KR102237947B1 - Vent hole processing device for wheel disk - Google Patents

Abstract

The present invention includes a lower mold having a piercing die with a perforated groove formed on an upper surface thereof, a rotating support part supporting the wheel disk to be processed in a seated state, and a pushing guide bar having a straight bar structure extending vertically downward at the lower part. The upper mold is provided with a coupling and has a perforation punch that is inserted to correspond to the perforation groove when moving in the lower mold direction.When the upper mold moves downward toward the lower mold direction, it is in contact with the bottom surface of the pushing guide bar in a horizontal direction by the pushing guide bar. When the upper mold moves upward so that the upper mold is separated from the lower mold and the contact with the lower surface of the pushing guide bar is released, the pushing guide bar returns to the initial position before being pushed by the pushing guide bar. The sliding moving part and the sliding moving part are pushed in the horizontal direction by the pushing guide bar while the sliding moving part and the sliding moving part are pushed in the horizontal direction by the pushing guide bar in the opposite direction by the elastic force. When it is pushed by an elastic force in the direction opposite to the direction pushed by the pushing guide bar to return to the initial position before being pushed by the pushing guide bar, a rotation that generates a rotational force of a certain angle by receiving the horizontal pushing moving force from the sliding moving part. It provides a vent hole processing apparatus for a wheel disk including a generating unit and a rotation transmitting unit for transmitting the rotational force generated by the rotation generating unit to the rotation support unit.

Description

Vent hole processing device for wheel disk}

The present invention relates to a vent hole processing apparatus, and more particularly, to a vent hole processing apparatus for a wheel disk for drilling a vent hole in a wheel disk of a vehicle.

In general, a wheel disk constitutes a wheel on which a tire of a vehicle is mounted, and is mounted on the inside of a cylindrical rim on which the tire is mounted to support the rim.

In more detail, the rim is a part to which the tire is directly mounted, and is formed into a cylindrical shape by sheet metal made of steel or aluminum alloy, and is mounted on the inside of the tire. Then, the wheel disk is mounted on the inside of the rim. The wheel disk shields the inner side of the rim and supports the rim so that it does not deform, and is formed in a shape corresponding to the shape of the inner side of the rim.

Meanwhile, the wheel disk is coupled while surrounding the brake disk installed on the axle so that the wheel rotates with the rotation of the axle so that the wheel can rotate and can be braked by the wheel disk.

As such, a wheel disk and a brake pad are mounted inside the rim, and considerable heat is generated due to contact between the wheel disk and the brake pad during braking. In order to discharge the heat to the outside, a plurality of vent holes are formed in the wheel disk.

In the bend hole forming operation of the wheel disk, a vent hole is formed in the wheel disk disposed on the lower mold by a punch while the upper mold moves downward. At this time, the wheel disk is formed after one vent hole is formed. After the operator manually changes the position of the wheel disk, the upper mold is moved downward and the work of forming the vent hole by punch is repeatedly performed.

However, since the operator has to change the position of the wheel disk manually, there is a problem in working time and work safety, and a bend hole processing device of the wheel disk that rotates the wheel disk using a driving device such as a motor is used. However, there is a problem in that manufacturing cost and maintenance cost are largely required because a driving device that consumes separate energy must be provided.

The technology related to the vent hole processing apparatus for a wheel disk is presented in Korean Patent Publication No. 10-2008-0012720 (2008.02.12) and Korean Patent Registration No. 10-0770796 (2007.10.22).

The present invention enables processing without a drive device that requires separate energy consumption to change the position of the wheel disk when forming a vent hole in the wheel disk, thereby reducing manufacturing cost and maintenance cost. It is an object to provide a hole processing device.

In the present invention, a lower mold having a piercing die having a perforated groove formed on an upper surface thereof, a rotating support part connected to the upper part of the lower mold and supporting the wheel disk to be processed in a seated state, so as to face the lower mold The upper mold, which moves vertically and reciprocally in the arranged state, and has a pushing guide bar having a straight bar structure so as to extend vertically downward at the lower part, and having a perforation punch inserted corresponding to the perforation groove when moving in the lower mold direction, the It is connected and installed on the upper part of the lower mold so that it is placed under the pushing guide bar, and when the upper mold moves downward toward the lower mold, it is pushed horizontally by the pushing guide bar in a state in contact with the bottom surface of the pushing guide bar, and the upper mold When the state of contact with the bottom of the pushing guide bar is released while moving upward so as to be spaced apart from the lower mold, it is returned to the initial position before being pushed by the pushing guide bar by the elastic force in the opposite direction to the direction pushed by the pushing guide bar. It is installed to be connected to the sliding moving part, the lower mold and the sliding moving part, and the sliding moving part is pushed in the horizontal direction by the pushing guide bar while the sliding moving part is in contact with the bottom surface of the pushing guide bar. When the contacting state of is released and it is pushed by an elastic force in the opposite direction to the direction pushed by the pushing guide bar to return to the initial position before being pushed by the pushing guide bar, the horizontal pushing moving force is transmitted from the sliding moving part and A vent hole processing device for a wheel disk including a rotation generating unit that is generated by a rotational force, a rotation transmission unit that is installed on the lower mold to connect the rotation generation unit and the rotation support unit, and transmits the rotational force generated from the rotation generation unit to the rotation support unit Provides.

In addition, the upper portion of the lower mold is provided with a coupling and a rotating plate body through which a rotating shaft is mounted so as to be axially rotatable, and the rotating support part is coupled to the end of the rotating shaft of the rotating plate body in a state in which the wheel disk is seated on the upper surface, and , The outer circumferential surface may include a rotating plate in the shape of a disk in which locking grooves are formed at regular intervals, and a locking fixing part installed on the rotating plate body and selectively inserted into the locking groove to fix the rotating plate.

In addition, the sliding movement unit is installed to be connected to the upper part of the lower mold so as to be slidably moved, and installed on the upper part of the lower mold so as to be connected to the moving block and the moving block that slides when the pushing guide bar moves downward, and the moving block is elastically moved. It may include a block elastic support member to support.

In addition, a first pushing inclined surface inclined from the bottom to the top is formed on the bottom of the pushing guide bar, and a second pushing inclined surface inclined to be symmetrical to the first pushing inclined surface is formed on the surface portion opposite to the first pushing inclined surface of the moving block. Can be formed.

In addition, the rotation generator is rotatably connected and installed on the upper part of the lower mold, a latch wheel having latch grooves formed at regular intervals on the outer circumferential surface, and rotatably connected to the sliding movable part, and one end is inserted into the latch groove A latch detent that rotates while pushing the latch wheel according to the reciprocating movement of the sliding part. It is connected to the upper part of the lower mold and is inserted into the latch groove to fix the rotated latch wheel by the latch detent. May include government.

In addition, the rotation transmission unit is a rotation connection shaft connected to the upper part of the lower mold so as to be axially rotatable, and connecting one end of the rotation connection shaft to a rotation generation unit to transmit the rotational force generated by the rotation generation unit to the rotation connection shaft. It may include a side rotation coupling part, a rear rotation coupling part connecting the other end of the rotation connection shaft and the rotation support part to transmit the rotational force of the rotation connection shaft to the rotation support part.

In the vent hole processing apparatus for a wheel disk according to the present invention, when the upper mold is moved in the direction of the lower mold, the vent hole is processed at the initial position of the wheel disk by a punching punch, and when the upper mold is moved upward, the sliding moving part The latch wheel of the rotation generator is rotated through the movement of the moving block. In this way, rotation of the latch wheel causes the rotation plate of the rotation support part that seats and supports the wheel disk to be rotated through the rotation transmission part. Since the position of the wheel disk can be easily changed so that the vent hole processing is performed, the processing operation is performed while minimizing energy consumption with a simple structure.

1 is a cross-sectional view showing the configuration of a vent hole processing apparatus for a wheel disk according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing the configuration of a vent hole processing apparatus for a wheel disk according to an embodiment of the present invention.
3 is a plan view of a sliding moving part and a rotation generating part shown in FIG. 1.
FIG. 4 is a front view showing a sliding moving part and a rotation generating part shown in FIG. 3.

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

1 is a cross-sectional view showing the configuration of a vent hole processing apparatus for a wheel disk according to an embodiment of the present invention. Referring to FIG. 1, a vent hole processing apparatus for a wheel disk according to an embodiment includes a lower mold 100, a rotation support part 200, an upper mold 300, a sliding moving part 400, a rotation generating part 500, It is provided with a rotation transmission unit 600.

The lower mold 100 is disposed to face each other with the upper mold 200 to be described later, so that a vent hole is formed in the wheel disk 10 to be processed which is disposed between the upper mold 300 and the upper mold 300. In the upper part of the lower mold 100, the piercing die 110 for forming a vent hole in the wheel disk 10 while allowing the perforation punch 320 to be correspondingly inserted when the upper mold 200 moves downward is fixed. It is equipped with a combination. Here, on the upper surface of the piercing die 110, a perforation groove 111 is formed extending downward so that a perforation punch 320 can be inserted correspondingly.

Further, a rotating plate body 120 for connecting and supporting a rotating support part 200 to be described later is coupled to the upper part of the lower mold 100 in a fixed state. That is, the rotating plate body 120 enables the rotating plate 210 of the rotating support part 200 to be rotatably connected and supported, as well as the locking fixing part 220 of the rotating support part 200 in a connected state. Here, the upper surface of the rotating plate body 120 has a rotating plate inclined surface 122 inclined downward from one side to the other so that the rotating plate 210 is mounted in an inclined manner. In addition, inside the rotating plate body 120, a rotating shaft 121 for rotating the rotating plate 210 by receiving a rotational force from the rotating transmission unit 600, which will be described later, is rotatably mounted in a penetrating state. Such, the rotation shaft 121 is disposed vertically on the upper surface of the rotation plate body 120, and a bearing member 123 is coupled to the inside of the rotation plate body 120 so that the rotation shaft 121 can be rotatably connected. In addition, a bearing member 124 is coupled to the rotating plate body 120 so that the rotating plate 210 of the rotating support part 200 can be rotatably connected.

In addition, the upper part of the lower mold 100 is guided to slide the moving block 410 of the sliding moving part 400 to be described later, and the block elastic support member 420 can be combined and installed, and rotation occurs. A drive generation guide 130 is coupled to allow the unit 500 to be installed to be connected to the sliding moving unit 400. The drive generation guide 130 has a box-shaped structure with an upper side open, and a movable block 410 is slidably inserted therein. In addition, a block elastic support member 420, a latch wheel 510 of the rotation generating unit 500, a latch detent 520, and a latch fixing part 530 are coupled to the driving generation guide 130. Here, at one side of the driving generation guide 130, a latch rotation shaft 131 is coupled to be axially rotatable so as to rotatably connect the latch wheel 510 to each other.

In addition, a wheel interference prevention groove 140 is formed on the upper surface of the lower mold 100 so as not to cause interference with the upper surface when the wheel disk 10 seated on the rotation support part 200 is rotated.

The rotation support part 200 is a part that supports the wheel disk 10 in a seated state. That is, the rotation support part 200 supports the wheel disk 10 on the rotation plate body 120 of the lower mold 100 so as to be rotatable and maintains the rotated position in a fixed state. Referring to FIG. 2, the rotation support part 200 is connected to the upper part of the rotating body 120 of the lower mold 100 and includes a rotating plate 210 and a locking part 220.

The rotating plate 210 is a plate portion having a circular horizontal cross-sectional shape that fixes the wheel disk 10 in a seated state. The rotating plate 210 is rotatably seated and disposed on the upper surface of the rotating plate body 120, and the bottom surface of the rotating plate 210 is fixedly coupled to one end of the rotating shaft 121 of the rotating plate body 120. Here, the upper surface of the rotating plate 210 is formed to have a shape corresponding to the opposite surface portion of the wheel disk 10 so as to fix the wheel disk 10 in a seated state, and a groove portion formed in the wheel disk 10 A fixing protrusion (not shown) inserted to correspond to may be formed to protrude. At this time, the upper surface of the rotating plate 210 is formed to have a diameter smaller than the diameter of the wheel disk (10).

In addition, a plurality of locking grooves 211 are formed on the outer circumferential surface of the rotating plate 210 at regular intervals. This, the locking groove 211 allows the locking portion 220 to be locked in a connected state to the rotating plate 210 while the rotating plate 210 is fixed in a locking state by the locking portion 220. At this time, the locking groove 211 receives the rotational force from the rotation transmission unit 600 in the locking state by the locking fixing unit 220, and the locking state of the locking fixing unit 220 is easily released when the rotating plate 210 is rotated. It is formed in a semicircular shape so that the rotating plate 210 can be rotated again. In addition, the locking groove 211 is a position corresponding to the position of forming the bent hole of the wheel disk 10 so that the vent hole processing portion of the wheel disk 10 stops while being located at the piercing die 110 of the lower mold 100 Is formed in, and the number of the locking grooves 210 is formed as much as the number corresponding to the number of vent holes to be formed.

The locking fixing part 220 is a part for fixing the rotating plate 210 in a locking state in a state in which the rotating plate 210 is rotated by receiving a rotational force from the rotation transmitting part 600. That is, the locking fixing part 220 is installed on the upper surface of the rotating plate body 120 of the lower mold 100 and is selectively inserted into the locking groove 210 of the rotating plate 210 to become a fixed state. 210) the changed position of the wheel disk 10 disposed on it is fixed. Such, the locking fixing unit 220 is installed a pair to be disposed on both sides with respect to the center of the rotating plate 210 so that the rotating plate 210 can be stably fixed, but not limited thereto, one or three or more may be installed. Of course there is. Here, the locking fixing unit 220 includes a detent body 221, a detent 222, and an elastic support member 223.

The detent body 221 is a portion having a rectangular parallelepiped shape that allows the detent 222 and the detent elastic support member 223 to be inserted and installed inside. An insertion and installation groove (221a) is formed on one side of the detent body 221 to insert and install the locking detent 222 and the engaging elastic support member 223. In addition, the bottom of the detent body 221 is fixedly installed on the upper surface of the rotating plate body 120.

The locking pawl 222 is a bar portion that is inserted and installed so as to be slidably moved into the insertion and installation groove 221a of the pawl body 221. Such, the locking stop 222 is arranged to be in contact with the outer circumferential surface of the rotating plate 210 in a state that is elastically supported by the locking elastic support member 223, and when the end is inserted into the locking groove 211 of the rotating plate 210 , The rotating plate 210 is fixed so as not to be rotated in a locked state. Here, the front end of the locking stop 222 is formed in a conical shape so that it can be easily inserted into the locking groove 211 and detached from the locking groove 211 when the rotating plate 210 is rotated.

The locking elastic support member 223 elastically supports the locking pawl 222 to keep the tip of the locking pawl 222 in contact with the outer circumferential surface of the rotating plate 210. Such, the elastic support member 223 is inserted and installed in the insertion and installation groove (221a) of the detent body 221 so as to be connected to the rear end of the detent (222). Here, as the locking elastic support member 223, a compression spring is selectively used.

The upper mold 300 is a mold portion disposed to face the lower mold 100. That is, the upper mold 300 is disposed to face vertically above the lower mold 100, and is installed to be reciprocally moved in the vertical direction through a moving force generated by a separate moving means (not shown). When the upper mold 300 moves downwardly adjacent to the lower mold 100, a vent hole is punched and molded in the wheel disk 10 through the perforated groove 111 of the piercing die 110, and the lower mold ( When moving upward to return to the original position after moving downward adjacent to 100), the sliding movement unit 400, which will be described later, is slid in the front-rear direction while generating a rotational force by the rotation generating unit 500.

And, when moving downward so as to be adjacent to the lower mold 100 in the lower part of the upper mold 300, the wheel disk 10 is inserted to correspond to the perforated groove 111 formed in the piercing die 110 of the lower mold 100. ), a punching punch 320 for punching and molding a vent hole is coupled to extend downward. In addition, a stripper 330 for fixing the wheel disk 10 in a pressurized state is provided at the bottom of the upper mold 300 by punching and forming a vent hole in the wheel disk 10 through the punching punch 320. .

In addition, in the lower part of the upper mold 300, when moving downwardly adjacent to the lower mold 100, the sliding moving part 400 is pushed and moved, and the upper mold 300 slides upward so that it returns to its original position. It includes a pushing guide bar 310 that releases the pushed state so that the moving part 400 can be returned to its original position. The push guide bar 310 has a straight bar structure, and is coupled to the upper mold 300 so as to extend vertically downward. At this time, a first pushing inclined surface 311 inclined from the bottom to the top is formed on a surface portion of the pushing guide bar 310 opposite to the lower mold 100, that is, on the bottom of the pushing guide bar 310.

When the sliding moving part 400 moves the upper mold 300 downwardly adjacent to the lower mold 100, it is pushed by the pushing guide bar 310 of the upper mold 300, and the upper mold ( When moving 300) upwardly to be spaced apart from the lower mold 100, it is a part that elastically returns to the initial position. This, the sliding movement unit 400 generates a linear motion through the movement of the upper mold 300, and the rotational force can be generated in the rotation generating unit 500, which will be described later, through the linear motion. 3 and 4, the sliding moving part 400 is installed on the upper part of the lower mold 300 and includes a moving block 410 and a block elastic support member 420.

The movable block 410 is a portion having a hexahedral shape installed on the upper part of the lower mold 100 so as to be slidably moved. That is, the moving block 410 is inserted and installed on the drive generation guide 130 of the lower mold 100 so as to be slidably moved, and when the upper mold 300 is moved downward, the pushing movement is made by the pushing guide bar 310. You lose. One surface of the movable block 410, more specifically, the surface of the movable block 410 opposite to the first sloping surface 311 of the movable block 410 is inclined to be symmetrical to the first sloping surface 311 A second jungle slope 411 is formed. Therefore, the moving block 410 is gradually pushed in one direction while the first sliding inclined surface 311 of the sliding guide bar 310 is in contact with the second sliding inclined surface 411 when the upper mold 300 moves downward. You lose.

The block elastic support member 420 is an elastic member that elastically supports the moving block 410. When the upper mold 300 moves downward, the block elastic support member 420 elastically supports the moving block 410 in a direction opposite to which it is pushed by the pushing guide bar 310. Here, the block elastic support member 420 is coupled to the drive generation guide 130 of the lower mold 130, and the end of the block elastic support member 420 is coupled to be connected to one side of the moving block 410. The block elastic support member 420 uses a gas spring, but is not limited thereto.

When the rotation generating unit 500 pushes and moves the moving block 410 of the sliding moving unit 400 according to the vertical movement of the upper mold 300, the sliding guide bar 410 is elastically returned to its original position. , It is a part that generates rotational force at a certain angle. The rotation generating unit 500 is installed to be connected to the driving generation guide 130 of the lower mold 100 and the moving block 410 of the sliding moving unit 400. 3 and 4, the rotation generator 500 includes a latch wheel 510, a latch detent 520, and a latch fixing part 530.

The latch wheel 510 is installed to be connected to the drive generation guide 130 of the lower mold 100 so as to be axially rotatable, and in more detail, the central part is fixedly installed at the end of the latch rotation shaft 131 in a connected state. . The latch wheel 510 has a disk shape, and latch grooves 511 are formed on the outer circumferential surface at regular intervals. Here, the latch groove 511 is formed by a latch protrusion 512 formed in the shape of a saw blade on the outer circumferential surface of the latch wheel 510. At this time, the latch protrusion 512 is formed in a substantially saw blade-like shape. Accordingly, the latch wheel 510 may be rotated by the latch detent 520, and at this time, the latch detent 520 rotates the latch wheel 510 while pushing the latch protrusion 512 into a latched state.

In addition, the latch groove 511 formed on the outer circumferential surface of the latch wheel 510 is formed equal to the number of locking grooves 211 formed on the rotating plate 210 of the rotation support part 200, Accordingly, the rotating plate 210 can be rotated by the same angle. Here, the number of the latch grooves 511 and the locking grooves 211 is formed in the same number or proportional to the number of vent holes to be processed, so that the rotation plate 210 is rotated by a certain angle according to the rotation of the latch wheel 510. It is fixed after rotation so that the vent hole can be formed at the correct position.

In addition, a latch connection key groove 513 is formed in the latch wheel 510 to be connected to the side rotation coupling part 620 of the rotation transmission part 600 to be described later.

The latch detent 520 is a part that rotates while pushing the latch wheel 510 while moving corresponding to the movement of the moving block 410 of the sliding moving part 400. The latch detent 520 is connected and installed to be axially rotatable to one side of the moving block 410 of the sliding moving part 400. In addition, one end of the latch detent 520 is disposed to be inserted into the latch groove 511 of the latch wheel 510. One end of the latch detent 520 is caught by the latch protrusion 512 when the latch wheel 510 is pushed through the movement of the moving block 410 while being inserted into the latch groove 511, and the latch wheel ( When the pushed state by 510 is released, a rounded locking end 521 is formed to protrude so that it can easily move to the next latch groove 511 along the inclined surface of the latch protrusion 512.

The latch fixing part 530 is a part for fixing the latch wheel 510 rotated at a predetermined angle by the latch detent 520 in a locked state. That is, the latch fixing part 530 is connected and installed to one side of the drive generation guide 130 of the lower mold 100 and is selectively inserted into the latch groove 511 of the latch wheel 510 to be fixed. Here, the latch fixing part 530 includes a latch fixing body 531, a latch fixing stop 532, and a fixed elastic support member 533.

The latch fixing body 531 is a part having a rectangular parallelepiped shape that allows one side of the fixed elastic support member 533 to be inserted and installed. A locking installation groove 531a is formed on one side of the latch fixing body 531 so that one side of the fixing elastic support member 533 can be inserted and installed. In addition, the latch fixing body 531 is coupled to one side of the driving generation guide 130 of the lower mold 100 in a fixed state.

The latch fixing detent 532 is connected to one side of the driving generation guide 130 of the lower mold 100 so as to be axially rotatable. The latch fixing detent 532 is disposed so as to be in contact with the outer circumferential surface of the latch wheel 510 while being elastically supported by the fixed elastic support member 533, and is once in the latch groove 511 of the latch wheel 510. When additionally inserted, the latch wheel 510 is fixed so that it is not rotated in a locked state. Here, one end of the latch fixing detent 532 is curved so that it can be easily separated from the latch groove 511 along the latch protrusion 512 when inserted into the latch groove 511 and rotates the latch wheel 510. A fixed end 532a having a semicircular cross-sectional shape made of is formed. At this time, a detent engaging groove 532b is formed on one side of the latch fixing detent 532 to insert and engage the end of the fixed elastic support member 533.

The fixed elastic support member 533 elastically supports the latch fixing pawl 532 to keep one end of the latch fixing pawl 532 in contact with the outer circumferential surface of the latch wheel 510. The fixed elastic support member 533 is inserted and installed inside the locking installation groove 531a of the latch fixing body 531 so as to be connected to one side of the latch fixing stop 532. Here, as the fixed elastic support member 533, a compression spring is selectively used.

The rotation transmission part 600 is a part that transmits the rotational force generated by the rotation generation part 500 to the rotation support part 200. That is, the rotation transmission unit 600 transmits the rotational force generated by the latch wheel 510 of the rotation generation unit 500 to the rotation shaft 121 of the rotation plate body 120, and the rotation plate 210 of the rotation support unit 200 To be able to rotate. Here, the rotation transmission unit 600 includes a rotation connection shaft 610, a side rotation coupling portion 620, and a rear rotation coupling portion 630.

The rotation connection shaft 610 is a shaft portion connected to and installed on the upper part of the lower mold 100 so as to be axially rotatable. One end in the longitudinal direction of the rotation connection shaft 610 is connected to the latch wheel 510 of the rotation generation unit 500 through the side rotation coupling part 620, and the other end in the longitudinal direction of the rotation connection shaft 610 is rear side. It is connected to the rotation shaft 121 of the rotating plate body 120 through the rotation coupling part 630. At this time, a rotation connection key groove 611 may be formed on an outer surface of one end in the longitudinal direction of the rotation connection shaft 610.

The ship-side rotation coupling part 620 is a part that transmits the rotational force generated by the latch wheel 510 of the rotation generating part 500 to the rotation connection shaft 610. The ship-side rotation coupling part 620 connects one end in the longitudinal direction of the rotation connection shaft 610 to the latch wheel 510 of the rotation generating part 500. Here, the side rotation coupling part 620 applies a parallel key, so that the parallel key is inserted into the latch connection key groove 513 of the latch wheel 510 and the rotation connection key groove 611 of the rotation connection shaft 610, and the latch The rotational force of the wheel 510 may be transmitted to the rotation connection shaft 610.

The rear rotation coupling part 630 is a part that transmits the rotational force transmitted to the rotation connection shaft 610 to the rotation shaft 121 of the rotation plate body 120. The rear rotation coupling part 620 connects the other end in the longitudinal direction of the rotation connection shaft 610 and the other end of the rotation shaft 121 of the rotation plate body 120. Here, the rear rotation coupling unit 630 selects and uses a universal joint.

The vent hole processing operation of the wheel disk according to the vent hole processing apparatus for a wheel disk according to an embodiment configured as described above will be described as follows.

First, the wheel disk 10 to be processed is fixedly disposed on the rotating plate 210 of the rotation support part 200 in a seated state, and then the upper mold 300 is moved downward in the direction of the lower mold 100.

Then, first, after the perforation punch 320 of the upper mold 300 passes through the wheel disk 10, while being inserted into the perforation groove 111 formed in the piercing die 110 of the lower mold 100, the wheel disk 10 ), a vent hole is formed.

As such, when the upper mold 300 moves downward, the moving part 410 of the sliding moving part 400 is pushed to the rear by the pushing guide bar 310 of the upper mold 300.

Then, the latch detent 520 of the rotation generating unit 500 is inserted into the latch groove 511 disposed at the next position with respect to the clockwise direction of the latch wheel 510 and is locked.

In such a state, when the upper mold 300 moves upward and the pushing of the moving block 410 by the pushing guide bar 310 is released, the moving block 410 through the elastic force of the block elastic support member 420 is It moves to return to the original position. In addition, the lower end of the perforation punch 320 of the upper mold 300 is also separated from the perforation groove 111 of the lower mold 100. When the moving block 410 moves back to the initial position, the latch detent 520 also moves correspondingly and pushes the latch wheel 510 through which the latch wheel 510 rotates by a certain angle in the counterclockwise direction. , The latch wheel 510 is held and fixed by the latch fixing part 530 again.

In this way, the rotational force generated by the latch wheel 510 is transmitted from the front rotational coupling portion 620 of the rotation transmission unit 600 to the rotational connection shaft 610, and then through the rear rotational coupling portion 630. The rotation shaft 121 of the 120 is rotated at a predetermined angle.

In this way, while the rotating shaft 121 rotates, the rotating plate 210 of the rotating support part 200 is also rotated at a predetermined angle to correspond thereto, and then fixed to the locking state by the locking pawl 222 of the locking fixing part 220 Keep.

As the rotating plate 210 rotates, the wheel disk 10 is also rotated correspondingly, so that the above-described operation is sequentially performed several times, and the processing is completed so that the vent holes are formed in the wheel disk 10 at regular intervals. You will be able to.

As described above, in the vent hole processing apparatus for a wheel disk according to an embodiment, when the upper mold 300 is moved in the direction of the lower mold 100, the vent hole processing at the initial position of the wheel disk 10 by the punching punch 320 When the upper mold 300 is moved upward again, the latch wheel 510 of the rotation generating unit 500 is rotated through the movement of the moving block 410 of the sliding moving unit 400. In this way, the rotation of the latch wheel 510 causes the rotation plate 210 of the rotation support part 200 to seat and support the wheel disk 10 through the rotation transmission part 600 to rotate, and then the upper mold 300 When moving downwards, the position of the wheel disk 10 can be easily changed so that the other vent hole processing in the wheel disk 10 by the punching punch 320 is performed at a position rotated at a certain angle, so energy consumption is reduced with a simple structure. It allows machining operations to be carried out while minimizing.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: lower mold 110: piercing die
111: drilling groove 120: rotating plate body
121: rotation shaft 130: drive generation guide
200: rotation support 210: rotation plate
220: jam fixing part 300: upper mold
310: jungle guide bar 320: punching punch
330: stripper 400: sliding moving part
410: second-class block 420: block elastic support member
500: rotation generator 510: latch wheel
520: latch detent 530: latch fixing unit
600: rotation transmission unit 610: rotation connection shaft
620: side rotational coupling portion 630: rear rotational coupling portion

Claims (6)

A lower mold having a piercing die having a perforated groove formed on an upper surface thereof;
A rotation support part connected to the upper part of the lower mold and supporting the wheel disk to be processed in a seated state;
It moves vertically and reciprocally in a state arranged to face the lower mold, and a pushing guide bar having a straight bar structure so as to extend vertically downward is coupled to the lower part, and a punching punch inserted to correspond to the drilling groove when moving in the lower mold direction An upper mold provided;
It is connected and installed on the upper part of the lower mold so as to be disposed under the pushing guide bar, and when the upper mold moves downward toward the lower mold, it is pushed in the horizontal direction by the pushing guide bar in a state in contact with the bottom surface of the pushing guide bar, and the upper part When the mold moves upward so that it is separated from the lower mold again and the state of contact with the bottom of the pushing guide bar is released, the elastic force is applied in the opposite direction to the direction pushed by the pushing guide bar to return to the initial position before being pushed by the pushing guide bar. A sliding moving part that is pushed and moved by;
It is installed to be connected to the lower mold and the sliding part, and the sliding part is pushed in a horizontal direction by the pushing guide bar while the sliding part is in contact with the bottom surface of the pushing guide bar, and then pushed while the contact with the pushing guide bar's bottom is released. When it is pushed by an elastic force in the direction opposite to the direction pushed by the pushing guide bar to return to the original position before being pushed by the guide bar, a rotational force that is generated by a rotational force of a certain angle by receiving the horizontal pushing moving force from the sliding part is generated. part; And
A vent hole processing apparatus for a wheel disk comprising: a rotation transmission unit installed on a lower mold to connect the rotation generation unit and the rotation support unit, and transmitting the rotational force generated by the rotation generation unit to the rotation support unit. The method according to claim 1,
The upper part of the lower mold is provided with a coupling body with a rotating shaft mounted therethrough so as to be axially rotatable,
The rotation support part,
A disk-shaped rotating plate with locking grooves formed at regular intervals on the outer circumferential surface of the rotating shaft end of the rotating plate body while fixing the wheel disk in a seated state on the upper surface,
A vent hole processing apparatus for a wheel disk that is installed on the rotating plate body and includes a locking portion that is selectively inserted into the locking groove to fix the rotating plate. The method according to claim 1,
The sliding moving part,
A moving block that is connected and installed to be slidably moved to the upper part of the lower mold, and moves pushed when the pushing guide bar moves downward,
A vent hole processing apparatus for a wheel disk comprising a block elastic support member installed on the upper part of the lower mold to be connected to the moving block and elastically supporting the moving block. The method of claim 3,
A first sliding inclined surface inclined from the bottom to the top is formed on the bottom of the pushing guide bar,
A vent hole processing apparatus for a wheel disk in which a second sliding inclined surface is formed on a surface of the moving block opposite to the first inclined inclined surface so as to be symmetric with the first inclined inclined surface. The method according to claim 1,
The rotation generating unit,
A latch wheel that is rotatably connected and installed on the upper part of the lower mold and has latch grooves formed at regular intervals on the outer circumferential surface thereof,
A latch detent that is rotatably connected to and installed to the sliding movable part, and has one end inserted into the latch groove to rotate while pushing the latch wheel according to the reciprocating movement of the sliding movable part; and
A vent hole processing apparatus for a wheel disk including a latch fixing part connected to the upper part of the lower mold and configured to fix a latch wheel rotated by a latch detent while being inserted into the latch groove. The method according to claim 1,
The rotation transmission unit,
A rotary connection shaft connected to and installed on the upper part of the lower mold so as to be axially rotated,
A ship-side rotation coupling part that connects one end of the rotation connection shaft to the rotation generation part and transmits the rotational force generated by the rotation generation part to the rotation connection shaft, and
A vent hole processing apparatus for a wheel disk comprising a rear rotation coupling part connecting the other end of the rotation connection shaft and the rotation support part to transmit the rotational force of the rotation connection shaft to the rotation support part.

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