KR101402128B1 - The drilling method by reverse circulation drilling rig - Google Patents

Abstract

The present invention relates to a continuous excavation method, and more particularly, to a continuous excavation method capable of rolling down to a deep place by preventing the pressure from being lowered.
A method of excavating a continuous excavator according to an aspect of the present invention comprises assembling a plurality of large diameter drill rod pipes in a line between a power sweeper and a chamber type drill rod pipe in which an air chamber is formed, A first excavation step is carried out to excavate to a certain depth with a drill bit which is removably fixed. After drilling to the predetermined depth, the drill rod pipe of the large diameter is separated to raise the drill bit. Then, the raised drill bit is separated from the chambered drill rod pipe, and a plurality of small drill rod pipes are assembled in series between the chambered drill rod pipe and the drill bit. And a second drilling unit for assembling a plurality of drill rod pipes of the large diameter between the power sweeper and the chamber drill rod pipe in a line after assembling the small diameter drill rod pipe, Step is carried out.
According to the present invention, a drill rod pipe of a large diameter is used only to a certain depth, and a drill rod pipe of a small diameter is used at a depth greater than the predetermined depth. Therefore, even if the pressure is not increased, The rock can be excavated to a deep range.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drilling method,

The present invention relates to a continuous excavation method, and more particularly, to a continuous excavation method capable of rolling down to a deep place by preventing the pressure from being lowered.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 schematically shows the opening of a continuous oyster disclosed in the patent application 1999-0064758. Power is supplied to each power system according to the operation of the power pack 100 and installed to the depth of the soil 104 to be excavated using the casing 102 and the installation of the excavator is completed do. The water pump 106 is operated to supply the water in the water tank 108 to the casing 102 through the water supply pipe 110 to store the air and operate the air compressor 112 to supply the air to the air supply hose 114 Through the air lift pipe 116 to the lower end of the drill rod pipe 118 to allow the rock layer 120 to be supplied to the drill bit 122 to be substantially rolled. The drill rod pipe 118 is rotated by the power swivel 124 and is simultaneously subjected to the vertical pressure by the power cylinder 126, So that the pressure is transmitted to the drill bit 122.

The drill bit 122 is rotated and rotated together with the drill bit 122 so that the rock layer 120 is crushed and the water in the casing 102 is separated from the rock layer 120, And the slime 128 is formed in the drill rod pipe 118 by the high pressure air supplied to the drill bit 122. The slurry 128 is supplied to the drill bit 122, And discharged to the discharge hose 130 through the discharge hose 130. That is, in the continuous excavation stage, the rock layer 120 is crushed using the drill bit 122, and then the high-pressure air is supplied to the air compressor to form a rising air stream of the air inside the drill rod pipe 118, 128 to the outside.

In the conventional excavation method, the rock layer 120 is fractured while inserting the drill bit 122 by connecting a plurality of drill rod pipes from above.

In the conventional continuous bending machine, the drill bit 122 and the air chamber are integrally formed. Thus, in order to discharge the slime 128 to the drill rod pipe 118, the drill bit 122 had to supply air to the air compressor to the depth that it crashed. In this case, as the drill bit 122 goes down into the underground, the pressure decreases as it goes down. However, not only is the sealing ability of the power swivel 124 limited, but also there is a limit to increasing the pressure with the air compressor 112. [ So far, up to now, there has been an excavation record up to 200 m, the sealing performance of the power sweeper 124 can not be expected at a further depth, and even if the sealing technology is developed, the air lift pipe 116 has to withstand more than 20 bar There is a problem that it is impossible.

The present invention is intended to solve the above problems. An object of the present invention is to provide a continuous excavation method capable of excavating to a depth of 200 m or more even if the pressure of the air compressor is not increased any further.

A method of excavating a continuous excavator according to an aspect of the present invention comprises assembling a plurality of large diameter drill rod pipes in a line between a power sweeper and a chamber type drill rod pipe in which an air chamber is formed, A first excavation step is carried out to excavate to a certain depth with a drill bit which is removably fixed. After drilling to the predetermined depth, the drill rod pipe of the large diameter is separated to raise the drill bit. And a plurality of small drill rod pipes are assembled in a line between the chamber type drill rod pipe and the drill bit after separating the raised drill bit from the chamber type drill rod pipe. And a second drilling unit for assembling a plurality of drill rod pipes of the large diameter between the power sweeper and the chamber drill rod pipe in a line after assembling the small diameter drill rod pipe, Step is carried out.

In addition, it is preferable that the continuous excavation method excavate the large diameter drill rod pipe after the second excavation step to elevate the chamber type drill pipe. In this case, a plurality of small-diameter drill rod pipes are further connected between the raised chamber-type drill rod pipe and the drill bit to further extend the distance between the chamber-type drill rod pipe and the drill bit. And a plurality of large diameter drill rod pipes are assembled in a line between the power sweeper and the chamber drill rod pipe after extending a distance between the chamber drill rod pipe and the drill bit, A third excavation step is carried out that drills deeper than one depth.

According to another aspect of the present invention, there is provided a continuous excavator excavation method comprising assembling a plurality of large-diameter drill rod pipes in series between a chamber-type drill rod pipe in which a power sweeper and an air chamber are formed, A plurality of small-diameter drill rod pipes are assembled in a row and are drilled with the drill bit.

According to the present invention, a drill rod pipe of a large diameter is used only to a certain depth, and a drill rod pipe of a small diameter is used at a depth greater than the predetermined depth. Therefore, even if the pressure is not increased, The rock can be excavated to a deep range.

1 is a conceptual view of a conventional continuous excavator,
Figs. 2 and 3 are conceptual views of a continuous excavation method according to the present invention.

The excavation method using the continuous excavator according to the present invention will be described with reference to FIGS. 2 and 3. FIG.

1, the air chamber and the drill bit are integrally formed and do not separate from each other. However, in order to perform the excavation method according to the present invention, a through hole is formed in the drill rod pipe 11 so that the air chamber 12 is formed in the drill rod pipe 11. [ And a chamber-type drill rod pipe 11 in which the air chamber 12 is formed is detachably engaged with the drill bit 13. [ That is, the drill bit 13 is detachably coupled to the chamber-type drill rod pipe 11. When compressed air is supplied to the air compressor, compressed air flows into the air chamber 12 to form a rising airflow inside the chamber-like drilled rod pipe 11. [ The water and the slime of the excavation hole are discharged together by the upward flow formed inside the chamber-type drill rod pipe 11. [

In the excavation method according to the present invention, a plurality of large diameter drill rod pipes 15 are connected as shown in FIG. 2 (a), and the drill bit 13 is lowered to excavate the rock layer 21. That is, a plurality of drill rod pipes 15 having a large diameter are arranged in a row between the power sweeper and the chamber-type drill rod pipe 11, and the drill bit 13 is lowered to excavate the rock layer 21. This is the same as the conventional method shown in Fig. Since the large diameter drill rod pipe 15 is assembled at the top, the drill bit 13 is lowered as the large diameter drill rod pipe 15 is assembled. When water is supplied to the excavated rock layer and then the air compressor is operated, high pressure air is supplied to the air chamber 12 of the chamber type drill rod pipe 11. As a result, a rising airflow is formed and the water and the slime are discharged to the upper portion through the large-diameter drill rod pipe 15 by the upward flow. Up to 100 m underground, excavation is performed as in the conventional method as shown in FIG. 2 (a). In this case, it is possible to excavate the same as the conventional method up to 200m underground, but if it goes down to 100m below the ground, more compressive force is needed to discharge the slime to the upper part. Therefore, not only the capacity of the air compressor should be increased but also the sealing performance of the power swivel should be improved.

When excavating to below 100m underground, use small diameter drill rod pipe (17). To this end, the drill rod pipe 15 of the large diameter is separated to raise the chamber-type drill rod pipe 11 upward. 2 (b), the chamber type drill rod pipe 11 and the drill bit 13 are separated from each other and connected to a plurality of small diameter drill rod pipes 17 by a desired length to form the chamber type drill rod pipe 11 ) And the drill bit (13). For example, when drilling to a depth of 200m underground, a plurality of small-diameter drill rod pipes 17 are connected by a length of 100m. 2 (c), the drill bit 13 is lowered while assembling the large-diameter drill rod pipe 15 to the chamber-type drill rod pipe 11, and the drill bit 13 is drilled to a depth of 200 m. At this time, the drill rod pipe 15 and the chamber-type drill rod pipe 11 of the large diameter are inserted only to a depth of 100 m underneath, and a drill rod pipe 17 of a small diameter is inserted thereinto. In this case, when the air compressor is operated, high-pressure air is injected into the air chamber 12, and a rising airflow is formed in the large-diameter drill rod pipe 15. The water immersed in the drill rod pipe 15 of large diameter is discharged together with the upward flow formed in the drill rod pipe 15 of the large diameter. When the air sucked through the air chamber 12 and the water form upward flow and are discharged to the outside through the large diameter drill rod pipe 15, a suction force is generated in the drill rod pipe 17 having a small diameter. Then, the slurry broken by the water and the drill bit 13 is sucked into the small-diameter drill rod pipe 17 and can be discharged to the outside through the large-diameter drill rod pipe 15. At this time, air, water and slime are simultaneously transported to the drill rod pipe 15 of the large diameter, but only the water and the slime are transported to the small diameter drill rod pipe 17. The size of the diameter of the small diameter drill rod pipe 17 can be adjusted to adjust the speed of the water and the slurry conveyed to the small diameter drill rod pipe 17. Here, the diameter of the drill rod pipe 17 of a small diameter is adjusted so that the diameter of the drill rod pipe 17 of a small diameter is controlled so as to be fed at the same speed as the feed rate of water and slime to be fed from the large diameter drill rod pipe 17 It is preferable to determine the diameter. In this case, since the chamber-type drill rod pipe 11 is inserted only to the same depth as that of the conventional working method, the drill rod pipe 15 of the large diameter is inserted into the chamber-type drill rod pipe 11 through the chamber- Water and air in the rock layer can be ejected to the outside. The vacuum pressure generated when the water and the air are blown out through the large diameter drill rod pipe 15 acts on the drill rod pipe 17 of a small diameter and flows through the small diameter drill rod pipe 17 through the water and The slime can be ejected to the outside.

At this time, if it is necessary to excavate to a depth of 200m under the ground, the drill rod pipe 15 of the large diameter is separated again to raise the chamber type drill rod pipe 11 again. When the chamber type drill rod pipe 11 is lifted as shown in FIG. 3 (d), a small diameter drill rod pipe 17 is assembled to a desired length between the drill bit 13 and the chamber type drill rod pipe 11 do. When the drill rod pipe 17 having a small diameter is assembled, the drill rod pipe 15 having a large diameter is assembled as shown in FIG. 3 (e), and the drill bit 13 is lowered while being drilled. Therefore, according to this method, the slime can be discharged to a much deeper place by using a pressure capable of sucking water at a depth of 100 m under the drill rod pipe 15 of a large diameter.

11: chamber type drill rod pipe 12: air chamber
13: Drill bit 15: Large diameter drill rod pipe
17: Drill rod of small diameter pipe 21:
100: Power pack 102: casing
104: soil layer 106: water pump
108: Water tank 110: Water supply pipe
112: air compressor 114: air supply hose
116: Air lift pipe 118: Drill rod pipe
120: rock layer 122: drill bit
124: Power swivel 126: Power cylinder
128: Slime 130: Discharge hose

Claims (3)

A plurality of large-diameter drill rod pipes are assembled in a row between a chamber-type drill rod pipe in which a power swivel and an air chamber are formed, and a plurality of drill rod pipes are drilled to a certain depth with a drill bit detachably fixed to one end of the chamber- An excavation step,
Drilling the drill rod pipe to a predetermined depth and then raising the drill bit;
Assembling a plurality of small drill rod pipes in series between the chamber type drill rod pipe and the drill bit after detaching the raised drill bit from the chamber type drill rod pipe,
A second drilling step of assembling a plurality of drill rod pipes of a large diameter between the power sweeper and the chamber drill rod pipes in a line after assembling the drill rod pipes of the small diameter and drilling the drill rod pipes deeper than the predetermined depth by the drill bit Wherein the continuous excavation method comprises the following steps: The method according to claim 1,
Separating the large diameter drill rod pipe after the second drilling step to raise the chamber drill rod pipe;
Further connecting a plurality of small diameter drill rod pipes between the raised chamber type drill rod pipe and the drill bit to further extend the distance between the chamber type drill rod pipe and the drill bit,
A plurality of drill rod pipes of a large diameter are arranged in a line between the power sweeper and the chamber drill rod pipes after extending the distance between the chamber type drill rod pipe and the drill bit, Further comprising a third excavation step of deeper deeper than the depth of the continuous excavation. A plurality of large diameter drill rod pipes are assembled in series between the chamber type drill rod pipe in which the power swivel and the air chamber are formed and a plurality of small drill rod pipes are assembled in series between the chamber type drill rod pipe and the drill bit Wherein the drill bit is excavated with the drill bit.

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