KR102298529B1 - Chamfering Machine - Google Patents

Abstract

The present invention can effectively remove a burr by grinding the edge of a hole machined on the inner diameter of a hollow hollow structure such as a pipe, and effectively copes with the axial distance from the end of the hollow structure to the hole to perform chamfering It relates to an inner diameter chamfering device of a hollow structure that can, and the inner diameter chamfering device of a hollow structure according to the present invention, a driving unit for generating a rotational force; a driving shaft that receives rotational force from the driving unit and rotates about one axis; a rod-shaped fixed mount member connected to a lower end of the drive shaft and extending in a direction perpendicular to the drive shaft and inserted into the hollow portion of the hollow structure through one end of the hollow structure; a movable mount member installed to be movable in the longitudinal direction with respect to the fixed mount member in front of the fixed mount member; position fixing means for releasably fixing the movable mount member with respect to the fixed mount member; a drive shaft that is rotatably installed on the rear portion of the fixed mount member and has a shaft coupling hole in the center to which a lower end of the drive shaft is fitted and coupled to receive rotational force from the drive shaft and rotates; a driving pulley coupled to the driving shaft to rotate; a chamfer drill that is rotatably installed around a drill shaft at the front end of the movable mount member to cut the rim of the hole formed in the inner diameter of the hollow structure; a driven pulley coupled to the drill shaft within the movable mount member to rotate together with the drill shaft; and a power transmission belt wound around the driving pulley and the driven pulley to transmit the rotational force of the driving pulley to the driven pulley.

Description

Inner diameter chamfering device for hollow structures {Chamfering Machine}

The present invention relates to a chamfering device, and more particularly, to remove a burr generated from the inner diameter side of a hollow structure after drilling a hole from the outside of a hollow hollow structure such as a pipe. It relates to an inner diameter chamfering device of a hollow structure that can grind the inner periphery.

In general, it is known that a chamfering machine mainly used for rounding or chamfering the edge of a workpiece rotates the cutter by receiving electricity or rotating the cutter by receiving air.

Chamfering using such a chamfering machine cuts the edges of straight or curved parts of the material to form a uniform chamfer to trim the sharp edges that occur after material processing. It prevents the body from being damaged and makes the appearance of the machined parts beautiful.

The chamfering is usually done as the last processing step of the product, and the quality of the product depends on the chamfering quality, so attention is paid to increase the surface degree as much as possible to obtain a mirror-like clear and clean slope.

However, when the machined part is exposed to the outside, the chamfering operation is easily performed, but when the machined part is located inside the inner diameter of a hollow structure having a hollow portion such as a pipe, it is difficult to insert the chamfering tool into the inner diameter and work There is a difficult problem.

For example, if a hole is drilled using a drill from the outside of the pipe, a burr is generated on the edge of the hole in the inner diameter of the pipe. If the inner diameter of the pipe is small, a chamfering tool is inserted into the inner diameter It is difficult to remove the burr.

In order to solve this problem, in order to effectively remove the burr generated toward the inner diameter of the workpiece when the hole is machined from the side of the pipe-shaped workpiece to the inner diameter in Korean Patent Laid-Open No. 10-2005-0123076, a long bar-shaped drive transmission unit A timing belt connecting two timing pulleys and a timing pulley is installed at both ends of the arm, the shaft of one timing pulley is connected to the driving part to receive rotational force, and a chamfering drill is connected to the shaft of the other timing pulley and pipe An 'inner diameter chamfering machine' capable of removing burrs by inserting a chamfering drill into the inner diameter of the pipe through one end of the and grinding the edge of the hole machined on the inner diameter of the pipe by transmitting the rotational force of the driving unit is disclosed.

However, there is a problem in that it is difficult to cope with the position of the hole to be machined in the pipe, that is, the axial distance from the end of the pipe to the hole, because the conventional inner diameter beveler as disclosed in the above patent has a fixed length.

Republic of Korea Patent Publication No. 10-2005-0123076 (published on Dec. 29, 2005) Republic of Korea Patent No. 10-1672042gh (registered on October 27, 2016) Republic of Korea Patent No. 10-1057011 (Registered on Aug. 9, 2011)

The present invention is to solve the above-mentioned conventional problem, and an object of the present invention is to drill a hole from the outside of a hollow hollow structure such as a pipe, and then insert it into the hollow through one end of the hollow structure while inserting the inner diameter of the hollow portion It is possible to effectively remove the burr by grinding the edge of the hole machined in the hole, and to effectively cope with the axial distance from the end of the hollow structure to the hole to provide an inner diameter chamfering device of a hollow structure that can perform chamfering will be.

An inner diameter chamfering device of a hollow structure according to the present invention for achieving the above object, a driving unit for generating a rotational force; a driving shaft that receives rotational force from the driving unit and rotates about one axis; a rod-shaped fixed mount member connected to a lower end of the drive shaft and extending in a direction perpendicular to the drive shaft and inserted into the hollow portion of the hollow structure through one end of the hollow structure; a movable mount member installed to be movable in the longitudinal direction with respect to the fixed mount member in front of the fixed mount member; position fixing means for releasably fixing the movable mount member with respect to the fixed mount member; a drive shaft which is rotatably installed on the rear portion of the fixed mount member and has a shaft coupling hole in the center to which a lower end of the drive shaft is fitted and coupled to receive rotational force from the drive shaft and rotates; a driving pulley coupled to the driving shaft to rotate; a chamfered drill installed rotatably around a drill shaft at the front end of the movable mount member to cut the rim of the hole formed in the inner diameter of the hollow structure; a driven pulley coupled to the drill shaft in the movable mount member to rotate together with the drill shaft; and a power transmission belt wound around the driving pulley and the driven pulley to transmit the rotational force of the driving pulley to the driven pulley.

In the fixed mount member and the movable mount member, a first opening/closing cover and a second opening and closing cover for opening and closing a portion of the fixed mount member and the movable mount member for replacement of the power transmission belt when the length adjustment operation of the movable mount member with respect to the fixed mount member is performed The opening/closing cover may be detachably installed.

In addition, first and second elastic pads made of a flexible resin material for absorbing vibration while elastically contacting each other may be installed on surfaces of the first opening and closing cover and the second opening and closing cover facing each other.

The position fixing means, a plurality of fixing grooves arranged at regular intervals along the longitudinal direction of the fixed mount member, are installed to protrude inward in the radial direction on the movable mount member, and are inserted into the fixing grooves of the fixed mount member. At least one or more fixtures for fixing the movable mount member with respect to the fixed mount member, and elastically supporting the fixture with respect to the movable mount member so that when the movable mount member moves with respect to the fixed mount member, the fixture is the fixed groove It may include an elastic body so that it can be elastically inserted and detached inward and outward.

The inner diameter chamfering device of a hollow structure according to another aspect of the present invention may further include a balancing bar extending horizontally to the rear to the rear end of the fixed mount member to maintain the balance of the fixed mount member.

According to the present invention, the drive shaft is connected to the rear of the elongated rod-shaped fixed mount member and the chamfered drill is configured at the front end of the movable mount member to align the chamfered drill with the hole formed inside the hollow structure such as a pipe. It is possible to easily remove the burr remaining on the edge of the hole by transmitting the rotational force of the drive shaft to the chamfering drill through the driving pulley, the driven pulley, and the power transmission belt provided in the fixed mount member and the movable mount member.

In particular, the inner diameter chamfering device of the present invention can easily adjust the position of the chamfering drill by moving the movable mount member in the longitudinal direction with respect to the fixed mount member according to the position of the hole formed inside the hollow structure.

In addition, the inner diameter chamfering device of the present invention can be easily configured using an existing drilling machine.

1 is a side view showing an inner diameter chamfering device of a hollow structure according to an embodiment of the present invention.
Figure 2 is a perspective view showing the main configuration of the inner diameter chamfering device shown in Figure 1;
3A to 3C are cross-sectional views showing the main configuration of the inner diameter chamfering device shown in FIG. 1 .
4 is a bottom view of the inner diameter chamfering device shown in FIG.

The configuration shown in the embodiments and drawings described in this specification is only a preferred example of the disclosed invention, and there may be various modifications that can replace the embodiments and drawings of the present specification at the time of filing of the present application.

Hereinafter, the inner diameter chamfering device of the hollow structure will be described in detail according to the embodiments described below with reference to the accompanying drawings. In the drawings, like reference numerals denote like elements.

1 to 4 show an inner diameter chamfering device of a hollow structure according to an embodiment of the present invention, and the inner diameter chamfering device of the present invention can be applied to a known drilling machine.

The inner diameter chamfering device according to an embodiment of the present invention includes a driving unit 10 that generates a rotational force, a driving shaft 11 that receives rotational force from the driving unit 10 and rotates about one axis, and the driving shaft 11 of A fixed mount member 21 detachably coupled to the lower end, a movable mount member 22 movably installed in the longitudinal direction with respect to the fixed mount member 21 in front of the fixed mount member 21, the movable mount Position fixing means for releasably fixing the member 22 with respect to the fixed mount member 21, and is rotatably installed around the drill shaft 31 at the front end of the movable mount member 22 to form a hollow structure (P) ) is installed inside the chamfering drill 30, the fixed mount member 21 and the movable mount member 22 for cutting the edge of the hole (H) formed in the inner diameter of the driving shaft 11, the rotational force and a driving shaft 40 and a driving pulley 51 and a driven pulley 52 and a power transmission belt 53 for transmitting the to the drill shaft 31 of the chamfered drill 30 .

The driving unit 10 may be configured by applying a driving device applied to a known drilling machine, for example, a driving motor 12 and a reduction gearbox 16 for reducing the rotational speed of the driving motor 12 . It may include a power transmission unit consisting of a driving pulley 13 and a driven pulley 14 and a belt 15 for transmitting. The reduction gearbox 16 may be configured to be able to move up and down by manipulating the handle 17 .

The upper end of the drive shaft 11 is coupled to the reduction gear box 16 to receive rotational force. The drive shaft 11 rotates about an axis perpendicular to the ground.

A work table 18 on which the hollow structure P is placed is disposed below the drive shaft 11 . Here, the hollow structure P may be a pipe in which a hole H is perforated by a drilling operation. In addition, any hollow structure having a hollow portion having an open at least one side may be applied as a target thereof.

The fixed mount member 21 and the movable mount member 22 extend horizontally in a direction orthogonal to the drive shaft 11 (forward in this embodiment) to form a hollow structure through one end of the hollow structure P. It is inserted into the hollow part of (P).

The fixed mount member 21 has a hollow, hollow rod shape with an open front end, and the drive shaft 40 and the drive pulley 51 are installed at the rear end of the inside. The first opening/closing cover 23 for opening and closing the hollow part of the fixed mount member 21 at one side of the fixed mount member 21, in this embodiment, at the lower end thereof, is formed by a fastening means such as a screw 23a. Removably installed. The first opening/closing cover 23 is opened when replacing the power transmission belt 53 coupled to the driving pulley 51 of the fixed mount member 21 .

The movable mount member 22 is made of a hollow hollow rod shape with an open rear end and is moved while sliding in the longitudinal direction (front and rear direction) with respect to the fixed mount member 21 to adjust the length of the fixed mount member 21 . possible. Therefore, by adjusting the position of the movable mount member 22 according to the position of the hole (H) of the hollow structure (P) to be processed, the position of the chamfering drill 30 can be aligned to the position of the hole (H). .

A second opening/closing cover 24 for opening and closing the hollow portion of the movable mount member 22 is also detachably installed at the lower end of the movable mount member 22 by a fastening means such as a screw 24a. The second opening/closing cover 24 is opened when replacing the power transmission belt 53 coupled to the driven pulley 52 installed in the movable mount member 22 .

On the lower side of the front end of the movable mount member 22, a chamfered drill 30 for removing the burr remaining on the edge of the hole (H) of the inner diameter of the hollow structure (P) is centered on the drill shaft (31). is rotatably installed. The chamfered drill 30 is rotatably installed on the movable mount member 22 by the drill shaft 31 by the bearing 32 . The chamfering drill 30 is made of a substantially conical shape, and a blade is formed on the outer surface to cut the edge of the hole (H) formed in the inner diameter of the hollow structure (P).

The drill shaft 31 of the chamfer drill 30 is a drive shaft 11 through a drive pulley 51 installed on the drive shaft 40, a driven pulley 52 and a power transmission belt 53 installed on the drill shaft 31. ) is transmitted and rotates.

The drive shaft 40 is coupled to the inner rear portion of the fixed mount member 21 via a bearing 42 and freely rotates about an axis perpendicular to the ground. A shaft coupling hole 41 into which the lower end of the drive shaft 11 is inserted and coupled is formed in the center of the drive shaft 40 to be opened in the vertical direction. In the shaft coupling hole 41, the lower end of the drive shaft 11 is relatively rotated so that the rotational force of the drive shaft 11 can be reliably transmitted to the drive gear 40 after the lower end of the drive shaft 11 is inserted. Impossible connection is desirable. To this end, the lower end of the drive shaft 11 may have a polygonal cross-sectional shape such as a rectangle or a hexagon, and the shaft coupling hole 41 may also have a polygonal cross-sectional shape corresponding to the lower end of the drive shaft 11 .

The driving pulley 51 and the driven pulley 52 are coupled to an approximately intermediate height of the driving shaft 40 and the drill shaft 31 to rotate together with the driving shaft 40 and the drill shaft 31 .

The power transmission belt 53 is wound around the driving pulley 51 and the driven pulley 52 to transmit the rotational force of the driving pulley 51 to the driven pulley 52 , and a timing belt may be applied. The power transmission belt 53 is replaced with a different length according to the adjustment of the position of the movable mount member 22 with respect to the fixed mount member 21 . That is, when the movable mount member 22 moves in the longitudinal direction with respect to the fixed mount member 21 , the distance between the driving pulley 51 and the driven pulley 52 changes, so the power transmission belt 53 coupled thereto ) should also be replaced with one that matches the distance between the driving pulley 51 and the driven pulley 52 .

On the other hand, the position fixing means, a plurality of fixing grooves 25 arranged at regular intervals along the longitudinal direction of the fixed mount member 21, and the movable mount member 22 are installed to protrude inward in the radial direction, At least one fixed body 26 for fixing the movable mount member 22 with respect to the fixed mount member 21 while being inserted into the fixing groove 25 of the fixed mount member 21, and the movable mount member ( 22) by elastically supporting the fixed body 26 against the fixed mount member 21, the fixed body 26 is elastically inserted into and out of the fixed groove 25 when the movable mount member 22 is moved with respect to the fixed mount member 21. It includes an elastic body 27 that can be separated.

The fixed body 26 is in the form of a ball and is elastically inserted into or separated from the inside and outside of the fixing groove 25 according to the movement of the movable mounting member 22 to secure the movable mounting member 22 to the fixed mount member 21 . It is fixed so that it can be moved in position.

A compression coil spring may be applied to the elastic body 27, but a plate spring may be applied in addition to the compression coil spring.

In addition, as the movable mount member 22 is configured to be movable with respect to the fixed mount member 21 , there is a slight gap between the inner surface of the movable mount member 22 and the inner surface of the fixed mount member 21 . Therefore, when the chamfering drill 30 is rotated at high speed to perform the chamfering operation, vibration and noise may occur due to this gap.

Accordingly, as shown in FIG. 3A, the first opening and closing cover 23 and the second opening and closing cover 24 are made of a flexible resin material such as rubber or silicone so as to absorb vibration while elastically contacting each other on the surfaces facing each other. An elastic pad 28 and a second elastic pad 29 may be installed.

In addition, the fixed mount member 21 and the movable mount member 22 have a long rod shape, and since the drive shaft 11 is connected to the rear of the fixed mount member 21, the center of gravity is biased forward. Therefore, when the drive shaft 11 is rotated in this state to rotate the drive pulley 51, the driven pulley 52, and the chamfer drill 30, the fixed mount member 21 and the movable mount member 22 are subjected to vibration and Due to the noise, the chamfering of the hole (H) is not performed accurately, and defects may occur.

Accordingly, the balancing bar 70 is installed at the rear end of the fixed mount member 21 to the opposite side of the chamfered drill 30, that is, horizontally extended to the rear, and the center of gravity of the fixed mount member 21 is moved backward to balance Vibration and noise can be suppressed by maintaining A male screw portion 71 is formed at the front end of the balancing bar 70 , and may be helically coupled to the female screw hole 21a formed at the rear end of the fixed mount member 21 .

The inner diameter chamfering device configured as described above operates as follows.

When the hole (H) is drilled using a drill from the outside of the hollow structure (P), a burr occurs inwardly at the rim of the hole (H) in the inner diameter of the hollow structure (P). Thus, the hole (H) is seated on the perforated hollow structure (P) on the work table (18). At this time, as shown in Fig. 3a, the assembly of the fixed mount member 21 and the movable mount member 22 is inserted into the hollow portion of the hollow structure P through the open end of the hollow structure P. and align the lower end of the chamfered drill 30 with the hole (H) of the hollow structure (P).

In this state, when power is applied to the driving motor 12 of the driving unit 10 to rotate the driving shaft 11, the rotational force of the driving shaft 11 is generated by the driving shaft 40, the driving pulley 51, and the power transmission belt ( 53) and the driven pulley 52 are transmitted to the drill shaft 31, the chamfered drill 30 is rotated, and the rim of the hole (H) is cut from the inner diameter of the hollow structure (P) to remove the burr .

However, if the position of the hole (H) formed in the inner diameter of the hollow structure (P) is located deeper, the position of the chamfer drill 30 needs to be moved further to the front end. Accordingly, as shown in Fig. 3b, the first opening/closing cover 23 and the second opening/closing cover 24 of the fixed mount member 21 and the movable mount member 22 are sequentially separated to form a fixed mount member 21 and a movable mount. After opening the inside of the member 22 , the power transmission belt 53 is separated from the driving pulley 51 and the driven pulley 52 . At this time, in order to facilitate the separation of the power transmission belt 53, it is preferable to install the driven pulley 52 to the drill shaft 31 so that separation and coupling are possible.

After separating the power transmission belt 53 as described above, the position is adjusted by moving the movable mount member 22 in the longitudinal direction with respect to the fixed mount member 21 as shown in FIG. 3C . At this time, the fixing body 26 of the position fixing means is detached to the outside of the fixing groove 25, and is elastically inserted into the fixing groove 25 at the adjusted position, and the movable mount member 22 is fixed to the fixing mount member 21. ) to be fixed temporarily.

Then, the drive pulley 51 and the driven pulley 52 are replaced with a power transmission belt 53 suitable for the adjusted distance between the drive pulley 51 and the driven pulley 52 and wound around the driven pulley 51 and the driven pulley 52 .

As such, the inner diameter chamfering device of the present invention connects the drive shaft 11 to the rear of the elongated rod-shaped fixed mount member 21 and configures a chamfering drill 30 at the front end of the movable mount member 22 to form a pipe and It is possible to align the chamfering drill 30 to the hole (H) formed on the inside of the same hollow structure (P), and the driving pulley 51 provided inside the fixed mount member 21 and the movable mount member 22 ) and the driven pulley 52 and the power transmission belt 53 to transmit the rotational force of the drive shaft 11 to the chamfering drill 30, it is possible to easily remove the burr remaining on the edge of the hole (H).

In particular, the inner diameter chamfering device of the present invention moves the movable mount member 22 in the longitudinal direction with respect to the fixed mount member 21 according to the position of the hole (H) formed on the inside of the hollow structure (P) in the longitudinal direction for the chamfering drill ( 30) can be easily adjusted.

In the above, the present invention has been described in detail with reference to the embodiments, but those of ordinary skill in the art to which the present invention pertains may make various substitutions, additions and modifications within the scope not departing from the technical spirit described above. Of course, it should be understood that such modified embodiments also fall within the protection scope of the present invention as defined by the appended claims below.

P : Hollow structure H : Hole
10: drive unit 11: drive shaft
12: drive motor 21: fixed mount member
21a: female thread hole 22: movable mount member
23: first opening/closing cover 24: second opening/closing cover
25: fixing groove 26: fixing body
27: elastic body 28: first elastic pad
29: second elastic pad 30: chamfer drill
31: drill shaft 32: bearing
40: drive shaft 41: shaft coupling hole
42: bearing 51: drive pulley
52: driven pulley 53: power transmission belt
70: balancing bar 71: male thread part

Claims (5)

a driving unit for generating a rotational force;
a driving shaft that receives rotational force from the driving unit and rotates about one axis;
A fixed mount member made of a hollow rod shape with an open front end, connected to the lower end of the drive shaft, extending in a direction perpendicular to the drive shaft, and inserted into the hollow portion of the hollow structure through one end of the hollow structure ;
The rear end is made of a hollow rod shape with an open rear end, and the fixed mount member is installed to be inserted into the inner space through the rear end. a movable mount member;
position fixing means for releasably fixing the movable mount member with respect to the fixed mount member;
a drive shaft that is rotatably installed on the rear portion of the fixed mount member and has a shaft coupling hole in the center to which a lower end of the drive shaft is fitted and coupled to receive rotational force from the drive shaft and rotates;
a driving pulley coupled to the driving shaft to rotate;
a chamfer drill that is rotatably installed around a drill shaft at the front end of the movable mount member to cut the rim of the hole formed in the inner diameter of the hollow structure;
a driven pulley coupled to the drill shaft within the movable mount member to rotate together with the drill shaft; and,
a power transmission belt wound around the driving pulley and the driven pulley to transmit the rotational force of the driving pulley to the driven pulley;
including,
In the fixed mount member and the movable mount member, a first opening/closing cover and a second opening and closing cover for opening and closing a portion of the fixed mount member and the movable mount member for replacement of the power transmission belt when the length adjustment operation of the movable mount member with respect to the fixed mount member is performed The opening/closing cover is installed detachably,
The inner diameter chamfering device of a hollow structure in which the first and second elastic pads made of a flexible resin material for absorbing vibrations while elastically contacting each other are installed on surfaces of the first opening and closing cover and the second opening and closing cover facing each other. delete delete According to claim 1, wherein the position fixing means, a plurality of fixing grooves arranged at regular intervals along the longitudinal direction of the fixed mount member, the movable mount member is installed to protrude inward in the radial direction of the fixed mount member At least one or more fixtures for fixing the movable mount member to the fixed mount member while being inserted into the fixing groove, and elastically supporting the fixture with respect to the movable mount member when moving the movable mount member with respect to the fixed mount member An inner diameter chamfering device of a hollow structure including an elastic body that allows the fixing body to be elastically inserted and separated into and out of the fixing groove. The inner diameter chamfering device of claim 1, further comprising a balancing bar extending horizontally to the rear end of the fixed mount member to maintain the balance of the fixed mount member.

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