the reduction of the excavation cross section, and further, the distance between the left and right support members in the height direction and the width direction is shortened to provide structural stability, and at the same time to add reinforcing bar to the inside of the support member. It is to provide a method shield method that greatly increases the structural stability of the structure by completing the structure by placing.

In the present invention, the support material is installed according to the tunnel shape to be excavated, and the earth plate is arranged outside the support material by advancing the method plate along the support material, and the filling concrete is poured on the inner wall to stabilize the inner surface of the excavated tunnel. Next, in the general method of the shield method of constructing the structure, the first waterproofing resin is installed on the outer surface of the supporting material, and the left and right ends of the first waterproofing resin exposed to the outside of the supporting material are supported by a U-shaped wedge clip. A first waterproofing installation step of being wrapped by the first waterproofing resin; A tunnel excavation process of carrying out tunnel excavation by advancing a messer plate on an outer side of the supporter supporting the first waterproofing material with a wedge clip; The earth plate is installed along the direction of the mesmer plate, and the U-shaped wedge clip surrounding both ends of the first waterproofing resin is separated from the support material, and then rotated and inserted between the earth plate and the support material, thereby inserting the support material. An earth plate and a first waterproofing contact step of allowing the first waterproofing material to be in close contact with the left and right wing portions of the first waterproofing material spaced apart from the support material and the ends of the earthing plate; A second waterproofing installation step of installing a second waterproofing material so as to cover the earth plate exposed between adjacent supporting materials, wherein the left and right ends of the second waterproofing material are exposed to the left and right sides of the supporting material and are bonded to the wing of the first waterproofing material to be integrated; Constructing a preliminary structure in the tunnel by arranging a filler in a space spaced from the earth plate and the support material spaced by the U-shaped wedge clip sealed with the first and second waterproofing materials; Constructing a predetermined main structure by reinforcing reinforcing bars and placing structural concrete inside the tunnel in which a preliminary structure is constructed; Characterized in that made.

The first waterproofing paper is composed of a wing portion exposed to the left and right sides of the support material so as to be coupled to the central portion in close contact with the support material, and the second waterproofing paper for covering the earth plate exposed between adjacent support materials; It is preferable to further include a step of adhering the second waterproofing resin for covering the earth plate to the wing portion exposed to the left and right of the support material.

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

Figure 4 is a structural diagram of the wedge clip applied to the construction of the tunnel structure of the present invention, Figure 5 is an excavated cross-sectional view of the tunnel formed by the method of the mesmer shield method of the present invention, Figure 6 to Figure 12 the tunnel structure of the present invention It is process chart of construction.

As shown in the figure, after installing the oscillation base at the tunnel entrance and installing the support 100 according to the shape of the tunnel to be excavated, the method plate 200 is arranged outside the support 100, and then these message plates ( 200 to oscillate to the oscillation base to construct a tunnel by arranging the earth plate 600.

In addition, the support member 100 is continuously arranged in the tunnel along the traveling direction. At this time, as shown in FIG. 6, the first waterproofing material 10 is installed on the outside of each support material 100 which is continuously arranged. As shown in FIG. 4, the left and right ends of the first waterproof resin 10 are formed on the left and right wing portions of the support 100 by a wedge clip 20 formed in a U shape. Secure to wrap.

The U-shaped wedge clip 20 is specifically shown in FIG. This is to maintain a constant thickness so that the first waterproofing resin 10 can be kept spaced apart from the Messer plate 200, and also durable so that the first waterproofing resin 10 is not easily detached from the support 100. A member of high elasticity is used.

After supporting the first waterproofing resin 10 with a pair of left and right wedge clips 20, tunneling is carried out by advancing the messer plate 200 to the outside of the support 100 as shown in FIG.

At this time, both ends of the first waterproofing resin 10 are supported by the highly elastic wedge clip 20 that maintains a constant thickness with durability, thereby avoiding direct friction with the messer plate 200.
In other words, the first waterproofing resin 10 supported by a pair of sieve left and right wedge clips 20 fixed to be wrapped around the left and right wing portions of the support 100 is a stable position before contacting the messer plate 200. If the friction occurs according to the progression of the Messer plate 200 while maintaining the wedge clip 20 has a satisfactory support force with only one of the left and right pair of wedge clips 20, the wedge clip 20 is durable. Since it is made of a highly elastic member having a high elasticity does not proceed without being separated from the left and right wing portion of the support material 100 can maintain a more stable support state.

In this way, after the messer plate 200 which proceeds to the outside of the support material 100 sufficiently passes through the support material 100 surrounding the first waterproofing material 10, the support material 100 through which the messager plate 200 passes is passed. Install the earth plate (600). At this time, as shown in Figure 9 after separating the pair of left and right wedge clip (20) fixed to the first waterproofing resin 10 installed in the support material 100 from the support material 100, by rotating it to the earth plate 600 and It is inserted between the support material 100. Then, the first waterproofing resin 10 surrounding the support 100 is in close contact with the left and right wing portions of the first waterproofing resin 10 spaced apart from the support 100 and the ends of the earth plate 600.

After the gap between the earth plate 600 and the other earth plate 600 adjacent to each other by the first waterproofing resin 10 is closely covered, the earth plate 600 exposed between the adjacent support members 100 is covered with FIG. 10. Similarly, the second waterproofing resin 30 is installed. At this time, the left and right end portions of the second waterproofing resin 30 are preferably integrally bonded to the first waterproofing resin 10 supported between the support 100 and the earth plate 600 in the vertical direction. To this end, the first waterproofing resin 10, the central portion 12 is installed so as to cover the outer surface of the support material 100, and exposed to the left and right of the support material 100, the second waterproofing resin 30 for covering the earth plate and It is provided with a wide width to have a wings 14 extending to be coupled.

The first and second waterproofing resins 10 and 30 preferably include a nonwoven fabric on one surface thereof. The nonwoven fabric provided on one surface of the first and second waterproofing resins 10 and 30 suppresses the stretching of the waterproofing paper and increases durability.

As such, while attaching the second waterproofing material 30 to the center surface of the earth plate 600, the process of connecting the second waterproofing material 30 with the first waterproofing material 10 attached to the edge surface of the earthing plate 600 is repeated. Tunnel excavation is performed.

The second waterproof resin 30 is attached as described above, since both ends thereof are fixed by the first waterproof resin 10 supported between the support 100 and the earth plate 600, it is more stable than the conventional art. State is maintained.

Nevertheless, watertightness is prevented by the first and second waterproofing resins 10 and 30 in order to prevent the second waterproofing resin 30 from being lifted due to groundwater flowing from the excavation surface of the tunnel or by the earth and sand flowing between the earth plate 600. Filling material 50 is installed in the spaced space between the earth plate 600 and the support material 100 spaced apart by the U-shaped wedge clip (20).

Since the filler 50 is sufficient to prevent the second waterproofing material 30 from lifting, it does not require a high-strength material, and thus, a material such as foam urethane or lightweight concrete that can be easily installed on site can be selectively used. . Through such a process, more specifically, the preliminary structure is to be built outside the support member 100 inside the tunnel.

In the interior of the tunnel in which the preliminary structure is constructed, as shown in FIG. 12, the reinforcing bar 41 is disposed between the support members 100 continuously arranged while maintaining the state of protruding into the tunnel. 40) will be built to build the intended main structure. Since the present structure is to accommodate the support member 100 as part of the design structure, it is possible to provide a desired design section while narrowing the gap between the internal support members 100 as a whole, thereby minimizing the tunnel excavation section.

As described above, the present invention is designed so that the support material installed on the upper and left and right sides of the structure can be included in the structure when the tunnel excavation through the divider method plate applied to the method of the shield method to minimize the excavation cross-section This results in an improved method of shielding the method with a minimum digging section which also significantly improves watertightness.

Claims (3)

Install the support material according to the tunnel shape to be excavated, proceed with the meser plate along the support material, arrange the earth plate on the outside of the support material, and install the filled concrete on the inner wall to stabilize the inner surface of the excavated tunnel, In the normal method of the shield method to construct, Installing a first waterproofing resin on an outer surface of the supporting material, and supporting the left and right ends of the first waterproofing material exposed to the outside of the supporting material with a wedge clip of a U-type so that the supporting material is wrapped by the first waterproofing material; A tunnel excavation process of carrying out tunnel excavation by advancing a messer plate on an outer side of the supporter supporting the first waterproofing material with a wedge clip; The earth plate is installed along the direction of the mesmer plate, and the U-shaped wedge clip surrounding both ends of the first waterproofing resin is separated from the support material, and then rotated and inserted between the earth plate and the support material, thereby inserting the support material. An earth plate and a first waterproofing contact step of allowing the first waterproofing material to be in close contact with the left and right wing portions of the first waterproofing material spaced apart from the support material and the ends of the earthing plate; A second waterproofing installation step of installing a second waterproofing material so as to cover the earth plate exposed between adjacent supporting materials, wherein the left and right ends of the second waterproofing material are exposed to the left and right sides of the supporting material and are bonded to the wing of the first waterproofing material to be integrated; Constructing a preliminary structure in the tunnel by arranging a filler in a space spaced from the earth plate and the support material spaced by the U-shaped wedge clip sealed with the first and second waterproofing materials; Constructing a predetermined main structure by reinforcing reinforcing bars and placing structural concrete inside the tunnel in which a preliminary structure is constructed; An improved method of shield method with a minimum excavation cross section, characterized in that consisting of. According to claim 1, wherein the first waterproofing is made of a wing portion exposed to the left and right of the support material to be coupled with the central portion in close contact with the support material, and the earth plate cover second waterproofing paper exposed between the adjacent support material; The method of claim 1, further comprising the step of adhering the second waterproofing material for covering the earth plate to the wing portions exposed to the left and right of the support material. The improved method of claim 1, wherein the first and second resins comprise a nonwoven fabric on one surface thereof.

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