KR101025399B1 - Underground Structure and Method for Constructing thereof - Google Patents

Abstract

The present invention can ensure the utilization of the ground, such as vehicle traffic by refilling the soil on the top of the slab immediately upon installation of the wall and the upper slab in the construction of underground structures such as three-dimensional intersection, underground walkway, open-type tunnel, etc. In addition, it is possible to omit the lateral support hole in the upper part of the wall in the process of excavation of the underground, thereby simplifying the construction and making it easy to secure the excavation work space. It is about.

In the present invention, the step of excavating the ground to form an upper excavation (2); Installing the retaining member 10 in the ground at intervals to secure an underground space in which the underground structure is to be built in the upper excavation portion 2; The upper slab 3 which consists of the center part 31 arrange | positioned across the both retaining members 10 provided at intervals, and the inclined end 32 which respectively extends in the both sides of the said center part 31, the retaining member 10 Step between the earth member (10) so that the inclined end 32 is placed on the upper end of the; Backfilling the upper excavation portion 2 with earth and sand over the upper slab 3 provided between the earth member 10; Excavating the ground between the retaining member (10) below the upper slab (3); And constructing the lower bottom plate 4 after the completion of the ground excavation; In installing the upper slab 3 between the retaining members 10, the horizontal force to the outside of the upper retaining member 10 is increased by the axial force applied by the inclined end 32 of the upper slab 3. In order to act, the inclined end 32 is placed on the top of the retaining member 10 in which the inclined end 32 is exposed to the upper excavation portion 2 such that the central axis of the inclined end 32 meets the inclined angle with respect to the vertical axis of the retaining member 10. There is provided an underground structure construction method and an underground structure thereby.

Dirt, underground, excavation, bending, upper slab, plain beam

Description

Underground Structure and Method for Constructing Technical Information

The present invention relates to an unsupported underground structure using pre-filling and a construction method thereof. Specifically, in constructing a structure installed in the ground such as a three-dimensional intersection, an underground walkway, an open tunnel, and the like, By refilling the soil of the upper part of the slab immediately after installation of the upper slab, it is possible to guarantee the utilization of the ground such as vehicle traffic, while also simplifying the construction and digging work by eliminating the transverse support of the upper wall of the earth wall during the excavation of the ground. The present invention relates to an underground structure having a new structure and an construction method thereof, which can exert an effect such as ease of securing space.

In constructing underground structures such as a three-dimensional intersection, an underground walkway, an open-type tunnel, and the like, conventionally, after installing the earthquake member, excavation of the space between the earthquake members was carried out, such as a support beam between the earthquake members. In other words, when excavating the space between the retaining members, the earth pressure on the back of the retaining member acts, so in order to maintain the gap between the retaining member had to install a brace between the retaining member at a predetermined interval between the retaining member.

In this way, if the support is carried out, the cost and time for performing the support is also increased, as well as the support installed by the support has become an obstacle to the excavation of the ground between the earth members. When the excavation equipment such as an excavator is put in the space between the earthquake members, since there is a brace above the excavating equipment, the operation of the excavating equipment or the work of workers was a great obstacle.

In addition to the excavation between the earthquake members, a temporary hollow plate, etc., was installed on the upper part, but after the installation of the underground structure was completed, it was necessary to remove the hollow plate and backfill the soil again. It has been the cause.

The present invention was developed in order to overcome the limitations and problems of the prior art as described above, in the excavation of the ground between the retaining member, by simplifying the construction by not performing a separate support, such as installing a support on the upper retaining member The aim is to be able to achieve.

In addition, an object of the present invention is to enable the passage of vehicles, such as vehicles on the ground surface even when underground excavation, to minimize the inconvenience, such as prohibition of vehicle traffic due to construction, and to achieve the effect of saving air and reducing construction costs.

In the present invention, in order to achieve the above object, the earth block member installed in the ground at intervals to secure the underground space in which the underground structure is to be built in the upper excavation of the ground; Comprising a center portion disposed across both of the earth retaining members provided at intervals, and inclined ends extending to both sides of the center portion, the inclined end is placed on the upper end of the earth retaining member, consisting of an upper slab installed between the earth retaining members; The inclined end is exposed to the upper rig in such a manner that its central axis meets inclined with respect to the vertical axis of the retaining member so that the horizontal force on the upper end of the retaining member is applied by the axial force applied by the inclined end of the upper slab. A retaining soil block is placed on top of the member; There is provided an underground structure, characterized in that the upper slab has a structure made of backfilling by soil in the upper excavation portion over the upper slab in the state installed between the earth member.

In addition, the present invention to achieve the above object, the step of excavating the ground to form an upper excavation; Installing an earthquake member in the ground at intervals to secure an underground space in which the underground structure is to be built in the upper excavation portion; Installing an upper slab comprising a center portion disposed across both of the earth retaining members spaced apart from each other, and an inclined end extending on both sides of the center portion, such that the inclined end portion is placed on the upper end of the earth retaining member; Backfilling the upper excavation with earth and sand over the upper slab provided between the mud members; Excavating the ground between the retaining members below the upper slab; And constructing a bottom plate after completion of the ground excavation; In the installation of the upper slab between the retaining members, the central axis of the inclined end is directed to the vertical axis of the retaining member so that the horizontal component acts outwardly on the upper end of the retaining member by the axial force applied by the inclined end of the upper slab. There is provided a method for constructing underground structures, characterized in that the inclined end is placed on the upper portion of the earth film member exposed to the upper excavation in an oblique manner.

In the construction method of the present invention as described above, the upper slab is made of precast concrete member, may be lifted by the lifting device may be mounted between the earth member.

According to the present invention, since the backfill soil load acts as an active external force in the outer horizontal direction at the upper end of the retaining member via the inclined end of the upper slab, it is possible to maintain the gap between the retaining members without the support such as installing a separate brace. As a result, the excavation of the ground can be performed while maintaining the gap between the retaining members even in the state of the non-supporting hole without performing a separate support for the upper part of the retaining member.

Therefore, it is possible to reduce the cost and air required to perform the geotechnical, such as the installation of the brace. In addition, since there are no obstacles such as braces, it is possible to easily operate equipment for excavation or excavation work.

Particularly, after the upper slab is installed even when the excavation of the ground is not completed, the upper space is refilled, so that vehicle traffic can be made from the upper portion regardless of the ground excavation work, and vehicle traffic restriction due to the ground excavation work is restricted. However, there is an effect to minimize the inconvenience, such as restriction of the passage of the upper space. Since the backfill portion on the upper slab is completed, no additional work such as digging the backfill portion is required and the construction is simplified accordingly.

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

1 to 7 are schematic cross-sectional views showing each step of constructing the underground structure according to the present invention. Although the drawings illustrate an underground vehicle passage as an example of the underground structure, the underground structure of the present invention is not limited thereto.

First, as shown in Figure 1, excavating the upper surface of the ground to be constructed underground structure to a predetermined depth and to install the earthquake member 10 in the ground corresponding to the interval of the underground structure to secure the underground space in which the underground structure will be built. The earth blocking member 10 may be an earth wall using a pile or a steel sheet pile, and the like, and there is no particular limitation thereto. In installing the retaining member 10 in the ground, as shown in the figure, the upper end of the retaining member 10 is to be exposed to the upper excavation (2). As shown in FIG. 2, the slab installation unit 11 for installing the upper slab 3 is integrally formed at the upper end of the earth blocking member 10. The slab installation unit 11 may be manufactured using concrete.

Subsequently, the upper slab 3 is formed over the slab installation portion 11 formed at the upper end portions of the both retaining members 10. The upper slab 3 may be manufactured by cast-in-place concrete, but is made of precast concrete member and upper part on the slab installation part 11 by lifting equipment 100 such as a crane as shown in FIG. 3. Both ends of the slab 3 may be placed so as to cover the space between the earth member 10.

Here, the upper slab 3 according to the present invention has the following configuration. Specifically, as shown in Figure 3, the upper slab (3) so that the central axis of both inclined end 32 is inclined to the vertical axis of the slab installation portion 11, respectively. Specifically, the upper slab (3) is composed of a central portion 31 disposed across the two retaining members 10 provided at intervals, and inclined ends 32 respectively extending to both sides of the central portion 31, The inclined end 32 is placed on the top of the retaining member 10 so that the central axis of the inclined end 32 meets the inclined relative to the vertical axis of the retaining member 10. In the embodiment shown in the drawing, the surface where the slab installation portion 11 and the inclined end portion 32 installed on the top of the earth member 10 is inclined and the step is formed. In the embodiment shown in the figure is shown that the portion connecting the central portion 31 and the inclined end 32 is bent at an angle, but need not necessarily be bent, the center portion 31 and the The inclined end 32 may continue smoothly. In addition, as long as the member axis of the upper slab 3 end can incline with the member vertical axis of the upper part of the earth block member 10, the center part 31 of the upper slab 3 may be formed in a curve other than a straight line. Therefore, in the present specification, the inclined end 32 should be interpreted to include both the end that is gently inclined from the central portion 31 and the end that is bent at a bending angle.

Subsequently, as shown in FIG. 4, the upper excavation 2 over the upper slab 3 is backfilled. In other words, the space above the upper slab 3 is prefilled before the ground between the soil member 10 is broken. When the soil is backfilled onto the upper slab 3 in this way, a compressive force acts on the inclined end 32 of the upper slab 3 by the load by the soil. This compressive force is eventually applied obliquely to the upper end of the retaining member 10 (slab installation in the embodiment shown in the figure). 5 is a schematic view showing a state of the force acting on the upper end of the retaining member 10 in the backfill state, as shown in the figure, the slope of the upper slab 3 on the upper end of the retaining member 10 The axial force F in the inclined direction from the end 32 acts, and this axial force F eventually acts on the upper end of the retaining member 10 in the form of the vertical component Fv and the horizontal component Fh. That is, the active horizontal component Fh acts on the outer side of the retaining member 10 by the above configuration.

In this way, the upper slab 3 is installed on the earth member 10 and the backfill is made to form the underground structure according to the present invention. That is, in the state in which the earthing member 10 is buried in the ground at intervals in the upper excavation portion 2, the central axis of the inclined end 32 of the upper slab 3 meets inclined with the vertical axis of the earthing member 10. The upper slab 3 is installed so as to span the upper end of the earth member 10 so that the underground structure according to the present invention is formed.

After filling the space above the upper slab (3) to excavate the ground between the retaining member 10, when excavating the ground between the retaining member (10), conventionally installed a brace between the retaining member (10) To carry out the support, such as to maintain the gap between the retaining member (10). However, in the present invention, since the backfill soil load acts as an active horizontal component Fh in the outer horizontal direction at the upper end portion of the retaining member 10 via the inclined end 32 of the upper slab 3 as described above. It is possible to maintain the gap between the retaining member 10 even without the support such as the support. Therefore, it is possible to carry out excavation of the ground while maintaining the gap between the retaining member 10 even in the state of the non-supporting ball does not perform a separate support for the top of the retaining member (10). In this way, when the ground excavation between the retaining member 10, it is not necessary to perform a support ball, such as a brace, thereby resulting in a cost and air saving effect. In addition, since there is no obstacle, such as braces, there is an effect that the operation or excavation work for the ground excavation can be easily made. Particularly, since the upper slab 3 is installed even after the excavation of the ground is not completed, the upper space is refilled, so that vehicle traffic may be performed at the backfill portion on the upper slab 3 regardless of the ground excavation work. As a result, it is possible to minimize inconvenience such as vehicle traffic restriction or other traffic restrictions in the upper space due to the ground excavation work. Since the backfill portion on the upper slab 3 is in a completed state, no additional work such as digging the backfill portion is required, and the construction is simplified.

After installing and backfilling the upper slab 3 on the top of the retaining wall 10, the ground between the retaining wall 10 below the upper slab 3 is excavated downward. After excavation to the design depth, the bottom plate 4 is constructed as shown in FIG. In case of excavation to a considerable depth, if necessary, the intermediate slab may be installed between the retaining walls 10, and then additional ground excavation may be performed, and then the lower bottom plate 4 may be constructed. The bottom floor plate 4 may be constructed after several operations such as excavation are repeated to form a basement layer of a double layer.

In the above description, the ground down excavation under the upper slab 3 is performed after backfilling the upper slab 3, but this is performed by the backfilling and the downward excavation at the same time and the downward excavation is performed. It is to be understood that the meaning includes all such things, and the same is true in the description of the claims.

FIG. 8 is a schematic cross-sectional view showing a state corresponding to the state shown in FIG. 3, that is, a state in which the upper slab 3 is installed and the upper portion thereof is not yet backfilled, and a plurality of retaining walls 10 are provided, respectively. Shows an embodiment in which the upper slab 3 is installed between the retaining wall (10). As shown in FIG. 8, if necessary, a plurality of retaining walls 10 may be provided, and an upper slab 3 may be provided between the respective retaining walls 10. The number of the retaining walls 10 and the number of the upper slabs 3 may be further increased. Other details are the same as the above description, so repeated description is omitted.

1 to 7 are schematic cross-sectional views showing each step of constructing the underground structure according to the present invention.

8 is a schematic cross-sectional view of another embodiment of the present invention showing a state corresponding to the state shown in FIG. 3.

<Description of the symbols for the main parts of the drawings>

2: upper excavation

3: upper slab

10: soil member

Claims (3)

 An earth retaining member 10 installed in the ground at intervals to secure an underground space in which the underground structure is to be built in the upper excavation portion 2 of the ground; It is composed of a central portion 31 disposed across the both sides of the retaining member 10 provided at intervals and inclined ends 32 respectively extending on both sides of the central portion 31, the inclined end portion at the upper end of the retaining member 10 32 is placed, consisting of the upper slab (3) is installed between the retaining member (10); The inclined end 32 is exposed to the upper rig 2 so that the horizontal force acts on the upper end of the retaining member 10 by the axial force applied by the inclined end 32 of the upper slab 3. The upper slab 3 is disposed across the occlusion member 10 so as to lie on top of the occlusion member 10, wherein the central axis of the inclined end 32 meets inclined with respect to the vertical axis of the occlusion member 10; Underground structure, characterized in that the upper slab (3) has a structure made of backfilling by the earth in the upper excavation (2) over the upper slab (3) in the state installed between the earth member (10).  Excavating the ground to form an upper excavation portion 2; Installing the retaining member 10 in the ground at intervals to secure an underground space in which the underground structure is to be built in the upper excavation portion 2; The upper slab 3 which consists of the center part 31 arrange | positioned across the both retaining members 10 provided at intervals, and the inclined end 32 which respectively extends in the both sides of the said center part 31, the retaining member 10 Step between the earth member (10) so that the inclined end 32 is placed on the upper end of the; And Backfilling the upper excavation portion 2 with earth and sand over the upper slab 3 provided between the earthquake members 10, and excavating the ground between the earthquake members 10 under the upper slab 3; And Constructing the bottom sole plate 4 after the ground excavation is completed; In installing the upper slab 3 between the retaining members 10, the horizontal force to the outside of the upper retaining member 10 is increased by the axial force applied by the inclined end 32 of the upper slab 3. To act, the inclined end 32 is placed on the top of the retaining member 10 in which the inclined end 32 is exposed to the upper excavation portion 2 in such a manner that the central axis of the inclined end 32 meets inclined with respect to the vertical axis of the retaining member 10. Underground structure construction method characterized in that. The method of claim 2, The upper slab (3) is made of precast concrete member, is lifted by the lifting device is underground structure construction method, characterized in that mounted between the retaining member (10).

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