KR100833700B1 - Steel pipe roof structure - Google Patents

Abstract

The present invention relates to a steel pipe loop structure, by connecting neighboring steel pipes to each other in a state aligned with each other in a horizontally aligned state to make the stiffness in the lateral rigidity, so that it can be installed without a separate transverse support Its purpose is to provide a steel pipe loop structure.

Steel pipe loop structure of the present invention for achieving the above object, the horizontal grooves 204 are formed in each side in the horizontal direction, the inner side of the horizontal grooves 204 are crushed in accordance with the load by the horizontal grooves A plurality of support 202 is installed at a predetermined interval to prevent falling, and the support 202 is installed on the other side of the horizontal groove 204, the angle 206 corresponding to the horizontal groove is installed, the constant between the angle A plurality of steel pipes 200 having communication grooves 210 formed at intervals are laterally coupled to each other in a aligned state.

Unsealed, Underground Structure, Steel Pipe Roof

Description

Pipe roof structures

1 and 2 is a cross-sectional view for explaining a conventional non-attached structure construction method.

Figure 3 is a detailed cross-sectional view showing a connection structure of the steel pipe loop structure in Figures 1 and 2.

4 and 5 are sectional views for explaining another conventional non-attached structure construction method.

Figure 6 is a cross-sectional view showing a connection structure of the steel pipe loop structure in Figures 4 and 5.

Figure 7 is a perspective view showing the connection of the steel pipes constituting the steel pipe loop structure according to the present invention.

FIG. 8 is a schematic cross-sectional view with the steel pipes coupled to FIG. 7.

Figures 9a to 9g is a work flow chart showing the step of sequentially constructing the incoming steel pipes according to the present invention.

10 and 11a, 11b is a cross-sectional view for explaining a non-bonded structure construction method using a steel pipe loop structure according to the present invention.

12 is a perspective view illustrating a connection relationship between steel pipes forming a steel pipe loop structure according to another embodiment of the present invention.

FIG. 13 is a schematic cross-sectional view with the steel pipes coupled to FIG. 12.

Figure 14 is a cross-sectional view showing a state in which the underground structure in a state in which the steel pipe loop structure according to Figures 12 and 13 connected by a connector.

15 and 16 are sectional views for explaining another non-bonded structure construction method using a steel pipe loop structure according to the present invention.

17 and 18 are structural cross-sectional views for explaining another non-bonded structure construction method using a steel pipe loop structure according to the present invention.

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

200: steel pipe 202: support

204: horizontal groove 206: angle

210: communication groove 220: connector

The present invention relates to a steel pipe loop structure, and more particularly, by connecting neighboring steel pipes to each other in a state in which the lateral stiffness is secured in a horizontally aligned state, so that construction without additional lateral support This relates to a steel pipe loop structure made possible.

In general, there is a structure construction method by the attachment and non-attachment in the manner of constructing the structure in the ground.

If it is necessary to install sewage rocks, underground roadways, tunnel structures, etc. across existing roads and railroads, 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 arrival base of the working tool concept are essential on both sides of the crossing road and the stored object, and the representative non-adhesive underground structure construction method includes the pull dog artificial method and the steel pipe loop method. Can be mentioned.

In the case of the ship prosthesis method, the steel pipes for supporting the housing of about 600mm in advance are horizontally press-fitted in the direction of the reach base from the forward base, 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 ship manufactured in the field, it is towed to remove the internal soil in the box, and the same towing and excavation work is repeated to install the structure in the ground.

However, this method may cause settlement of roads or obstacles on the upper part of the enclosure due to the propulsion load of the enclosure or the gap between the propulsion enclosure and the temporary steel pipe installed in the underground. Therefore, when the size of the enclosure increases, the traction is restricted and the size of the workplace is large, so it is difficult to work in a deep underground space.

In addition, if the connection between the enclosures is insufficient treatment, there was a risk of leakage, etc. Due to the drawbacks of the hull prosthesis method, the steel pipe loop method is applied as a non-removable underground structure construction method.

Since the present invention is mainly applied to the steel pipe loop method of the non-adhesive method, the present invention will be explained by explaining an example of the existing steel pipe loop method.

Hereinafter, the conventional steel pipe loop method will be described with reference to FIGS. 1 to 3 in order to explain the difference from the conventional steel pipe loop method.

In the conventional steel pipe loop method, the steel pipe 1 is sequentially press-ined and connected to the ground where the structure is to be formed to form a steel pipe loop, and remove all the internal soil inside the steel pipe loop and construct the structure, as shown in FIG. As described above, the upper or side loads generated during the excavation are supported by temporary materials such as lateral support beams 4 and temporary columns 5.

Briefly describing the construction process of the steel pipe loop, considering the size of the sphere to be constructed at the forward base, horizontally indented the temporary steel pipe (1) of about 600 ~ 800mm to the outer surface of the sphere and cast concrete in the steel pipe in Figure 1 To form a steel pipe loop.

From the forward base, the inside of the steel pipe loop will be excavated, and the excavation is carried out step by step from the upper part of the steel pipe loop in consideration of the safety of the upper load and the side pressure.

At this time, the excavation is primarily to excavate the bottom of the steel pipe loop with a depth of about 3m, the steel pipe (1) and the steel pipe (1) used in the steel pipe loop is a simple ring shape (2, 3) as shown in FIG. Since it is connected, horizontal support beams (4) are installed with H-shaped steel in the direction perpendicular to the steel pipe on the lower surface and side of the steel pipe loop, and supported by a plurality of temporary columns (5) to support the load over the entire section.

In other words, the existing steel pipe loops as shown in Figure 3, the steel pipes pre-indented by the connection structure of the concave-convex structure with a pair of L-shaped ring (2) and T-shaped clasp (3) attached to the central portion of the steel pipe side It is only a concept to prevent the positional deviation of the steel pipes rather than to bear the load by connecting the construction in the form of mutual rings.

Therefore, there is a problem that can not secure the lateral rigidity between the connecting portion of the steel pipe loop. The transverse support (4) and a larger number of temporary columns (5) should be installed, because the structure should be installed spaced apart by the support beam (4) there was a problem that the size of the temporary installation increases.

After the 2nd and 3rd excavation, the already installed temporary column (5) is carefully extended downward to complete the excavation of the earth and sand to the installation depth of the structure, and finally, the upper slab (60), the wall (65), and Install the reinforcing bar and formwork for the lower slab (80) and the like to finish the structure of the underground construction.

The conventional steel pipe loop method constructed as above has a high possibility of subsidence during construction due to a problem that the installed temporary pillar is extended downward to the installation depth after excavation, and it is inferior to the existing installed temporary materials (4, 5). The problem was that the air was delayed and the construction cost was high.

Therefore, in order to solve the above problems, it is possible to install by installing only temporary pillars without installing a transverse support beam regardless of the scale or depth of underground construction work when constructing underground constructions using steel pipe loops. A steel pipe loop structure has been proposed.

That is, as shown in FIGS. 4 and 5, the structure constructed by the non-adhesive steel pipe loop structure also has the upper and lower slabs 60 and 80 and the wall portion 65 under the steel pipe loop structure as in the conventional method described above. have.

However, the steel pipe loop structure does not have a transverse support to withstand the upper load.

The reason for this is that, as shown in Fig. 6, the flange 12 and the clasp steel plate 100 are attached to both sides, and the flange 12 of a certain steel pipe is connected to this steel pipe. Since the clasp steel plate 100 of the steel pipe to be fitted to each other, the steel pipe inside, and the concrete pressure is filled in the closed pressure space (6) formed by the flange 12 and the clasp steel plate 100 to increase the load capacity. to be.

In other words, when the steel pipes are continuously connected to each other as described above, a space 6 forcibly closed by the flange and the clasp steel plate is formed.

Of course, by filling the mortar or concrete in the closed space (6) formed by the interior of the steel pipe (10) and the connection device, such as the flange 12 and the clasp steel plate 100 of the steel pipe and steel pipe can better support the upper soil load. An integrated transverse continuous hypothetical loop structure is formed, which eliminates the need for the transverse support beams 4 installed under the steel pipe loops.

However, the steel pipe loop structure described above, by filling concrete or mortar in the closed pressure space formed by the flange and the clasp steel plate and the inside of the steel pipes, respectively, so that the steel pipe loop has a lateral rigidity, thereby eliminating the conventional lateral support. However, this is a problem that can not work in reality.

In other words, the inside of the steel pipe forms a separate space from the top and side soils, and as the pressure of the steel pipes is pushed out, the soils existing inside the steel pipes are pulled out and there is no difficulty in filling concrete or mortar (the diameter of the steel pipe is workable). Because of the size), the closed pressure space formed by the flange and the clasp plate is not a workable space, so that it is impossible to work out the earth and sand to fill the concrete and mortar.

Therefore, the steel pipe loop has lateral rigidity only at the site where the flange and the clasp steel are connected before curing after filling concrete or mortar into the steel pipe, and this alone does not endure the load of the upper side soil and thus requires a separate transverse support. There is no choice but to.

In addition, even if the lateral stiffness without a separate lateral support, the pressure of the earth and sand is concentrated to the site where the clasp plate of the steel pipe adjacent to the flange of the steel pipe is concentrated, so that the steel pipe loop is aligned in the horizontal direction By not achieving the state, there is a problem that can not be made smooth construction.

Accordingly, the present invention has been devised in view of the above problems, by connecting neighboring steel pipes in a state facing each other to ensure that the stiffness in the horizontal direction is firmly aligned, thereby supporting a separate lateral direction It is an object of the present invention to provide a steel pipe loop structure that enables construction without a beam.

The steel pipe loop structure of the present invention for achieving the above objects, in the steel pipe loop structure applied to the steel pipe loop method for constructing the structure in the ground, to be installed after installing the work tool on both sides of the road or obstacle to be traversed In order to be press-fitted sequentially in accordance with the outline of the structure, horizontal grooves are formed on one side in a horizontal direction, respectively, and inside the horizontal grooves at a predetermined interval to prevent distortion by the horizontal grooves in accordance with the load. A plurality of supports are installed over the other side of the horizontal groove, a pair of angles corresponding to the horizontal groove is installed, and a plurality of steel pipes having communication grooves formed at regular intervals between the angles are arranged side by side. Orientationally coupled, the angles are formed in the form of the letter L so that one side of one side is opposite to each other on one side of the outer surface of the steel pipe It is fixedly installed, the other end is characterized in that the steel pipes are laterally coupled in a mutually aligned state by sliding the surface friction in a state inclined in the inward direction of the horizontal groove end of the other adjacent steel pipe.

In this case, through the communication grooves and the horizontal grooves of the steel pipes pass through the connector such as reinforcement to bind the steel pipes coupled laterally to each other.

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

First, FIG. 7 is a perspective view illustrating a connection relationship between steel pipes constituting the steel pipe loop structure according to the present invention, and FIG. 8 is a schematic cross-sectional view of the steel pipes in FIG.

In addition, Figures 9a to 9g is a work flow chart showing the step of sequentially constructing the incoming steel pipes according to the present invention.

First, the steel pipe that is pushed and pushed first during the construction of the steel pipe loop structure uses a diameter set according to the size of the construction, and uses a conventional steel pipe.

In this way, the support 202 is installed on one side of the inner pipe of the first press-propelled steel pipe 200 in a vertical direction at regular intervals.

At this time, the support 202 is preferably fixed to the inner surface of the steel pipe 200 by welding, but is not limited to the fixing method.

Next, the horizontal groove 204 may be formed by cutting the direction in which the support 202 is installed, that is, one side direction in the longitudinal direction, wherein the load according to the earth pressure in the upper part is supported by the support 202 already installed. One side of the steel pipe 200 is cut so that the horizontal groove 204 is not crushed even if it is formed.

As such, when the first steel pipe is press-propelled and the horizontal groove 204 is formed on one side thereof, a pair of angles corresponding to the horizontal grooves 204 are formed on one side of the steel pipe 200 to be press-propelled next. Fix 206.

That is, the angle 206 may be fixed to one side of the steel pipe to be press-propelled at an interval corresponding to the length of the upper and lower horizontal grooves 204 of the steel pipe 200.

At this time, the fixing of the angle 206 is preferably fixed by welding, but may be fixed by bolts, and the fixing means and method are not limited.

Here, the angle 206 is made of a L-shape so that one side of one end is fixedly installed opposite to each other on one side of the outer surface of the steel pipe.

Therefore, the steel pipe and the other end that is not fixed to each other take a form inclined by a predetermined angle in the form of being separated from each other.

As described above, in a state where one end of the angle 206 is fixed to one side of the steel pipe to be pushed, the angle 206 is pushed and pushed while sliding into the horizontal groove 204 of the steel pipe push-propelled.

Then, the other end of the one end fixed to the steel pipe, that is, formed in the form of a mutually inclined area that is inclined by a certain angle is sliding in a state of inclined surface friction in the inclined inward direction of the horizontal groove end of the press-propelled steel pipe, The binding force between the steel pipe and the steel pipe becomes firm.

In this case, a bolting hole (not shown) is fixed to one side of the steel pipe to be propelled in a state of pre-construction, and then press-propelled to bolting to one side of the support 202 of the press-propelled steel pipe to provide a more solid binding force. You can also have it.

Then, as shown in FIGS. 8 and 9c, the steel pipes are connected to each other in a state in which they are prevented from escaping from each other, and even if the press-propelled steel pipes are in an error position from the set position, the steel pipes to be push-propelled are sufficiently pushed in while pushing the push-propelled steel pipes. You can modify it.

After that, the support is fixed up and down on one side of the press-propelled steel pipe, cut to form a horizontal groove on one side, and then press-propelled the next steel pipe in the same manner as before.

Then, as shown in FIG. 9g, the steel pipes are connected to each other without being separated from each other to form an integrated steel pipe loop structure.

Therefore, the steel pipe loop structure is more firmly aligned, thereby maintaining the transverse direction, that is, the horizontal direction even under the load due to the pressure of the soil, and having a stronger transverse rigidity, so that a separate transverse support is required. There will be no.

In this state, when the earth and sand existing therein is pushed out according to the push-in propulsion of the steel pipes, and the concrete or mortar is filled and cured therein, the steel pipe loop structure forms a unitary structure in a horizontal state.

For reference, in the press-propelled state of the steel pipe, the support is installed at one side at regular intervals, and a part of the incision is formed to form a horizontal groove in the longitudinal direction. However, when the depth of the working place is not large, the outside for convenience of work After cutting a portion to form a horizontal groove in the state, and press-propelled in this state, a support may be installed.

The structure constructed by the steel pipe loop structure described above also has the upper and lower slabs 60 and 80 and the wall portion 65 under the steel pipe loop structure as shown in FIGS. 11A, 11B, and 12, and support beams 40 on both sides. ) Only the construction of the tunnel is made easier.

On the other hand, Figure 12 is a perspective view showing the connection of the steel pipes constituting the steel pipe loop structure according to another embodiment of the present invention, Figure 13 is a schematic cross-sectional view in a state in which the steel pipes are coupled in FIG.

In the present embodiment, the communication groove 210 is formed at a predetermined interval on a side opposite to the horizontal groove 204 of the steel pipe 200 at a predetermined interval.

That is, the other steel pipes except for the first press-propelled steel pipe is formed in the communication groove 210 at regular intervals on the opposite side formed with the support 202 and the horizontal groove 204.

Like the horizontal groove 204, the communication groove 210 may also be formed by cutting in a state in which the steel pipe is press-propelled, or may be formed before press-propulsion.

The communication grooves 210 are formed on the opposite side of the support 202 and the horizontal groove 204, and thus are positioned between the angles 206 formed up and down.

As such, when the steel pipe 200 having the communication groove 210 is formed by press-propelling the steel pipe 200 in the same manner as in the previous embodiment, the steel pipe loop structure is installed, and the steel pipes of the steel pipe loop structure are horizontal grooves with the communication grooves 210. Intercommunication is achieved by means of 204.

Therefore, when the concrete or mortar is filled and cured in the steel pipe 200 in this state, the concrete or mortar is connected to each other by the communication grooves 210 and the horizontal grooves 204 to form one integrated structure. Is achieved.

As a result, the lateral coupling force of the steel pipes in the steel pipe loop structure is increased, and thus the lateral rigidity of the steel pipe loop structure is increased.

On the other hand, through the communication grooves 210 and the horizontal grooves 204 formed in the steel pipes of the steel pipe loop structure through the connector 220, such as reinforcing bar can be more solid as a structure.

That is, as described above, the steel pipe structures communicate with each other by the communication grooves 210 and the horizontal grooves 204 formed in the steel pipes, thereby forming a plurality of rebars through the communication grooves 210 and the horizontal grooves 204. In the inserted and connected state, when the concrete or mortar is filled and cured inside the steel pipe, the concrete or mortar is connected to each other by the communication grooves 210 and the horizontal grooves 204 to form one integrated structure. This room, of course, the connector 220, such as reinforcing bars further increase the binding force of the steel pipes to further increase the lateral coupling of the steel pipes in the steel pipe loop structure.

For reference, in the present invention, the tunnel between the reciprocating section is shown as an example, but as shown in Figs. 15 and 16, the tunnel between the knitting tools can be constructed as a steel pipe loop structure having the same configuration, and the upper wall and the sidewall are perpendicular to each other. 17 and 18, but also in the elliptical tunnel, it can be seen that the construction as a steel pipe loop structure of the same configuration is also possible.

Of course, the steel pipe loop structure applied to the inter-knife tunnel as shown in Figs. 15 and 16, or the ellipsoidal tunnel as shown in Figs. 17 and 18, the concrete in the state of forming a communication groove as in another embodiment of the present invention. B or mortar may be poured, or concrete or mortar may be poured in a state in which a connector such as reinforcing bar is installed through the communication groove and the horizontal groove to have more robustness.

As described above, one side of the steel pipe is cut out to form a horizontal groove, and the angle fitted to the horizontal groove is fixed to one side of the other steel pipe adjacent to each other, while the angle slides into the horizontal groove of the press-propelled steel pipe. By repeating the alignment to be in a mutually aligned state to form a steel pipe loop structure, by filling and curing concrete or mortar to the steel pipe loop structure thus formed to provide an integral steel pipe loop structure having a more secure binding force in the transverse direction, In the earthworking work for the construction of the structure, due to the lateral rigidity of the steel pipe loop structure, the construction of the earthwork is possible by installing only temporary columns without the installation of a separate lateral support beam, thereby reducing the size of the temporary roof and simplifying the construction process. This is a very useful effect.

In addition, when the communication grooves are formed in the steel pipes, concrete or mortar filled in the steel pipes are integrally cured by the communication grooves and the horizontal grooves, thereby providing a steel pipe loop structure having a more secure binding force. In addition, when the reinforcing bars, etc. are connected through the communication grooves, there is an effect of providing a more rigid steel pipe loop structure.

Claims (2)

In the steel pipe loop structure applied to the steel pipe loop method for constructing the structure in the ground, After installing the work tool on both sides of the road or obstacle to be traversed and sequentially installed in accordance with the outline of the structure to be installed, horizontal grooves 204 are formed in each of the horizontal direction, Inside the horizontal groove 204, a plurality of supports 202 are installed over the top and bottom with a predetermined interval to prevent the horizontal groove from being distorted in accordance with the load, The other side of the horizontal groove 204 is provided with a pair of angles 206 corresponding to the horizontal groove, Between the angles, a plurality of steel pipes 200 having communication grooves 210 formed at predetermined intervals are laterally coupled to each other in a state aligned with each other, The angles 206 are formed in an L-shape so that one end surface thereof is fixed to both sides of the outer surface of the steel pipe so as to face each other, and the other end slides in a state of inclining the surface in an inclined direction toward the horizontal groove end of the other adjacent steel pipe. Steel pipe loop structure characterized in that the plurality of steel pipes 200 are laterally coupled to each other aligned. The method of claim 1, Steel pipe loop structure, characterized in that through the communication grooves 210 and the horizontal grooves 204 of the steel pipes 200 through the connector 220, such as reinforcing bars to bind the steel pipes coupled laterally.

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