KR101535642B1 - Reverse circulation drilling apparatus - Google Patents

Abstract

The present invention relates to a reverse circulation drilling bit apparatus which improves a conventional drilling bit apparatus to drill weak ground. The reverse circulation drilling bit apparatus comprises: an inflow pipe into which compressed air flows; a cylinder connected to the inflow pipe; a piston hammer which is disposed inside the cylinder and moves up or down by entry or exit of the compressed air; a drill bit disposed on a lower portion of the piston hammer to strike the ground by a downward movement of the piston; a discharge pipe disposed in the inflow pipe to discharge excavated soil crushed by a strike of the drill bit to the outside; and a casing to enclose outer surfaces of the inflow pipe and the cylinder. A partitioning member is installed in the inflow pipe in a longitudinal direction to form a first and a second flow passage. The compressed air flows into the first flow passage, and the second flow passage is connected to the casing and the discharge pipe.

Description

[0001] Reverse circulation drilling apparatus [0002]

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a reverse rotation perforated bit device for forming perforation holes in a ground.

In general, a large number of pipes are buried in the ground or rock to prevent leakage and to stabilize the soil. In order to embed pipes, a drilling operation should be performed to form perforation holes in the ground or rock.

FIG. 1 schematically shows a cross section of a perforated bit device according to the prior art. As shown in FIG. 1, the perforated bit device 1 includes an inlet pipe 10 into which compressed air flows, A piston hammer 30 accommodated in the cylinder 20 and descending or rising by the inflow or outflow of the compressed air; a piston hammer 30 disposed below the piston hammer 30 for performing drilling; Bit (40). At this time, a plurality of cutting tips 41 are provided on the outer circumferential surface of the drilling bit 40 to directly contact the ground to be excavated. An inlet channel 42 communicated with the inlet pipe 10, A discharge channel 43 for discharging the soil is formed.

Therefore, the excavated soil generated as the drilling bit 40 performs the excavation operation is discharged to the discharge channel 43 by the compressed air introduced through the inlet pipe 10 and the inlet channel 42. [

However, the conventional perforated bit device 1 has a structure in which the compressed air discharged through the discharge channel 43 of the perforated bit 40 is discharged to the outside of the perforated bit device 1 together with the excavated soil in the perforated hole There is no problem in drilling the solid ground. However, when the soft ground such as tidal flats is drilled, there is a problem that the excavated soil mixed with moisture blocks the discharge channel 43 and the excavation of the excavated soil is not smooth.

Registration Utility Model Bulletin 20-0425452 (published on Aug. 29, 2006)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a counter-rotating perforated bit device that improves the structure of a perforated bit device to enable perforation of soft ground.

According to an aspect of the present invention, there is provided a counter-rotating perforated bit device comprising: an inlet pipe through which compressed air flows; A cylinder communicating with the inflow pipe; A piston hammer housed in the cylinder and descending or rising by the inflow or outflow of the compressed air; A drill bit disposed at a lower portion of the piston hammer and applying a blow to the ground by a downward movement of the piston; A discharge pipe accommodated in the inflow pipe and discharging the excavated soil crushed by the impact of the drill bit to the outside; And a casing enclosing the outer circumferential surface of the inflow pipe and the cylinder, wherein the inflow pipe is provided with a partition member in the longitudinal direction to form first and second flow paths, And the second flow path communicates with the casing and the discharge pipe.

According to the present invention, by forming the first and second holes in the inflow pipe and the discharge pipe, it is possible to securely discharge the excavated sands accumulated around the perforation hole. That is, conventionally, when the excavated surface is a soft ground such as a tidal flat, the ground is broken at the time of perforation, and the soil obstructs the entrance of the discharge channel. In this case, the casing is mounted to the outside, , It is possible to prevent the excavated soil from being discharged to the inside of the drilling bit apparatus and to allow the vapors to flow into the discharge channel.

1 is a cross-sectional view of a perforated bit device according to the prior art;
2 is a cross-sectional view of a perforated bit device in accordance with an embodiment of the present invention.
Fig. 3 is an illustration of the inside of the casing for explaining the air flow of the puncturing bit device shown in Fig. 2; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional view of a counter-rotating perforated bit device according to an embodiment of the present invention, and FIG. 3 is a view illustrating the inside of a casing to explain an air flow of the counter- . Here, the drilling bit device 100 is used in the groundwater development or excavation work of the civil engineering work, and may be a RC (Reverse Circulation) type that discharges the excavated soil generated in the drilling operation out of the drilling hole.

2 and 3, the drilling bit device 100 includes an inlet pipe 110, a cylinder 120, a piston hammer 130, a drill bit 140, a discharge pipe 150, And a casing (160).

The inflow pipe 110 has a hollow shape in which the inside is hollow, and compressed air flows into the inside of the inflow pipe 110. More specifically, the inflow pipe 110 is provided with a partition member 111 in its longitudinal direction to form the first and second flow paths 112 and 113. Compressed air may be introduced into the first flow path 112 and a first long hole 113a may be formed on one side of the second flow path 113 to communicate with the casing 160 and the discharge pipe 150, . This is for discharging the excavated soil accumulated in the perforation hole to the outside, and a detailed description will be given later.

The cylinder 120 is disposed below the inflow pipe 110 and may be formed to communicate with the inflow pipe 110. Accordingly, compressed air can be supplied to the piston hammer 130 disposed in the cylinder 120 by receiving the compressed air discharged from the inlet pipe 110.

The piston hammer 130 is received in the cylinder 120 and is lowered or raised by the inflow or outflow of compressed air. As the piston hammer 130 is moved up and down by the compressed air, the impact force can be transmitted to the drill bit 140 disposed below the piston hammer 130.

The drill bit 140 is disposed at the lower portion of the piston hammer 130 and applies a blow to the ground by the downward motion of the piston. At this time, the drill bit 140 is also formed with a hollow therein like the piston hammer 130, so that a flow path can be formed.

The drill bit 140 has a plurality of holes in the longitudinal direction at the front end thereof to form the inlet channel 141 and a plurality of slots in the longitudinal direction at the outer circumferential surface to form the outlet channel 142. The compressed air supplied from the inflow pipe 110 is supplied to the inlet channel 141 through the hollow of the piston hammer 130 and the drill bit 140 and then to the excavated soil To the discharge channel (142).

The drill bit 140 may further include an extension bit 170 that rotates so as to enlarge and drill around the perforation hole at the tip thereof. For this purpose, an entrance may be formed on the lower side of the drill bit 140, and an extension bit 170 may be drawn or drawn on the entrance. Here, the method of extracting or drawing the extension bit 170 from the drill bit 140 is a known technique and will not be described here.

As described above, since the extension bit 170 is rotatably mounted on the tip of the drill bit 140, the striking force can be applied not only in the vertical direction but also in the rotation direction. Thus, through the drill bit 140 having a small diameter, it becomes possible to form a perforation hole having a desired-sized diameter.

The discharge pipe 150 is accommodated in the inlet pipe 110 and serves as a flow path for discharging the excavated soil crushed by the impact of the drill bit 140 to the outside. More specifically, the discharge pipe 150 can be closed by the stopper portion 151 disposed at the upper side of the cylinder 120, and the discharge pipe 150 can be closed at one side of the discharge pipe 150 corresponding to the first long hole 113a of the inflow pipe 110 A second hole 152a may be formed. This is because the discharge pipe 150 communicates with the first hole 113a of the inlet pipe 110 to discharge the excavated soil to the outside, and a detailed description will be given later.

The casing 160 may be hollow to surround the inlet pipe 110 and the cylinder 120. At this time, a sealing part 180 disposed above the first and second long holes 113a and 152a may be mounted between the casing 160 and the inflow pipe 110. As the sealing portion 180 is mounted between the casing 160 and the inflow pipe 110, the compressed air passing between the casing 160 and the inflow pipe 110 does not flow out to the outside, And 152a, respectively.

As described above, since the casing 160 is disposed on the outer circumferential surface of the inlet pipe 110 and the cylinder 120, the compressed air having passed through the discharge channel 142 is supplied into the casing 160 and discharged So that it can be safely discharged to the discharge pipe 150 through the first and second holes 113a and 152a together with the soil.

Further, since the casing 160 is disposed on the outer circumferential surface of the inlet pipe 110 and the cylinder 120, soft ground such as tidal flats can be pierced. In other words, conventionally, when the excavated surface is a soft ground such as a tidal flat, etc., there is a problem that the ground is collapsed at the time of perforation so that the soil obstructs the discharge channel 142. When the casing 160 is attached to the outside as described above, Thereby preventing the objects of the discharge channel 142 from obstructing the discharge channel 142.

The drill bit 140 may be mounted inside the casing 160 by a casing shoe 161 formed to surround the periphery of the drill bit 140. A rotation unit may be mounted on the discharge pipe 150 protruding upward from the casing 160, and one end of the cylinder 120 may be mounted on the discharge pipe 150. Accordingly, when the discharge tube 150 is rotated to the left or right through the rotation unit, the drill bit 140 and the extension bit 170 connected to the cylinder 120 can be rotated.

As the first and second holes 113a and 152a are formed in the inlet pipe 110 and the discharge pipe 150 of the perforated bit device 100 as described above, the excavated piles accumulated around the perforation holes can be safely discharged to the outside . That is, when the excavated surface is a soft ground such as a tidal flats, the ground is broken at the time of perforation so that the soil obstructs the entrance of the discharge channel 142. As described above, the casing 160 is mounted on the outside, When the first and second holes 113a and 152a are formed in the pipe 110 and the discharge pipe 150, the excavated soil is discharged to the inside of the perforated bit device 100 to prevent the inclusions from flowing into the discharge channel 142 .

2 and 3, a process of discharging the excavated soil to the puncturing bit device 100 will be described.

First, when high pressure compressed air flows into the first flow path 112 of the inflow pipe 110 through the compressor, compressed air is supplied into the cylinder 120 communicated with the inflow pipe 110. At this time, a check valve may be installed in the first flow path 112, and a piston hammer 130 having a cavity formed therein may be received in the cylinder 120. Accordingly, when the check valve is forcibly opened by the pressure of the compressed air, the pressure inside the cylinder 120 is instantaneously raised to move the piston hammer 130 upward.

As the piston hammer 130 rises, the upper side of the drill bit 140 is opened and the compressed air is exhausted through the hollow of the drill bit 140. When the piston hammer 130 rises, the piston hammer 130 is instantaneously lowered by the compressed air flowing into the first flow path 112.

As the piston hammer 130 is lifted or lowered by the inflow or outflow of the compressed air supplied through the inflow pipe 110 and strikes the drill bit 140 disposed at the lower side, 130 to receive a hitting force and crush the ground to form a perforation hole.

As the drill bit 140 crushes the ground as described above, the excavated soil finely crushed is formed around the perforation hole, and if such excavated soil is accumulated, the excavation property is hindered, so that the excavated soil must be discharged to the outside of the perforated hole.

A plurality of inlet channels 141 communicating with the hollow of the drill bit 140 are formed at the tip of the drill bit 140 and an outlet channel 142 communicating with the casing 160 is formed on the outer circumferential surface. The compressed air that has passed through the piston hammer 130 is thereby moved to the discharge channel 142 along with the excavated soil piled around the perforation hole through the hollow and inflow channel 141 of the drill bit 140.

The compressed air including the excavated soil flows into the casing 160 separated from the cylinder 120 and the outer circumferential surface of the inflow pipe 110. The inflowed compressed air moves upward and flows into the first and second long holes 113a, 152a and then discharged through the discharge pipe 150 to the outside.

As described above, since the structure of the perforated bit unit 100 is improved to an RC (Reverse Circulation) type so that the excavated soil can be discharged to the outside, the discharged soil does not block the discharge passage during the excavation work, . ≪ / RTI >

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100 .. Perforated bit device
110 inlet pipe 111 partition member
112 .. First Euro 113 .. Second Euro
113a .. Chapter 1 Hole 120 .. Cylinder
130 .. Piston hammer 140 .. Drill bit
150 .. discharge pipe 151 .. stopper section
152a .. SECTION 2 HALL 160 .. CASE
170 .. extension bit 180 .. sealing part

Claims (5)

An inflow pipe into which compressed air flows;
A cylinder communicating with the inflow pipe;
A piston hammer housed in the cylinder and descending or rising by the inflow or outflow of the compressed air; And
And a drill bit disposed at a lower portion of the piston hammer and applying a blow to the ground by a downward movement of the piston,
A discharge pipe accommodated in the inflow pipe and discharging the excavated soil crushed by the impact of the drill bit to the outside; And
And a casing formed to surround the inlet pipe and the outer circumferential surface of the cylinder,
Characterized in that the inflow pipe has first and second flow paths formed therein with a partition member in the longitudinal direction, the compressed air is introduced into the first flow path, and the second flow path is communicated with the casing and the discharge pipe Circular puncturing bit device. The method according to claim 1,
Wherein the inlet pipe is formed with a first long hole on one side where the second flow path is disposed,
Wherein the discharge tube has an end disposed on the upper side of the cylinder closed and a second elongated hole corresponding to the first elongated hole formed on one side of the discharge tube. 3. The method of claim 2,
And a sealing portion disposed on the upper side of the first and second holes is mounted between the inflow pipe and the casing. The method according to claim 1,
Wherein the drill bit further comprises an extension bit at the tip. The method according to claim 1,
Wherein the drill bit is mounted within the casing by a casing shoe configured to wrap around the tip of the drill bit.

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