KR101649423B1 - Apparatus for electrochemical discharge machining - Google Patents

Abstract

A machining apparatus using electrolytic discharge machining is disclosed.
A holder cover which can contain an electrolytic solution therein and includes an inlet capable of supplying an electrolytic solution and an outlet capable of discharging the electrolytic solution and sealed so that the electrolytic solution does not flow out to the outside when the outlet or outlet is closed; And a tool holder fixed to one side of the holder cover and exposed to the outside of the holder cover in a state where the tool electrode is mounted on the other side so as to process the workpiece, Since the workpiece is transported to the machining position of the workpiece, no additional power for position control is required, and a precise position control device is not required because the tool holder is processed by the length of the tool electrode exposed to the outside of the holder cover using the spring inside the tool holder. In addition, the structure is simple and portable and easy to use.

Description

[0001] APPARATUS FOR ELECTROCHEMICAL DISCHARGE MACHINING [0002]

The present invention relates to a machining apparatus using electrolytic discharge machining. More particularly, when a tool electrode is placed in an electrolytic solution and a voltage is applied, a spark is generated around the tool electrode. An electrolytic discharge To a processing apparatus using processing.

Electrolytic discharge machining involves connecting the (+) and (-) poles to the electrode and the tool in the electrolyte. When the voltage is applied, spark occurs in the tool through electrical and chemical reactions. It is a method to remove the material. It is a suitable method for machining nonconductive materials such as glass and ceramics with little tool wear.

Conventional electrolytic discharge machining apparatuses include a method of controlling the position of a tool electrode using a separate transfer mechanism and a method of making a workpiece contact a tool electrode with a constant force using a pulley without a transfer mechanism.

However, such a conventional machining method requires a motor and various sensors for position control of the feed mechanism, and various devices such as a driver for controlling the same are additionally required. Therefore, it is difficult to move or carry the processing apparatus and it is limited by space. In addition, since the workpiece to be processed is put into the electrolytic water bath, it is difficult to process the workpiece when the size of the workpiece is large.

Korean Patent Publication No. 2002-0087258

According to one aspect of the present invention, there is provided a machining apparatus using electrolytic discharge machining, comprising: a holder cover capable of holding an electrolyte solution; a holder cover having one side fixed and a tool electrode mounted on the other side, And a tool holder provided so as to be able to process a workpiece.

Another aspect of the present invention is to provide a method of manufacturing a workpiece by using electrolytic discharge machining in which the machining apparatus is moved to the upper surface of the workpiece, the end of the tool electrode mounted on the tool holder coincides with the machining position, And provides a processing method.

According to an aspect of the present invention, there is provided a processing apparatus using electrolytic discharge machining, the apparatus including an inlet capable of supplying the electrolytic solution and an outlet capable of discharging the electrolytic solution, the outlet or outlet being closed And the tool electrode is exposed to the outside of the holder cover in a state where the tool electrode is mounted on the other side of the holder cover so that the workpiece can be processed. The tool holder may be provided with a tool holder.

The holder cover has a semi-cylindrical shape capable of holding the electrolyte, and a counter electrode is provided on a bottom surface of the holder cover. The bottom surface of the holder cover has a bottom surface in contact with the workpiece, And a plate made of an elastic material may be provided to prevent leakage to the outside.

The tool holder includes a wire in the tool holder so that a voltage can be applied to the tool electrode, and a spring is provided in the tool holder, so that the tool electrode connected to one end of the spring can be pressed in the vertical lower direction .

According to another aspect of the present invention, there is provided a method of manufacturing a spark plug, comprising: moving a processing device, which is a combination of a holder cover having a counter electrode inside and a tool holder equipped with a tool electrode, to the upper surface of a workpiece, It is possible to process the workpiece by using heat of the workpiece.

In addition, the counter electrode and the tool electrode are located in the electrolyte, and power can be applied to both the counter electrode and the tool electrode by a power supply device.

In addition, moving the machining apparatus to the upper surface of the workpiece may place the tip of the tool electrode exposed to the outside of the holder cover at the machining position of the workpiece.

The machining of the workpiece using the heat of the spark causes the workpiece to melt due to the heat of the spark and the tool electrode mounted on the tool holder and exposed to the outside of the holder cover is advanced in the vertical lower end direction The workpiece can be processed.

The tool electrode connected to one end of the spring inside the tool holder can press the workpiece in the vertical lower end direction and process the workpiece by the length of the tool electrode exposed to the outside of the holder cover.

Further, it is possible to process the workpiece with the end of the tool electrode exposed to the outside of the holder cover, and move the position of the machining apparatus to process it into a desired shape.

Further, the machining is performed by the length of the tool electrode exposed to the outside of the holder cover, the tool electrode is separated from the workpiece, the machining device is moved in the direction to be machined, .

According to one aspect of the present invention, the machining apparatus is manually moved to match the machining position of the workpiece with the end of the tool electrode exposed to the outside of the holder cover, so that no separate power and mechanism for position control is required, It is possible to perform electrolytic discharge machining regardless of the size of the workpiece because it is processed to the tip of the tool electrode exposed to the outside of the electrolytic water bath.

In addition, it is possible to manually move the position of the processing device during electrolytic discharge machining to process the workpiece in a desired shape.

1 is a configuration diagram of a machining apparatus using electrolytic discharge machining according to an embodiment of the present invention.
2 is a view for explaining a shape of a machining apparatus using electrolytic discharge machining.
3 is a conceptual diagram of a machining apparatus using electrolytic discharge machining according to an embodiment of the present invention.
4 is a view showing a method of machining a workpiece with a tool electrode having one side mounted on the tool holder shown in Fig.
5 is a view showing a method of processing a workpiece by electrolytic discharge machining according to another embodiment of the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

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

Fig. 1 is a configuration diagram of a machining apparatus using electrolytic discharge machining according to an embodiment of the present invention, and Fig. 2 is a diagram for explaining a shape of a machining apparatus using electrolytic discharge machining.

Electrolytic discharge machining is one of the special processing methods applying the electrode effect generated during the electrolytic action. When a voltage exceeding a predetermined threshold value is applied to the two electrodes located in the electrolyte, hydrogen gas generated around the negative electrode forms an electrical insulating film through bonding. As soon as the insulating film thus formed completely cuts off the contact between the electrode and the electrolytic solution, a spark due to gas discharge is generated, and machining can be performed using the thermal energy of the spark.

The machining apparatus 100 using electrolytic discharge machining includes a holder cover 10 capable of holding the electrolyte solution 30 therein so as to perform the above operation, a tool holder 40 fixed to the holder cover 10, A tool electrode 50 having one side mounted to the tool holder 40 and exposed to the outside of the holder cover 10 and a counter electrode 60 inserted into the bottom surface of the holder cover 10 .

The holder cover 10 has a semi-cylindrical shape capable of holding the electrolyte solution 30 therein. The holder cover 10 may be formed into a shape having a central portion penetrated to fix and mount the tool holder 40. The holder cover 10 includes at least one inlet 20 capable of supplying the electrolyte 30 into the inside thereof and at least one outlet 25 capable of discharging the electrolyte 30 to the outside, The amount of the electrolytic solution 30 can be controlled. The holder cover 10 has a counter electrode 60 and an electric wire on the bottom surface of the holder, and a voltage can be applied to the counter electrode 60 through the electric wire. The holder cover 10 has a plate 70 made of an elastic material on the bottom surface of the outside and a plate 70 made of an elastic material is used so that when the working device 100 contacts the upper surface of the work 90, It is possible to minimize the outflow of the electrolyte 30 in the holder cover 10 to the outside of the holder cover 10 where the electrode 50 is exposed. The holder cover 10 is made of a transparent material so that the end of the tool electrode 50 of the tool holder 40 fixed to the holder cover 10 is positioned at the machining position 95 of the workpiece 90, It can be visually confirmed through the cover 10 and when the position is not correct, the machining position 100 can be moved again to match the end of the tool electrode 50 with the machining position 95.

On the other hand, the tool holder 40 is inserted and fixed to the center portion of the holder cover 10, and the tool electrode 50 is mounted on one side of the tool holder 40 to limit the horizontal movement of the tool electrode 50 And the tool electrode 50 can be moved in the vertical direction. Further, the tool holder 40 is made of an insulating material so that no reaction occurs with the electrolytic solution 30 during electrolytic discharge machining. The tool holder 40 has a joining portion to be engaged with one side of the tool electrode 50 and the joining portion includes a spring (not shown) so that the tool electrode 50 can be pressed in the vertical direction, The workpiece 90 can be machined by the length of the tool electrode 50 exposed to the outside.

The electrolytic solution 30 can be supplied and discharged using a circulating pump through an inlet 20 and an outlet 25 of the holder cover 10 using a basic aqueous solution and the inlet 30 of the holder cover 10 The electrolytic solution 30 can be supplied to the outside through the discharge port 25 when the electrolytic solution 30 is contained in the holder cover 10 or the processing operation is completed. Can be discharged. In addition, the electrolytic solution 30 can smoothly flow current between the tool electrode 50 and the counter electrode 60 during electrolytic discharge machining, so that electrolysis and discharge phenomenon can be easily caused.

The tool electrode 50 is mounted on the tool holder 40 having one side inserted into the center portion of the holder cover 10 and the other side exposed to the outside of the holder cover 10, It can be connected to the wire and receive the voltage. The tool electrode 50 may be made of a metal material such as tungsten or copper which is strong against heat and has high strength. The shape of the tool electrode 50 may be a cylindrical shape , Blade type, taper type, V shape, and the like. In the electrolytic discharge machining, the tool electrode 50 is electrically and chemically reacted with the counter electrode 60, and as the reduction reaction occurs in the tool electrode 50, a spark is generated, and the generated heat is used So that the workpiece 90 can be machined into the shape of the tool electrode 50. The tool electrode 50 has a force in the vertical direction due to a spring (not shown) inside the tool holder 40. The tool electrode 50 can be pressed by using this force, The workpiece 90 can be machined by the length of the tool electrode 50 projected to the workpiece 90. [

The counter electrode 60 is one of the metals that are relatively difficult to dissolve in the electrolyte 30, which is a basic aqueous solution, and platinum, gold, and silver may be used. The counter electrode 60 is smaller than or equal to the bottom surface size of the inside of the holder cover 10 so as to be inserted into the bottom surface of the holder cover 10 and connected to the electric wire provided inside the holder cover 10, Can be applied. During the electrolytic discharge machining, the counter electrode (60) undergoes an electrical and chemical reaction with the tool electrode (50), and at this time, the counter electrode (60) may undergo an oxidation reaction.

3 is a conceptual diagram of a machining apparatus using electrolytic discharge machining according to an embodiment of the present invention.

The tool electrode 50 is prepared according to the machining shape to be machined, and the prepared tool electrode 50 can be mounted on one side of the tool holder 40. At this time, the shape of the tool electrode 50 can be varied in a cylindrical shape, a blade shape, a tapered shape, or the like.

The tool holder 40 on which the tool electrode 50 is mounted is inserted and engaged with the center portion of the holder cover 10 so that when the holder cover 10 is moved to the machining position 95 of the workpiece 90, (40) can also be moved together.

The tool holder 40 can also process the workpiece 90 by the length of the tool electrode 50 exposed to the outside of the holder cover 10 using a spring (not shown) inside the tool holder 40.

The machining apparatus 100 in which the holder cover 10 and the tool holder 40 are combined is moved to the machining position 95 of the workpiece 90 and the end of the tool electrode 50 exposed to the outside of the holder cover 10 To the machining position 95 of the workpiece 90. [

The electrolyte solution 30 is supplied into the holder cover 10 through the inlet 20 of the holder cover 10 and the tool electrode 50 and the counter electrode 60 are supplied with the electrolyte 30, do. When the supply of the electrolyte solution 30 is completed, the inlet 20 can be sealed to prevent the electrolyte solution 30 in the holder cover 10 from flowing out.

At this time, the portion of the holder cover 10 from which the tool electrode 50 is exposed is held by the holder cover 10 by the elastic plate 70 provided on the bottom surface of the holder cover 10, It is possible to prevent leaking to the outside.

On the other hand, the tool electrode 50 and the counter electrode 60 are accommodated one side by the electrolyte 30 supplied through the inlet 20 and the other side is electrically connected through the electric wire of the power supply device 80. The power supply device 80 applies electrolytic discharge machining by applying a (-) voltage to the tool electrode 50 side and a (+) voltage to the counter electrode 60 side, and hydrogen gas is generated in the tool electrode 50 , And an oxidation reaction may occur in the counter electrode (60).

At this time, when the voltage applied from the power supply device 80 is increased, the hydrogen gas generated from the tool electrode 50 forms an electrical insulating film through bonding, and the insulating film formed thereon forms a gap between the tool electrode 50 and the electrolyte 30 The contact is completely cut off, sparks due to gas discharge are generated, and the workpiece 90 can be machined by the tool electrode 50 using the generated heat of the spark.

FIG. 4 is a view showing a method of machining a workpiece using a tool electrode having one side mounted on the tool holder shown in FIG. 3;

The length of the tool electrode 50 exposed to the outside of the holder cover 10 coincides with the depth of machining of the machining position 95 and the tool electrode 50 is displaced by the spring (not shown) of the tool holder 40, The machining position 95 of the tool electrode 90 is pressed in the vertical direction. When the electrolytic discharge machining is started, the machining position 95 can be melted by the heat of the spark generated at the tip of the tool electrode 50.

The tool electrode 50 can be processed by advancing by using the force in the vertical lower end direction of the spring (not shown) provided in the tool holder 40 by melting the workpiece 90 by using the heat of the spark generated.

At this time, the distance that the tool electrode 50 advances in the vertical lower end direction may coincide with the length of the tool electrode 50 exposed to the outside of the holder cover 10.

5 is a view showing a method of processing a workpiece by electrolytic discharge machining according to another embodiment of the present invention.

A processing apparatus 100 including a holder cover 10 capable of holding an electrolyte 30 therein and a tool holder 40 having one side fixed to the holder cover 10 and a tool electrode 50 mounted on the other side, The electrode 30 is supplied and a voltage is applied to the counter electrode 60 and the tool electrode 50 by using the power supply device 80 to perform electrolytic discharge machining Can be performed.

At this time, by moving the position of the machining apparatus 100 during electrolytic discharge machining, the workpiece 90 having a desired shape can be machined according to the direction in which the machining apparatus 100 moves.

More specifically, when a desired shape is to be machined, such as drawing a gold in a predetermined direction with respect to the workpiece 90, machining or cutting a groove, or the like, the machining position of the workpiece 90 is changed by the length of the tool electrode 50 exposed to the outside of the holder cover 10 The tool electrode 50 of the machining apparatus 100 is extracted from the machining position 95 when machining is completed. Then, the machining apparatus 100 is moved in the direction to be machined, the end of the tool electrode 50 is matched with the next machining position 95, and then electrolytic discharge machining is started again. If this process is repeated, the desired shape of the workpiece 90 can be processed. At this time, the length of the tool electrode 50 exposed to the outside of the holder cover 10 may coincide with the depth of the shape to be processed.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be appreciated by those skilled in the art that various other modifications and variations can be made without departing from the spirit and scope of the invention, Are all within the scope of the appended claims.

100: Processing device

Claims (10)

In a processing apparatus using electrolytic discharge machining,
A holder cover which can contain an electrolytic solution therein and includes an inlet capable of supplying the electrolytic solution and an outlet capable of discharging the electrolytic solution and sealed so that the electrolytic solution does not flow out to the outside when the inlet or the outlet is closed; And
Wherein the holder cover is fixed at one side thereof and the other side thereof is equipped with a tool electrode and the tool electrode is adapted to process the machining position when the machining apparatus is moved to the machining position of the workpiece, Processing equipment using machining. The method according to claim 1,
Wherein the holder cover has a semi-cylindrical shape capable of containing the electrolyte, and a counter electrode having a voltage applied to a bottom surface of the holder cover,
And a bottom surface of the holder cover is provided with a plate made of an elastic material to prevent the electrolyte from flowing out to the outside when the workpiece is brought into contact with the workpiece. The method according to claim 1,
Wherein the tool holder has an electric wire therein so that a voltage can be applied to the tool electrode,
And a spring is provided in the tool holder to press the tool electrode connected to one end of the spring in a vertical downward direction. A machining device having a tool holder with a tool electrode mounted thereon is moved to the upper surface of the workpiece,
Supplying the electrolytic solution to the machining apparatus so that the tool electrode and the counter electrode can be stacked by the electrolytic solution,
And applying a voltage to the tool electrode and the counter electrode to generate a spark to process the workpiece. 5. The method of claim 4,
Wherein the counter electrode and the tool electrode are located in an electrolyte and power is applied to both the counter electrode and the tool electrode by a power supply device. 5. The method of claim 4,
Moving the machining device to the upper surface of the workpiece,
Wherein an end of the tool electrode is placed at a machining position of the workpiece. 5. The method of claim 4,
Applying a voltage to the tool electrode and the counter electrode to generate a spark to process the workpiece,
Wherein the workpiece is melted due to the heat of the spark, and the tool electrode advances in the vertical lower end direction to process the workpiece. 8. The method of claim 7,
Wherein the tool electrode connected to one end of the spring inside the tool holder presses the workpiece in the vertical lower end direction and processes the workpiece by the length of the tool electrode. 5. The method of claim 4,
Wherein the workpiece is machined at an end of the tool electrode, and the position of the machining apparatus is moved to a desired shape. 10. The method of claim 9,
Processing is performed by electrolytic discharge machining in which machining is performed by the length of the tool electrode, the tool electrode is separated from the workpiece, the machining apparatus is moved in a direction to be machined, Way.

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