KR101516745B1 - Column member and construction method for underground structure without temporary structure using the same - Google Patents

Abstract

The present invention includes a guide pillar (610) inserted into a support bed of a crushed area; A main column 630 coupled to the upper portion of the guide column 610; And a guide connecting member 620 installed on the upper side of the guide pillar 610 and the lower side surface of the main pillar 630 in order to ensure verticalness when the main pillar 630 is installed, The insertion hole 620 is formed at the center so that the upper part of the guide column 610 can be inserted and the plate member 620 coupled to the lower part of the main column 630 and the upper part of the guide column 610 621); A plurality of support members 623 protruding from the upper portion of the plate member 621 so as to guide the coupling direction of the main column 630 and spaced apart along the circumference of the main column 630; A plurality of coupling members (not shown) which are coupled to the lower side surface of the main column 630 so as to engage with the plurality of support members 623 and which are configured so that the other side of the main column 630 is engaged with the support member 623 624), and a method of constructing an underground structure of a non-utility facility using the same, thereby improving the installation accuracy of the column and the girder, thereby making the structure stable, easy to install, It is advantageous for acupressure effect and shear resistance. It improves the waterproof function to prevent water leakage, and omits the process for installing and dismantling the temporary structure, thereby reducing the period, cost and risk of safety accidents.

Description

Technical Field [0001] The present invention relates to a column member and a method of constructing an underground structure using the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a civil engineering field, and more particularly, to a pole member and a method of constructing an underground structure of a powerless facility using the same.

Conventional methods of constructing an underground structure can be roughly divided into a forward punch method and a reverse punch method.

The sanding method is a universally applied method. It excavates up to the foundation plan while installing the earth retaining wall by the supporting means such as brace, anchor, rock bolt, nail ring, lacquer, tension beam supporting the retaining wall from the ground , The foundation structure is laid, the bottom floor supporting wall is demolished, the walls are sequentially laid, and the supporting wall supporting wall is repeatedly demolished.

The tower method is a top-down method. It is a method of top-down method. It is used for excavation and construction of the structure at the same time while installing a supporting means such as a retaining wall, a brace, an anchor, a rock bolt, a nail ring, a lacquer, Down or up to down.

This is a reinforced concrete structure or a steel-reinforced concrete structure, and it is necessary to install a retaining structure such as CIP, SCW, H-shaped steel, and slurry wall.

However, since all of the conventional sand filling method and the back filling method are based on the assumption of installation and dismantling of the temporary structure, it is necessary to install the bracket in stages in order to resist the transverse earth pressure applied to the retaining wall, .

Further, there is a problem that the air is delayed and the construction cost is excessively increased.

In case of severe cases, the cost of the construction work may be more than 40% ~ 50% of the construction cost.

On the other hand, conventionally, the construction is carried out in such a manner that the pillar is approximated by the punching equipment in the state that the ground is not excavated.

However, since the work is performed in the air, and the precision of the construction of the perforated equipment is low, there is a problem that it is difficult to perform accurate construction in the vertical direction.

In addition, there is a possibility that an error may partially occur due to lack of connectivity of the girder.

In addition, if the groundwater level is high, leakage of material may occur due to the material heterogeneity of the foundation concrete and the steel column.

Accordingly, it is possible to reduce the labor and cost required for installation and dismantling of the truss, and various studies have been made to secure the stability by improving the installation accuracy of the column and the girder.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to improve the installation accuracy of a column and a girder so that it is structurally stable, easy to install, And a method for constructing a ground structure of a powerless facility using the same, which is capable of reducing the risk of safety accidents, time, cost and safety accidents by omitting steps for installation and disassembly It is for that purpose.

In order to solve the above-mentioned problems, the present invention provides a pneumatic tire comprising: a guide pillar (610) inserted into a supporting ground of a crushed area; A main column 630 coupled to an upper portion of the guide column 610; And a guide connecting member 620 installed on the upper side of the guide column 610 and the lower side surface of the main column 630 in order to ensure verticalness when the main column 630 is installed, The connecting member 620 is formed with an insertion groove 622 at the center so that the upper part of the guide column 610 can be inserted and the lower part of the main column 630 and the upper part of the guide column 610 A plate member 621 for engaging with the plate member 621; A plurality of support members 623 protruding from the upper portion of the plate member 621 and spaced apart from each other around the main column 630 so as to guide the coupling direction of the main column 630; A plurality of support members 623 are formed so that one side of the main column 630 is coupled to the lower side of the main column 630 and the other side of the main column 630 is engaged with the support member 623, And a joining member (624) of the joining member (624).

The plate member 621 is preferably welded to the lower portion of the main column 630.

A bolt coupling hole 625 is formed along the height direction of the support member 623 and the coupling member 624 and the support member 623 and the coupling member 624 are bolted to each other .

It is preferable that the water expansition index material 626 is applied to the lower end of the plate member 621 to prevent water from flowing upward in the plate member 621. [

The insertion groove 622 is preferably formed in a circular shape.

The insertion groove 622 is preferably formed in a cross-sectional shape of the H-file.

The present invention provides a method for constructing an underground structure of a groundless facility using the column member, comprising: forming an outer wall body (500) of an underground structure in a perforation hole (20) of a ground; An initial crushing step of crushing an inner region of the outer wall body 500 to form an initial crushed area; Inserting the guide column (610) into the support base of the initial crawl region; An upper wale band and an upper girder installation step in which an upper wale band 511 and an upper girder 710 are installed at an interval from an upper portion of the guide column 610; A main column mounting step for mounting the main column 630 such that an upper portion thereof is coupled to the upper girder 710 and a lower portion is coupled to the upper portion of the guide column 610; A final squeeze step of squeezing the outer region of the main column 630; The upper portion of the upper girder 710 and the upper region of the foundation foundation and the area between the outer wall body 500 and the upper girder 710 are reinforced by reinforcement placement, formwork and concrete pouring to form the slab 730, the floor 740 And a slab and a floor forming step of forming a slab 520 and a slab bottom forming step.

The step of installing the main column includes the steps of installing the upper part of the main column 630 on the upper girder 710; And adjusting the verticality of the main column 630 using the guide connecting member 620 provided on the upper portion of the guide column 610 and the lower side of the main column 630 Do.

Inserting abandoned concrete in a lower portion of the plate member (621) after the step of inserting the guide columns; Installing the main column 630 by installing the upper portion of the main column 630 on the upper girder 710 and then coupling the other side of the coupling member 624 to the support member 623; .

The method of claim 1, further comprising the step of pouring concrete into the guide column (610) through the insertion groove (622) after the step of pouring the abandoned concrete, wherein the insertion groove (622) It is preferable that the upper part of the guide part is formed in a circular shape so that the upper part of the guide part can be inserted.

In the slab and bottom forming step, the floor 740 may be formed by pouring the floor concrete so that the guide connecting member 620 is embedded.

Preferably, the method further includes the step of applying a water expansion index material 626 to the lower end of the plate member 621 after pouring the abandoned concrete.

Further excavating the inner region of the outer wall body (500) and the outer region of the main column (630) to form an additional crawl region prior to the final crawl step; It is preferable to further include a lower wale band and a lower girder installing step in which the lower wale band 512 and the lower girder 720 are installed in the lower portion of the upper wale 511 and the upper portion of the upper girder 710 .

Forming a plurality of continuous perforation holes (10) before the outer wall formation step; A grouting step of grouting inside the plurality of through holes (10); A wall member inserting step of inserting the wall member 100 along the longitudinal direction of the plurality of perforation holes 10; Forming an underground wall body (200) by placing concrete inside the wall member (100); A crushing step of crushing a front region of the ground wall body 200; Installing a connecting member (320) on a front surface of the exposed underground wall (200); Coupling the reinforcing assembly (310) and the connecting member (320); And forming a closed wall body 400 by pouring concrete so that the reinforcing bar assembly 310 is embedded in the outer wall body 500. The outer wall body forming step may include forming the outer wall body 500 in the front of the closed wall body .

Wherein the wall member has a rectangular box-shaped body (110) formed with upper and lower trim portions; A plurality of partition walls 120 formed in the body 110 to have a lattice structure; And a guide member 130 installed on an inner surface of the partition 120. The guide member 130 includes a tubular member 131 through which the reinforcing bar 133 is inserted. And an interval member 132 which is engaged with the inner surface of the tubular member 131 and the partition 120 or the inner surface of the tubular member 131 and the inner surface of the partition 120 to maintain mutual spacing therebetween Do.

The connecting member 320 preferably includes a stud.

The present invention improves the installation accuracy of columns and girders, and is structurally stable, easy to install, is advantageous in the effect of acupressure and the shear resistance to disperse column load, improves waterproof function to prevent water leakage, This paper proposes a pillar structure which can reduce the time, cost and risk of safety accidents by omitting the process for dismantling, and a method of constructing an underground structure of a non -

1 to 8 show an embodiment of a column member according to the present invention,
1 is an installation front view of the first embodiment;
Fig. 2 is an installation front view of the plate member and the support member; Fig.
3 is a perspective view of a guide connecting member;
Figure 4 is a plan view of Figure 3;
Fig. 5 is a perspective view showing a coupled state of the support member and the engagement member; Fig.
6 is a perspective view showing a coupled state of the first embodiment of the plate member and the guide column.
7 is a perspective view showing a coupled state of a plate member and a guide column according to a second embodiment;
8 is a cross-sectional view showing the use state of the guide connecting member.
9 to 24 illustrate an embodiment of a method of constructing an underground structure for a barn facility using a column member according to the present invention,
9 is a sectional view showing an outer wall body forming step.
Figure 10 is a cross-sectional view showing an initial digging step;
11 is a cross-sectional view showing a step of inserting a guide column.
12 is a sectional view showing an upper wale and upper girder installation step and a main column installation step.
FIG. 13 is a cross-sectional view showing further squeezing steps. FIG.
14 is a cross-sectional view showing steps of installing a lower wale band and a lower girder.
15 is a sectional view showing the final squeezing step;
16 is a cross-sectional view showing steps of slab, bottom, and sidewall forming.
17 is a plan view showing a drilling step for installing a wall member;
18 is a plan view showing a wall member inserting step;
19 is a plan view showing an underground wall forming step;
20 is an installation plan view of an underground wall, a reinforcing bar assembly and a connecting member.
21 is a perspective view showing a step of forming a closed wall.
22 is a sectional view showing an underground wall, a closed wall and an outer wall body.
23 is a perspective view of one embodiment of a wall member.
24 is a plan view of one embodiment of a guide member;

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

As shown in FIG. 1 and below, the column member shown in the present invention includes a guide column 610 inserted into a supporting ground of a crushed area; A main column 630 coupled to the upper portion of the guide column 610; And a guide connecting member 620 installed on the upper side of the guide pillar 610 and the lower side surface of the main pillar 630 in order to ensure verticalness when the main pillar 630 is installed, The insertion hole 620 is formed at the center so that the upper part of the guide column 610 can be inserted and the plate member 620 coupled to the lower part of the main column 630 and the upper part of the guide column 610 621); A plurality of support members 623 protruding from the upper portion of the plate member 621 so as to guide the coupling direction of the main column 630 and spaced apart along the circumference of the main column 630; A plurality of coupling members (not shown) which are coupled to the lower side surface of the main column 630 so as to engage with the plurality of support members 623 and which are configured so that the other side of the main column 630 is engaged with the support member 623 624). ≪ / RTI >

The pillar member of the present invention is characterized by the above structure and the guide pillar 610 is first inserted in a culverted ground where the ground is excavated, 630 are assembled in this order.

That is, there is a problem that precise construction in the vertical direction is impossible and an error occurs in the girder connecting portion of the middle layer because the column is inserted using a punching machine such as auger in the state that the ground is not excavated in the past. However, The purpose is to fundamentally solve the problem.

In other words, according to the present invention, since the installation of the guide column 610 and the main column 610 is performed in the excavated soil, that is, in the exposed state, the installation accuracy and workability of the column can be improved.

In addition, since the connection between the main column and the girder is also made in the exposed state, the installation accuracy of the girder and the column can be improved.

The guide connecting member 620 according to the present invention is a member for connecting the guide column 610 and the main column 610. When the main column 630 is installed, So that the work can be easily performed.

The pillar member of the present invention is combined with the upper girder and plays a role of resisting the transverse earth pressure against the outer wall body 500 during construction and acts as a pillar of the structure after the construction.

As a result, there is no need to install a separate hypothetical structure during construction, so that the construction period and cost can be reduced more effectively, and a stable construction of the earth retaining structure can be realized to enable safe construction.

The structure of the guide connecting member 620 of the column member according to the present invention will be described in more detail as follows.

1, the guide connecting member 620 is installed on the lower side of the main column 630 and a plurality of support members 623 and a plate member 621 provided on the upper portion of the guide column 610. [ And a plurality of engaging members 624 that engage with each other.

That is, when the main column 630 is installed on the upper part of the guide column 610, the guide column 610 is inserted into the support base with the plate member 621 and the plurality of support members 623 installed on the upper part of the guide column 610 , And the engaging member 624 is engaged with the supporting member 623 (Figs.

In other words, when the main column 630 is installed, the coupling of the coupling member 624 and the support member 623 is engaged, so that the verticality of the main column 630 can be adjusted and precise installation can be achieved.

Here, the coupling between the coupling member 624 and the support member 623 is structurally preferable to be bolted.

For this purpose, a bolt coupling hole 625 is formed along the height direction of the coupling member 624 and the support member 623, respectively.

At the time of mutual coupling, the supporting member 623 and the coupling member 624 are bolted to each other by overlapping each other (FIG. 5).

On the other hand, the plate member 621 performs the following functions.

First, it functions as a member favorable in shear resistance as well as an effect of distributing the column load generated from the upper part of the plate member 621.

Second, it functions as a waterproof steel plate.

That is, in the case of a ground having a high level of ground water, it is possible to effectively prevent the water leakage which may occur due to the heterogeneity of the material of the foundation concrete and the steel column.

For this purpose, it is preferable that the water expansition index material 626 is applied to the lower end of the plate member 621 (FIG. 2) so as to prevent the groundwater from flowing upward in the direction of the plate member 621.

Third, the upper part of the lower guide column 610 is inserted and the rigid coupling can be fastened.

For this purpose, an insertion groove 622 is formed at the center so that the upper part of the lower guide column 610 can be inserted (FIG. 3).

It is preferable that the insertion groove 622 is formed in a circular shape when the guide column 610 is a general round steel pipe (FIG. 6).

On the other hand, when the guide column 610 is an H file, it is preferable that the insertion groove 622 is formed in the cross-sectional shape of the H file (FIG. 7).

It is structurally preferable that the plate member 621 and the lower portion of the main column 630 are welded together.

Next, a method of constructing an underground structure of a barn facility using the column member of the present invention will be described.

First, an outer wall body 500 of an underground structure is formed in the perforation hole 20 of the ground (FIG. 9).

Since the outer wall body 500 of the present invention is formed in front of the finishing wall body 400 and the finishing wall body 400 has a permanently stable structure, it is not necessary to provide a separate hypothetical structure to resist the lateral earth pressure.

Specifically, the closed wall 400 of the present invention is installed on the front surface of the underground wall body 200 formed through the wall member 100, the wall member 100 is formed of an iron plate structure, The gap between the barrier rib 120 and the reinforcing bar 133 can be secured through the structure in which the guide member 130 is provided.

In other words, since the interval between the inner surface of the wall member 100 and the reinforcing bar 133 can be permanently maintained, the reinforcement effect of the reinforcing bars can be enhanced, thereby maximizing the strength of the wall and preventing the occurrence of displacement in the wall There is an effect that can be.

The underground wall body 200 and the finishing wall body 400 formed by pouring concrete into the wall member 100 can realize an integrated structure and can be used as a whole permanent wall body.

In this way, since the outer wall body 500 of the present invention is formed in front of the structurally stable underground wall body 200 and the finishing wall body 400, it is possible to obtain the effect that there is no need to provide a separate hypothesis in the present invention.

In other words, since the finished wall 400 serves as a stable toe wall in the step of forming the outer wall body 500, it is not necessary to provide a brace such as a brace or an anchor in order to resist the transverse earth pressure applied to the earth retaining wall.

Therefore, in the present invention, it is possible to reduce the cost of installation and disassembly of the temporary structure, shorten the construction period, and effectively resist the lateral earth pressure during construction, thereby improving the stability of the operation.

Since the outer wall body 500 of the present invention must have a retaining function and an order function, it must be installed by an underground wall construction method such as CIP, SCW, slurry wall, and sheet file by the insertion of a plurality of steel pipes.

Next, after the inner area of the outer wall body 500 is crushed to form an initial crushed area, a guide pillar 610 is placed on the supporting crest of the initial crushed area (FIGS. 10 and 11).

Since the outer wall body 500 of the present invention performs the earth retaining function and the order function during the construction and performs the waterproof function and the underwater wall function of the structure together with the closed wall body 400 after the construction, none.

It is preferable that a step of pouring the abandoned concrete 30 at the lower part of the plate member 621 is performed after the step of inserting the guide column.

And a step of pouring concrete into the guide pillar 610 through the insertion groove 622 formed in the plate member 621 is preferably performed.

In this case, the guide column 610 is a round steel pipe, and the insertion groove 622 is formed in a circular shape so that the upper portion of the guide column 610 can be inserted.

As described above, in order to effectively exhibit the function of the waterproof steel plate by the plate member 621 of the present invention, after the step of casting the abandoned concrete, the water expansion index material 626 is applied to the lower end of the plate member 621 Step is preferably performed.

Next, the upper wale 511 and the upper girder 710 are installed with an interval from the upper part of the guide column 610, the upper part is coupled to the upper girder 710, the lower part is coupled to the upper part of the guide column 610 A step of installing the main column 630 is performed (Fig. 12).

That is, unlike the prior art, the present invention excavates the ground first and then installs the guide pillar 610 and the main pillar 630 step by step in the exposed state.

Accordingly, the accuracy of installation of the column is improved, and precision construction is advantageous. In the installation work of the upper girder 710 and the main column 630, work is performed more quickly and accurately by reducing the possibility of error There is an advantage that it can be.

In addition, in the case of the conventional method, the installation work of the column and beam of the present structure is performed together with the dismantling work of the hypothetical construction in the air, so that there is a great risk of safety accidents. In the case of the construction method according to the present invention, There is no risk of a safety accident because the installation of the guide column 610, the upper girder 710 and the main column 630 of the structure is performed.

Since the guide pillar 610 and the main pillar 630 of the present invention are in contact with the upper girder 710, they act to resist the transverse earth pressure against the outer wall body 500 during construction, As well.

Therefore, since there is no need to install a separate hypothetical structure during the construction, the construction period and cost can be reduced more effectively, and a stable construction of the earth retaining structure can be realized to enable safe construction.

More specifically, in the step of installing the main column 630, the upper part of the main column 630 is installed on the upper girder 710, and then the lower part is installed to be coupled to the upper part of the guide column 610 .

The upper portion of the main column 630 is first coupled to the upper girder 710 and then the lower portion is installed on the upper portion of the guide column 610 and the other side of the coupling member 624 is coupled to the support member 623 So that the main column 630 can be installed quickly and precisely in the vertical direction.

In order to maximize the above advantages, it is more effective to adjust the verticality of the main column 630 by using the guide connecting member 620 of the present invention (FIG. 12).

After the step of installing the main column 630, a final squeeze step is performed to exclude the outer region of the main column 630 (Fig. 15).

The upper area of the upper girder 710, the upper area of the foundation foundation, and the area between the outer wall body 500 and the upper girder 710 are reinforced by reinforcement, formwork, and concrete pouring to form slabs 730, A step of forming the sidewall 520 is performed (Fig. 16).

Here, it is preferable to form the floor 740 by installing the floor concrete so that the guide connecting member 620 of the present invention is embedded.

This is because the connection between the guide column 610 and the main column 630 is buried in the concrete of the floor 740, so there is no possibility of deterioration of the connection and the structure is stable.

13, an additional squeeze step may be further performed prior to the final squeeze step to excavate the inner region of the outer wall body 500 and the outer region of the main column 630 to form an additional squeeze region.

This can be regarded as a process for additionally installing the lower girder 720 of the structure.

That is, a lower wale band and a lower girder are installed in the upper wale 511 and the lower portion of the upper girder 710 to provide the lower wale 512 and the lower girder 720, 14).

In addition, a step of installing the connecting portion 711 along the horizontal direction of the upper girder 710 and the lower girder 720 may be further performed.

It is preferable that a hydraulic jack or the like is used as the connection portion 711, and the gap between the upper girder 710 and the lower girder 720 can be appropriately set.

As described above, the outer wall body 500 of the present invention is installed in front of the finishing wall body 400. Construction of the finishing wall body 400 and the underground wall body 200 is performed by the following process .

First, a perforation step is performed in which a plurality of perforation holes 10 are continuously formed before the outer wall formation step (FIG. 17).

A step of inserting the wall member 100 along the longitudinal direction of the perforation hole 10 is performed after grouting the inside of the plurality of perforation holes 10 (Fig. 18).

The structure of the wall member 100 is as follows.

A plurality of partition walls 120 formed in the main body 110 and a guide member 130 installed on the inner surface of the partition wall 120 to form a lattice structure; (Fig. 23).

The guide member 130 includes a tubular member 131 to which the reinforcing bar 133 is inserted and an inner rear surface of the tubular member 131 and the inner surface of the tubular member 120 or the inner surface of the tubular member 131, And a spacing member 132 which keeps mutual spacing (Fig. 24).

Such a wall member 100 is formed of a steel plate structure, and is stable in penetration into the ground, and is excellent in durability and structural stability.

In addition, the wall member 100 of the present invention is advantageous in that the gap between the barrier rib 120 and the reinforcing bar 133 can be secured through the structure in which the guide member 130 is provided on the inner surface of the barrier rib 120.

That is, in the conventional underground wall construction method, it is difficult to secure the space between the wall and the reinforcing bars, and the reinforcing bars may be separated, so that the reinforcing effect of the walls of the reinforcing bars is significantly lowered. However, The gap between the inner surface of the wall member 100 and the reinforcing bar 133 can be maintained to reliably prevent such a problem.

Since the interval between the partition wall 120 and the reinforcing bar 133 is permanently ensured through the spacing member 132, the reinforcing effect by the reinforcing bar 133 can be enhanced to maximize the strength of the wall, The effect of preventing the occurrence of displacement can be obtained.

In addition, there is an advantage that it is possible to further improve the water repellency and waterproofness of the wall by preventing the occurrence of displacement in the wall.

The wall member 100 may be manufactured in the factory with the guide member 130 installed or with the reinforcing bar 133 inserted into the guide member 130, It is advantageous that the workability is also excellent.

After the step of inserting the wall member 100, the inner grout of the wall member 100 is removed, cleaned, and then the reinforcing bar 133 is inserted along the height direction of the wall member 100 An underground wall forming step is performed in which concrete is installed in the inside to form the underground wall 200 (FIG. 19).

After the front region of the underground wall 200 is excavated, a connecting member 320 is installed on the exposed surface of the underground wall 200 to connect the reinforcing bar assembly 310 and the connecting member 320 20).

It is more structurally preferable that the connecting member 320 uses a stud.

It is effective that the studs are mounted by welding, and the wall member 100 of the present invention is formed of an iron plate structure, so that the mounting of the studs is facilitated.

Next, a finishing wall forming step is performed in which the concrete wall is formed by pouring the concrete so that the reinforcing bar assembly 310 is embedded (FIG. 21).

As shown in FIG. 22, the outer wall body 500 of the present invention is formed in front of the closed wall body 400.

Here, the ground wall 200 and the finishing wall 400 of the present invention can be used as an entire permanent wall through an integrated structure.

As described above, since the wall member 100 of the present invention can permanently secure excellent strength and structural stability, it can be used as a soil facility during construction and can exhibit the function of the main structural wall even after construction.

Therefore, the underground wall body 200 using the wall member 100 of the present invention and the finishing wall body 400 provided on the front surface thereof can be used as a permanent wall body.

As a result, it is possible to reduce the required section of the wall to improve the economical efficiency, shorten the construction period, and maximize the strength of the wall.

In addition, in the step of forming the outer wall body 500 in front of the finishing wall body 400 of the present invention, there is no need to provide a separate structure, so that economical efficiency can be ensured and workability and stability can be improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

10: Perforation hole 20: Perforation hole
100: wall member 110:
120: partition wall 130: guide member
131: pipe member 132: spacing member
133: rebar 200: underground wall
310: Reinforcing assembly 320: Connecting member
400: closed wall body 500: outer wall body
511: upper wale 512: lower wale
520: anchor wall 610: guide post
620: guide connecting member 621: plate member
622: insertion groove 623: support member
624: coupling member 625: bolt coupling hole
626: water expansion index material 630: main column
710: upper girder 711:
720: lower girder 730: slab
740: bottom

Claims (16)

A guide pillar (610) inserted into the supporting ground of the crushed area;
A main column 630 coupled to an upper portion of the guide column 610;
A guide connecting member 620 installed on the upper side of the guide pillar 610 and the lower side of the main pillar 630 in order to ensure verticalness when the main pillar 630 is installed;
≪ / RTI &
The guide connecting member 620
An insertion groove 622 is formed in the center so that the upper part of the guide column 610 can be inserted and a plate member 621 coupled to the lower part of the main column 630 and the upper part of the guide column 610 );
A plurality of support members 623 protruding from the upper portion of the plate member 621 and spaced apart from each other around the main column 630 so as to guide the coupling direction of the main column 630;
A plurality of support members 623 are formed so that one side of the main column 630 is coupled to the lower side of the main column 630 and the other side of the main column 630 is engaged with the support member 623, A coupling member 624
A method of constructing an underground structure of a powerless facility using a pillar member,
Forming an outer wall body (500) of an underground structure in the perforation hole (20) of the ground;
An initial crushing step of crushing an inner region of the outer wall body 500 to form an initial crushed area;
Inserting the guide column (610) into the support base of the initial crawl region;
An upper wale band and an upper girder installation step in which an upper wale band 511 and an upper girder 710 are installed at an interval from an upper portion of the guide column 610;
A main column mounting step for mounting the main column 630 such that an upper portion thereof is coupled to the upper girder 710 and a lower portion is coupled to the upper portion of the guide column 610;
A final squeeze step of squeezing the outer region of the main column 630;
The upper portion of the upper girder 710 and the upper region of the foundation foundation and the area between the outer wall body 500 and the upper girder 710 are reinforced by reinforcement placement, formwork and concrete pouring to form the slab 730, the floor 740 ) And a sidewall forming step (520)
The method comprising the steps of: The method according to claim 1,
The plate member 621
And welded to a lower portion of the main column (630). The method according to claim 1,
A bolt coupling hole 625 is formed along the height direction of the support member 623 and the coupling member 624,
Wherein the support member (623) and the coupling member (624) are bolted to each other by overlapping each other. The method according to claim 1,
Wherein a water expansion index material (626) is applied to a lower end of the plate member (621) so as to prevent water from flowing in an upper direction of the plate member (621). The method according to claim 1,
The insertion groove 622
Wherein the ground structure is formed in a circular shape. The method according to claim 1,
The insertion groove 622
H file in the form of a cross-sectional shape. delete The method according to claim 1,
The main column installation step
Installing an upper portion of the main column (630) on the upper girder (710);
Adjusting the verticality of the main column 630 using the guide connecting member 620 provided on the upper portion of the guide column 610 and the lower side surface of the main column 630;
The method comprising the steps of: The method according to claim 1,
After the step of inserting the guide columns,
Pouring abandoned concrete at a lower portion of the plate member 621;
Installing the main column 630 by installing the upper portion of the main column 630 on the upper girder 710 and then coupling the other side of the coupling member 624 to the support member 623;
The method comprising the steps of: 10. The method of claim 9,
Pouring the concrete into the guide column 610 through the insertion groove 622 after pouring the abandoned concrete;
Further,
Wherein the insertion groove (622) is formed in a circular shape so that an upper portion of the guide column (610) can be inserted. The method according to claim 1,
The slab and bottom forming step
Wherein the floor (740) is formed by pouring the floor concrete so that the guide connecting member (620) is embedded. 10. The method of claim 9,
After pouring the abandoned concrete,
Applying a water expansion index material 626 to the lower end of the plate member 621;
The method comprising the steps of: The method according to claim 1,
Prior to the final squeeze step,
Further excavating an inner region of the outer wall body (500) and an outer region of the main column (630) to form an additional crawl region;
A lower wale band and a lower girder installation step in which the lower wale band 512 and the lower girder 720 are installed in the upper wale 511 and the lower part of the upper girder 710 among the additional wasted areas,
The method comprising the steps of: The method according to claim 1,
Before the outer wall formation step,
A drilling step of continuously forming a plurality of perforation holes (10);
A grouting step of grouting inside the plurality of through holes (10);
A wall member inserting step of inserting the wall member 100 along the longitudinal direction of the plurality of perforation holes 10;
Forming an underground wall body (200) by placing concrete inside the wall member (100);
A crushing step of crushing a front region of the ground wall body 200;
Installing a connecting member (320) on a front surface of the exposed underground wall (200);
Coupling the reinforcing assembly (310) and the connecting member (320);
Forming a closed wall body (400) by pouring concrete so that the reinforcing bar assembly (310) is embedded;
Further,
The outer wall formation step
And the outer wall body (500) is installed in front of the closed wall body. 15. The method of claim 14,
The wall member
A main body 110 of a rectangular box structure having upper and lower trim portions;
A plurality of partition walls 120 formed in the body 110 to have a lattice structure;
A guide member 130 installed on the inner surface of the partition 120;
≪ / RTI &
The guide member (130)
A pipe member 131 formed to insert the reinforcing bar 133;
A spacing member 132 which is engaged with the inner surface of the tubular member 131 and the inner surface of the partition 120 or the inner surface of the tubular member 131 and the inner surface of the partition 120,
The method comprising the steps of: 15. The method of claim 14,
The connecting member 320
Wherein the method comprises the steps of:

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