KR20200141710A - Core drill device with changing operated mode - Google Patents

Abstract

The present invention is a mode changeable core capable of selectively performing a centering operation using a center drill and a drilling operation using a core bit through axial fixation and adjustment of axial movement for a center drill disposed coaxially with the core bit. Start the drill device.
In the above-described core drilling device, the connector bar 20 coupled with the spindle 10, the core bit 30 coupled with the connector bar 20, and the axial movement and rotation in the circumferential direction with respect to the connector bar 20 In the interior of the sleeve 60 that is respectively installed possible, the movable body 50 whose position is changed in the radial direction with respect to the connector bar 20 according to the position of the sleeve 60, and the core bit 30 It is disposed, and includes a center drill 40 axially fixed or axially moved with respect to the connector bar 20 according to a radial movement position of the movable body 50, the center drill 40 A pressure receiving part 41 for restraining axial movement with respect to the connector bar 20 by contact with the movable body 50, and an axis for the connector bar 20 by contact with the movable body 50 It is provided with a guide portion 42 for allowing direction movement.

Description

Core drill device with changing operated mode

The present invention relates to a core drill device, and more particularly, a centering operation using a center drill and a core bit through an axial fixation of a center drill disposed coaxially with a core bit and selective adjustment of axial movement. It relates to a mode-changing type core drill device capable of continuously performing a drilling operation more conveniently.

In general, a core drill corresponds to a machine tool for performing drilling, and is used to drill a hole of a predetermined diameter in a work object of a hard material having a predetermined strength or higher, such as a rock or concrete structure at various construction sites. It becomes.

In this case, the core drill includes a spindle that rotates at high speed by a driving force provided from the outside, and a core bit mounted on the spindle and having a cylindrical drill bit at the tip.

In order to perform a drilling operation using a core drill having such a structure, a centering operation to ensure a stable rotation of the core bit on the center, which is a reference for the drilling operation, must be preceded.

In other words, in the conventional drilling work using a core drill, the first centering work that precedes the centering work using the center drill while a separate center drill is mounted on the center of the core bit, and the second centering work using only the core bit after removing the center drill. Drilling should be carried out sequentially.

Accordingly, in the conventional drilling operation using a core drill, a process for attaching and removing the center drill is required, so that not only the workability is deteriorated, but the time required for the entire operation is increased.

In contrast, the conventional drilling operation has been performed in a manner in which the drill bit on the tip side of the core bit is obliquely entered with respect to the work object to perform local contact, and then additionally proceed with the drilling operation using the groove generated by the local contact.

However, in the above drilling work, there is a lot of difficulty in aligning the exact drilling position in the process of local contact between the work object and the drill bit on the tip side of the core bit, and in the case of workers with low work skill, the exact position It will cause a problem that the drilling operation cannot be performed properly.

In addition, in the conventional drilling operation, the equipment disclosed in Patent No. 10-0615468 was used to enter the drill bit at the tip end of the core bit inclined with respect to the work object. In this case, the correct drilling operation by correct angle adjustment of the core bit was used. Although there are possible advantages, there is a disadvantage that it cannot be used in a narrow space where it is difficult to enter the equipment.

Registered Patent No. 10-0615468

The technical problem to be solved by the present invention is to selectively perform a centering operation using a center drill and a drilling operation using a core bit through axial fixation and adjustment of the axial movement of the center drill disposed coaxially with the core bit. In addition to being able to, it is to provide a mode-changing core drilling device that enables continuous work more conveniently and smoothly drills in a narrow space.

Another technical problem to be solved by the present invention is to provide a mode-changing core drill device capable of selectively implementing the replacement of the center drill or the overall disassembly and assembly of the core drill equipment along with the control of the working mode of the center drill for the core bit. Is to do.

The present invention for solving the above technical problem is a connector bar coupled with a spindle, a core bit coupled with the connector bar, a sleeve installed to enable axial movement and circumferential rotation with respect to the connector bar, respectively, and the sleeve A movable body whose position is changed in a radial direction with respect to the connector bar according to the position of, and is disposed inside the core bit, and is axially fixed or axially fixed with respect to the connector bar according to the radially moving position of the movable body And a center drill in which movement is made, wherein the center drill is a pressure receiving part for restraining the axial movement of the connector bar by contact with the movable body, and the connector bar by contact with the movable body. It is preferable to be configured to have a guide for allowing axial movement.

The present invention further comprises a stop pin for adjusting the axial movement position and the circumferential rotation position of the sleeve with respect to the connector bar, the stop pin is configured to be installed to be movable radially with respect to the connector bar It is desirable.

In the present invention, the sleeve controls the axial movement position and circumferential rotation position of the sleeve with respect to the connector bar on the inner circumferential surface, and the axial fixation and axial movement of the center drill with respect to the connector bar. It is preferable to provide a groove for adjusting the operating mode of the core drill through.

In the present invention, the concave groove portion is a first group of insertion grooves contacting the stop pin for adjusting the axial movement position and the circumferential rotation position of the sleeve with respect to the connector bar, and the center drill for the connector bar. In order to adjust the axial fixation and axial movement of the movable body, it is preferable to include a second insertion groove group in contact with the movable body.

In the present invention, the first insertion groove group is composed of a first long groove and a first end groove contactable with the stop pin by varying extension lengths along the axial direction on the inner peripheral surface of the sleeve, and the first long groove and the first The first-stage groove is preferably disposed to be spaced apart from each other as a radial structure with respect to the center of the inner peripheral surface of the sleeve.

In the present invention, at least one of the first long grooves is composed of a through groove formed in an axial direction along the inner circumferential surface of the sleeve, and the rest of the first long grooves and the first end groove are respectively in the inner peripheral surface of the sleeve. It is preferable to have a structure in which one end is closed in the axial direction by a stepped portion.

In the present invention, the second insertion groove group is composed of a second long groove and a second end groove capable of contacting the movable body by varying extension lengths along the axial direction on the inner peripheral surface of the sleeve, and the second long groove and the second groove The two-stage groove is preferably arranged to be spaced apart from each other as a radial structure with respect to the center of the inner peripheral surface of the sleeve.

In the present invention, it is preferable that at least one of the second long grooves is disposed at a position facing the second end groove, and the other of the second long grooves is disposed at a position facing the arc-shaped portion.

In the present invention, it is preferable that all of the second insertion groove groups have a structure in which one end is blocked in the axial direction by a step on the inner circumferential surface of the sleeve, and the arc-shaped part has a curvature structure substantially the same as the inner circumferential surface of the sleeve. .

The present invention further comprises a first return spring installed to adjust the elastic axial displacement of the sleeve with respect to the connector bar, the connector bar has a main passage for receiving the center drill axially movable And, it is preferable that the inside of the main passage is provided with a second return spring for elastically supporting the center drill.

In the present invention, it is preferable that the connector bar includes a first through hole for receiving the movable body to be movable in a radial direction, and a second through hole for receiving the stop pin so as to be movable in a radial direction.

The present invention can be implemented by changing the operation mode of the center drill rather than the detachable replacement method of the center drill for the core drill device in performing the centering work using the center drill and the drilling work using the core bit, so it is more convenient. Not only can the centering work and the drilling work be implemented continuously, but also the drilling work can be performed more easily in a narrow space accompanied by space constraints.

That is, in the present invention, when a centering operation using a center drill is required before performing a drilling operation using a core bit, the centering operation and the drilling operation can be selectively performed only by changing the operation mode. Not only can the inconvenience of installing or removing after work can be eliminated, but also the time required for the entire work can be greatly shortened through the continuous work of the centering work and the drilling work.

1 is a perspective view showing a core drilling device according to an embodiment of the present invention.
2 is a longitudinal sectional view of a core drilling device according to an embodiment of the present invention, showing a partial enlarged view of a main component.
3 is an exploded perspective view illustrating a coupling relationship between components of a core drill device according to an embodiment of the present invention.
4 is a partially enlarged perspective view of the connector bar, sleeve, and center drill shown in FIG. 3.
5 is a partially enlarged perspective view showing the connector bar, sleeve, and center drill shown in FIG. 3 in opposite directions.
6 is a front view and a perspective view of the sleeve shown in FIG. 3 in different directions.
7 to 10 are longitudinal cross-sectional and cross-sectional views showing only the core part separately to explain each operation mode of the core drilling device according to the embodiment of the present invention, and the displacement of the sleeve with respect to the connector bar and dependent accordingly. It is a diagram showing the change in the contact state between the movable body and the center drill.

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

1 to 6, the core drilling device according to the embodiment of the present invention includes a connector bar 20 installed to be interlocked with a spindle 10, and a core bit 30 coupled to the connector bar 20. ), a center drill 40 disposed coaxially with the core bit 30, a movable body installed to be movable in a radial direction with respect to the connector bar 20 to support the center drill 40 so as to be restrained (50), by adjusting the radially moving position of the movable body 50 with respect to the connector bar 20, the connector bar 20 and the center drill 40 can be interlocked or not interlocked. It comprises a sleeve 60 for releasing the coupling, and a stop pin 70 for adjusting the axial movement position and the circumferential rotation position of the sleeve 60 with respect to the connector bar 20.

The spindle 10 is rotated by a driving force provided from the outside, and is composed of a shaft member that rotates at high speed by external power accompanying electric drive by a motor or pressurization by compressed air.

The connector bar 20 is a hollow member disposed coaxially with respect to the spindle 10 so as to be interlocked, and one end is coupled to the spindle 10 and the other end is the core bit 30 And are coaxially coupled to the center drill 40, respectively. At this time, the coupling between them may be implemented in the manner of screwing.

In addition, one end of the connector bar 20 may be provided with a single-stage coupling structure or two or more coupling structures with respect to the spindle 10. In an embodiment of the present invention, the spindle as shown in FIG. For (10), it is exemplified that it is provided in a two-stage shaft-coupled structure.

In addition, the connector bar 20 is provided with a first return spring 81 on the outer circumferential surface, and the first return spring 81 is an elastic axial direction of the sleeve 60 with respect to the connector bar 20 It is provided to adjust the displacement. In this case, one end of the first return spring 81 is supported through a fixing ring 83 with respect to the seating groove formed on the outer circumferential surface of the connector bar 20, and the other end of the first return spring 81 Is configured to be supported by the locking projection (60a) located on the inner circumferential surface of the sleeve (60).

In addition, the connector bar 20 includes a main passage 20a that is elongated along the axial direction of the member to accommodate the center drill 40 in an axial direction. In this case, the main passage (20a) is a resilient axial direction toward the front protruding direction of the center drill (40) by installing a second return spring (82) to support elasticity of the center drill (40) therein. You will be able to move. To this end, the second return spring 82 may be installed so that one end thereof supports the rear surface of the center drill 40 and the other end may be fixed inside the main passage 20a.

In addition, the connector bar 20 includes a first through hole 21 formed along the radial direction of the member to accommodate the movable body 50 in a radial direction. In the embodiment of the present invention, the first through hole 21 is formed at two positions with a phase angle of 180 degrees in the vertical direction with respect to the axial center of the connector bar 20. In this case, the position or quantity of the first through-hole 21 may be modified and implemented in various embodiments. Even in this case, the location or quantity of the first through-hole 21 is the movable body 50 It will depend on the location and quantity of

The first through hole 21 has a flange portion 21a protruding toward the radial center of the first through hole 21 at a base portion toward the axial center of the connector bar 20, wherein the plan The branch portion 21a serves to prevent the movable body 50 from being separated toward the axial center of the connector bar 20. In this case, the displacement of the movable body 50 toward the axial center of the connector bar 20 may be determined by the amount of protrusion of the flange portion 21a.

In addition, the connector bar 20 includes a second through hole 22 formed along the radial direction of the member to accommodate the stop pin 70 so as to be movable in the radial direction. In this case, the second through-hole 22 is disposed at a position spaced apart from the first through-hole 21 with an appropriate distance along the axial direction. In this case, it is preferable that the stop pin 70 is installed so that the bottom of the second through hole 22 is elastically supported through a compression spring (not shown). In the embodiment of the present invention, the second through hole 22 is provided in a single position with respect to the connector bar 20, and the position or quantity of the second through hole 22 is various modified embodiments. Could be implemented.

The core bit 30 corresponds to a drilling tool for performing a drilling operation on a work object, and is formed of a hollow member disposed coaxially with respect to the connector bar 20 to be interlocked. In this case, the core bit 30 may be coupled to the connector bar 20 by screwing.

The center drill 40 corresponds to a centering tool that performs a centering operation on a work object, and is configured to be disposed coaxially within the core bit 30. In this case, the center drill 40 is configured such that the front end of the center drill 40 protrudes slightly more forward than the front end of the core bit 30 for centering work.

In particular, the center drill 40 is disposed coaxially inside the core bit 30, and the connector bar 20 according to the radial movement position of the movable body 50 relative to the connector bar 20 ) Is constrained in the axial direction and fixed, or the constrained in the axial direction is released so that the movement can be changed to a dependent state.

That is, the center drill 40 is fixed in the axial direction with respect to the connector bar 20 and rotates integrally so that the centering operation can be performed, or it moves in the axial direction toward the inside of the connector bar 20 By doing so, it is configured so that only the drilling operation can be implemented by being accommodated as a position incapable of performing the centering operation.

In summary, the center drill 40 is fixed in the axial direction with respect to the connector bar 20 according to the radial movement position of the movable body 50 and is present at a centering working position, or the connector bar 20 It is moved in the axial direction through the main passage (20a) of and transferred to the storage position, thereby moving to a position where the centering operation is impossible.

To this end, the center drill 40 is in contact with the pressure receiving part 41 and the movable body 50 for restraining the axial movement of the connector bar 20 by contact with the movable body 50 It is configured to have a guide portion 42 for allowing the axial movement of the connector bar 20 by. Here, the pressure receiving part 41 and the guide part 42 are respectively concave from the outer circumferential surface of the center drill 40 toward the inside in the radial direction, for convenience of illustration as shown in FIGS. 2 and 7 to 10. , It means a part corresponding to the virtual base circle connecting the bottom of the cutting edge of the drill.

In this case, the pressure receiving part 41 is formed on the center drill 40 at a single local position capable of contacting the movable body 50. In addition, the guide portion 42 is formed along the entire length of the center drill 40, it will be preferably formed to surround the entire portion of the drill in the form of a spiral.

That is, the pressure receiving part 41 restricts the rotation of the center drill 40 with respect to the main passage 20a of the connector bar 20 by contact with the movable body 50 to limit axial movement. The guide part 42 guides the movement of the center drill 40 toward the inside of the main passage 20a of the connector bar 20 by contact with the movable body 50 It serves to allow the receiving movement in the axial direction.

To this end, the movable body 50 is preferably composed of a quantity capable of individually contacting the pressure receiving part 41 and the guide part 42 of the center drill 40, and the movable body 50 It would be desirable to be configured so that simultaneous contact with the pressure receiving part 41 and the guide part 42 of the center drill 40 is not made. In addition, it would be more preferable that the pressure receiving part 41 and the guide part 42 are set to be disposed at positions opposite to each other in a contact part with the movable body 50.

Accordingly, when the movable body 50 comes into contact with the pressure receiving part 41, the axial movement of the center drill 40 relative to the connector bar 20 is restricted and restricted, so that the spindle 10 During rotation of, the center drill 40 rotates integrally with the connector bar 20 so that the centering operation can be performed.

In addition, when the movable body 50 contacts the guide part 42, the axial restraint of the center drill 40 with respect to the connector bar 20 is released, so that when the spindle 10 is rotated The guide portion 42 of the center drill 40 enters while rotating toward the inside of the main passage 20a of the connector bar 20 by contact with the movable body 50, so that the centering operation is no longer On the other hand, only the drilling operation by the core bit 30 can be performed.

The movable body 50 is a member made of a spherical hard material installed to be movable in a radial direction within the first through hole 21 of the connector bar 20, and the connector bar 20 It plays a role of selectively controlling the movement of the center drill 40 by axial restraint and release by axial restraint. In this case, the radial position of the movable body 50 relative to the connector bar 20 is configured to be dependently determined by the position of the sleeve 60 relative to the connector bar 20. Accordingly, the movable body 50 is fixed in the axial direction or the axial direction with respect to the center drill 40 through contact with any one of the pressure receiving part 41 and the guide part 42 of the center drill 40 Only one of the moves is allowed.

That is, the movable body 50 is installed to be movable radially toward the axial center within the first through hole 21 of the connector bar 20, and the center drill 40 for the connector bar 20 ) By selectively adjusting either one of fixed by axial restraint and movement by axial restraint release, so that the connector bar 20 and the center drill 40 can be interlocked in the axial direction or interlocked It is configured to disable the axial coupling between them impossible.

The sleeve 60 is a member of a hollow shape surrounding the outer circumferential surface of the connector bar 20 and is installed to enable axial movement and circumferential rotation with respect to the connector bar 20, respectively. In this case, the sleeve 60 is configured to serve as a member for switching an operation mode capable of converting an operation mode of the core drilling device to a desired mode.

That is, the sleeve 60 is installed to enable axial movement and circumferential rotation with respect to the connector bar 20, so that the movable body 50 moves in the radial direction with respect to the axial center of the connector bar 20 By adjusting the position and selectively adjusting the axial fixation or axial movement of the center drill 40 relative to the connector bar 20 through this, interlocks between the connector bar 20 and the center drill 40 It is configured to enable coupling or disengagement so as not to be interlockable.

To this end, the sleeve 60 adjusts the axial movement position and the circumferential rotation position of the sleeve 60 relative to the connector bar 20 on the inner circumferential surface, and the center drill 40 for the connector bar 20 ) Is provided with a groove for adjusting the axial fixing and axial movement. For example, in the embodiment of the present invention, the concave portion is a drilling mode, a hollow mode, a replacement mode, and a separation mode of the entire core drill operation mode including the operation mode of the center drill 40 with respect to the core bit 30. It is configured to adjust to any one of the modes, and the types and positions of the operation mode of the center drill 40 may be implemented as various modified embodiments.

In an embodiment of the present invention, the concave portion is configured to be separated into a first insertion groove group and a second insertion groove group, wherein the first insertion groove group is an axial movement position of the sleeve 60 with respect to the connector bar 20 And the stop pin 70 to adjust the rotational position in the circumferential direction, and the second insertion groove group is fixed in the axial direction and moved in the axial direction of the center drill 40 with respect to the connector bar 20 Corresponds to the configuration in contact with the movable body 50 to adjust.

Hereinafter, detailed configurations of the first insertion groove group and the second insertion groove group will be described in detail with reference to FIGS. 6 and 7 to 10.

The first insertion groove group is a plurality of grooves that can contact the stop pin 70 by varying their extension lengths along the axial direction from the inner circumferential surface of the sleeve 60, and the first long groove 61 and the first end groove 62 ). In this case, the first long groove 61 and the first end groove 62 have a radial structure with respect to the center of the inner circumferential surface of the sleeve 60 and are disposed at positions spaced apart from each other at appropriate intervals.

In addition, at least one of the first long grooves 61 is configured in the form of a through groove 63 formed in an axial direction along the inner circumferential surface of the sleeve 60, and the first long groove 61 has an open structure. The rest of the first end groove 62 except for the through hole 63 of the sleeve 60 are configured to have one end of the sleeve 60 blocked in the axial direction by a step 64.

In this case, the stepped portion 64 protrudes inward from the inner circumferential surface of the sleeve 60 along the circumferential direction to block one end of the remaining first insertion groove groups except for the through groove 63 in the axial direction, thereby stopping the It serves to limit the axial movement position of the sleeve 60 by the pin 70.

Accordingly, when a contact occurs between any one of the first insertion groove groups formed on the inner peripheral surface of the sleeve 60 and the stop pin 70, the axial direction of the sleeve 60 with respect to the connector bar 20 The moving position and the circumferential rotation position can be determined independently.

In an embodiment of the present invention, at least one pair of the first long grooves 61, and the first end groove 62 and the through groove 63 face each other with respect to the center of the inner circumferential surface of the sleeve 60 And the first long groove 61 implements a drilling mode and a hollow mode, the first end groove 62 implements a replacement mode, and the through groove 63 is set to implement a separation mode. That is, the first insertion groove group has a different extension length along the axial direction on the inner circumferential surface of the sleeve 60, and the first long groove 61 for implementing the drilling mode and the empty mode, for implementing the replacement mode It consists of a first end groove 62 and a through groove 63 for implementing the separation mode.

The second insertion groove group is a plurality of grooves that can contact the movable body 50 by varying their extension lengths along the axial direction from the inner circumferential surface of the sleeve 60, and the second long groove 65 and the second end groove 66 ). In this case, the second long groove 65 and the second end groove 66 have a radial structure with respect to the center of the inner circumferential surface of the sleeve 60 and are disposed at positions spaced apart from each other at appropriate intervals.

In addition, at least one of the second long grooves 65 is disposed at a position facing the second end groove 66 to implement the replacement mode and the separation mode, and the other one of the second long grooves 65 is drilling In order to implement the mode and the void mode, the sleeve 60 is configured to be disposed at a position facing the unprocessed arc-shaped portion 67 on the inner circumferential surface of the sleeve 60.

In addition, all of the second insertion groove groups have a structure in which one end of the sleeve 60 is closed in the axial direction by the stepped portion 64, and the arc-shaped portion 67 is an inner peripheral surface of the sleeve 60 It is configured to have a curvature structure substantially the same as

In this case, the stepped portion 64 protrudes inward from the inner circumferential surface of the sleeve 60 along the circumferential direction to block one end of the second insertion groove groups in the axial direction, so that the movable for the connector bar 20 The radial movement position of the sieve 50 is dependently changed.

Accordingly, when contact occurs between any one of the second insertion groove groups formed on the inner circumferential surface of the sleeve 60 and the movable body 50, the radius of the movable body 50 with respect to the connector bar 20 The directional movement position can be determined dependently, through which the center drill 40 with respect to the connector bar 20 can be selectively adjusted to be fixed by axial restraint or release by axial restraint. .

In an embodiment of the present invention, when the second long groove 65 and the arc-shaped part 67 are positioned on the movable body 50, a drilling mode and a void mode are implemented, and the second long groove 65 and the When the second end groove 66 is located on the movable body 50, it is set to implement a replacement mode and a separation mode.

The stop pin 70 is inserted into the second through hole 22 of the connector bar 20 to be installed so as to protrude in the radial direction, and is configured to contact a concave portion formed on the inner circumferential surface of the sleeve 60 do. In this case, it is preferable that the stop pin 70 is configured such that the bottom surface is elastically supported in the second through hole 22 of the connector bar 20.

Accordingly, the stop pin 70 serves to adjust the axial movement position and the circumferential rotation position of the sleeve 60 with respect to the connector bar 20. For example, the stop pin 70 is the connector through contact with any one of the first long groove 61, the first end groove 62, and the through groove 63 constituting the first insertion groove group among the concave grooves. It is possible to determine the axial movement position and the circumferential rotation position of the sleeve 60 relative to the bar 20.

Accordingly, the core drilling device configured as described above performs selective operation in various operation modes as shown in FIGS. 7 to 10. In this case, for convenience of understanding, the pressure receiving part 41 and the guide part 42 in contact with the movable body 50 in FIGS. 7 to 10 connect the bottom of the cutting edge of the center drill 40 It should be noted that the virtual basic circle is indicated by a solid line, and the part corresponding to the outer peripheral surface of the center drill 40 is indicated by a two-dot chain line.

Referring to FIG. 7, in the drilling mode (centering operation mode) in which the centering operation by the center drill 40 can be performed, between the first long groove 61 and the stop pin 70 of the first insertion groove group The contact is made so that the axial movement position and the circumferential rotation position of the sleeve 60 relative to the connector bar 20 are dependently determined.

In this process, any one of the movable bodies 50 is moved radially inward by contact with the arc-shaped part 67 in the second insertion groove group so as to come into contact with the pressure receiving part 41 of the center drill 40. The other of the movable bodies 50 is moved radially outward so as to be able to contact the second long groove 65 from among the second insertion groove groups, so that the guide portion 42 of the center drill 40 and the It is converted to a separated state.

As a result, since the rotational force provided to the connector bar 20 through the spindle 10 is transmitted to the center drill 40 by contact between the movable body 50 and the arc-shaped part 67, the center The centering operation by the drill 40 can be performed normally.

8, in the replacement mode in which the replacement work for the center drill 40 can be performed, contact between the first end groove 62 and the stop pin 70 among the first insertion groove group is made. Thus, the axial movement position and the circumferential rotation position of the sleeve 60 relative to the connector bar 20 are dependently determined.

In this process, any one of the movable bodies 50 is moved radially outward so that contact with the second end groove 66 of the second insertion groove group is possible, so that the pressure receiving part 41 of the center drill 40 And the other one of the movable bodies 50 is moved radially outward so that contact with the second long groove 65 of the second insertion groove group is possible, so that the guide portion 42 of the center drill 40 ) Is also converted to a state separated from.

As a result, since the center drill 40 is in a state where it does not receive any axial restraining force from the movable body 50, it can be freely separated from the main passage 20a of the connector bar 20 toward the outside. .

Referring to FIG. 9, in the hollow mode (perforation operation mode) in which the centering operation by the center drill 40 is not performed and only the drilling operation by the core bit 30 is performed, the first insertion groove group Among them, the contact between the first long groove 61 and the stop pin 70 is made so that the axial movement position and the circumferential rotation position of the sleeve 60 relative to the connector bar 20 are determined dependently.

In this process, any one of the movable bodies 50 moves outward in the radial direction in which contact with the second long groove 65 is possible among the second insertion groove group, and thus from the pressure receiving part 41 of the center drill 40 It is in a spaced state, and the other of the movable bodies 50 is moved radially inward by contact with the arc-shaped part 67 of the second insertion groove group, so that the guide part 42 of the center drill 40 It is converted to the state in contact with.

As a result, since the center drill 40 does not receive any axial restraining force from the movable body 50 and there is only contact between the guide part 42 and the movable body 50, the spindle ( The rotational force provided to the connector bar 20 through 10) cannot be transmitted to the center drill 40, and the center drill 40 is formed by contact between the guide part 42 and the movable body 50 It enters while rotating toward the inside of the main passage 20a of the connector bar 20, and only the drilling operation by the core bit 30 can be performed normally.

In this process, the center drill 40 presses and compresses the second return spring 82 while entering the inside of the main passage 20a of the connector bar 20, so that the center drill is compressed in the next drilling mode. 40 is moved to the original position via the restoration by the second return spring 82, so that a state in which the movable body 50 can contact the pressure receiving part 41 can be prepared.

Referring to FIG. 10, in a separation mode in which disassembly and assembling work for the core drilling device can be performed, contact between the through groove 63 and the stop pin 70 is made among the first insertion groove group. The axial movement position and the circumferential rotation position of the sleeve 60 relative to the connector bar 20 are dependently determined.

In this process, any one of the movable bodies 50 is moved radially outward so that contact with the second end groove 66 of the second insertion groove group is possible, so that the pressure receiving part 41 of the center drill 40 And the other one of the movable bodies 50 is moved radially outward so that contact with the second long groove 65 of the second insertion groove group is possible, so that the guide portion 42 of the center drill 40 ) Is also converted to a state separated from.

As a result, the center drill 40 not only does not receive any axial restraining force from the movable body 50, but also the sleeve 60 exerts no restraining force in the axial direction with respect to the connector bar 20. Since it is not received, the axial movement of the sleeve 60 from the connector bar 20 is free, and thus, the overall disassembly and assembly of the core drilling device is possible.

In the embodiment of the present invention, the operation mode for the core drill device was described only as a drilling mode, a hollow mode, a replacement mode, and a separation mode, but the operation mode of the core drill device is based on the position of the movable body 50 and The type and position of the groove formed on the inner circumferential surface of the sleeve 60 and the position of the stop pin 70 may be implemented in various modified embodiments through various combinations.

In addition, the position and quantity of the movable body 50 will be dependently determined according to the positions of the pressure receiving part 41 and the guide part 42 of the center drill 40, and the sleeve 60 A combination of the type and position of the recessed portion of) and the position of the stop pin 70 may be determined together.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. In addition, the scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10-spindle 20-connector bar
20a-main passage 21-first through hole
22-second through hole 30-core bit
40-center drill 41-hydraulic part
42-guide 50-movable body
60-Sleeve 61-Chapter 1 Groove
62-first step groove 63-through groove
64-Step 65-Chapter 2 Groove
66-second step groove 67-arc shape part
70-stopping pin 81-first return spring
82-second return spring 83-fixing ring

Claims (12)

A connector bar coupled with the spindle;
A core bit coupled to the connector bar;
A sleeve installed to enable axial movement and circumferential rotation with respect to the connector bar, respectively;
A movable body whose position is changed in a radial direction with respect to the connector bar according to the position of the sleeve; And
It is disposed inside the core bit, and includes a center drill axially fixed or axially moved with respect to the connector bar according to the radially moving position of the movable body,
The center drill,
A pressure receiving part for restraining the axial movement of the connector bar by contact with the movable body; And
And a guide portion for allowing the axial movement of the connector bar to be allowed by contact with the movable body. The method according to claim 1,
A core, characterized in that it further comprises a stop pin for adjusting the axial movement position and the circumferential rotation position of the sleeve with respect to the connector bar, wherein the stop pin is installed to be movable radially with respect to the connector bar Drill device. The method according to claim 2,
The sleeve operates the core drill by adjusting the axial movement position and the circumferential rotation position of the sleeve with respect to the connector bar on the inner circumferential surface, and the axial fixation and axial movement of the center drill with respect to the connector bar. A core drilling device comprising a groove for adjusting the mode. The method of claim 3,
The concave portion,
A first group of insertion grooves in contact with the stop pins for adjusting the axial movement position and the circumferential rotation position of the sleeve with respect to the connector bar; And
And a second insertion groove group contacting the movable body to adjust the axial fixation and axial movement of the center drill with respect to the connector bar. The method of claim 4,
The first insertion groove group is composed of a first long groove and a first end groove capable of contacting the stop pin by varying extension lengths along the axial direction from the inner peripheral surface of the sleeve, and the first long groove and the first end groove are the sleeve Core drill device, characterized in that arranged to be spaced apart from each other as a radial structure with respect to the center of the inner peripheral surface. The method of claim 5,
At least one of the first long grooves is composed of a through groove formed in an axial direction along the inner circumferential surface of the sleeve, and the rest of the first long grooves and the first end grooves each have one end on the inner peripheral surface of the sleeve. Core drill device, characterized in that the structure is blocked in the axial direction by the. The method according to claim 4 or 5,
The second insertion groove group is composed of a second long groove and a second end groove capable of contacting the movable body by varying extension lengths from the inner circumferential surface of the sleeve along the axial direction, and the second long groove and the second end groove are the sleeve Core drill device, characterized in that arranged to be spaced apart from each other as a radial structure with respect to the center of the inner peripheral surface. The method of claim 7,
At least one of the second long grooves is disposed at a position facing the second end groove, and the other one of the second long grooves is disposed at a position facing the arc-shaped portion. The method of claim 8,
Each of the second insertion groove groups has a structure in which one end of the inner circumferential surface of the sleeve is blocked in the axial direction by a step, and the arc-shaped part has a curvature structure substantially the same as that of the inner circumferential surface of the sleeve. The method according to claim 1,
And a first return spring installed to adjust the elastic axial displacement of the sleeve with respect to the connector bar. The method according to claim 1,
The connector bar has a main passage for accommodating the center drill in an axial direction, and a second return spring for elastically supporting the center drill is installed inside the main passage. The method according to claim 2,
The connector bar,
A first through hole for receiving the movable body to be movable in a radial direction; And
And a second through hole for receiving the stop pin so as to be movable in a radial direction.

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