KR101496282B1 - Propulsion apparatus and propulsion method using the same - Google Patents

Abstract

The present invention relates to a propulsion apparatus for an indentation method of a construction (100) comprising: a lower line conduit (110); an upper line conduit (120) to drive the upper part of the lower line conduit (110) to slide; a lower line conduit propulsion unit (130) installed in the rear part of the lower line conduit (110) to propel the lower conduit (110) to the front; a pipe mounting unit (140) formed on the upper line conduit (120) and the rear part of the lower line conduit propulsion unit (130); and an entire propulsion unit installed in the rear part of the pipe mounting unit (140) to propel an underground pipe (200) mounted on the pipe mounting part (140) to the front, and the indentation method of construction using the same. The subsidence of the upper ground is risked less, and the control of the direction and construction are facilitated.

Description

TECHNICAL FIELD [0001] The present invention relates to a propulsion device for a press-fitting method and a press-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction field, and more particularly, to a propulsion device for a press-fitting method and a press-fitting method using the same.

Generally, the method of constructing a structure in the ground can be classified into an open type and a non-open type.

In the latter non-installation method, when it is necessary to install drainage, underground roadway, tunnel structure, etc. across existing roads and railways, it is difficult to transfer the obstacle due to construction work, It can not be installed.

Conventionally, as such a non-installation type method, a steel pipe propulsion method (a steel pipe loop method, a steel pipe indenting method) in which a plurality of steel pipes (leading pipes) are heated by a propelling device and then press-fitted and fixed by concrete, Has been mainly used.

However, such a conventional method has the following problems.

First, during the propulsion of the steel pipe, the soil is continuously discharged through the inside of the steel pipe (clay), which leads to the loss of the soil in the upper region of the steel pipe and eventually to the subsidence of the upper ground.

Second, since a large-scale steel pipe with an integral structure is press-fitted at one time by a propelling device, it is difficult to work and it is difficult to adjust the direction.

It is an object of the present invention to provide a propelling device for a press-fitting method and a press-fitting method using the same, which are less susceptible to settlement of the upper ground and can be easily adjusted in construction and direction .

In order to solve the above-mentioned problems, the present invention provides a method of manufacturing a semiconductor device, including: a lower guide pipe (110); A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110); A lower guide pipe propulsion unit 130 installed at the rear of the lower guide pipe 110 to propel the lower guide pipe 110 forward; A tube mounting part 140 formed at the rear of the upper guide pipe 120 and the lower guide pipe guide 130; And a total propulsion unit installed at the rear of the tube mounting unit 140 to propel the submerged tube 200 mounted on the tube mounting unit 140 forward. .

The tube mounting part 140 may include a seating part 141 formed to extend rearward from a lower portion of the lower guide pipe 110 and to receive the underground pipe 200.

The lower guide pipe 110 is formed with a rear end edge of the side wall of the lower guide pipe 110 so that the driving force of the lower guide pipe guide 130 is stably transmitted to the lower guide pipe 110. A reinforcing plate 111; And a reinforcing rib 112 provided between the reinforcing plate 111 and the side wall.

It is preferable that the cross section of the lower guide pipe 110 is larger than the cross section of the upper guide pipe 120.

Preferably, a stopper 113 is provided at an upper portion of the lower guide pipe 110 to prevent excessive press-fitting of the upper guide pipe 120.

Both sides of the upper portion of the lower guide pipe 110 and the lower portion of the upper guide pipe 120 are guided by the guide portion 300 to guide sliding movement of the upper guide pipe 120 to the lower guide pipe 110, Is preferably formed.

It is preferable that the cross section of the lower guide pipe 110 and the upper guide pipe 120 is rectangular.

The guide unit 300 includes guide grooves 311 formed on both sides of the upper guide pipe 110, And a guide protrusion 312 formed on both lower sides of the upper guide pipe 120 so as to be inserted into the guide groove 311 and slide in the forward and backward directions.

Preferably, a soil inflow prevention plate 114 extends rearward on both sides of the rear end of the lower guide pipe 110.

Preferably, the cross section of the lower guide pipe 110 and the upper guide pipe 120 is circular.

The guide part 300 includes a cover part 321 installed to surround the upper outer surface of the upper guide pipe 120 and extending downward to cover a part of both sides of the lower guide pipe 110 .

The guide unit 300 includes a lower guide protrusion 322 protruding from both sides of the upper guide pipe 110; And an upper guide protrusion 323 formed on both lower sides of the upper guide pipe 120 so as to be slidably moved in the forward and backward directions while contacting the outer surface of the lower guide protrusion 322. [

The present invention is a press-fitting method using the propulsion device 100 for a press-fitting method, wherein the lower guiding pipe 110, the upper guiding pipe 120, and the tube fitting unit 140 are installed on the closing surface, A pipe mounting step of mounting the underground buried pipe 200 in the pipe mounting step; A lower guide pipe propelling unit 130 for propelling the lower guide pipe 110; Wherein the upper guide pipe (120) and the underground pipe (200) are propelled by the entire propelling unit while the lower guide pipe (110) is stationary. present.

It is preferable that the entire propelling step is performed until the front end of the lower leading pipe 110 is positioned forward of the front end of the upper leading pipe 120.

A tube addition mounting step of mounting a further additional submerged buried pipe (200a) so as to come into contact with the rear of the underground buried pipe (200) mounted on the pipe mounting part (140) after the entire propulsion step; A second lower conduit conduit step of propelling the lower conduit conduit 110 by the lower conduit conduit 130 secondarily; In the state where the lower guide pipe 110 is in a stopped state, the upper guide pipe 120, the pipe mounting unit 140, the underground pipe 200, and the additional underground pipe 200a are connected to the second pipe And a second overall overall propelling step is performed until the front end of the lower leading pipe 110 is positioned in front of the front end of the upper leading pipe 120.

The pipe additional mounting step further includes a pipe fixing step of fixing the outer surface of the contact portion between the underground buried pipe 200 and the additional underground buried pipe 200a with a plurality of anchors 211 with the steel plate 210 therebetween .

The contact portion between the underground buried pipe 200 and the additional underground buried pipe 200a is formed in a stepped structure and the cushioning material 220 is mounted on the edge portion of the step structure and the exporter material 230 is mounted on the center portion thereof desirable.

The present invention proposes a propulsion device for a press-fitting method and a press-fitting method using the same, in which there is less concern of settlement of the upper ground and the adjustment of the construction and direction is easy.

1 shows an embodiment of the present invention,
1 is a perspective view of a first embodiment of a propulsion device;
2 is a rear view of the lower guide pipe.
3 is a sectional view of the guide portion.
4 is a perspective view of the stopper.
5 to 10 are process drawings of a press-fitting method.
11 is a sectional view of the joint portion of the underground buried pipe.
12 is a side view of the engaging portion of the underground buried pipe.
Figure 13 is a front view of a second embodiment of the propulsion device.
Figure 14 is a side view of a second embodiment of the propulsion device.

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

1 and 2, the propulsion device 100 for a press-fitting method according to the present invention basically comprises a lower guide pipe 110; A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110); A lower guiding tube 130 installed at the rear of the lower guiding tube 110 to propel the lower guiding tube 110 forward; A tube mounting part 140 formed at the rear of the upper leading pipe 120 and the lower leading pipe pushing part 130; And an entire propelling section provided at the rear of the tube mounting section 140 to propel the submerged tube 200 mounted on the tube mounting section 140 forward.

The press-fitting method using the propelling device 100 for press-fitting method is performed by the following process.

A bottom leading pipe 110, a top leading pipe 120 and a pipe mounting part 140 are installed on the closing face side and the underground pipe 200 is mounted on the pipe mounting part 140 (FIGS. 5 to 7).

First, the lower guiding tube 130 pushes and pushes the lower guiding tube 110 in order to excavate a lower part of the excavation area first (FIG. 8).

The lower guide pipe 110 is entirely driven by the upper guide pipe 120 and the underground pipe 200 by the entire propulsion unit (not shown) while the stationary pipe 110 is stopped (FIG. 9).

At this time, since the upper guide pipe 120 is press-fitted into the ground disturbed in advance by the lower guide pipe 110, the press-in operation is easy and the loss of the gravel-like material in the upper area is minimized.

This has the following effects.

First, as in the case of the conventional method, instead of using a large-scale leading pipe having an integral structure, the small-sized leading pipes having the structure divided into the lower leading pipe and the upper leading pipe are sequentially used, The risk of subsidence in the upper ground can be reduced.

Second, since the small-sized leading pipes of divided structure are press-fitted sequentially, the press-fitting operation is easy, and the small-sized bottom pipe is press-fitted while orienting the small-sized leading pipe, and then the remaining is press-fitted.

Hereinafter, a concrete structure of the propulsion device 100 for a press-fitting method according to the present invention will be described.

The tube mounting part 140 includes a seating part 141 formed to extend rearward from a lower portion of the lower guide pipe 110 and to receive the underground buried pipe 200, (141) may be realized by a structure of a pair of steel plates or the like protruding toward the rear of the lower guide pipe (110) (FIG. 1).

In the process of pushing and pushing the lower guide pipe 110 by the lower guide pipe propelling unit 130, the underground pipe 200 is positioned in the lower guide pipe 110 and the lower guide pipe 110, The seating portion 141 is first press-fitted into the ground, and the seating portion 141 slides on the bottom surface of the underground pipe 200 (Figs. 7 to 10).

Then, in the process of pushing the upper guide pipe 120 and the underground pipe 200 as a whole by the entire pushing portion, the underground pipe 200 is press-fitted into the underground while sliding on the mount portion 141 .

This is because the seating portion 141 is first pressed into the ground with the lower guide pipe 110 and then the underground pipe 200 is slid over the seating portion 141 rather than the soil, It has the advantage of being easy to maintain linearity.

A reinforcing plate 111 is provided around the rear end edge of the side wall of the lower guide pipe 110 in order to stably transmit the driving force of the lower guide pipe driving unit 130 having a hydraulic jack structure to the lower guide pipe 110, And a plurality of reinforcing ribs 112 are provided between the reinforcing plate 111 and the side walls (FIG. 2).

It is preferable for the rear end edge of the side wall of the upper guide pipe 120 to have the same structure as described above for stable press-fitting operation.

It is preferable in view of the efficiency of the entire press-fitting operation that the cross-section of the lower guide pipe 110 to be press-fitted before is larger than the cross-section of the upper guide pipe 120 (FIG.

It is necessary to maintain the structure in which the lower leading pipe 110 always protrudes forward from the upper leading pipe 120 in order to perform a stable press-fitting operation. Therefore, the upper leading pipe 120 is provided at the upper portion of the lower leading pipe 110, It is preferable that a stopper 113 is provided to prevent excessive press-fitting of the stopper (FIG. 4).

Guide portions 300 are formed at both sides of the upper and lower sides of the lower guide pipe 110 and the lower portion of the upper guide pipe 120 to guide the sliding movement of the upper guide pipe 120 to the lower guide pipe 110 Is preferable for performing a stable and easy press-fitting operation.

FIGS. 1 to 4 show an embodiment of a structure in which the cross section of the lower leading pipe 110 and the upper leading pipe 120 is rectangular, which is advantageous in the case of a square cross-sectional tube propelling operation.

In this case, the upper guide portion 300 includes guide grooves 311 formed on both sides of the upper portion of the lower guide pipe 110; And a guide protrusion 312 formed on both sides of the lower portion of the upper guide pipe 120 so as to be inserted into the guide groove 311 and slide in the forward and backward directions.

In order to prevent the inflow of the soil to the lower guiding pipe 130 in the rear of the lower guiding pipe 110 when the forward movement of the lower guiding pipe 110 is to be prevented, Structure.

Figs. 13 and 14 show an embodiment of a structure in which the cross section of the lower leading pipe 110 and the upper leading pipe 120 are mutually coupled, which is advantageous in the tube-guiding operation of the circular cross section.

In this case, the upper guide part 300 includes a cover part 321 installed to surround the upper outer surface of the upper guide pipe 120 and extending downward to cover a part of both sides of the lower guide pipe 110 It is preferable to take a structure including the above.

The lid part 321 can simultaneously perform the function of guiding the press-fit drive of the upper guide pipe 120 and the function of preventing the introduction of the gravel to the lower guide pipe guide part 130.

Further, as the upper guide portion 300, a lower guide protrusion 322 protruding from both sides of the upper portion of the lower guide pipe 110; When the upper guide pipe portion 322 is further configured to include the upper guide protrusion portion 323 formed on both lower sides of the upper guide pipe 120 so as to be slidably moved in the forward and backward directions while being in contact with the outer side surface of the lower guide protrusion portion 322, It is possible to more reliably guide the press-fitting drive of the pressing member 120.

Hereinafter, a concrete embodiment of the press-fitting method according to the present invention will be described.

It is preferable to perform the press-fitting operation so that the front end of the lower guide pipe 110 is positioned forward of the front end of the upper guide pipe 120 during the entire propelling process after the lower guide pipe 110 is pre-press- desirable.

For this purpose, a stopper 113 is preferably provided in the guide groove 311 formed on both sides of the upper portion of the lower guide pipe 110 to prevent over-pressurization of the upper guide pipe 120 (FIG. 4).

A tube addition mounting step of mounting an additional underground buried pipe 200a so as to be in contact with the rear of the underground buried pipe 200 mounted on the tube mounting part 140 after the entire propulsion step; A second lower conduit conduit step of propelling the lower conduit conduit 110 by the lower conduit conduit propulsion section 130 secondarily; A second overall propulsion step for propelling the upper guide pipe 120, the underground pipe 200 and the additional underground pipe 200a by the entire propulsion unit while the lower guide pipe 110 is in a stopped state; (Figs. 9 and 10).

When the outer surface of the contact portion between the underground buried pipe 200 and the additional underground buried pipe 200a is further surrounded by the plurality of anchors 211 with the steel plate 210 being placed therebetween, An advantage that the mutual contact of the concrete pipe and the breakage due to press-fitting can be prevented is added (Figs. 11 and 12).

At this time, the contact portion between the underground buried pipe 200 and the additional underground buried pipe 200a is formed in a stepped structure. A cushioning material 220 such as wood is mounted on the edge of the stepped structure, When the structure is mounted, the above-described damage prevention effect can be further increased.

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.

100: propelling device 110: lower leading pipe
111: reinforcing plate 112: reinforcing rib
113: stopper 114: sand protection plate
120: upper guide pipe 130: lower guide pipe member
140: tube mounting part 141: seat mounting part
200, 200a: underground buried pipe 210: steel plate
211: anchor 220: cushioning material
230: Index material 300: Guide part
311: guide groove 312: guide projection
321: lid portion 322: lower guide projection
323: upper guide projection

Claims (17)

delete A lower leading pipe 110;
A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110);
A lower guide pipe propulsion unit 130 installed at the rear of the lower guide pipe 110 to propel the lower guide pipe 110 forward;
A tube mounting part 140 formed at the rear of the upper guide pipe 120 and the lower guide pipe guide 130;
And an entire propelling unit installed at the rear of the tube mounting unit 140 to propel the submerged tube 200 mounted on the tube mounting unit 140 forward,
The tube mounting part (140)
A seating portion 141 formed to extend rearward from a lower portion of the lower guide pipe 110 and configured to receive the underground buried pipe 200;
(100) for a press-fitting method. A lower leading pipe 110;
A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110);
A lower guide pipe propulsion unit 130 installed at the rear of the lower guide pipe 110 to propel the lower guide pipe 110 forward;
A tube mounting part 140 formed at the rear of the upper guide pipe 120 and the lower guide pipe guide 130;
And an entire propelling unit installed at the rear of the tube mounting unit 140 to propel the submerged tube 200 mounted on the tube mounting unit 140 forward,
The lower guide pipe (110)
A reinforcing plate 111 formed at the rear end edge of the side wall of the lower guide pipe 110 so that the driving force of the lower guide pipe driving unit 130 is stably transmitted to the lower guide pipe 110;
A reinforcing rib 112 provided between the reinforcing plate 111 and the side wall;
(100) for a press-fitting method. A lower leading pipe 110;
A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110);
A lower guide pipe propulsion unit 130 installed at the rear of the lower guide pipe 110 to propel the lower guide pipe 110 forward;
A tube mounting part 140 formed at the rear of the upper guide pipe 120 and the lower guide pipe guide 130;
And an entire propelling unit installed at the rear of the tube mounting unit 140 to propel the submerged tube 200 mounted on the tube mounting unit 140 forward,
Wherein a section of the lower guide pipe (110) is larger than an end face of the upper guide pipe (120). A lower leading pipe 110;
A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110);
A lower guide pipe propulsion unit 130 installed at the rear of the lower guide pipe 110 to propel the lower guide pipe 110 forward;
A tube mounting part 140 formed at the rear of the upper guide pipe 120 and the lower guide pipe guide 130;
And an entire propelling unit installed at the rear of the tube mounting unit 140 to propel the submerged tube 200 mounted on the tube mounting unit 140 forward,
Wherein a stopper (113) is provided at an upper portion of the lower guide pipe (110) to prevent overpressure of the upper guide pipe (120). A lower leading pipe 110;
A top guide pipe (120) installed to slide the upper portion of the lower guide pipe (110);
A lower guide pipe propulsion unit 130 installed at the rear of the lower guide pipe 110 to propel the lower guide pipe 110 forward;
A tube mounting part 140 formed at the rear of the upper guide pipe 120 and the lower guide pipe guide 130;
And an entire propelling unit installed at the rear of the tube mounting unit 140 to propel the submerged tube 200 mounted on the tube mounting unit 140 forward,
Both sides of the upper portion of the lower guide pipe 110 and the lower portion of the upper guide pipe 120 are guided by the guide portion 300 to guide sliding movement of the upper guide pipe 120 to the lower guide pipe 110, (100) for a press-fitting method. The method according to claim 6,
Wherein the cross section of the lower guide pipe (110) and the upper guide pipe (120) is rectangular. 8. The method of claim 7,
The guide part 300 includes:
Guide grooves 311 formed at both sides of the upper portion of the lower guide pipe 110;
A guide protrusion 312 formed on both lower sides of the upper guide pipe 120 so as to be inserted into the guide groove 311 and to be slidably moved in the forward and backward directions;
(100) for a press-fitting method. 8. The method of claim 7,
And a soil inflow prevention plate (114) extends rearward on both sides of the rear end of the lower guide pipe (110). The method according to claim 6,
Wherein the cross section of the lower guide pipe (110) and the upper guide pipe (120) is circular. 11. The method of claim 10,
The guide part 300 includes:
A cover part 321 installed to surround the upper outer surface of the upper guide pipe 120 and extending downward to cover a part of both sides of the lower guide pipe 110;
(100) for a press-fitting method. 12. The method of claim 11,
The guide part 300 includes:
A lower guide protrusion 322 protruding from both sides of the upper portion of the lower guide pipe 110;
An upper guide protrusion 323 formed at both lower sides of the upper guide pipe 120 so as to be slidably moved in the forward and backward directions while being in contact with the outer side surface of the lower guide protrusion 322;
(100) for a press-fitting method. A press-fitting method using the propelling device (100) according to any one of claims 2 to 12,
A tube mounting step of installing the bottom guiding tube 110, the top guiding tube 120 and the tube mounting part 140 on the closing surface and mounting the underground tube 200 on the tube mounting part 140;
A lower guide pipe propelling unit 130 for propelling the lower guide pipe 110;
A total propulsion step of propelling the upper guide pipe 120 and the underground pipe 200 by the entire propelling unit while the lower guide pipe 110 is in a stopped state;
Wherein the press-fitting method comprises: 14. The method of claim 13,
Wherein the entire propulsion step comprises:
And the front end of the lower guide pipe (110) is positioned in front of the front end of the upper guide pipe (120). 14. The method of claim 13,
After the entire propulsion phase,
A tube addition mounting step of mounting an additional underground buried pipe 200a so as to contact the rear of the underground buried pipe 200 mounted on the tube mounting part 140;
A second lower conduit conduit step of propelling the lower conduit conduit 110 by the lower conduit conduit 130 secondarily;
In the state where the lower guide pipe 110 is in a stopped state, the entire secondary propelling unit is used to push the upper guide pipe 120, the underground pipe 200, and the additional underground pipe 200a in a second order Step;
And the front end of the lower guide pipe (110) is positioned in front of the front end of the upper guide pipe (120). 16. The method of claim 15,
Wherein the tube addition mounting step includes:
A pipe fixing step of fixing the outer surface of the contact portion between the underground buried pipe 200 and the additional underground buried pipe 200a by surrounding the steel plate 210 with a plurality of anchors 211;
Further comprising the steps of: 17. The method of claim 16,
The contact portion between the underground buried pipe 200 and the additional underground buried pipe 200a is formed in a stepped structure and the cushioning material 220 is mounted on the edge portion of the step structure and the exporter material 230 is mounted on the center portion The indentation method is characterized by.

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