KR100597238B1 - Automatic production line for heat treatment apparatus for case-hardening - Google Patents

Abstract

The present invention relates to an automated production line for a surface hardening heat treatment, which comprises a rotating plate provided with a central axis in the form of a disk and rotatable about the central axis, A rotary member including at least four rotatable accommodating portions provided so that a portion thereof can be accommodated; A supply member which is provided at one side of any one of the accommodating portions and supplies the objects to be heated one by one so that a part of the object to be heated is received in the accommodating portion; And a connection part connected to the cooling water line, the connection part extending from one side of the heating part, and the connection part connecting the cooling water line to the heating part accommodated in the accommodation part, A high frequency induction heating member for applying high frequency heat to heat treatment; A cooling member provided at one side of the another accommodating portion for cooling the cooling water injected to the object heated by the high frequency induction heating member to cool the object; And a collecting member provided at one side of the another accommodating portion and collecting and collecting the object to be heated that has been cooled by the cooling member from the rotating member and is capable of high efficiency and high output, The space occupied by the apparatus can be reduced and the space can be utilized. In addition, since the object to be heated is automatically accommodated in the receiving portion in turn, is subjected to the high frequency heat treatment, cooled, and then collected and collected, The occurrence of defective products can be reduced, and the working environment can be greatly improved and the productivity can be improved.

High frequency, surface hardening, heat treatment, induction heating, rotating plate

Description

[0001] The present invention relates to an automatic production line for surface hardening heat treatment,

1 is a perspective view illustrating an automated production line for surface hardening heat treatment according to a preferred embodiment of the present invention.

2 is a partial cross-sectional view showing the internal structure of the housing of FIG. 1;

FIG. 3 is an enlarged perspective view of the alignment unit of FIG. 1; FIG.

4A and 4B are enlarged perspective views showing the operation of the supply unit of FIG. 1;

5 is an enlarged perspective view of the high frequency induction heating member;

6 is an enlarged perspective view of the collecting member;

Description of the Related Art

10: rotating member 11: rotating plate

111: center shaft 13: receiving portion

20: feeding member 21:

211: main body 212: vibration motor

213: spiral support 214: receiving groove

215: guide rail 216: supply pipe

23: supply part 231: closing plate

232: cylinder 30: high frequency induction heating member

31: Heating part 32: High frequency induction heating

33: connection part 34: cooling water line

40: cooling member 50: collecting member

51: air nozzle 52: air supply part

53: removal pipe 54: suction pipe

55: Vacuum suction motor

The present invention relates to an automated production line for surface hardening heat treatment.

In general, high-frequency and medium-frequency heat treatment is a surface hardening heat treatment, which is a method of selectively hardening a part of a component only, or a heat treatment method used for obtaining a heat treatment characteristic of a specific part. That is, the surface of the object to be heated is heated to a quenching temperature suitable for the material characteristics by using a high frequency induction heating method, and rapidly cooled to water or oil, thereby hardening the surface of the mechanical structural parts to improve wear resistance and mechanical properties. If necessary, it is heated by using various frequencies such as low frequency, medium frequency, and high frequency.

In the conventional high frequency surface hardening heat treatment apparatus, a vacuum tube type high frequency surface hardening heat treatment apparatus has a structure in which four accommodating sections are provided on the upper part of the housing. Four heaters are manually inserted into the accommodating section, After the heating, cooling, and again by the operator, the four objects to be heated are removed from the receiving portion and collected.

The conventional high-frequency surface-hardening heat treatment apparatus as described above is costly because of its high cost, and its electrical control is complicated, and the apparatus is very large and occupies a large space.

In addition, since the worker manually inserts the object to be heated and then removes it again, the worker must always work in an upright posture, thereby accumulating fatigue of the worker, resulting in a process dropout, The worker has a tendency to avoid his / her job and thus the productivity is decreased.

The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a high-efficiency and high- Which are housed in a receiving portion, are subjected to a high-frequency heat treatment, cooled and then collected and collected, thereby preventing the occurrence of process omission, reducing the generation of defective products, and greatly improving the work environment, The purpose of this is to provide an automated production line.

According to an aspect of the present invention, there is provided an automated production line for surface hardening heat treatment, comprising: a rotating plate having a central axis in a disc shape and rotatable about the central axis; A rotary member including at least four rotatable accommodating portions provided so that a part of the water can be accommodated; A supply member which is provided at one side of any one of the accommodating portions and supplies the objects to be heated one by one so that a part of the object to be heated is received in the accommodating portion; And a connection part connected to the cooling water line, the connection part extending from one side of the heating part, and the connection part connecting the cooling water line to the heating part accommodated in the accommodation part, A high frequency induction heating member for applying high frequency heat to heat treatment; A cooling member provided at one side of the another accommodating portion for cooling the cooling water injected to the object heated by the high frequency induction heating member to cool the object; And a collecting member provided at one side of the another accommodating portion for collecting and collecting the object to be heated cooled by the cooling member from the rotating member.

The supplying member may include an aligning portion and a supplying portion, and the aligning portion may include a body having a plurality of objects to be heated therein; A vibration motor disposed at a lower portion of the main body and generating vibration so that the main body vibrates along a circumferential direction; A spiral support provided on an inner wall of the main body to form a spiral toward an upper side of the main body; A receiving groove provided at an end of the helical support to receive a portion of the heated object guided along the helical support to align the heated object in a predetermined direction; A guide rail extending from the receiving groove for moving the object to be heated aligned by the receiving groove; And a supply pipe connected to the guide rail and supplying the object to be heated moved by the guide rail to the supply unit. The object to be heated contained in the body is moved by the vibration of the vibration motor to move the spiral support And a part of the object to be heated is received in the receiving groove, the object to be heated contained in the receiving groove is aligned in a predetermined direction and is moved to the feeding pipe by the guide rail, A closing plate that closes one end of the supply pipe and is disposed above the accommodating portion; Wherein when the closing plate is moved in one direction by the cylinder, the supply pipe and the accommodating portion are connected to each other, and a part of the object to be heated is connected to the accommodating portion, .

The collecting member may include an air nozzle provided at a lower portion of the containing portion in which the object to be heated cooled by the cooling member is accommodated, for jetting air; An air supply unit connected to the air nozzle to supply air to the air nozzle; A removal pipe disposed at an upper portion of the containing portion provided with the air nozzle at a lower portion thereof; A suction pipe connected to one side of the removing pipe and providing a vacuum suction force to the removing pipe; And a vacuum suction motor connected to the suction pipe to form a vacuum therein.

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

FIG. 1 is a perspective view showing an automated production line for surface hardening heat treatment according to a preferred embodiment of the present invention, FIG. 2 is a partial cross-sectional view for showing the internal structure of the housing of FIG. 1, 4 is an enlarged perspective view of the high frequency induction heating member, and FIGS. 4 (a) and 4 (b) are enlarged perspective views showing the operation of the supply unit of FIG. 1. FIG. 5 is an enlarged perspective view of the high frequency induction heating member, Is an enlarged perspective view of the member.

1, the automated production line for the surface hardening heat treatment of this embodiment comprises a rotating member 10, a feeding member 20, a high frequency induction heating member 30, a cooling member 40, and a collecting member 50 ).

In the present embodiment, the object to be heated A is a ball stud used as a part of an automobile and, as will be described below, it is not limited to a ball stud, and small parts such as bolts and pins can be widely used Of course.

The rotary member (10) comprises a rotary plate (11) and a receiving portion (13).

2, a motor 112 for rotating the central axis 111 of the rotary plate 11 is provided in the housing 60. The motor 112 is rotatably mounted on the rotary shaft 11, And is rotatable with respect to the housing 60 with respect to the center shaft 111. [

The receiving portion 13 is provided so that a part of the object A can be received along the edge on the upper surface of the rotating plate 11 and the center axis 131 is provided in the receiving portion 13 like the rotating plate 11 And the housing 60 is provided with a motor 132 for rotating the central axis 131 of the accommodating portion 13 so that the accommodating portion 13 rotates about the center axis 131 of the rotary plate 11, As shown in Fig.

In this embodiment, a groove is formed in the upper part of the receiving part 13 so that studs of the ball stud can be inserted. The shape of the receiving part 13 may vary depending on the shape of the object A to be inserted Of course.

The accommodating portion 13 is formed on the upper surface of the rotary plate 11 along at least four edges along its edge and is preferably a multiple of four, that is, four, eight, twelve, sixteen, twenty-four And the like. This is because the supply member 20, the high frequency induction heating member 30, the cooling member 40 and the collecting member 50 must be provided in the accommodating portion 13, respectively.

In the drawings of the present specification, sixteen storage portions 13 are provided on the rotary plate 11, but this is merely an embodiment. A supply member 20 is provided on one side of any one of the accommodating portions 13 and a receiving portion 13 provided on the fourth side in the counterclockwise direction with respect to the accommodating portion 13 provided with a supply member 20 Frequency induction heating member 30 which will be described later is provided on one side of the receiving portion 13 provided in the counterclockwise direction with respect to the receiving portion 13 provided with the high frequency induction heating member 30 on one side, A cooling member 40 to be described later is provided on one side of the receiving portion 13 provided on the first side in the counterclockwise direction with respect to the receiving portion 13 provided with the cooling member 40 on one side, Although it is shown that the collecting member 50 to be described is provided, this arrangement is only one embodiment, and various modifications can be made according to the embodiment.

The supply member 20 is provided on one side of one of the accommodating portions 13 and supplies the heated object A one by one so that a part of the target A is received in the accommodating portion 13. [

The supply member 20 is preferably composed of an alignment unit 21 and a supply unit 23.

3, the alignment unit 21 includes a main body 211, a vibration motor 212, a spiral support 213, a receiving groove 214, a guide rail 215, and a supply pipe 216 .

The main body 211 accommodates a plurality of objects A to be heated therein.

The vibration motor 212 is disposed at a lower portion of the main body 211 and generates vibration so that the main body 211 vibrates along the circumferential direction.

The spiral support 213 is provided on the inner wall of the main body 211 and is formed as a spiral toward the upper side of the main body 211.

The receiving groove 214 is provided at the end of the spiral support 213 so that a part of the object A to be heated guided along the spiral support 213 is received to align the object A in a predetermined direction. That is, in the present embodiment, the stud portion of the ball stud is received in the receiving groove 214 and vertically aligned so that the ball portion is located above.

The guide rail 215 extends from the receiving groove 214 and serves to move the object A aligned by the receiving groove 214.

The supply pipe 216 is connected to the guide rail 215 and supplies the heated object A moved by the guide rail 215 to the supply unit 23.

The object to be heated A accommodated in the main body 211 is moved upward along the spiral support 213 by the vibration of the vibration motor 212 to the upper part of the main body 211 (A stud of the ball stud in this embodiment) is accommodated in the receiving groove 214 and the object A accommodated in the receiving groove 214 is aligned in a predetermined direction, And is moved to the supply pipe 216 by the rail 215.

The supply section 23 includes a closing plate 231 and a cylinder 232, as shown in Fig.

The closing plate 231 closes one end of the supply pipe 216 and is disposed on the upper side of the accommodating portion 13, as shown in Fig. 4 (a).

The cylinder 232 is provided at one side of the closing plate 231 to move the closing plate 231 in one direction.

The opposite side of the closing plate 231 provided with the cylinder 232 on one side is supported by a spring 233.

4 (b), when the closing plate 231 is moved in one direction by the cylinder 232, the supply pipe 216 and the accommodating portion 13 are closed, And one side of the object A to be heated is received in the receiving portion 13.

5, the high-frequency induction heating member 30 includes a heating portion 31 and a connecting portion 33. The high-frequency induction heating member 30 includes a heating portion 31, A high frequency heat is applied to heat treatment.

The heating section 31 is disposed at the upper portion of the other accommodating section 13 and is connected to the high frequency induction heater 32. The high frequency induction heater 32 in this embodiment is a semiconductor type high frequency induction heater Open 32 is used.

The shape of the heating part 31 is configured such that one side is cut and the other side is arcuate so that the ball stud contained in the housing part 13 can easily pass through. The present invention is not limited thereto. In addition, although the heating portion 31 is located on both sides of the ball stud, since the receiving portion 13 is rotated and the ball stud is also rotated, the high frequency heat generated by the heating portion 31 is uniformly sprayed on the ball stud The ball stud surface can be evenly heat treated.

The connection part 33 extends from one side of the heating part 31 and is connected to the cooling water line 34 and functions to cool the connection part 33 by flowing cooling water into the cooling water line 34.

On the other hand, the cooling member 40 is provided at one side of the other accommodating portion 13 to cool the object A heated by the high frequency induction heating member 30 to cool it.

The collecting member 50 collects and collects the object A to be cooled, which is provided at one side of the other accommodating portion 13 and is cooled by the cooling member 40, from the rotating member 10, It is preferable to include the air nozzle 51 and the air supply part 52, the removal pipe 53, the suction pipe 54 and the vacuum suction motor 55 as shown in the figure.

The air nozzle 51 is provided in a lower portion of the accommodating portion 13 in which the object A cooled by the cooling member 40 is accommodated and ejects air.

The air supply unit 52 is connected to the air nozzle 51 and supplies air to the air nozzle 51. [

The removal pipe 53 is disposed on the upper side of the accommodation portion 13 provided with the air nozzle 51 at the lower portion thereof.

The suction pipe 54 is connected to one side of the removing pipe 53 to provide a vacuum suction force to the removing pipe 53.

The vacuum suction motor 55 is connected to the suction pipe 54 to form a vacuum therein.

Air is injected through the air nozzle 51 provided in the lower portion of the accommodating portion 13 so that the object A is moved upward from the accommodating portion 13 and at the same time, 54 to the removal pipe 53 so that the object A is moved upward from the receiving portion 13 so that the object A is separated from the receiving portion 13 And is collected through the removal pipe 53.

Hereinafter, the operation of the embodiment of the present invention having the above-described configuration will be described.

1 to 6, first, the supply member 20 is operated to supply the ball stud so that the stud of the ball stud is received in the receiving portion 13.

The operation of the supply member 20 will be described by the fact that the ball stud received in the main body 211 of the alignment part 21 moves upwardly of the main body 211 along the spiral support 213 by the vibration of the vibration motor 212 The bolster received in the receiving groove 214 is aligned in a predetermined direction and is moved to the supply pipe 216 by the guide rail 215. [ One end of the supply pipe 216 is closed by the closing plate 231 so that the bolster in the supply pipe 216 is not accommodated in the accommodating portion 13 and the closing plate 231 is biased by the cylinder 232 in one direction The supply pipe 216 and the receiving portion 13 are connected to each other and the stud of the ball stud is received in the receiving portion 13. [

Although the housing portion 13 in which the ball stud is accommodated is rotated and moved in one direction by the rotation of the rotating plate 11 and the rotating plate 11 is shown moving in the counterclockwise direction in the drawings of the present specification, Of course.

As described above, the accommodating portion 13, in which the ball stud is accommodated by the supply member 20, moves toward the high frequency induction heating member 30 in the counterclockwise direction by the rotation of the rotary plate 11. [ The accommodating portion 13 moved toward the high frequency induction heating member 30 is disposed in the lower portion of the heating portion 31 and the high frequency heat is applied to the heating portion 31 so that the bolster is heat treated and the accommodating portion 13 rotates The ball stud can be rotated together with the receiving portion 13 to be evenly heat treated on the surface of the ball stud.

The accommodating portion 13 containing the heat-treated ball stud is again moved toward the cooling member 40 by the rotation of the rotary plate 11. The cooling water of the cooling member 40 is injected into the accommodating portion 13 moved toward the cooling member 40 and cooled.

The receiving portion 13 containing the cooled ball stud is moved to the collecting member 50 by the rotation of the rotating plate 11 and the ball stud of the receiving portion 13 moved to the collecting member 50 Air is injected through the air nozzle 51 and the vacuum suction force is supplied through the upper suction pipe 54 to the removal pipe 53 to be collected and collected from the accommodation portion 13. [

In this case, the supply member 20 and the high frequency induction heating member 30 of the automated production line for the surface hardening heat treatment, Since the cooling member and the collecting member 50 are operated simultaneously, 1800 to 2000 ball studs can be heat-treated per hour.

It can be seen that, in the case of the heat treatment by the conventional manual work, the working speed is much faster than the case where 1200 ball studs are heat-treated per hour.

It will be apparent to those skilled in the art that various modifications may be made to the present invention without departing from the spirit and scope of the present invention as defined by the following claims Or modified.

According to the automated production line for the surface hardening heat treatment of the present invention as described above, the following effects can be obtained.

High-speed operation, high efficiency and high output are possible, resulting in improved productivity and miniaturization of the device, thereby reducing the space occupied by the device and utilizing the space.

In addition, since the object to be heated is automatically stored in the receiving part in a fully automatic manner, and is subjected to high-frequency heat treatment, cooled, and then collected and removed, it is possible to prevent the occurrence of process omission, reduce the generation of defective products, .

Claims (3)

A rotating plate provided with a central axis in the shape of a disk and provided so as to be rotatable about the central axis and at least four rotatable accommodating portions provided on the upper surface of the rotating plate so as to accommodate a part of the heated material along the edge, A rotary member; A supply member which is provided at one side of any one of the accommodating portions and supplies the objects to be heated one by one so that a part of the object to be heated is received in the accommodating portion; And a connection part connected to the cooling water line, the connection part extending from one side of the heating part, and the connection part connecting the cooling water line to the heating part accommodated in the accommodation part, A high frequency induction heating member for applying high frequency heat to heat treatment; A cooling member provided at one side of the another accommodating portion for cooling the cooling water injected to the object heated by the high frequency induction heating member to cool the object; And a collecting member provided at one side of the another accommodating portion for collecting and collecting the object to be heated cooled by the cooling member from the rotating member, The supplying member is composed of an aligning portion and a supplying portion, The alignment unit may include a body having a plurality of objects to be heated therein; A vibration motor disposed at a lower portion of the main body and generating vibration so that the main body vibrates along a circumferential direction; A spiral support provided on an inner wall of the main body to form a spiral toward an upper side of the main body; A receiving groove provided at an end of the helical support to receive a portion of the heated object guided along the helical support to align the heated object in a predetermined direction; A guide rail extending from the receiving groove for moving the object to be heated aligned by the receiving groove; And a supply pipe connected to the guide rail and supplying the object to be heated moved by the guide rail to the supply unit. The object to be heated contained in the body is moved by the vibration of the vibration motor to move the spiral support A part of the object to be heated is received in the receiving groove, the object to be heated contained in the receiving groove is aligned in a predetermined direction and is moved to the feeding pipe by the guide rail, Wherein the supply portion includes a closing plate that closes one end of the supply pipe and is disposed on the upper side of the accommodating portion; Wherein when the closing plate is moved in one direction by the cylinder, the supply pipe and the accommodating portion are connected to each other, and a part of the object to be heated is connected to the accommodating portion, Lt; / RTI > Wherein the collecting member includes an air nozzle provided at a lower portion of the containing portion in which the object to be heated cooled by the cooling member is accommodated, An air supply unit connected to the air nozzle to supply air to the air nozzle; A removal pipe disposed at an upper portion of the containing portion provided with the air nozzle at a lower portion thereof; A suction pipe connected to one side of the removing pipe and providing a vacuum suction force to the removing pipe; And a vacuum suction motor connected to the suction pipe to form a vacuum inside the automation production line. delete delete

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