KR20050098338A - Structure of steel pipe applied to steel pipe roof construction method for building underground structure, and steel pipe roof structure therefor using the same, and steel roof construction method thereof - Google Patents

Abstract

The present invention relates to a structure of a steel pipe applied to an unattached steel pipe loop method for constructing a structure in a ground where a non-opening method is required, and a steel pipe loop structure to which the same is applied. Two first flanges are attached to one outer side of the steel pipe, and a second flange corresponding to the first flange of the other steel pipe is attached to the other side up and down, and a latch ring is formed at the central portion of one side of the steel pipe. The central portion is formed with a T-shaped flange connected to the clasp of the other steel pipe, and a plurality of through holes for penetrating the fixing hardware for coupling the steel pipe adjacent to both sides of the steel pipe to each other is formed. The ends of the flanges are formed in a straight line, and the flanges overlap each other or are butt-shaped. The fixing steel penetrating the through hole is installed through the fixing steel through hole formed in the adjacent steel pipe. After that, the mortar or concrete is filled in the closed space formed by the upper and lower flanges of the inner and adjacent steel pipes. Thus, due to the rigid lateral stiffness can be installed in the earthwork by installing only the temporary pillar without the installation of a separate lateral support beam, the size of the temporary roof is reduced and the construction process is simplified. During earthwork, segregation excavation is carried out in the roof structure to secure the safety of the tunnel during construction, and the excavation is carried out selectively to the site where the structure is to be installed. Therefore, it prevents ground displacement and ensures stability during construction, as well as shortens the air and reduces construction costs.

Description

Structure of steel pipe applied to steel pipe roof construction method for building underground structure, and steel pipe roof structure therefor using the same, and steel roof construction method

The present invention is difficult to transfer obstacles due to construction when the sewage rock, underground roadway, tunnel structure, etc. must be installed across the existing roads and railways, or it is impossible to fix them due to obstacles, obstacles in vehicle communication, etc. The present invention relates to a structure of a steel pipe applied to a steel pipe loop method for constructing a structure in the ground, a steel pipe loop structure applied thereto, and a steel pipe loop method.

In more detail, the present invention is provided with a clasp connection at the upper and lower ends of the outer side of each steel pipe and the central portion of the outer side of each steel pipe to secure structural continuity to ensure the structural continuity of the steel pipe forming the loop and for fixing the installation through the steel pipe outer surface It relates to a steel pipe having a through-hole, and a steel pipe loop structure formed by installing the fixing iron through the inside of the steel pipe by pressing the steel pipe in the ground and connected to each other, and the steel pipe loop method. Due to the strong lateral stiffness of the constructed roof structure, the temporary roof can be installed by installing only temporary columns without installing additional lateral support beams. There is also the effect of being simplified.

In general, there is a structure construction method by the attachment and non-attachment in a way to build the structure in the ground. If it is necessary to install sewage rocks, underground roadways, tunnel structures, etc. across existing roads and railways, it is difficult to transfer obstacles due to construction, or it is impossible to fix them due to obstacles and obstacles in vehicle communication. In the non-adhesive structure construction method, the forward base and the reaching base of the concept of the work tool are essential to both sides of the crossing road or obstacle, and the typical non-adhesive underground structure construction method includes the hamp dog artificial method and the steel pipe loop method. Can be mentioned.

The ship prosthesis method is to press-through a steel pipe for supporting the housing about 600mm in advance from the forward base to the reach base in the ground through which the ship will pass, and then cross the ground from the reach base on the opposite side of the ship to be towed. After binding the PC steel wire to the manufactured enclosure on the site, it is towed to remove the internal soil in the enclosure and to repeat the towing and excavation work to install the structure in the ground. In this method, the propulsion load of the enclosure or the gap between the propulsion vessel and the temporary steel pipe installed in the ground may cause settlement on the road or obstacles on the upper part of the enclosure. If the size of the larger the traction constraints and the larger size of the workplace is difficult to work in deep underground space. If the connection between the enclosures is insufficient, leakage may occur. Due to the drawbacks of such hull prosthesis method, steel pipe loop method is often applied as a non-removable underground structure construction method.

Since the steel pipe of the present invention is mainly applied to the loop method of the non-adhesive method, the present invention will be understood by explaining examples of the existing non-adhesive steel pipe loop method and the steel pipe loop structure.

Hereinafter, a conventional steel pipe loop method and a steel pipe loop structure will be described with reference to FIGS. 1 to 5. In the conventional steel pipe loop method, the steel pipe 1 is sequentially press-connected to the ground where the structure is to be formed, thereby forming a steel pipe loop, removing all the internal soil inside the steel pipe loop, and constructing the structure. As shown, the upper or side loads generated during the excavation are supported by temporary materials such as transverse support beams 4 and temporary columns 5.

The construction process of the steel pipe loop is as follows. First, in consideration of the size of the sphere to be formed at the forward base base horizontally indented steel pipe (1) of about 600-800mm to the outer surface of the sphere and cast concrete in the steel pipe, to form a steel pipe loop (Fig. 2). From the forward base, the excavation is performed inside the loop where the structure is to be constructed. Excavation is excavated step by step downward from the upper part of the roof steel pipe considering the safety of the upper load and the side pressure. Excavation is primarily to excavate the bottom of the steel pipe loop with a depth of about 3m. Since the steel pipe (1) and the steel pipe (1) used in the loop is connected in a simple ring form (2, 3), as shown in Figure 6, The horizontal support beam 4 is installed with H-shaped steel in the direction perpendicular to the steel pipe at the bottom and side of the steel pipe loop, and is supported by a plurality of temporary columns 5 to support the load over the entire section (FIG. 3). In other words, as shown in FIG. 6, a conventional steel pipe loop has a pair of ?? It is a concept to prevent the deviation of the steel pipe rather than the role of bearing the load by connecting the steel pipes pre-indented in the form of mutual rings by connecting the concave-convex structure with the female ring (2) and the T-shaped clasp (3). .

Therefore, there is a disadvantage that it is not possible to secure the lateral rigidity between the connecting portion of the steel pipe loop. Accordingly, the lateral support beam 4 and a larger number of temporary columns 5 should be installed, and the structure should be installed so as to be spaced apart by the support beam 4, thereby increasing the size of the temporary installation. After the 2nd and 3rd excavation, the installation pillars (5), which have already been installed, are carefully extended downward (5 ', 5 ") to complete the excavation of the earth and sand until the installation depth of the structure (FIGS. 4 and 5). By installing reinforcing bars and formwork for the upper slab 60, the wall 65, and the lower slab 80, and placing the concrete to complete the structure of the underground construction as shown in Figure 5. The steel pipe loop method has a high possibility of subsidence during construction due to the problem of digging the already installed temporary columns and extending them downward to the installation depth, and the speed of construction due to problems with existing installed temporary materials (4, 5). Late.

The technical problem to be achieved by the present invention is to connect the adjacent steel pipe to the upper and lower flanges and the clasp connection of the central portion of the side and to install a fixing hardware to bear the tension in the transverse direction, mortar in the closed space formed by the inner and upper flanges of the steel pipe Or it is intended to provide a steel pipe structure to ensure the lateral bearing capacity by placing concrete.

Another technical problem to be achieved by the present invention is to install by installing only the temporary pillars without the installation of a transverse support beam regardless of the scale or depth of construction of the underground construction work when constructing underground construction using a steel pipe loop with improved lateral bearing capacity It is an object of the present invention to provide a steel pipe loop structure, and a steel pipe loop method using the same, so that the scale of the temporary loop can be reduced and the construction process can be simple and easy.

The present invention, in order to achieve the above another technical problem, in the steel pipe applied to the steel pipe loop method for constructing the structure in the ground, sequentially installed in accordance with the outline of the structure to be installed after installing work tools on both sides of the road or obstacle to be traversed Up and down two first flanges are attached to the outer one side, which is press-fitted to the second side, and a second flange corresponding to the first flange of the other steel pipe is attached to the other side up and down, and at the central part of one side of the steel pipe when the steel pipe is press-fitted A clasp ring is formed to prevent the hook, and a clasp flange connected to the clasp of the other steel pipe is formed at the other central portion, and a plurality of through holes are formed to penetrate the fixing hardware for joining the steel pipes adjacent to both sides of the steel pipe to each other. To provide steel pipes.

Preferably, the ends of the first and second flanges are formed in a straight shape, and the flanges of adjacent steel pipes are formed to overlap each other or combine in a butt shape to form a closed space.

The present invention, in order to achieve the above another technical problem, in the steel pipe loop structure applied to the steel pipe loop method for constructing the structure in the ground, after installing work tools on both sides of the road or obstacle to be traversed, the upper and lower sides 2 Two first flanges are attached to the other side and a second flange corresponding to the first flange of the other steel pipe is attached up and down, and a clasp ring is formed at the central portion of one side of the steel pipe, and the clasp of the other steel pipe is formed at the other central portion. When the clasp flange is connected and the steel pipes are formed to have a plurality of through-holes for the installation of the fixing steel coupling the steel pipes adjacent to both sides of the steel pipe to each other, and sequentially press-fit installation in accordance with the outline of the structure to be installed, The steel pipe clasp is looped with the clasp flange of the other steel pipe while drilling the steel pipe into the auger in the ground. The first flange is overlapped with the second flange of the other steel pipe or coupled in a butt type, and then press-installed in sequence, and the steel pipes are connected by inserting the fixing hardware through the fixing steel through-hole, and then to the inside of the steel pipe and the flange It provides a steel pipe loop structure made by pouring concrete into the closed space formed by the.

The present invention, in order to achieve the above technical problem, in the steel pipe loop method for constructing the structure in the ground, in order to ensure the safety of the structure before the construction of earthwork, first, in accordance with the size of the underground structure, Prepare a steel pipe with a central clasp connection, align the clearances of the upper and lower flanges adjacent to each other, connect the clasp connections between the steel pipes, press-fit and adjust the center position, and connect the upper and lower flanges of adjacent steel pipes to form a closed space. The steel pipe loop structure is formed by connecting adjacent steel pipes by using the fixing steel penetrated from the inside of the steel pipe through the fixing hole formed in the steel pipe, and pouring mortar or concrete into the closed space formed by the steel pipe connection flange. Forming a; Securing an equipment path through excavation; Installing only temporary pillars if necessary without securing the transverse support after securing the equipment passage; Installing the temporary piles if necessary and putting the equipment into the walls and the pillars, which are the next excavation sites, to perform the next excavation; And constructing a bottom slab after constructing a structure such as an upper slab and left and right wall pillars and finally performing a final earthwork.

In the following embodiments of the present invention will be described in detail the configuration and operation of the steel pipe structure applied to the non-adhesive steel pipe loop method and the steel pipe loop structure applied thereto, and the preferred embodiment of the steel pipe loop method applied thereto. However, the present invention is not necessarily limited thereto, and many modifications and variations are possible to those skilled in the art.

In the present invention will be described in more detail with reference to FIGS.

7 illustrates a structure of a steel pipe and a connection relationship between steel pipes according to a first embodiment of the present invention. In the detailed cross-sectional view of Figure 7, the upper and lower flanges are attached to both sides of the steel pipe, the flanges of adjacent steel pipes are coupled to each other in the form of a butt, the clasp and T-shaped flanges are attached to both sides of the central portion and the adjacent steel pipes are mutually coupled to each other and the steel pipes mutually The interconnection relationship of the steel pipes is shown to secure a predetermined position of the steel pipe, and also show that a plurality of through-holes for fixing fixtures are formed so that adjacent steel pipes are mutually coupled.

As shown in FIG. 7, the first flange 12 is vertically attached to one outer side of the steel pipe 10, and the other side of the steel pipe 10 is connected to the first flange 12 of the adjacent steel pipe in a butt type to close the closed space 150. The 2nd flange 100 which forms) is attached up and down. Ends of the first and second flanges 12 and 100 are formed to have a straight line indentation. However, the end of the flange does not necessarily have to be straight, and as long as the structure is easy to press in, it does not matter whether it is ?? or ??. In addition, the clasp ring 20 is formed in the central portion of one side of the steel pipe, the T-shaped flange 22 connected to the clasp 20 of the other steel pipe is formed in the other central portion, the upper and lower parts of both sides of the steel pipe 10 There are formed a plurality of through-holes 135 for penetrating the fixing hardware 130 for coupling adjacent steel pipes to each other. The through hole may be provided above and below both sides of the steel pipe, but may be provided only on one side or a part thereof. As shown, the fixing hardware 130 is one end of the through-hole 135 of one steel pipe after passing through the through-hole 135 of the other steel pipe is preferably a structure that is coupled to the screw, both ends of the bolt Instead of a head structure or a screw structure, a bolt headless structure may be formed, or a screw may be screwed and at least one side of a headless tension bolt type fixing hardware may be formed to be penetrated through the through hole 135.

On the other hand, by filling the mortar or concrete in the closed space 150 formed by the butt joint of the inner 15 of the steel pipe 10 and the first and second flanges 12, 100 of the adjacent steel pipe, the upper soil load is better It is possible to form an integral transverse continuous hypothesis loop structure that can be supported.

In addition, the T-shaped flange 22 attached to the central portion of the steel pipe 10 is caught by the latch ring 20 attached to the central portion of the adjacent steel pipe to prevent the positional deviation during construction due to the press-fitting of the steel pipe. Here, the clasp ring and the T-shape flange forms a clasp connection, the T-shaped flange does not necessarily have to be a T-shape, it does not matter if the structure is caught in a clasp, such as a straight, ??.

8 illustrates a structure of a steel pipe and a connection relationship between steel pipes according to a second embodiment of the present invention. In the detailed cross-sectional view of Figure 8, the upper and lower flanges are attached to both sides of the steel pipe, the flanges of adjacent steel pipes are coupled to each other in the form of overlapping, the clasp and T-shaped flanges are attached to both sides of the central portion and adjacent steel pipes are mutually interlinked and a plurality of The interconnection relationship of the steel pipes is shown, which shows that the through-holes for installing the fixing steel are formed so that adjacent steel pipes are mutually connected.

As shown in FIG. 8, the first flange 12 is vertically attached to an outer side of the steel pipe 10, and the other side is connected to the first flange 12 of the adjacent steel pipe in an overlapping manner to form a closed space 150. The 2nd flange 100 which forms) is attached up and down. Ends of the first and second flanges 12 and 100 are formed to have a straight line indentation. However, the end of the flange does not necessarily have to be straight, and as long as the structure is easy to press in, it does not matter whether it is ?? or ??. In addition, a clasp ring 20 is formed at one central portion of the steel pipe, a T-shaped flange 22 connected to the clasp 20 of the other steel pipe is formed at the other central portion, adjacent to both sides of the steel pipe 10 A plurality of through-holes 135 for penetrating the fixing hardware 130 for coupling the steel pipes to each other is formed. The through hole may be provided above and below both sides of the steel pipe, but may be provided only on one side or a part thereof. Here as well, as shown, the fixing hardware 130 is one end of the through-hole 135 of one steel pipe after passing through the through-hole 135 of the other steel pipe is preferably a structure that is coupled to the screw Instead of the bolt head structure or the screw structure, both ends may be formed without a bolt head, or may have a structure in which a fixing bolt of a headless tension bolt type is not screwed and at least one side is penetrated through the through hole 135. .

Of course, by filling mortar or concrete in the closed space 150 formed by the combination of the overlapping form of the inner 15 of the steel pipe 10 and the first and second flanges 12 and 100 of the adjacent steel pipe, the upper soil load is increased. It is possible to form an integrated transverse continuous hypothesis loop structure that can be well supported. Here, the T-shaped flange 22 attached to the central portion of the steel pipe 10 is caught by the clasp ring 20 attached to the central portion of the adjacent steel pipe to prevent the positional deviation during construction due to the press-fitting of the steel pipe. Here, the clasp and the T-shaped flange forms a clasp connection, the T-shaped flange does not necessarily have to be a T-shaped, it will not matter if the structure is caught in the clasp, such as straight, ??.

As in the first and second embodiments of the present invention described above, the concept of sustaining the lateral tension in the present invention is not primarily made through flange coupling and shackle connection, but is fixed to the side wall in the interior of the steel pipe after the steel pipe is installed. Through the fixing steel installation through-holes 135 installed at intervals adjacent to the steel pipe through the fixing hardware 130, such as tension bolts are made by combining the steel pipes to each other. In addition, after completing the installation of the continuous steel pipe is filled with the mortar or concrete in the closed space 150 formed by the flanges (12, 100) of the inner pipe 15 and the adjacent steel pipe of the steel pipe loop structure is larger It becomes a structure with lateral rigidity, and the lateral support 4 installed below the loop in the steel pipe loop method as shown in FIG. 1 becomes unnecessary.

Hereinafter, a steel pipe loop structure according to the present invention based on the structure of the steel pipe of the present invention described above will be described with reference to FIG. 9.

As shown in FIG. 9, the steel pipe loop structure applied to the steel pipe loop method for constructing a structure in the ground is constructed by applying the steel pipe shown in FIG. 7 or 8. The flange 12 is attached to the other side and the second flange 100 corresponding to the first flange of the other steel pipe is attached up and down, one side central portion of the steel pipe has a latch ring 20 is formed, the other side T-shaped flange 22 is connected to the clasp 20 of the other steel pipe is formed, a plurality of through-holes 135 for penetrating the fixing hardware 130 for joining the steel pipe adjacent to both sides of the steel pipe to each other After preparing the steel pipe 10 to be formed, and then install the work tool on both sides of the road or obstacle to be traversed is made by sequentially pressing in accordance with the outline of the structure to be installed. At this time, the steel pipe clasp ring 20 is coupled to the T-shaped flange 22 of the other steel pipe while the excavation to the auger in the ground at the same time to align the center while preventing mutual separation, and further 1, the flange 12 is connected to the second flange 100 of the other steel pipe in a fixed or overlapping manner, and then press-installed sequentially, and then through the fixing hardware 130 through the fixing hardware through-hole 135 Connect the steel pipes. Next, a steel pipe loop structure is constructed by pouring concrete into the closed space 150 formed by the steel pipe inner portion 15 and the flanges 12 and 100.

As shown in Fig. 9, the structure constructed by the non-adhesive steel pipe loop method of the present invention also has upper and lower slabs 60 and 80 and a wall portion 65 under the steel pipe loop structure as in the conventional method. However, the steel pipe loop structure is not provided with lateral support (4 in FIG. 5) to withstand the upper load. The reason is that the steel pipe structure applied to the steel pipe loop structure is connected by the flanges 12 and 100, the clasp 20 and the T-shaped flange 22 to connect the adjacent steel pipes, and the fixing steel 130 penetrates. This is because it is connected through the ball 135 and is integrated by concrete placed in the closed space 150 formed by the steel pipe inner portion 15 and the flanges 12 and 100 to increase the transverse load capacity.

Accordingly, when the roof structure is constructed using the steel pipe of the present invention, the transverse support 4 is not necessary, so that the size of the temporary steel pipe loop is reduced by the height occupied by the transverse support, and the number of temporary steels is also small. Used. In the earthwork work in the roof structure, the equipment is input by using the passage secured by the first earthwork work, and the soil and piles are selectively installed on the walls and the pillars, and the soil is removed secondly, and the walls, columns, After constructing the structure such as the upper slab, earthwork is performed on the remaining part supporting the upper load in the third order and the lower slab is constructed. Therefore, inevitably occurring in the process of removing all the soil inside the loop of the existing steel pipe loop method Since there is no ground subsidence, it not only secures stability during construction but also reduces the size of temporary facilities, which can shorten construction air and reduce construction costs.

In the present invention, when constructing a steel pipe loop structure, the steel pipe of the above-described structure is first formed by pressing the steel pipe of the above-described structure in the working tool of the underground structure. Such a steel pipe loop structure and a non-adhesive steel pipe loop method using the same are described below with reference to the accompanying drawings. This will be described.

10 to 15 is a construction flow chart of the non-adhesive steel pipe loop method applying the steel pipe and the steel pipe loop structure of the present invention. The construction and operation of the construction method in detail through the construction sequence is as follows.

As shown in Figure 10, the first step is to press and connect the steel pipe of the structure described above and then filling the mortar or concrete in the steel pipe. That is, after installing work tools on both sides of the road or obstacle to be traversed, the clasp 20 and the T-shaped flange 22 connect the steel pipe 10 with the flanges 12 and 100 to the outline of the structure to be installed. Insert it together and press-fit the steel pipe to the auger at the same time. Through the fixing steel through-hole 135 of the side wall of the press-fitted steel pipe, the fixing steel 130 is penetrated with the other steel pipe. Thereafter, concrete pouring or grouting is performed to the closed space 150 formed by the steel pipe interior 15 and the flanges 12 and 100.

As shown in FIG. 11, the first primary drilling is performed in a second step, and a temporary pillar 40 is installed. That is, while excavating the lower surface of the formed steel pipe loop structure to the depth that small equipment can enter, the upper load is supported by installing the H-beam 40 (temporary column) at appropriate intervals. At this time, the transverse support is not installed.

As shown in FIG. 12, a small piece of equipment is entered using a workspace secured in a third step to install a temporary H-pile 50 on a wall and a pillar.

As shown in Fig. 13, while the second earthwork is carried out in the fourth step, the wall and the intermediate pillar mounting provision (vertical beam: 75) is installed, and the reinforcing bars and formwork are assembled in the installed provisional wall to form the wall 65 and the upper portion. The slab 60 is constructed.

As shown in Figure 14, in the fifth step after the removal of the remaining internal soil and sewage in the third installation, the support 70 is installed on the floor slab, and the concrete is poured to install the floor slab (80).

As shown in FIG. 15, in the sixth step, the central wall and the slab surface treatment are performed and the site is cleaned to complete the construction of the desired underground structure.

As shown in Figures 10 to 15, the non-adhesive steel pipe loop method applying the steel pipe and the steel pipe loop structure of the present invention primarily in the passage for entering small equipment first in the internal excavation wrapped with the steel pipe loop structure Secure the earthwork facility by installing the H pile for the construction of the wall with the small equipment and install the earthquake temporary installation at the site where the wall and the pillar will be installed, and perform the multi-stage earthwork such as the second and third as needed. To form the desired structure. Thus, after excavating only the site where the structure is to be selectively installed, the structure is installed, and since the earthwork is performed on the remaining part supporting the upper load, it is possible to secure displacement suppression and stability of the ground during construction. Therefore, excavation in the first and second stages of earthwork in the constructed steel pipe loop, excavating the supporting part of the pre-installed column, connecting the members, removing all the soil in the loop, and then constructing the structure Settlement problems and lack of stability are solved.

In addition, the structural system capable of receiving a tensile force in the transverse direction through the fixing steel 130 through the fixing steel through-hole 135 installed at regular intervals on the side wall in the interior of the steel pipe as shown in Figure 7 or 8 through the other steel pipe Then, the mortar or concrete is filled in the inner steel pipe 15 and the mortar or grouting liquid is injected into the closed space 150 formed by the flanges 12 and 100 of the steel pipe to form a steel pipe having a transverse rigidity. It has the characteristics of the synthesized structure.

In addition, the present invention has been described so far as being limited to the non-adhesive steel pipe loop structure and the steel pipe structure, but the present invention is not limited thereto, and may be applied to the earthwork of the non-adhesive as well as the open-type perforated structure, such as steel pipes. It is to be understood that section steel as well as steel pipe may be used. In addition, it should be understood that various modifications and changes can be made within the scope of the appended claims regardless of the purpose and purpose of construction.

As described above, in the present invention, flanges 12 and 100 are connected to upper and lower outer portions of the steel pipe so as to form a closed space for filling mortar or concrete in the connection portion between the steel pipe and the steel pipe, Through holes 135 for attaching the clasp 20 and the T-shaped flange 22 to prevent separation during indentation of adjacent steel pipes, and connecting the fixing hardware 130 to enhance the transverse load-bearing force between the steel pipes 135 By forming concrete in the closed space of the steel pipe or the connection part, and constructing a steel concrete composite loop having a binding force in the transverse direction, so that the lateral rigidity of the roof structure during internal earthwork for structure construction Due to this, earthwork can be done by installing only temporary columns without installing additional transverse support beams, thus reducing the size of temporary loops and simplifying the construction process. It is.

Thus, in the earthwork work in the roof structure, the drilling equipment is input by using the passage secured by the first earthwork work, and the soil pile is selectively installed at the site where the wall and the pillar will be constructed, and the soil is removed secondly. After the construction of earthwork, earthwork is carried out on the remaining part supporting the upper load in the third step, so ground sedimentation, which is inevitably generated in the process of removing all the soil inside the loop of the existing steel pipe loop method, does not occur In addition to securing the size of the facility, construction air can be shortened and construction costs can be reduced.

1 is a general view for explaining a conventional non-attached structure construction method.

2 to 5 are cross-sectional views for explaining the construction procedure of the existing steel pipe loop method.

Figure 6 is a detailed view of the connection structure of the steel pipe of the existing construction method.

7 is a top and bottom flanges are attached to both sides of the steel pipe according to the first embodiment of the present invention, the flanges of adjacent steel pipes are coupled to each other in a mutually butt-type, and the clasp and T-shaped flanges are attached to both sides of the central portion adjacent steel pipes It is a detailed cross-sectional view showing the interconnection relationship of the steel pipes which are mutually coupled and a plurality of through-holes for the installation of fixing steel are formed so that adjacent steel pipes are mutually through.

8 is a top and bottom flange is attached to both sides of the steel pipe according to the second embodiment of the present invention, the flanges of adjacent steel pipes are combined in a mutually overlapping form, the clasp and T-shaped flanges are attached to both sides of the central portion adjacent steel pipes It is a detailed cross-sectional view showing the interconnection relationship of the steel pipes which are mutually coupled and a plurality of through-holes for the installation of the fixing steel is formed so that adjacent steel pipes are mutually through.

9 is a cross-sectional view showing an underground structure using an unattached steel pipe loop structure of the present invention.

10 to 15 is a construction flowchart of the construction method of the underground structure using the non-attached steel pipe loop structure of the present invention.

<Description of main parts of drawing>

10 ... steel pipe, 12, 100 ... first and second flange

15 ... inside steel pipe, 20 ... clasp

22 ... T-shaped flange, 40 ...

50 ... hypothetical files, 60 ... upper slab

65 ... wall, 70, 75 ...

80 ... lower slab, 130 ... fixed hardware

135 ... fixed steel through hole, 150 ... closed space

Claims (4)

In the steel pipe applied to the steel pipe loop method for constructing the structure in the ground, After the work tools are installed on both sides of the road or obstacle to be traversed, two first flanges are attached to one outer side and the first flange of the other steel pipe is attached to one side of the external pipe, which is sequentially press-fitted according to the outline of the structure to be installed. Correspondingly connected second flange is attached to the upper and lower sides, the clasp ring is formed in the central portion of one side of the steel pipe, the clasp flange is formed in the other central portion is connected to the clasp of the other steel pipe, the steel pipe adjacent to both sides of the steel pipe Steel pipes are formed with a plurality of through-holes for penetrating the fixing fixture to be combined. The steel pipe according to claim 1, wherein the flanges of adjacent steel pipes overlap each other or are joined in a butt type to form a closed space. In the steel pipe loop structure applied to the steel pipe loop method for constructing a structure in the ground, after installing work tools on both sides of the road or obstacle to be traversed, two first flanges are mounted on one side of the outer side and the other steel pipe on the other side. A second flange corresponding to the first flange of the upper and lower sides is attached up and down, and the clasp ring is formed in the central portion of one side of the steel pipe, the clasp flange is formed in the other central portion is connected to the clasp of the other steel pipe, both sides of the steel pipe When preparing a steel pipe formed with a plurality of through-holes for the installation of the steel fittings adjacent to the steel pipes adjacent to each other, and sequentially press-fitted to fit the outline of the structure to be installed, the steel pipes are drilled in parallel with the auger in the ground The clasp of the steel pipe is looped with the clasp flange of the other steel pipe, and the first flange of one steel pipe overlaps or meets the second flange of the other steel pipe. Combined in the form, press-installed sequentially, through the fixing hardware through-hole to connect the steel pipes through the connection of the steel pipes, steel pipe loop made by pouring mortar or concrete into the closed space formed by the inside of the steel pipe and the flange Structure. In the steel pipe loop method for constructing the structure in the ground, In order to ensure the safety of the structure before the earthwork work, first prepare the steel pipes with side up and down connecting flanges and the center clasp connection according to the size of the underground structure, and then connect the clasp connections between adjacent steel pipes to adjust the center position. Press-fitting, connecting the upper and lower flanges of adjacent steel pipes to form a closed space, and connect the adjacent steel pipes using the fixing steel penetrated from the inside of the steel pipe through the through-hole for fixing fixtures formed in the steel pipe, and the inside of the steel pipe and Pouring mortar or concrete into the closed space formed by the steel pipe connecting flange to form a steel pipe loop structure; Securing an equipment path through excavation; Installing only temporary pillars if necessary without securing the transverse support after securing the equipment passage; Installing the temporary piles if necessary and putting the equipment into the wall and the pillar which are the next excavation site, and performing the next excavation as necessary; And Steel pipe roofing method comprising the step of building the bottom slab after the final earthwork after the construction of the upper slab and left and right wall pillars.