KR20130006420A - Method of constructing underground structure to be newly built - Google Patents

Abstract

It aims at providing the construction method of the new underground structure that can reduce the load burden of the new underground sphere about an existing underground sphere, and can also reduce the public affairs to build a new ground sphere. A new underground structure 100 having a basement that can be used as a living space and an underground pit that is an underground facility for accommodating plumbing facilities, and fluidized between the existing underground concrete sphere 200 and the new underground concrete sphere 400. It is constructed to arrange the soil wall 300.

Description

Construction method of new underground structure {METHOD OF CONSTRUCTING UNDERGROUND STRUCTURE TO BE NEWLY BUILT}

The present invention relates to a construction method of a new underground structure, and more particularly, to a construction method of a new underground structure that can reduce the load burden of the new underground structure for the existing underground structure, and can reduce the cost of construction (construction cost) will be.

When rebuilding various buildings such as buildings, existing buildings need to be dismantled, but in existing buildings with underground structures such as basement floors, existing structures must also be dismantled. However, underground outer walls, columns, underground beams, foundations, and the like that constitute the existing underground structure bear earth pressure from the surrounding ground, and when disintegrated unintentionally, it causes collapse and ground displacement of the mountain. There is a risk of significant impact on neighboring areas.

Therefore, Patent Literature 1 proposes a method of establishing an underground structure without dismantling the existing underground structure.

In the construction method of the underground structure proposed in Patent Literature 1, first, a short strut is installed at the center of the floor height of the existing underground outer wall of the first basement, and a load is applied to the external wall direction with a jack. The floor beam is demolished. This series of work is carried out on each floor, a new wall is placed inside the existing basement outer wall, a composite wall is built with the existing basement outer wall, and the floor beam is then demolished. This series of work is carried out on each floor and construction of the new underground structure is carried out.

Japanese Patent Publication No. 2005-201007

However, according to the construction method of the underground structure disclosed by patent document 1, since the composite wall to be constructed integrates an existing underground outer wall and a new wall, the load burden on a layer below increases. Therefore, there is a problem that more support force is required to support this load, and the cost for it increases.

The present invention has been made in view of such a problem, and it is possible to reduce the load burden on a new underground sphere with respect to an existing underground sphere, and also to reduce the cost of constructing a new underground sphere. The purpose is to provide a construction method.

In order to achieve the above object, the present invention provides a method for constructing a new underground structure without dismantling and removing all existing underground spheres, by filling fluidized soil in the inner circumferential surface of the existing underground sphere. It is to provide a construction method of a new underground structure, characterized in that the fluidized soil wall is constructed, and a new concrete sphere is built on the inner circumferential surface of the fluidized soil wall.

In addition, the present invention, in order to achieve the above object, in the construction method of a new underground structure to build a new underground sphere using a part of the existing underground sphere without dismantling and removing all the existing underground sphere, the existing underground sphere Build a fluidized soil wall by placing (installing) the first mold (form) on the inner circumferential surface of the mold at a predetermined distance from the existing underground sphere, and filling the fluidized soil between the existing underground sphere and the first mold. And placing a second mold body on the inner circumferential surface of the fluidized soil wall at a predetermined distance from the fluidized soil wall, and placing concrete between the fluidized soil wall and the second mold body to construct a new concrete sphere. It is to provide a construction method of a new underground structure characterized in.

In this case, it is preferable that the erected state of the said 1st frame and the said 2nd frame is hold | maintained by a separator, and the said 1st frame and the said 2nd frame are substantially square in front of the plate | board material of a steel plate. Moreover, it is preferable that it is a mold panel shape | molded by carrying out the bending | flexing | cutting process by bending | folding in the shape of a substantially angular wave shape of a cross section.

According to the present invention, when constructing a new underground structure, the new underground sphere formed in the existing underground sphere is constructed by the fluidized soil wall and the new concrete sphere, so that the new underground sphere is constructed only by the new concrete sphere. This can reduce the amount of concrete used. In addition, since the fluidized soil has a specific gravity lower than that of concrete, it is possible to reduce the load burden on the new underground spheres related to the existing underground spheres.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the structure of the newly built underground structure which concerns on this embodiment.
2 is a schematic configuration diagram of a mold panel used in the present embodiment;
3 is a view showing an AA cross section of the mold panel shown in FIG.
4 is a cross-sectional view showing a XX cross section of the underground structure shown in FIG. 1;
5 is a flowchart showing a procedure of a construction method of a newly installed underground structure according to the present embodiment;
6 is a schematic view of a construction method of a newly installed underground structure according to the present embodiment;
7 is a schematic view of a construction method of a newly installed underground structure according to the present embodiment;
8 is a schematic view of a construction method of a newly installed underground structure according to the present embodiment;
9 is a schematic view of a construction method of a new underground structure according to the present embodiment;
10 is a schematic view of a construction method of a newly installed underground structure according to the present embodiment;
11 is a schematic view of a construction method of a new underground structure according to the present embodiment.

Hereinafter, the construction method of the newly built underground structure which concerns on this embodiment is demonstrated, referring drawings.

1 is a longitudinal side view showing the structure of an underground structure constructed by the construction method according to the present embodiment.

As shown in FIG. 1, the underground structure constructed by the construction method which concerns on this embodiment is a new underground structure which has a basement which can be used as a living space, and an underground pit which is an underground facility for accommodating piping facilities, etc. It is constructed to arrange the fluidized soil wall 300 between the concrete sphere 200 and the new underground concrete sphere 400.

In addition, the underground pit in this underground structure is an underground space for accommodating plumbing facilities, and if there is a space for accommodating plumbing facilities in the basement, it is not necessary to provide an underground pit. In addition, in the underground structure shown in FIG. 1, although it is an underground structure of only one underground level, the number of underground floors may be sufficient, and even in that case, there is no change in a structure and a construction method.

When dismantling the existing underground structure, the columns, etc., which were constructing the structure, are dismantled and dismantled, and the existing underground concrete sphere consisting of the existing beam 201, the existing bearing wall 202, and the existing foundation (base / ground beam) 203 ( Only 200 is in the remaining form.

Inside the existing underground concrete sphere 200, a fluidized soil wall 300 is constructed. The fluidized soil wall 300 is constructed by filling fluidized soil (a fluidized backfill material that can be pumped into a slurry-like backfill soil in which cement is managed in advance in a factory). Specifically, the mold panel 500 is driven at a predetermined interval inside the existing concrete concrete sphere 200, and the standing state is maintained by the separator 501, and the mold panel 500 and the existing underground concrete sphere are kept. The fluidized soil is filled and solidified between 200 to build the fluidized soil wall 300.

Then, inside the fluidized soil wall 300, a new sphere, that is, a new underground concrete sphere 400, is constructed. The new underground concrete sphere 400 is composed of a new slab 401, a new beam 402, and a new wall 403 constituting a ceiling of a basement floor and an underground pit. The newly formed underground concrete sphere 400 drives the mold panel 600 newly at predetermined intervals inside the fluidized soil wall 300, and the mold of the mold panel 600 and the fluidized soil wall 300 described above. The panel 500 is connected to the separator 601 to maintain the standing state, and the concrete is poured between the mold panel 500 of the fluidized soil wall 300 and the new mold panel 600 to be constructed.

FIG.2 and FIG.3 is a figure which shows the structure of the mold panels 500 and 600 used for the construction method of the underground structure which concerns on this embodiment.

As shown in Fig. 2, the mold panels 500 and 600 are made of steel plate (for temporary foundations used for foundation work, etc.) formed by bending and cutting a steel plate material having a substantially rectangular front face and an approximately angular wave shape in cross section. It is a form panel of type) that is buried as it is without being removed and filled with earth and sand. In the mold panel 500, a panel steel sheet is bent in a substantially rectangular cross-sectional shape, so that a plurality of ridges 11 parallel to each other are arranged at predetermined intervals to reinforce the strength of the panel itself. In addition, by forming a panel cross section into an equilateral angular waveform, it is possible to exhibit particularly excellent strength with respect to the force from the front or back surface side.

In addition, in this embodiment, the formation direction of this ridge 11 is made into the longitudinal direction of the mold panel 500, and in the mold panel 500, the direction perpendicular | vertical to the longitudinal direction is made into the width direction.

As shown in this figure, this ridge 11 is comprised by the upper surface 31 and the side surface 32 of the two surface provided in connection with the width direction of this upper surface 31 in both directions. In the concave surface between the ridges 11, a plurality of cross-sectional convex ribs 12 in the width direction and grooves 16 in the cross-sectional concave shape in the width direction are repeated in parallel with the ridges at predetermined intervals. Formed.

Moreover, the cutting 13 of predetermined length ridges at predetermined intervals on the both ends of the panel width direction of the ridge 11, ie, on the boundary line between the rib 12 and the groove part 16 adjacent to the rib 12. It is provided in broken line parallel to (11). The corner part of the mold can be formed by bending the mold panel 500 at a predetermined angle along the row of the broken lines 13. In addition, the mold panel 500 can be easily cut to a desired size by repeatedly bending the mold panel 500 in the forward / reverse direction along the row of the broken line cutouts 13. .

This cutting | disconnection 13 is the cutting | disconnection of the small width and predetermined length which penetrated the front and back of the mold panel 500. FIG. This cutting 13 is the extent to which the excess moisture contained in the concrete and the fluidized soil can be discharged from the cutting 13 after the concrete is poured or the filling of the fluidized soil, and liquid concrete or the fluidized soil does not leak. It is formed in the width | variety (gap) and length of the degree which it does not have.

On the upper surface 31 side of the ridge 11, a plurality of lid-shaped lid portions 14 are provided. The cover portion 14 is opened to form a separator insertion hole. By inserting the above-mentioned separators 501 and 601 into this separator insertion hole and fastening by a predetermined method, the standing state of the mold panels 500 and 600 can be maintained.

4 is a cross-sectional view taken along the line X-X of FIG.

As shown in the figure, the newly built underground structure has a structure having a fluidized soil wall 300 between the existing underground concrete sphere 200 and the newly built underground concrete sphere 400.

In order to build the fluidized soil wall 300, first, the mold panel 500 is driven, and then, the anchor 307 is driven into the existing underground concrete sphere 200, and the separator 501 is embedded in the embedded anchor 307. ), The mold panel 500 is held in the standing state by the separator 501, and the fluidized soil is filled and constructed in this state.

Washers 301 and 302 having both ends bent are provided at the connection point between the mold panel 500 and the separator 501. The washer 301 is provided on the back side of the mold panel 500 (the existing underground concrete sphere 200 side) and is fastened to the mold panel 500 by the nut 303. The washer 302 is provided on the surface side (new basement concrete sphere 400 side) of the mold panel 500. The washer 302 is a long washer in the longitudinal direction and is fastened by the long nut 304 to the tip of the separator 501 protruding from the mold panel 500. Then, the fluidized soil is filled between the existing underground concrete sphere 200 and the mold panel 500 to build the fluidized soil wall 300.

As described above, the newly formed underground concrete sphere 400 is driven into the mold panel 600 at predetermined intervals inside the fluidized soil wall 300, and the mold panel 600 and the fluidized soil wall 300 are formed. The form panel 500 is connected to the separator 601 to maintain the standing state, and the concrete is poured between the form panel 500 and the new form panel 600 of the fluidized soil wall 300 to be constructed. At this time, one end of the separator 601 is connected to the long nut 304, the other end is connected to the mold panel 600, the standing state of the mold panel 600 is maintained, and the surface side of the mold panel 600 is maintained. The pipe 305 is provided in this and it is fixed by the groove tie 306. In this state, the new underground concrete sphere 400 is constructed by pouring concrete between the mold panel 500 and the mold panel 600.

Fig. 5 is a flowchart showing the construction procedure of the underground structure, and Figs. 6 to 11 are diagrams showing the construction method of the underground structure according to the present embodiment executed based on this trial procedure.

Hereinafter, the construction method of an underground structure is demonstrated, referring FIGS. 6-11 based on the flowchart which shows the construction procedure of FIG.

In addition, Figure 6 (a) is a view after removing a part of the existing concrete concrete spheres, Figure 6 (b) is a view of bringing in the soil pit to the underground pit after removing a portion of the existing underground concrete spheres, Figure 7 (a) is a view in which the soil is brought into the existing underground concrete sphere, Figure 7 (b) is a view of installing a new pile on a part of the foundation, Figure 8 (a) is a depth that the existing bearing wall and the existing beam withstand the earth pressure Figure 6 (b) is a drawing of a fluidized soil wall in an underground pit, Figure 9 (a) is newly installed in an underground pit It is a figure which provided the concrete sphere of the pressure-resistant board, FIG. 9 (b) is a figure which installed the new concrete foundation and slab in the underground pit, and FIG. 10 (b) is a view of a fluidized soil wall in the basement. And, FIG. 11 (a) is a view of assembling a formwork panel for concrete for new concrete basement, Figure 11 (b) is a view prepared by the new concrete in concrete basement.

<Removal of a part of existing underground concrete spheres>

First, as shown in FIG. 6 (a), after the structure of the ground portion is demolished, the existing pillar 204 constructed in the basement and the underground pit of the existing underground concrete sphere 200 is dismantled and removed, and the basement and the underground pit are removed. Open the slabs 205 and 206 by dismantling (in some cases, the original beam 201 may be dismantled and subjected to earth pressure), and a part of the existing pressure plate 208 is dismantled to prepare an opening (step). S100). In addition, by dismantling and removing the existing column 204, a space for constructing a new sphere in the basement and the underground pit is secured, while the slab 205 and 206 are dismantled to leave an existing beam 201 to prepare an opening. To secure the work site.

In addition, in the present embodiment, the existing underground concrete sphere 200 is an existing outer wall in which the existing beam 201, the existing bearing wall 202, and the existing foundation 203 are continuous, for supporting earth pressure from the ground. It is used as a retaining wall.

<Setting of backfill work and new pile>

Next, as shown in FIG. 6 (b), the soil is introduced into the underground pits of the existing underground concrete sphere 200 from the opening provided by dismantling the slabs 205 and 206, leaving the existing beam 201. As shown to 7 (a), earth and sand are carried in in a basement, and backfilling is performed inside the existing underground concrete sphere 200 with earth and sand (step S101). By this backfilling operation, the burden of earth pressure applied to the existing underground concrete sphere 200 used as the wall of the soil can be reduced. In addition, the backfilling operation enables securing of a work place of heavy machinery (not shown) and support of the weight of heavy machinery in the ground portion. As shown in FIG. Installation of the new pile 405a can be performed in the hole 405 previously opened in the pressure-resistant plate 208 (step S102). This new pile 405a is for supporting the weight of the new sphere (mainly a new wall) built inside the existing underground concrete sphere 200.

In addition, the installation of the new pile 405a is not necessary depending on the pressure resistance performance of the existing foundation 203 and the existing pressure plate 208 of the existing underground concrete sphere 200 and the bearing capacity of the ground.

<Demolition of earth and sand of backfilling and setting of saving quantity wale for mudguard>

Next, as shown in Fig. 8 (a), after the installation of the new pile 405a, the earth-bearing wall 202 and the existing beam 201 withstand the earth pressure from the basement and the underground pit from the earth and sand used for backfilling. The soil piled up to the depth is removed (step S103), and the existing beam 201 remaining is removed. Next, the earth pressure applied to the existing underground concrete 200 from the surrounding ground increases by the removal of the earth and sand used for dismantling removal and backfilling of the existing beam 201. ) Is installed in a portion of the existing beam 201 (step S104). Digging wale 406 for mud use a mud H steel having a cross section of H type. Thereby, the earth pressure applied to the existing underground concrete sphere 200 can be reduced by the mud-proofing wale 406. After installation of the retaining cut wale 406, the earth and sand used for the remaining backfill is removed (step S105).

<Construction of fluidized soil walls of underground pits>

Next, as shown in FIG. 8 (b), the fluidized soil wall 300 is placed on the underground pit in a state where the earth pressure from the surrounding ground is supported by the existing underground concrete sphere 200 and the quasi-toning wale 406. Build it. In order to build this fluidized soil wall 300, first, a plurality of anchors 307 are driven into an existing foundation 203 which is a wall of an underground pit, and a separator 501 is attached to each of these anchors 307. FIG. It connects (step S106). Next, the above-mentioned form panel 500 is assembled so as to conform to the shape of the inside of the existing underground concrete sphere 200, and the form panel 500 is maintained by the separator 501 (step S107). ). In addition, the mold panel 500 and the separator 501 are fixed by fastening with the washers 301 and 302 and the nut 303 as mentioned above.

Next, the fluidized soil wall 300 is constructed in the underground pit by filling and hardening the fluidized soil between the existing foundation 203 and the mold panel 500 (step S108). Here, the fluidized soil to be used is a slurry-type backfilling soil in which cement is pre-mixed and managed in a factory, and is a backfilling soil which can be pumped and poured into a live concrete mixer car. And when constructing the fluidized soil wall 300, by using the mold panel 500, the excess moisture can be discharged by the cutting 13 provided in this mold panel 500, and hardening of the fluidized soil is carried out. It is possible to shorten the time.

<Building of new concrete sphere of underground pit>

Next, as shown in Fig. 9 (a), a reinforcing bar (not shown) for assembling the new internal pressure plate 407 is assembled on the existing internal pressure plate 208 of the underground pit (step S109), and the new internal pressure is obtained. Concrete for pouring the board 407 is poured (step S110). Next, as shown in FIG. 9 (b), in order to construct the new slab 401 and the new foundation (base / ground beam) 404, the mold panel 600 is placed inside the fluidized soil wall 300. It installs (step S111). First, the reinforcing bar is assembled inside the fluidized soil wall 300 (step S112), the separator 601 is connected to the separator 501 protruding from the mold panel 500, and assembled by this separator 601. The mold panel 600 is kept in an upright state. Moreover, in order to build the new slab 401 for underground pits, the mold panel 600 is provided so that it may become a slab shape, supporting the mold panel 600 with a support pillar. At this time, since the mold panel 600 can be easily bent along the cutting 13 provided in the mold panel 600, the mold panel 600 can be assembled into a slab shape. Moreover, the mold panel 600 hold | maintained in the standing state and the mold panel 600 assembled in the slab shape are provided so as to be mutually provided.

In order to support the instantaneous pressure applied to the mold panel 600 when concrete is poured into the mold panel 600 installed in this way, as described above, the longer side of the mold panel 600 is placed on the surface side of the mold panel 600. Direction pipe 305 is secured with a groove tie 306. Next, the new slab 401 and the new foundation 404 are constructed by pouring concrete (step S113). Thereby, the newly built concrete foundation sphere 400 can be built in the underground pit.

In addition, when the new concrete sphere 400 is constructed, the cutting 13 provided in the mold panel 600 prevents the leakage of concrete and discharges excess moisture in the concrete when the concrete is poured. Can be.

<Construction of fluidized soil wall of basement>

Next, as shown in FIG. 10 (a), the earthquake-saving wale 406 provided in the existing beam 201 is dismantled and removed (step S114), and as shown in FIG. 10 (b), in the basement. Construct a fluidized soil wall 300.

First, a plurality of anchors 307 are driven into the existing beam 201 and the existing bearing wall 202 of the existing underground concrete sphere 200, and the separator 501 is connected to each anchor 307 (step S115). ). Next, the mold panel 500 is assembled so as to be provided in succession to the mold panel 500 provided in the underground pit, and the standing state is maintained by the separator 501 (step S116). At this time, the mold panel 500 and the separator 501 are fixed by fastening with the washers 301 and 302 and the nut 303.

Then, the fluidized soil is filled between the existing underground concrete sphere 200 and the mold panel 500 to build the fluidized soil wall 300 (step S117). Thereby, the fluidized soil wall 300 constructed in the underground pit and the fluidized soil wall 300 constructed in the basement are constructed as one continuous wall. The load of the fluidized soil wall 300 is supported by a portion of the existing beam 201, the existing bearing wall 202, and the existing foundation 203 constituting the existing underground concrete sphere 200.

<Building of new concrete sphere of basement>

Next, as shown to Fig.11 (a), the column, the beam, the wall, and the floor which become the new underground concrete sphere 400 are first constructed on the upper part of the new underground concrete sphere 400 built in the underground pit. Assemble the reinforcing bar (step S118). Next, the separator 601 is connected to the separator 501 protruding from the mold panel 500 of the fluidized soil wall 300 constructed for basement (step S119), and the mold panel (601) is connected by this separator 601. 600) is standing up. Then, the mold panel 600 for building the new slab 401 and the new beam 402 for the basement is assembled (step S120). The mold panel 600 is supported by a support column.

In addition, the mold panel 600 maintained in the standing state and the mold panel 600 assembled in the shape of the slab and the beam are assembled by connecting to form the continuous mold panel 600.

Next, reinforcing bars for the newly formed slab 401 are assembled (step S121), and concrete is poured between the fluidized soil wall 300 and the mold panel 600 (step S122). Thereby, the new concrete sphere 400 for basements can be constructed. Moreover, the new concrete sphere 400 constructed in the underground pit and the new concrete sphere 400 constructed in the basement are continuous new concrete spheres, and the load of this sphere is supported by the new pile 405a.

From the above description, in the method of constructing the underground structure according to the present embodiment, the existing underground concrete sphere is used as a retaining wall without dismantling the existing underground concrete sphere, and the fluidized soil wall and the new concrete sphere are constructed inside. By doing so, a new underground structure can be constructed.

In addition, the fluidized soil walls and the new concrete spheres built inside the existing underground concrete spheres have a frame panel between them, each of which is independent, and the load of the fluidized soil walls can be supported at the part facing the existing underground concrete spheres. In addition, the load of the new concrete sphere can be supported at the foundation of the new pile or the existing underground concrete sphere prepared in advance.

As a result, the load of the fluidized soil wall and the new concrete sphere can be dispersed and supported by the existing underground concrete sphere, thereby reducing the burden of supporting the existing underground concrete sphere.

In addition, by providing a fluidized soil wall between an existing underground concrete sphere and a new underground concrete sphere, the construction method of providing a new underground concrete sphere directly to an existing underground concrete sphere will be established underground by the existence of a fluidized soil wall. Since the thickness of the concrete sphere can be made thin, the amount of concrete can be reduced.

In addition, in the mold panel according to the present embodiment, the plurality of parallel ridges are arranged side by side at predetermined intervals by bending the panel steel sheet into a substantially angular waveform in cross section, so that the strength of the panel itself can be reinforced. As a result, even when the fluidized soil is filled or when concrete is poured, it can withstand the immediate pressure applied to the mold panel. And the cutting of the predetermined length provided in this mold panel facilitates bending of the mold panel itself, and can prevent the excess moisture to be discharged while preventing the leakage of fluidized soil or concrete. Thereby, while a form panel in a corner makes bending process easy, the construction of a fluidized soil wall and a new underground concrete sphere can be quickened.

11 Ridges 12 Ribs
13 Cut 14 Cover
16 Groove 31 Top
32 side 200 existing underground concrete sphere
201 Conventional beam 202 Conventional bearing wall
203 Existing Foundations (Basic / Underground Beams)
204 Original Column 205, 206 Slabs
208 Existing Pressure Plate 300 Fluidized Soil Wall
301, 302 Washer 303 Nut
304 long nut 305 pipe
306 Home Tie 307 Anchor
400 new underground concrete spheres
401 new slab 402 new beam
403 new wall 404 new foundation (foundation / underground beam)
405 new hole 405a new pile
406 saving wall wedge 407 new pressure plate
500, 600 mold panel 501, 601 separator

Claims (4)

In the construction method of the new underground structure to build a new underground sphere without dismantling and removing all existing underground spheres,
A method of constructing a new underground structure, characterized by filling the fluidized soil on the inner circumferential surface of the existing underground sphere, and building a new concrete sphere on the inner circumferential surface of the fluidized soil wall. In the construction method of a new underground structure that uses a portion of the existing underground sphere to build a new underground sphere without dismantling and removing all existing underground spheres,
The first frame is placed on the inner circumference of the existing underground sphere at a predetermined distance from the existing underground sphere.
Filling the fluidized soil between the existing subterranean sphere and the first mold body to build a fluidized soil wall,
The second mold is placed on the inner circumferential surface of the fluidized soil wall at a predetermined distance from the fluidized soil wall.
A method of constructing a new underground structure, wherein concrete is poured between the fluidized soil wall and the second frame to construct a new concrete sphere. The method of claim 2,
A method for constructing a new underground structure, wherein the first frame and the second frame are held in a standing state by a separator. The method according to claim 2 or 3,
And said first frame and said second frame are frame panels formed by bending and shaping a steel plate-like material having a substantially square front face and a substantially angular cross section.

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