KR102243146B1 - Core Drill - Google Patents

Abstract

The present invention relates to a core drill. More specifically, since a worker moves a bit advancement bolt, which moves a core bit forming a hole on a drilling point, along a center rod by rotating the same with a tool, a constraint of workspace can be avoided due to drilling work able to be performed even in a confined or curved workplace, which can result in an increase in working efficiency. Also, since the center rod, the core bit, the bit advancement bolt and the fixing bolt are separated into individual unit components, the components are sequentially assembled only when used to smoothly perform drilling work, and, after the end of the work, the components are separated to be stored in a separate portable case with a reduced volume, which can result in convenient storability and portability. Also, since a foreign substance cover part is installed at an end of the center rod, foreign substances such as dust and the like produced during the drilling of the core bit can be blocked by the foreign substance cover part to be prevented from being stuck in screw threads of the center rod, thereby leading the bit advancement bolt to smoothly move along the center rod, which can result in efficient drilling work.

Description

Core Drill

The present invention relates to a core drill, and more particularly, by rotating a bit advance bolt for moving a core bit that forms a hole at a perforation point by using a tool and moving it along a central bar, even in a narrow or curved work place. Since the drilling work is performed, the work space is not restricted, and the work efficiency is increased accordingly, and the foreign substance cover part is installed at the end of the center bar, so that foreign substances such as dust and dust generated when the core bit is drilled It is blocked by the cover part to prevent pinching in the thread of the center rod, thereby allowing the bit advance bolt to move smoothly along the center rod, it relates to a core drill in which drilling is efficiently performed.

In general, a core drill is used to drill a concrete structure, rock, etc. while a cylindrical core bit rotates, or to extract a test specimen for strength testing in a concrete structure, etc., with an electric motor installed in the drill body, It is a conventional structure in which a reduction gear connected to the shaft of the electric motor, a rotation shaft connected to the reduction gear, and a cylindrical bit are combined in front of the rotation shaft.

In the conventional core drill, when drilling work is performed on a perforated object such as a concrete structure, a core bit rotating at high speed is drilled by frictional contact with the perforated object, which is simply drilled by the rotational force of the core drill. In this case, a perforated object with strong strength, such as mortar concrete or reinforced concrete, takes a long time to perforate, resulting in a very large loss of time.

Therefore, the worker presses the core drill by applying force to the perforated object, and in this case, there is a problem in that the work efficiency decreases because physical fatigue of the worker increases.

As a prior art for solving this problem, Korean Utility Model Publication No. 0260501 (name/core drill) has been disclosed.

The prior art improves the efficiency of the drilling operation by increasing the drilling capacity by installing a vibrating body capable of selectively paralleling the rotational force of the core drill rotary shaft and the impact force by vibration.

However, the prior art does not have a means to support the core drill horizontally positioned in a state where the core bit is in contact with the concrete wall, so it takes a lot of effort for the operator to directly hold and support the heavy core drill, and to drill while the core drill moves. A problem arises in that it is impossible to drill an exact point out of the puncturing point.

In addition, when a vibrating body is used to apply an impact force due to vibration to the rotational shaft of the core drill, the vibration is transmitted to the operator as well as the force to hold the core drill that exerts such vibration increases the operator's fatigue. As a result, work efficiency is lowered, and the life of the core bit is shortened due to the accumulation of repeated vibrations.

In addition, the reduction gear applied to the conventional core drill does not use the reduction gear method due to the increase in the mounting space and manufacturing cost, but the belt pulley method has a short lifespan. Depending on the type of belt, a slip phenomenon occurs and a problem occurs in power transmission.

As a prior art for solving this problem, Korean Patent Registration No. 10-1858106 (name/core drill for easy drilling of a concrete wall) has been disclosed.

However, the prior art is limited to work in a narrow or curved work place because the automatic pressing tool is formed long, and thus, there is a problem in that the work efficiency is deteriorated.

Republic of Korea Utility Model Publication No. 0260501 Korean Patent Registration No. 10-1858106

The present invention was devised to solve the above conventional problems,

The operator rotates the bit forward bolt that moves the core bit that forms the hole at the drilling point and moves it along the central bar by rotating it using a tool, so that the drilling work is performed even in a narrow or curved work place, without being restricted by the work space. It is an object of the present invention to provide a core drill in which work efficiency is increased accordingly.

In addition, the center rod, core bit, bit advance bolt, and fixing bolt are separated into separate units, so that they are assembled sequentially only when using them to smoothly perform the drilling work, and after the work is finished, separate them to reduce the volume and reduce the volume for a separate portable. The purpose is to provide a core drill that can be put in a case and is very convenient for storage and portability.

In addition, by installing a foreign material cover part at the end of the center bar, foreign materials such as dust and dust generated when the core bit is drilled are blocked by the foreign material cover part to prevent being caught in the threads of the center bar, thereby preventing the bit advance bolt There is an object to provide a core drill in which drilling is efficiently made by being able to move smoothly along the central bar.

In order to achieve the above object, the present invention is integrally fixed to the anchor bolt inserted into the anchor hole of the perforation point, and a male thread is formed in the longitudinal direction at the outer periphery, and a polygonal bolt mountain is formed at the outer periphery of one or both ends. Central rod;

A core bit provided on the outer periphery of the central bar so that the central bar is exposed to the outside through a rotational force receiving portion formed on one side thereof, and rotated by a rotational power device connected to the rotational force receiving portion to form a perforation at a perforation point;

The core bit is screwed to the outside of the central bar and moved in the longitudinal direction of the central bar, and the fastening part formed on one side penetrates the rotational force receiving part of the core bit and is exposed to the outside and is connected to the core bit. A bit forward bolt for pressing and moving toward the concrete wall;

A fixing bolt that is screwed to the fastening portion of the bit advance bolt to connect the bit advance bolt to the core bit;

A foreign material cover part installed at the end of the center rod fixed to the anchor bolt to block the inside of the core bit to prevent foreign matters from being caught in the male thread of the center rod when the core bit is drilled. It relates to a core drill characterized by.

In addition, the bit advance bolt of the present invention has a support protrusion protruding from the outer periphery of the opposite side of the fastening part so as to control the fastening part to be exposed to the outside through the rotational force receiving part, and the support protrusion is supported inside the rotational force receiving part to expose the fastening part. It relates to a core drill, characterized in that to control the site.

In addition, it relates to a core drill, characterized in that a friction preventing member is further installed between the bit advance bolt and the rotational force receiving part of the present invention to prevent friction with the bit advance bolt when the core bit is rotated by a rotational power device. .

In addition, the fixing bolt of the present invention is screwed to the fastening part of the bit advance bolt and supported on one side of the rotational force receiving part, thereby fixing the bit advance bolt inside the rotational force receiving part and connecting it to the core bit. will be.

In addition, the circumference of the fixing bolt of the present invention is formed smaller than the circumference of the rotational force receiving portion, and thus relates to a core drill, wherein the rotational power device does not interfere when connected to the rotational force receiving portion.

In addition, the present invention relates to a core drill, characterized in that a coupling groove formed with a female thread is formed at an inner periphery so that the male thread of the anchor bolt is coupled to one side or both end surfaces of the center rod of the present invention.

In addition, the rotational force receiving unit of the present invention relates to a core drill, characterized in that a polygonal bolt mountain or gear groove is formed on the outer periphery so that the rotational power device is engaged to receive the rotational force.

In addition, the foreign material cover part of the present invention is screwed to the male thread or bolt thread of the end of the central bar, and is formed orthogonal to the central bar so as to contact the inner periphery of the core bit to block the penetrating one side of the core bit to be drilled. A cover fastening part that blocks foreign substances generated;

A cover body portion fixed to the rear surface of the cover fastening portion and formed so as to surround the outer periphery of the central rod, and having a body flexibly operated in the longitudinal direction of the central rod;

It relates to a core drill comprising a; a cover connection portion fixed to the end of the cover body portion is supported on one side of the bit advance bolt, and operates the cover body according to the movement of the bit advance bolt.

In addition, the central rod of the present invention has through holes formed therein so that both ends of the central rod are penetrated, and communication holes communicating with the through holes are formed in the bolt mounts at both ends of the central rod,

When the core bit is punctured by suction of an external suction device connected to one end of the center bar, the foreign matter generated is sucked through the communication hole formed at the other end of the center bar, and then moves to the external suction device through the through hole. It is all about the core drill.

As discussed above, in the core drill of the present invention, the operator rotates the bit advance bolt for moving the core bit forming the perforation at the perforation point and moves it along the central bar, even in a narrow or curved work place. Since the drilling work is performed, there is an effect of increasing work efficiency without being restricted by the work space.

In addition, the center rod, core bit, bit advance bolt, and fixing bolt are separated into separate units, so that they are assembled sequentially only when using them to smoothly perform the drilling work, and after the work is finished, separate them to reduce the volume and reduce the volume for a separate portable. Since it can be put in a case, it has a very convenient effect of storage and portability.

In addition, by installing a foreign material cover part at the end of the center bar, foreign materials such as dust and dust generated when the core bit is drilled are blocked by the foreign material cover part to prevent being caught in the threads of the center bar, thereby preventing the bit advance bolt It is possible to move smoothly along the central bar, so there is an effect that the drilling is made efficiently.

1 is a front view showing the overall core drill according to an embodiment of the present invention,
2 is a front view showing a core drill according to an embodiment of the present invention,
3 is a front view showing a separated core drill according to an embodiment of the present invention,
4 is a cross-sectional view showing a separated core drill according to an embodiment of the present invention,
5 is a cross-sectional view showing a combined core drill according to an embodiment of the present invention,
6 is a schematic diagram showing the outside and a cross section of a core bit according to an embodiment of the present invention,
7 is a schematic diagram showing the outside and a cross section of the bit forward bolt according to an embodiment of the present invention,
8 is a schematic view showing the outside and a cross section of a foreign material cover part according to an embodiment of the present invention.

The present invention having such characteristics will be more clearly described through preferred embodiments accordingly.

Before describing various embodiments of the present invention in detail with reference to the accompanying drawings, it will be appreciated that the application is not limited to the details of configurations and arrangements of components described in the following detailed description or illustrated in the drawings. will be. The present invention can be implemented and practiced in different embodiments, and can be carried out in various ways. Also, device or element orientation (eg "front", "back", "up", "down", "top", "bottom" The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral"), etc. are used only to simplify the description of the present invention, and related devices Or you will find that the element simply does not indicate or implies that it should have a particular orientation. Further, terms such as “first” and “second” are used in this application and the appended claims for purposes of explanation and are not intended to represent or imply any relative importance or spirit.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all the technical spirit of the present invention. It should be understood that there may be equivalents and variations.

1 is a front view showing an overall core drill according to an embodiment of the present invention, Figure 2 is a front view showing a core drill according to an embodiment of the present invention, Figure 3 is a separated according to an embodiment of the present invention A front view showing a core drill, Figure 4 is a cross-sectional view showing a separated core drill according to an embodiment of the present invention, Figure 5 is a cross-sectional view showing a combined core drill according to an embodiment of the present invention, Figure 6 is Figure 7 is a schematic diagram showing the outside and a cross section of the core bit according to an embodiment of the present invention, Figure 7 is a schematic diagram showing the outside and cross section of the bit forward bolt according to an embodiment of the present invention, Figure 8 is an embodiment of the present invention It is a schematic diagram showing the outside and a cross section of a foreign material cover part according to an example.

1 to 8, the core drill 100 of the present invention includes a central rod 10, a core bit 20, a bit forward bolt 30, a fixing bolt 40, and a foreign material cover It consists of a part 70.

As shown in Figs. 1 to 5, the center rod 10 is not struck downwards while facing the concrete wall 1 without exerting a force for working while the operator directly holds and supports the core drill 100. It is to play a role of advocating to prevent.

Here, in order to fix the central rod 10 to the concrete wall surface 1, an anchor hole 2 is firstly excavated at a perforation point to be drilled using a separate drill, and the anchor hole 2 is formed on one side. The anchor bolt 3 is fitted so that the screw part is exposed to the outside, and the male thread of the anchor bolt 3 is screwed into the coupling groove 11 formed at the end of the central bar 10 to be integrally fixed. . At this time, coupling grooves 11 having female threads are formed on both end surfaces of the center rod 10 so that they can be coupled to the anchor bolts 3 in any direction.

And, the outer periphery of the center rod 10 is formed with a male thread in the longitudinal direction, the bit advance bolt 30 is screwed, and tightening tools such as spanners and wrenches are fastened to the outer peripheries of both ends of the central rod 10 Each polygonal bolt mountain is formed as possible. At this time, the bolt mountain means that the outer periphery is formed in a polygonal shape like the head of the bolt, and the bolt mountain has the same meaning in the following.

However, in the above, it has been described that both ends of the center rod 10 have the same shape, but this is according to an embodiment of the present invention, and in another embodiment, an anchor bolt coupling groove 11 is provided at the other end. In the same way as the bolt mountain is formed in the part, it is also possible to form both ends of different shapes.

In addition, the center rod 10 has a through hole 12 formed therein so that both end surfaces of the center rod 10 penetrate, that is, one side of the through hole 12 communicates with the coupling groove 11 so that the inner central portion of the central rod 10 It is formed long in the longitudinal direction of the central rod 10 to penetrate through the other end surface of the central rod 10, and communication holes 13 communicating with the through holes 12 are formed in the bolt mounts at both ends of the central rod 10. It is formed at right angles.

Here, a suction device (also referred to as a dust collecting device, not shown) or a cooling water supply device (not shown) formed externally is connected to one end of the center rod 10 (the opposite side connected to the anchor bolt 3) to suck When the core bit 20 is punctured by the suction force of the device, the foreign material generated is sucked through the communication hole 13 formed in the other end of the center rod 10 (the part connected to the anchor bolt 3). Afterwards, the through hole 12 is discharged through the opposite communication hole 13 and moved to the suction device, or the cooling water supplied from the cooling water supply device is connected to one end of the central rod 10 (anchor bolt 3). The communication hole 13 is inserted through the communication hole 13 formed in the opposite side) and transferred through the through hole 12, and formed at the other end of the center rod 10 (the part connected to the anchor bolt 3). ) To remove cooling water and foreign substances during drilling.

The core bit 20 is provided outside the outer periphery of the central bar 10 so that the central bar 10 passes through the rotational force receiving portion 21 protruding from one side and is exposed to the outside, as shown in FIGS. 1 to 6. The core bit 20 has a hollow inside and penetrates both sides, and a rotational force receiving portion 21 protrudes on one side thereof, and the rotational force receiving portion 21 has a hole 22 formed in the central portion thereof to form a central bar and A part of the bit forward bolt 30 is penetrated.

Here, the outer periphery of the rotational force receiving unit 21 is formed with a polygonal bolt mountain or gear groove to be connected to the rotational power unit 60, and the rotational power unit 60 is at a right angle to the rotational force receiving unit 21 It is connected, and the rotational force of the rotational power device 60 is transmitted to the rotational force receiving portion 21 so that the core bit 20 is rotated, and a hole is formed at the puncturing point by the rotation.

On the other hand, the rotational power device 60 is a device that generates rotational power and transmits the rotational power to the rotational power receiving unit 21 to rotate the core bit 20, and at this time, the rotational power device 60 and the rotational force are accommodated. A speed reducer 61 for adjusting the rotational force of the rotational power device 60 is further formed between the parts 21. That is, after the speed reducer 61 is coupled to the rotational force receiving portion 21 of the core bit 20, a rotational power device 60 is connected to one side of the speed reducer 61, The rotational force is transmitted to the rotational force receiving unit 21 through the reducer 61. Here, since the rotational power device 60 and the reducer 61 are conventional power devices and reducers, the configuration and structure are not separately described.

As shown in FIGS. 1 to 7, the bit advance bolt 30 has an insertion hole 33 penetrating through both sides in a central portion, and a female thread is formed in the insertion hole 33 so as to be inserted into the insertion hole 33. As the center rod is fitted, the bit advance bolt 30 is screwed to the outside of the center rod 10 and moves along the longitudinal direction of the center rod 10 so that the core bit 20 performs a drilling operation. ) To the concrete wall surface (1).

Here, at one side of the bit advance bolt 30, a fastening part 31 is protruded so as to be exposed to the outside through the rotational force receiving part 21 of the core bit 20, and the outer periphery of the fastening part 31 In this, a male thread is partially formed so that the fixing bolt 40 is screwed, and a polygonal bolt thread is formed on the outer periphery of the other so that a tightening tool such as a spanner or a wrench is fastened.

In addition, the bit advance bolt 30 has a support protrusion 32 protruding on the outer periphery of the opposite side of the fastening part 31 to control the fastening part 31 to pass through the rotational force receiving part 21 and be exposed to the outside. And, the support protrusion 32 is supported inside the rotational force receiving portion 21 to control the exposed portion of the fastening portion 31. That is, the bit advance bolt 30 is provided inside the rotational force receiving part 21 so that the fastening part 31 protrudes to the outside of the rotational force receiving part 21. If the support protrusion 32 is not present, the bit advance bolt (30) The support protrusion 32 protruding at a right angle to the outer periphery of the bit forward bolt 30 is supported on the inside of the rotational force receiving part 21 to prevent separation from the rotational force receiving part 21, The forward bolt 30 is not deviated to the outside of the rotational force receiving portion (21).

In addition, an insertion groove 34 is formed on one surface of the support protrusion 32 in contact with the inner side of the rotational force receiving part 21 so that the anti-friction member 50 is inserted, and the bit advance bolt 30 and the rotational force are accommodated. A friction preventing member 50 is formed between the portions 21 to prevent the core bit 20 from being rubbed with the bit advance bolt 30 when rotating by the rotational power device 60. At this time, the friction preventing member 50 is a bushing, a bearing, etc., a bushing is installed in the insertion groove 34 of the support protrusion 32, and the outer periphery of the bit advance bolt 30 and the inside of the rotational force receiving part 21 Bearings are installed between the peripheries so that the rotational force is not transmitted to the bit forward bolt 30 even when the core bit 20 rotates.

The fixing bolt 40 is screwed to the fastening part 31 of the bit advance bolt 30 to connect the bit advance bolt 30 to the core bit 20, as shown in FIGS. That is, the fixing bolt 40 is screwed to the fastening part 31 of the bit advance bolt 30 and supported on one side of the rotational force receiving part 21, thereby allowing the bit advance bolt 30 to be fitted with the rotational force receiving part ( It is fixed to the inside of 21) and connected to the core bit (20).

In other words, the bit advance bolt 30 is rotated by a fixing bolt 40 that is screwed to the fastening part 31 while one side is supported by one side of the rotational force receiving part 21 by the support protrusion 32. It is supported on the other side of the receiving portion 21 is fastened to the rotational force receiving portion (21).

Here, between the fixing bolt 40 and the rotational force receiving portion 21, a friction preventing member 50 made of a bushing is further installed to prevent the frictional force from being transmitted to the fixing bolt 40 when the core bit 20 rotates. As a result, the bit advance bolt 30 has a structure that is fastened to the rotational force receiving portion 21, but since the friction preventing member 50 is installed therebetween, the rotational force of the core bit 20 is not transmitted.

Further, the fixing bolt 40 is formed in two and is screwed to the fastening part 31 of the bit forward bolt 30, so that the fixing bolt 40 is prevented from being loosened from the fastening part. That is, even if the fixing bolt 40 at the front is rotated and released, the fixing bolt 40 at the rear plays a role of tightening, so that it is not released through interaction.

In addition, the fixing bolt 40 has a polygonal bolt mountain formed at the outer periphery, and the outer periphery of the fixing bolt 40 is formed smaller than the periphery of the outer periphery of the rotational force receiving portion 21, so that the rotational power device 60 Does not interfere when connected to the rotational force receiving portion (21). That is, since the fixing bolt 40 is formed in the same shape in a straight line with the rotational force receiving part 21, when the rotational power device 60 is horizontally connected to the rotational force receiving part 21, the outer periphery of the fixing bolt 40 Since the flue may be interfered, the fixing bolt 40 is formed smaller than the rotational force receiving part 21.

The foreign material cover part 70 is installed at the end of the center rod 10 fixed to the anchor bolt 3, as shown in FIGS. 2 to 4 and 7 to 8, and the core bit 20 Blocks the inside of the core bit 20 to prevent foreign matters from being introduced into the core bit 20 and being pinched to the male threads of the center rod 10 when the core bit 20 is punctured.

Here, the foreign material cover part 70 is composed of a cover fastening part 71, a cover body part 72, and a cover connecting part 73, and the cover fastening part 71 is the end of the central bar 10 It is installed in the core bit 20 is formed orthogonal to the center rod 10 so as to contact the inner circumference of the core bit 20, the cover fastening portion 71 has a ring-shaped disk 74 is formed on the outer circumference, the disk 74 is formed to come into contact with the inner periphery of the core bit 20 to block the penetrating one side of the core bit 20, thereby preventing foreign substances such as dust and dust generated when the core bit 20 is punctured. Blocks so as not to flow into the inside of the core bit 20, thereby preventing foreign matters from being caught in the male thread of the center rod 10. At this time, the cover fastening portion 71 is formed in the form of a screw thread or a bolt thread on the inner periphery so as to be coupled to the male thread or bolt thread of the end of the central bar 10.

In addition, the disk 74 is formed on the outer periphery of the cover fastening portion 71, and is not formed integrally with the cover fastening portion 71, but is spaced apart to contact the inner periphery of the core bit 20 in a tight fitting manner. When coupled, the rotational force of the core bit 20 is not transmitted to the cover fastening portion 71.

In addition, the cover body portion 72 is fixed to the rear surface of the cover fastening portion 71 and the cover connection portion 73 to surround the outer periphery of the central rod 10, and the body of the cover body portion 72 The portion is formed in a bellows shape so as to be flexibly operated in the longitudinal direction of the central rod 10.

In addition, the cover connection part 73 is fixed to the end of the cover body part 72 and connected to one side of the bit advance bolt 30, at this time, the bit advance bolt 30 connected to the cover connection part 73 The insertion protrusion 35 is protruded so as to be inserted into the inside of the cover connection part 73, and the outer periphery of the insertion protrusion 35 has a rotational force when the bit advance bolt 30 rotates. ), a member such as a bushing is further formed so that it is not transmitted to the cover connection part 73. At this time, the cover connection part 73 is moved in the longitudinal direction of the center rod 10 by the rotation of the bit advance bolt 30, and at this time, the cover body part 72 can be moved while contracting and relaxing.

Hereinafter, the operation method of the core drill described above will be briefly described. First, the anchor hole 2 is excavated at the perforation point as described above, and the anchor hole 2 has a thread formed on one side of the anchor hole 2 exposed to the outside. Install the bolt (3). Then, the threaded portion of the anchor bolt 3 is screwed into the coupling groove 11 formed at the end of the central rod 10 to fix the central rod 10 to the anchor bolt 3.

Then, after screwing the bit forward bolt 30 to the outer periphery of the center rod 10, a core bit 20 is provided on the outer periphery of the bit forward bolt 30, at this time, the bit forward bolt 30 The core bit 20 is installed outside the bit advance bolt 30 so that the fastening part 31 of) penetrates and is exposed to the outside of the rotational force receiving part 21 of the core bit 20. At this time, the friction preventing member 50 is inserted between the bit advance bolt 30 and the rotational force receiving portion 21.

In addition, two fixing bolts 40 are screwed to the fastening part 31 of the bit forward bolt 30 exposed to the outside of the rotational force receiving part 21, and the fixing bolt 40 is a fastening part 31 ) While being screwed into close contact with one side of the rotational force receiving portion (21). At this time, a friction preventing member 50 made of a bushing is inserted between the fixing bolt 40 and the rotational force receiving part 21.

In such a fastened state as described above, after the rotational power device 60 is coupled to the rotational force receiving portion 21 of the core bit 20, the core bit 20 is rotated, and the operator uses a tightening tool such as a spanner or a wrench. In the state of being fastened to the fastening part 31 exposed to the outside of the rotational force receiving part 21, the bit advance bolt 30 moves along the center bar 10 and rotates the core bit 20 by the operation of the tightening tool. Move.

As described above, by moving the bit advance bolt 30, the core bit 20 is moved toward the concrete wall surface 1 to perform the drilling operation to perform drilling, and when the drilling work of the core bit 20 is completed, the bit By moving the forward bolt 30 to the opposite side to separate the core bit 20 from the concrete wall surface 1, the drilling work is completed.

10: center rod 11: coupling groove
12: through hole 13: communication hole
20: core bit 21: rotational force receiving portion
22: hall
30: bit forward bolt 31: fastening part
32: support protrusion 33: insertion hole
34: insertion groove 35: insertion protrusion
40: fixing bolt 50: friction preventing member
60: rotary power device 61: reducer
70: foreign material cover portion 71: cover fastening portion
72: cover body 73: cover connection
74: original plate
100: core drill

Claims (10)

It is integrally fixed to the anchor bolt 3 inserted into the anchor hole 2 of the perforation point, and a male thread is formed in the longitudinal direction at the outer periphery, and a polygonal bolt mountain is formed at the outer periphery of one or both ends, respectively. )and;
The central rod 10 is provided on the outer periphery of the central rod 10 so as to be exposed to the outside through the rotational force receiving portion 21 formed on one side, and connected to the rotational force receiving portion 21 A core bit (20) which is rotated to form a perforation in the perforation point;
It is screwed to the outside of the central rod 10 and moved in the longitudinal direction of the central rod 10, and the fastening portion 31 formed on one side passes through the rotational force receiving portion 21 of the core bit 20 and is exposed to the outside. By being connected to the core bit 20, a bit advance bolt 30 for pressing and moving the core bit 20 toward the concrete wall surface 1 so that the core bit 20 performs a drilling operation;
A fixing bolt 40 which is screwed to the fastening part 31 of the bit advance bolt 30 to connect the bit advance bolt 30 to the core bit 20;
When the core bit 20 is drilled by being installed at the end of the central bar 10 fixed to the anchor bolt 3 to block the inside of the core bit 20, foreign matter generated when the core bit 20 is punctured is prevented by the male thread of the central bar 10. Foreign matter cover part 70 to prevent being caught in the;
Core drill, characterized in that configured to include.
The method of claim 1,
The bit advance bolt 30 has a support protrusion 32 protruding from the outer periphery of the opposite side of the fastening part 31 to control the fastening part 31 to pass through the rotational force receiving part 21 and be exposed to the outside, The support protrusion 32 is supported on the inner side of the rotational force receiving portion 21 to control the exposed portion of the fastening portion 31.
The method of claim 2,
A friction preventing member 50 between the bit forward bolt 30 and the rotational force receiving part 21 in order to prevent the core bit 20 from being rubbed with the bit forward bolt 30 when rotating by the rotational power device 60. ) Core drill, characterized in that it is further installed.
The method of claim 2,
The fixing bolt 40 is screwed to the fastening part 31 of the bit advance bolt 30 and supported on one side of the rotational force receiving part 21, thereby allowing the bit advance bolt 30 to be inside the rotational force receiving part 21. Core drill, characterized in that to be fixed and connected to the core bit (20).
The method of claim 4,
Core drill, characterized in that the circumference of the fixing bolt 40 is formed smaller than the circumference of the rotational force receiving part 21 so that the rotational power device 60 does not interfere when connected to the rotational force receiving part 21.
The method of claim 1,
Core drill, characterized in that a coupling groove (11) having a female thread formed at an inner periphery is formed on one side or both end surfaces of the center rod (10) so that the male screw portion of the anchor bolt (3) is coupled.
The method of claim 1,
The rotational force receiving portion 21 is a core drill, characterized in that a polygonal bolt mountain or gear groove is formed on the outer periphery so that the rotational power device 60 is engaged to receive rotational force.
The method of claim 1,
The foreign material cover part 70,
It is coupled to an end of the center rod 10 to a male thread or a bolted thread, and is formed orthogonal to the center rod 10 so as to contact the inner periphery of the core bit 20 to block the penetrating one side of the core bit 20 A cover fastening part 71 that blocks foreign substances generated during perforation;
A cover body portion 72 fixed to the rear surface of the cover fastening portion 71 and formed to surround the outer periphery of the central rod 10, the body being flexibly operated in the longitudinal direction of the central rod 10;
A cover connection part 73 that is fixed to the end of the cover body part 72 and supported on one side of the bit advance bolt 30, and operates the cover body part 72 according to the movement of the bit advance bolt 30 ;
Core drill, characterized in that configured to include.
The method of claim 8,
Core drill, characterized in that a ring-shaped disk 74 is formed on the outer periphery of the cover fastening part 71 to block one side of the core bit 20 through contact with the inner periphery of the core bit 20 .
The method of claim 1,
The central rod 10 has through holes 12 formed therein so that both ends of the central rod 10 penetrate, and communication holes 13 communicating with the through holes 12 are formed in bolt mounts at both ends of the central rod 10. Core drill characterized by.

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