KR101941868B1 - Drilling bit apparatus - Google Patents

Abstract

The present invention relates to a drilling bit device. More specifically, relates to the drilling bit device in which not only is an expansion operation of the drill bit for expanding an inner diameter of a drilled hole is stably performed, but can stably maintain the expanded state, and an operation of returning the extended part of the drilled bit after drilling the ground can be stably performed, thereby being capable of preventing foreign matters from flowing into the drilled bit during a process of drilling the ground. According to the drilling bit device, the drilling bit device comprises: a body for which a rotational force of the driving part is transmitted; a rotating bit connected to a lower part of the body and disposed between the body and the rotating bit; and a wing bit capable of extending or returning in a radial direction along a rotational direction of the driving part.

Description

[0001] DRILLING BIT APPARATUS [0002]

The present invention relates to a perforated bit device. More specifically, it is possible to stably maintain the expanded state of the drilled hole in addition to stable operation of expanding the drilled bit for drilling the inner diameter of the drilled hole, and to restore the extended portion of the drilled bit after the drilling of the ground, The present invention relates to a perforated bit device capable of preventing foreign matter from entering into a perforated bit during a ground drilling process.

Generally, in an excavation site including a beam tunnel, an anchor or a lock bolt is installed in the perforation hole to reinforce the ground, and the inner diameter of the perforation hole is expanded to strengthen the reinforcement more firmly. Then, a grouting material such as cement or mortar Injection method is used.

The conventional puncturing bit is configured such that a specific portion of the puncturing bit is expanded in the circumferential direction by using the centrifugal force of the puncturing bit to expand the inside diameter of the puncturing hole.

However, if the centrifugal force of the perforated bit is not sufficient, there is a problem that the extended portion of the perforated bit can not be maintained sufficiently.

Further, when the ground is punched in the horizontal direction, there is a problem that the expansion portion is not sufficiently expanded due to the self weight of the expanded portion of the perforated bit, or the extended portion is not expanded sufficiently due to the resistance due to the structure of the ground.

In addition, there is also a problem that the foreign material due to the perforation flows into the perforated bit during the perforation process, the return operation of the extended portion of the perforated bit does not progress properly, or the durability of the perforated bit is deteriorated due to such foreign matter.

Therefore, it is urgent to solve these problems.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a perforated bit device in which an operation of expanding a perforated bit for expanding an inner diameter of a perforated hole can be stably performed.

It is another object of the present invention to provide a drilling bit device capable of stably maintaining a state in which a drilled bit is expanded in the case of ground drilling.

It is another object of the present invention to provide a drilling bit device capable of stably returning an expanded portion of a drilled bit after drilling of a ground.

It is another object of the present invention to provide a perforated bit device capable of preventing foreign matter from entering into a perforated bit during a ground penetration process.

According to an aspect of the present invention, there is provided a drilling bit apparatus comprising a body to which a rotational force of a driving unit is transmitted, a rotating bit to be connected to a lower portion of the body, And a wing bit that can extend or return in the radial direction according to the direction.

At this time, the body is provided with a rotating core formed with a core projection, and the wing bit is formed with an extended guide surface for contacting the core projection. When the rotating core is rotated in one direction, To move outwardly.

At this time, the wing bit may be formed with an extended seating surface on which the core projection is seated when the rotating core is rotated in one direction.

At this time, the body may be provided with a blocking wall along the circumferential direction, and a wing bit supporting surface may be formed at one side of the wing bit to be contacted with the blocking wall when the rotating core is rotated in one direction.

At this time, when the rotating core is rotated in one direction, the other side of the blocking wall is held in contact with the wing bit supporting surface, and one side of the blocking wall may be disposed adjacent to the other side of the wing bit.

At this time, the wing bit is provided with a wing bit support shaft passing through the wing bit, one end of the wing bit support shaft may be connected to the body, and the other end may be connected to the rotation bit.

In this case, the body is provided with a first wing bit support hole having a long hole shape, one end of the wing bit support shaft is inserted into one side of the first wing bit support hole, One end of the wing bit support shaft may be configured to move from one side of the first wing bit support hole to the other side while rotating.

At this time, the rotation bit may have a circular second wing bit support hole, and the other end of the wing bit support shaft may be inserted into the second wing bit support hole.

At this time, the wing bit is provided with a wing bit guide shaft protruding to the lower end of the wing bit, and a wing bit guide hole having a long hole shape in which the wing bit guide shaft is inserted is formed in the rotation bit.

At this time, one end of the wing bit guide shaft may move relative to the other side of the wing bit guide hole while the rotating core rotates in one direction so that the wing bit is expanded.

At this time, the wing bit may have a return guide surface contacting the blocking wall, and the blocking wall may move the return guide surface radially inward when the rotating core rotates in the other direction.

At this time, the wing bit may be formed with a return seating surface on which the core projection is seated when the rotating core rotates in the other direction.

At this time, a blow hole for blowing air toward the wing bit may be formed around the support shaft of the rotary bit.

The drilling bit device of the present invention having the above-described configuration has an effect that the core protrusion of the rotating core moves the extended guide surface of the wing bit directly outward in the radial direction by using the rotational force of the driving part, thereby enabling stable expansion operation.

In addition, since the core protrusion of the rotating core and the enlarged seating surface of the wing bit are engaged with each other and the blocking wall supports the wing bit supporting surface, the expansion state of the wing bit can be stably maintained, thereby ensuring the roundness of the perforation hole .

In addition, there is an effect that the blocking wall moves the return guide surface of the wing bit directly inward in the radial direction, and the core projection is coupled to the return seating surface, thereby enabling stable return operation.

The blocking wall is moved a certain distance along the circumferential direction to reduce a space through which the foreign matter can flow. The blocking wall directly blocks the foreign matter from entering and at the same time, a blow hole is formed in the rotating bit, It is possible to prevent the durability of the drilling bit device from deteriorating by discharging the foreign matter to the outside.

FIGS. 1 to 4 are views showing a drilling bit apparatus according to the present invention, FIGS. 1 and 3 are perspective views showing a state in which a drilling bit apparatus is assembled, and FIGS. 2 and 4 are cross- Fig.
5 and 6 are diagrams showing the returning state of the perforated bit device, wherein FIG. 5 is a sectional view of a portion II and FIG. 6 is a sectional view of a portion II-II.
7 and 8 are enlarged views of a perforated bit device, wherein FIG. 7 is a sectional view of a portion II and FIG. 8 is a sectional view of a portion II-II.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

In this specification, the terms "comprises" or "having" and the like refer to the presence of stated features, integers, steps, operations, elements, components, or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof. Also, where a section such as a layer, a film, an area, a plate, or the like is referred to as being "on" another section, it includes not only the case where it is "directly on" another part but also the case where there is another part in between. On the contrary, where a section such as a layer, a film, an area, a plate, etc. is referred to as being "under" another section, this includes not only the case where the section is "directly underneath"

FIGS. 1 to 4 are views showing a drilling bit apparatus according to the present invention, FIGS. 1 and 3 are perspective views showing a state in which a drilling bit apparatus is assembled, and FIGS. 2 and 4 are cross- 5 is a cross-sectional view of a portion II, FIG. 6 is a cross-sectional view of a portion II-II, and FIGS. 7 and 8 Fig. 7 is a sectional view of a portion II, and Fig. 8 is a sectional view of a portion II-II.

1 to 4, the drilling bit device according to an embodiment includes a body 100 to which rotational force of a driving unit is transmitted, a rotary bit 200 connected to a lower portion of the body 100, And a wing bit 300 which is provided between the rotating shaft 100 and the rotating bit 200 and can be extended or returned in the radial direction according to the rotating direction of the driving unit.

In this case, a driving shaft 10 for connecting the driving unit and the body 100 is provided, and a plurality of connecting grooves may be formed in the driving shaft 10 for effectively transmitting the driving force.

In addition, the rotary bit 200 is connected to the body 100 to perforate the ground so that a perforation hole is formed along the axial direction. The wing bit 300 is formed so that the inner diameter of the perforation hole is expanded in the radial direction .

1, the wing bit 300 extends in the radial direction. When the wing bit 300 is extended, the drilling process is performed. Accordingly, the inner diameter of the bore hole 300 It is extended.

In addition, when the driving unit rotates in the other direction (b), the wing bit 300 is configured to return in the radial direction. If the puncturing bit device is recovered while the wing bit 300 is returned, Do.

5 to 8, the body 100 is provided with a rotating core 110 having a core projection 111 formed therein, and the wing bit 300 is provided with an extension guide The core protrusion 111 is configured to move the extension guide surface 310 radially outward when the rotary core 110 rotates in one direction a.

That is, when the driving unit rotates in one direction (a), the body 100 rotates together, and the rotating core 110 formed on the body 100 also rotates together. At this time, the rotation direction of the rotating core 110 is defined as rotating along the clockwise direction with reference to Figs. 5 and 6. Fig. The core protrusion 111 is moved by the rotation of the rotating core 110 to apply a force to the extended guide surface 310 formed on the inner side of the wing bit 300, As shown in FIG. The extension guide surface 310 is preferably formed in an arc shape so that the extension guide surface 310 can smoothly move.

The core protrusion 111 of the rotary core 110 moves the extension guide surface 310 of the wing bit 300 directly outward in the radial direction using the rotational force of the driving unit.

At this time, the wing bit 300 may be formed with an extended seating surface 320 on which the core projection 111 is seated when the rotating core 110 is rotated in one direction (a). 7 and 8, when the expansion operation of the wing bit 300 is completed, the core projection 111 is seated on the extended seating surface 320, The drilling process proceeds while the rotating core 110 rotates in the same direction continuously.

That is, since the core protrusion 111 supports the extended seating surface 320 of the wing bit 300, the drilling process is performed, so that the expanded state of the wing bit 300 can be stably maintained.

The body 100 is provided with a blocking wall 120 along the circumferential direction and one side of the wing bit 300 is contacted with the blocking wall 120 when the rotating core 110 rotates in one direction The wing bit support surface 330 may be formed. 5 and 6, in a state where the wing bit 300 is returned, the blocking wall 120 is disposed to support the outside of the wing bit 300. However, when the rotating core 110 rotates The blocking wall 120 formed in the same body 100 moves together to change the position of supporting the outside of the wing bit 300 so that the wing bit 300 moves in a radial direction as shown in Figs. And extend outwardly in the direction. In addition, the wing bit 300 is formed with an enlarged surface 40 that expands the inner diameter of the perforated hole in the perforating process. In this enlarged surface 40, an external force is applied during the perforating process, Since the wing bit support surface 330 formed on one side of the wing bit 300 is supported, even if an external force is applied to the wing bit 300 during the drilling process, the wing bit 300 can be stably extended. It is possible to secure the roundness of the perforation hole.

7 and 8, the other side of the blocking wall 120 is supported in contact with the wing bit supporting surface 330 when the rotating core 110 rotates in one direction (a) One side of the wing bit 300 may be arranged adjacent to the other side of the wing bit 300. That is, as described above, since the blocking wall 120 is configured to move by a certain distance in accordance with the rotation of the rotating core 110 in the one direction (a), the other side of the blocking wall 120 contacts the wing bit supporting surface 330 So that one side of the blocking wall 120 is disposed adjacent to the other side of the wing bit 300. In addition, As a result, the space through which the foreign matter can flow into the drilling bit device in which the rotating core 110 is disposed is reduced during the drilling process, and the blocking wall 120 directly blocks the foreign matter from entering, thereby preventing the drilling bit device from decreasing in durability There is an effect that can be done.

The wing bit 300 is provided with a wing bit support shaft 340 passing through the wing bit 300. The wing bit support shaft 340 has a wing- One end is connected to the body 100, and the other end is connected to the rotation bit 200.

That is, the wing bit 300 is rotatably fastened around the wing bit support shaft 340.

2 and 4, the body 100 is formed with a first wing bit support hole 130 having an elongated shape, and one end of the wing bit support shaft 340 is connected to the first wing bit support hole 130 As shown in Fig.

At this time, one end of the wing bit support shaft 340 is rotated from one side of the first wing bit support hole 130 to the other side of the first wing bit support hole 130 while the rotation core 110 rotates in one direction (a) Lt; / RTI > 5, the wing bit support shaft 340 is located at one side of the first wing bit support hole 130, and the wing bit support shaft 340 is positioned on one side of the first wing bit support hole 130, The support shaft 340 is positioned on the other side of the first wing bit support hole 130. 5 and 7, the wing bit support shaft 340 is fixed in the process of widening the wing bit 300, and the body 100 is rotated in one direction (a) The relative position of the wing bit support shaft 340 changes as the first wing bit support hole 130 formed in the wing bit support shaft 100 moves.

That is, the rotating core 110, the blocking wall 120, and the first wing bit support hole 130 rotate together as the body 100 rotates in one direction (a) The core protrusion 111 moves along the rotation of the wing bit 300 to move the extension guide surface 310 of the wing bit 300 radially outward and at this time the blocking wall 120 also moves together, It is possible to expand it. Since the wing bit support shaft 340 is inserted into the elongated first wing bit support hole 130, the wing bit 300 is not rotated together with the body 100 but is fixed in position, And is configured to rotate around the wing bit support shaft 340 as the projection 111 moves. Thus, the blocking wall 120 is then held in contact with the wing bit support surface 330 so that the wing bit 300 is stably positioned during the boring process.

At this time, the rotation bit 200 is formed with a circular second wing bit support hole 210 and the other end of the wing bit support shaft 340 is inserted into the second wing bit support hole 210. That is, in the process of expanding the wing bit 300, the position of the wing bit support shaft 340 is fixed, so that the rotation bit 200 does not rotate. However, when the wing bit 300 is extended, 340 are positioned on the other side of the first wing bit support hole 130. In this state, the wing bit support shaft 340 rotates together with the body 100, .

The wing bit 300 is provided with a wing bit guide shaft 350 projecting to the lower end of the wing bit 300. The rotary bit 200 has a slotted wing bit guide hole 220 are formed.

That is, when the rotary core 110 is rotated in one direction (a) so that the wing bit 300 is extended, the wing bit guide shaft 350 is positioned from one side of the first wing bit guide hole 220 to the other side The wing bit guide shaft 350 moves in the wing bit guide hole 220 in the process of expanding the wing bit 300 by the force applied by the core protrusion 111 formed on the rotating core 110. [ So that the wing bit 300 can be stably expanded.

The wing bit (300) is formed with a return guide surface (360) in contact with the blocking wall (120). That is, as the body 100 rotates in the other direction (b), the rotating core 110, the blocking wall 120, and the first wing bit support hole 130 rotate together and the rotation of the rotating core 110 The core protrusion 111 moves away from the extended seating surface 320 and the blocking wall 120 applies a force to the return guide surface 360 of the wing bit 300, The return guide surface 360 of the wing bit 300 is moved inward in the radial direction, so that the wing bit 300 can be returned. It is preferable that the return guide surface 360 is formed in an arc shape so that the return guide surface 360 smoothly moves.

 On the other hand, since one side of the wing bit support shaft 340 is inserted into the elongated first wing bit support hole 130, the wing bit 300 is not rotated together with the body 100, its position is fixed, And is configured to rotate around the wing bit support shaft 340 as the wall 120 moves.

At this time, the wing bit 300 is formed with a return seating surface 370 on which the core projection 111 is seated when the rotating core 110 rotates in the other direction (b). That is, when the wing bit 300 is returned, the core protrusion 111 is seated on the return seating surface 370 so that the return operation of the wing bit 300 can be stably performed. In the state where the wing bit 300 is returned, When the bit device is recovered, it is possible to recover easily.

As shown in FIG. 2, a support shaft 230 is formed on the rotary bit 200. That is, the support shaft 230 is inserted into the body 100 through the wing bit 300, and is fastened by the fixing pin 20 in a state where the support shaft 230 is inserted into the body 100. That is, the fixing pin 20 passes through the body 100 and is fastened to the supporting shaft 230, and the pin fixing groove 232 in which the fixing pin 20 is seated is formed on the supporting shaft 230 .

In addition, a blowing hole 231 for blowing air toward the wing bit 300 is formed around the support shaft 230. The air is introduced through the driving shaft 10 of the body 100 and then discharged through the air blowing hole 231 to block foreign matter from entering.

Also, the rotary bit 200 is formed with a blowing groove 30 capable of blowing air to prevent foreign matter from entering.

The core protrusion 111 of the rotary core 110 moves the extension guide surface 310 of the wing bit 300 directly in the radial outward direction by using the rotational force of the driving unit as described above, The core protrusion 111 of the rotating core 110 and the extended seating surface 320 of the wing bit 300 are coupled and the blocking wall 120 supports the wing bit supporting surface 330, The expanded state of the hole 300 can be stably maintained, thereby ensuring the roundness of the perforation hole.

In addition, the blocking wall 120 moves the return guide surface 360 of the wing bit 300 directly radially inward, and the core projection 111 is engaged with the return seating surface 370 to enable a stable return operation The blocking wall 120 is moved a certain distance along the circumferential direction to reduce a space through which the foreign matter can flow, and the blocking wall 120 directly blocks the foreign matter from entering, Holes 231 are formed to prevent foreign matter from entering by using the air pressure and to discharge the foreign substances to the outside, thereby preventing the durability of the perforated bit device from being deteriorated.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. Deletion, addition, and the like of other embodiments may be easily suggested, but this is also within the scope of the present invention.

10: drive shaft 20: stationary pin
30: Ventilation groove 40: Extension surface
100: body 110: rotating core
111: core projection 111a: return section
111b: rest area after return 120: blocking wall
130: first wing bit support hole 200: rotation bit
210: second wing bit support hole 220: wing bit guide hole
230: Support shaft 231: Ventilation hole
232: Pin fixing groove 300: Wing bit
310: Extension guide surface 320: Extended seat surface
330: Wing bit support surface 340: Wing bit support shaft
350: Wing bit guide shaft 360: Return guide face
370: return face: a: rotation in one direction
b: Rotate in the other direction

Claims (13)

A body to which the rotational force of the driving unit is transmitted;
A rotating bit connected to a lower portion of the body; And
A wing bit provided between the body and the rotary bit and extending or returning in a radial direction according to a rotation direction of the driving unit;
/ RTI >
Wherein the body is provided with a rotating core having a core projection,
Wherein the wing bit is provided with a wing bit support shaft passing through the wing bit,
One end of the wing bit support shaft is connected to the body and the other end is connected to the rotation bit,
A first wing bit support hole having a long hole shape is formed in the body,
One end of the wing bit support shaft is inserted into one side of the first wing bit support hole,
One end of the wing bit support shaft relatively moves from one side of the first wing bit supporting hole to the other side while the rotating core rotates in one direction so that the wing bit extends,
A circular second wing bit support hole is formed in the rotation bit,
The other end of the wing bit support shaft is inserted into the second wing bit support hole,
Wherein the wing bit is provided with a wing bit guide shaft protruding from the lower end of the wing bit,
And the rotation bit is formed with a slotted wing bit guide hole into which the wing bit guide shaft is inserted. The method according to claim 1,
Wherein the wing bit is formed with an extended guide surface for contacting the core projection,
Wherein the core protrusion moves the extension guide surface radially outward when the rotating core is rotated in one direction. 3. The method of claim 2,
Wherein the wing bit is formed with an extended seating surface on which the core projection is seated when the rotating core is rotated in one direction. The method of claim 3,
The body is provided with a blocking wall along the circumferential direction,
Wherein a wing bit supporting surface is formed at one side of the wing bit so as to be contacted with the blocking wall when the rotating core is rotated in one direction. 5. The method of claim 4,
Wherein the other side of the blocking wall is contactably supported on the wing bit supporting surface when the rotating core is rotated in one direction, and one side of the blocking wall is disposed adjacent to the other side of the wing bit. delete delete delete delete 5. The method of claim 4,
Wherein one end of the wing bit guide shaft relatively moves from one side of the wing bit guide hole to the other side while the rotating core rotates in one direction so that the wing bit is expanded. 11. The method of claim 10,
Wherein the wing bit is formed with a return guide surface for contacting the blocking wall,
Wherein the blocking wall moves the return guide surface radially inward when the rotating core is rotated in the other direction. 12. The method of claim 11,
Wherein the wing bit is formed with a return seating surface on which the core projection is seated when the rotating core rotates in the other direction. 13. The method of claim 12,
And a blow hole for blowing air toward the wing bit is formed around the support shaft of the rotary bit.

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