KR102295173B1 - An apparatus of electrodeposition for manufacturing multi-layer diamond electrodeposited micro tool and a method for manufacturing multi-layer diamond electrodeposited micro tool using thereof - Google Patents

Abstract

The present invention relates to an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool and a manufacturing method for manufacturing a multi-layer diamond electrodeposition microtool using the same. More particularly, the present invention relates to an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool and a manufacturing method for manufacturing a multi-layer diamond electrodeposition microtool using the same, which can provide a long tool life and perform a self-sustaining operation by evenly dispersing diamond particles and controlling the floating state of the diamond particles to electrodeposit a diamond electrodeposited layer in multiple layers.

Description

An apparatus of electrodeposition for manufacturing multi-layer diamond electrodeposited micro tool and a method for manufacturing multi-layer diamond electrodeposited micro tool using thereof}

The present invention relates to an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool and a manufacturing method for manufacturing a multi-layer diamond electrodeposition microtool using the same. It relates to an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool having a long tool life and capable of self-sustaining action by controlling the electrodeposition of a diamond electrodeposition layer in multiple layers, and a manufacturing method for manufacturing a multi-layer diamond electrodeposition microtool using the same.

Diamond electrodeposition micro-tools used for precision processing of ceramic material parts used in semiconductors and displays are required for more precise processing as the industry is active in high integration and high-precision research.

In general, diamond electrodeposition is performed by adding diamond particles in a plating solution, placing a plating material such as nickel and a substrate such as a micro tool in the plating solution, and applying an anode and/or a cathode to the plating material and the object to be coated with the plating material. It can be made through an electrodeposition process of electrically forming a film on the surface of the object, and by this process, diamond particles can be electrodeposited on the shank, which is the body of the micro tool. Microtools with diamond particles electrodeposited have excellent productivity and can be re-deposited, so they have excellent economic feasibility.

In the electrodeposition process, a horizontal electrodeposition technique of horizontally electrodepositing diamond particles with respect to the shank is widely used. Since it is configured in a shape having an obtuse-angled protrusion, there is a problem in reducing the workability of the tool.

In addition, the current electrodeposition technology for electrodeposition of diamond particles is at a level that can electrodeposit diamond particles in a single layer, and the single-layer electrodeposition technology is not suitable for electrodeposition of diamond particles on micro-tools with fine and complex special shapes. ), the tool life is short because autogenous action is not possible, so the related technology is urgently needed.

The present invention provides an electrodeposition device for manufacturing a multi-layer diamond electrodeposition microtool with a long tool life and a self-sustaining action by evenly dispersing diamond particles and controlling the floating state of the diamond particles to electrodeposit the diamond electrodeposition layer in multiple layers, and a multi-layer diamond electrodeposition device using the same - An object of the present invention is to provide a manufacturing method for manufacturing a layer diamond electrodeposition microtool.

In order to solve the above problems, the present invention provides an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool, comprising: an electrodeposition tank in which a plating solution and diamond particles floating in the plating solution are accommodated; a plating material disposed inside the electrodeposition tank; The shank of the micro tool to be manufactured is disposed, the rotation module for rotating the shank; a floating part for suspending the diamond particles in the plating solution; and a voltage supply unit for applying a voltage to the plating material and the shank, wherein the electrodeposition device applies a voltage to the plating material and the shank by the voltage supply unit, and removes the diamond particles by the floating unit Floating, a diamond electrodeposition mode in which the shank is rotated by the rotation module; and a plating electrodeposition mode in which a voltage is applied to the plating material and the shank by the voltage supply unit, and the shank is rotated by the rotation module; by alternately operating, two or more diamond electrodeposition layers can be formed on the shank An electrodeposition apparatus for manufacturing multi-layer diamond electrodeposition microtools is provided.

In one embodiment of the present invention, the electrodeposition apparatus provides an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool, wherein the tip of the tool can produce a multi-layer diamond electrodeposition microtool having a diameter of 1 millimeter or less. do.

In one embodiment of the present invention, the rotation module, a motor, and a motor unit including a motor power transmitting means for transmitting the power of the motor drive shaft of the motor to the outside; a first rotating die rotating by the power transmitted from the motor; and a second rotating die disposed on one surface of the first rotating die and capable of being rotated relative to the first rotating die, wherein the shank is fixed by the second rotating die, and the first Provided is an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool, which rotates inside the electrodeposition bath by rotation of a rotary die and rotation of the second rotary die.

In an embodiment of the present invention, the rotation module includes: a first shaft coupled to the motor power transmitting means and the first rotating die, and rotating the first rotating die by the power of the motor; and a second shaft capable of rotating by the rotation of the first shaft and rotating the second rotary die, wherein the first shaft is rotated by the motor power transmission means, and the first shaft is rotated As the first rotary die and the second shaft rotate by the rotation of the second shaft, the second rotary die rotates by , an electrodeposition apparatus for manufacturing multi-layer diamond electrodeposition microtools.

In one embodiment of the present invention, the rotating module provides an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool, including a plurality of the second rotating dies for one of the first rotating dies.

In one embodiment of the present invention, the second rotary die, a second shaft connecting portion that rotates on the first rotary die by external power; a shank fixing part coupled to the second shaft connection part and having a first through hole therein; a sealing member disposed inside the first through hole and having a second through hole fixing a part of the shank therein; and an electrode for applying a voltage to the shank.

In an embodiment of the present invention, the floating part floats the diamond particles by using at least one of a method of injecting air, a method of circulating a plating solution, and a method of driving a fan by a motor, multi-layer diamond An electrodeposition apparatus for manufacturing electrodeposition microtools is provided.

In order to solve the above problems, the present invention provides a method for manufacturing a multi-layer diamond electrodeposition microtool, comprising: an electrodeposition tank in which a plating solution and diamond particles floating in the plating solution are accommodated; a plating material disposed inside the electrodeposition tank; The shank of the micro tool to be manufactured is disposed, the rotation module for rotating the shank; a floating part for suspending the diamond particles in the plating solution; and a voltage supply unit for applying a voltage to the plating material and the shank, wherein a voltage is applied to the plating material and the shank by the voltage supply unit, and the diamond particles are suspended by the floating unit and , a diamond electrodeposition mode in which the shank is rotated by the rotation module; and a plating electrodeposition mode in which a voltage is applied to the plating material and the shank by the voltage supply unit, and the shank is rotated by the rotation module; by alternately operating, two or more diamond electrodeposition layers can be formed on the shank A method for manufacturing a multi-layer diamond electrodeposition microtool is provided.

According to an embodiment of the present invention, as the diamond particles in the plating liquid are suspended by the floating portion, the diamond particles are electrodeposited to have acute-angled protrusions, thereby improving the workability of the diamond electrodeposition microtool.

According to an embodiment of the present invention, diamond particles are uniformly dispersed and electrodeposited by a rotating module in which a plurality of rotating dies each rotate, thereby exhibiting the effect of securing the reproducibility of the multi-layer diamond electrodeposition microtool. can

According to an embodiment of the present invention, by selecting and using diamond particles satisfying a preset condition, the machinability, machinability, and tool life of the multi-layer diamond electrodeposited microtool can be improved.

According to one embodiment of the present invention, the electrodeposition apparatus alternately operates the diamond electrodeposition mode and the plating electrodeposition mode, so that a multi-layer diamond electrodeposition microtool in which the diamond electrodeposition layer is electrodeposited in multiple layers on the surface of the shank can be manufactured. can perform

According to an embodiment of the present invention, truing is possible by electrodepositing the diamond electrodeposited layer on the shank in multiple layers, thereby increasing the tool life and achieving the effect of realizing self-reliance.

According to one embodiment of the present invention, as the shank is fixed to the second rotary die, the diamond electrodeposition layer in which the diamond particles are evenly dispersed on the surface of the shank can be electrodeposited by rotating by the second rotary die while the electrodeposition is performed. can have an effect.

According to an embodiment of the present invention, as the rotating module includes a plurality of second rotating dies with respect to one first rotating die, it is possible to exhibit the effect of improving the productivity of the multi-layer diamond electrodeposition microtool. .

1 schematically shows an internal structure of an electrodeposition apparatus according to an embodiment of the present invention.
2 schematically shows a cross-section of the diamond pre-production layer according to the operation of the floating part, the voltage supply part, and the rotation module according to an embodiment of the present invention.
3 schematically illustrates a multi-layer diamond electrodeposition microtool according to an embodiment of the present invention.
4 schematically shows a rotation module according to an embodiment of the present invention.
5 schematically shows a cross-sectional view of a rotation module according to an embodiment of the present invention.
6 schematically shows a cross-sectional view of a second rotating die according to an embodiment of the present invention.
7 schematically shows an embodiment of a second rotary die according to an embodiment of the present invention.
8 schematically shows an embodiment of a floating part according to an embodiment of the present invention.

Hereinafter, various embodiments and/or aspects are disclosed with reference to the drawings. In the following description, for purposes of explanation, numerous specific details are set forth to provide a thorough understanding of one or more aspects. However, it will also be recognized by one of ordinary skill in the art that such aspect(s) may be practiced without these specific details. The following description and accompanying drawings set forth in detail certain illustrative aspects of one or more aspects. These aspects are illustrative, however, and some of the various methods in principles of the various aspects may be employed, and the descriptions set forth are intended to include all such aspects and their equivalents.

Further, various aspects and features will be presented by a system that may include a number of devices, components and/or modules, and the like. It is also noted that various systems may include additional devices, components, and/or modules, etc. and/or may not include all of the devices, components, modules, etc. discussed with respect to the drawings. must be understood and recognized.

As used herein, “embodiment”, “example”, “aspect”, “exemplary”, etc. may not be construed as an advantage or advantage in any aspect or design described above over other aspects or designs. .

In addition, the term “or” is intended to mean an inclusive “or” rather than an exclusive “or.” That is, unless otherwise specified or clear from context, "X employs A or B" is intended to mean one of the natural implicit substitutions. That is, X employs A; X employs B; or when X employs both A and B, "X employs A or B" may apply to either of these cases. It should also be understood that the term “and/or” as used herein refers to and includes all possible combinations of one or more of the listed related items.

Also, the terms "comprises" and/or "comprising" mean that the feature and/or element is present, but excludes the presence or addition of one or more other features, elements and/or groups thereof. should be understood as not

Also, terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

In addition, in the embodiments of the present invention, unless otherwise defined, all terms used herein, including technical or scientific terms, are generally understood by those of ordinary skill in the art to which the present invention belongs. have the same meaning as Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in an embodiment of the present invention, an ideal or excessively formal meaning is not interpreted as

Hereinafter, an electrodeposition apparatus 1 for manufacturing a multi-layer diamond electrodeposition microtool according to an embodiment of the present invention and a method for manufacturing a multi-layer diamond electrodeposition microtool using the same will be described.

1 schematically shows an internal structure of an electrodeposition apparatus 1 according to an embodiment of the present invention.

As an electrodeposition apparatus (1) for manufacturing a multi-layer diamond electrodeposition microtool (2) according to an embodiment of the present invention, a plating solution (800) and diamond particles (d) floating in the plating solution (800) are accommodated. Joe (100); a plating material 200 disposed inside the electrodeposition tank 100; The shank 600 of the microtool to be manufactured is disposed, the rotation module 300 for rotating the shank 600; a floating part 400 for suspending the diamond particles d in the plating solution 800; and a voltage supply unit 500 for applying a voltage to the plating material 200 and the shank 600 .

As shown in FIG. 1 , the electrodeposition apparatus 1 for manufacturing the multi-layer diamond electrodeposition microtool 2 according to an embodiment of the present invention includes the electrodeposition bath 100 and the plating material 200 . , the rotation module 300 , the floating unit 400 , and the voltage supply unit 500 may be included. Preferably, the plating solution 800 is accommodated in the electrodeposition tank 100 , the plating material 200 in the electrodeposition tank 100 , and the shank fixed to one side of the rotation module 300 . 600 are disposed and are respectively connected to the voltage supply unit 500 , and the diamond particles d may float in the plating solution 800 by the floating unit 400 .

The electrodeposition tank 100 may accommodate the plating solution 800 and the diamond particles d floating in the plating solution 800 in an embodiment of the present invention. The plating solution 800 may include at least one of nickel sulfate, nickel chloride, boric acid, distilled water, and other additives, but is not limited thereto, and may include any solvent capable of performing wet electrodeposition depending on the implementation environment. . In addition, the electrodeposition tank 100 may be in the form of a water tank having no upper surface and a through hole provided on the lower surface. The through-hole may be fitted with a module plate 350 to be described later of the rotation module 300 . However, depending on the implementation environment, a lid capable of covering the upper surface of the electrodeposition tank 100 may be provided, and the through-hole of the lower surface may depend on the shape and size of the module plate 350 provided in the rotation module 300 . Accordingly, the shape and size may vary.

Meanwhile, the plating material 200 may be disposed inside the electrodeposition tank 100 in an embodiment of the present invention. The plating material 200 may be accommodated in a container provided with a metal mesh. The plating material 200 may be accommodated in the container in the form of a plurality of lumps, but the form of the plating material 200 may be varied according to embodiments without being limited thereto. In addition, the plating material 200 according to an embodiment of the present invention may include one or more metal elements among nickel, cobalt, zinc, iron, silver, platinum, copper, chromium, and tungsten. Additionally, an additional barrier rib structure such as a nonwoven fabric may be included in the interior of the container.

On the other hand, the rotation module 300, in an embodiment of the present invention, the shank 600 of the microtool to be manufactured is disposed, the shank 600 can be rotated. The rotation module 300 includes a motor unit 310 on the lower side, and a first rotation die 330 and a second rotation die 340 on the upper side, and one side of the second rotation die 340 . The shank 600 is disposed in the shank 600 as the first rotary die 330 and the second rotary die 340 perform respective rotations by the operation of the motor unit 310 . can be rotated. Details of the detailed components and operation of the rotation module 300 will be described later.

Meanwhile, the voltage supply unit 500 may apply a voltage to the plating material 200 and the shank 600 in an embodiment of the present invention. An electric wire may be in contact with one side of the container provided with the mesh network accommodating the plating material 200 therein, and as the electric wire is connected to the voltage supply unit 500 , the anode voltage from the voltage supply unit 500 . can be authorized. The shank 600, inside the rotation module 300, a part may contact the electrode 344 provided with the electric wire, and as the electric wire is connected to the voltage supply unit 500, the voltage supply unit ( 500) can receive a negative voltage. That is, the voltage supply unit 500 applies an anode voltage to the wire provided in the plating material 200 , and applies a cathode voltage to the wire provided in the electrode 344 contacting the shank 600 . Accordingly, the plating material 200 may be electrodeposited on the surface of the shank 600 .

Meanwhile, the floating part 400 may float the diamond particles d in the plating solution 800 in an embodiment of the present invention. The diamond particles (d) may be selected diamond particles (d) having predetermined conditions as will be described later. When the floating part 400 does not operate, the diamond particles d may be deposited on the lower side of the electrodeposition tank 100 after a certain time has elapsed. When the diamond particles (d) are deposited on the inner surface of the lower side of the electrodeposition tank 100, even if the electrodeposition of the plating material 200 is performed by the voltage application of the voltage supply unit 500, the diamond particles (d) The electrodeposition of the shank 600 may not be included in the electrodeposition layer that is electrodeposited on the surface of the shank 600 . On the other hand, when the diamond particles d float in the plating solution 800 accommodated in the electrodeposition tank 100 by the operation of the floating unit 400 , the voltage is applied by the voltage supply unit 500 . The electrodeposition of the plating material 200 and the electrodeposition of the diamond particles (d) are simultaneously performed, so that the diamond electrodeposition layer including both the plating material 200 and the diamond particles (d) on the surface of the shank 600 ( 700) can be formed. That is, the floating part 400 may allow the diamond particles d deposited on the lower inner surface of the electrodeposition tank 100 to float again in the plating solution 800 , and the floating part 400 . When the electrodeposition is performed by the electrodeposition apparatus 1 according to an embodiment of the present invention, both the plating material 200 and the diamond particles d are included on the surface of the shank 600 as is operated. The diamond electrodeposition layer 700 may be formed. Details on this will be described later.

In addition, in an embodiment of the present invention, the floating part 400 suspends the diamond particles d when electrodeposition is performed by the electrodeposition device 1 , so that the diamond particles d are acute-angled projections. It is possible to form the diamond electrodeposition layer 700 of the vertical electrodeposition method to have an electrodeposition. When the diamond particles (d) are vertically electrodeposited, an acute angle surface may protrude from the diamond electrodeposition layer 700, and the workability of the diamond electrodeposition microtool on which the diamond electrodeposition layer 700 is formed by the protruding acute angle surface is improved. can do it On the other hand, when the diamond particles (d) are horizontally electrodeposited, an obtuse surface may protrude from the diamond electrodeposition layer 700, and the diamond electrodeposition layer 700 is formed by the protruding obtuse surface. Machinability of the diamond electrodeposition microtool can lower In one embodiment of the present invention, as the diamond particles d in the plating solution 800 are suspended by the floating part 400, the diamond particles d are electrodeposited to have acute-angled projections, so that the diamond electrodeposition micro The effect of improving the machinability of a tool can be exhibited.

On the other hand, in general, since the diamond particle (d) has a shape closer to an octahedron as Tau(t) is closer to 0, a tool having excellent machinability can be manufactured. In one embodiment of the present invention, the electrodeposition tank 100 may accommodate therein the diamond particles d having 0.2 Tau or less floating in the plating solution 800 . Preferably, the electrodeposition tank 100 may accommodate the diamond particles d having 0.18 Tau or less floating in the plating solution 800 therein. More preferably, the electrodeposition tank 100 may accommodate the diamond particles d having 0.08 Tau to 0.16 Tau floating in the plating solution 800 therein. On the other hand, in another embodiment of the present invention, the electrodeposition tank 100 can accommodate the diamond particles (d) that has undergone four screening steps therein. The step of selecting the diamond particles (d) according to an embodiment of the present invention comprises: a toughness value screening step of selecting the diamond particles (d) having a predetermined toughness value by colliding the stainless balls with the diamond particles (d); a sieving step of classifying and selecting the diamond particles (d) by size; a shape classification step of classifying the shape of the diamond particles (d) into 9 steps; and a metallic particle removal step of removing the diamond particles (d) containing a metal element in a predetermined content or more. In the toughness value selection step, an impact is applied to the diamond particle (d) by vibrating the sealed container containing the stainless ball and the diamond particle (d) therein in the left and right directions, and the diamond particle that is not destroyed after the impact ( By classifying d), it is possible to select the diamond particles (d) having a toughness value corresponding to a preset condition. The toughness value corresponding to the predetermined condition may be a toughness value suitable for a multi-layer diamond electrodeposition process. In one embodiment of the present invention, the diamond particles (d) having a toughness value of 50 to 60 Ti may be selected in the toughness value selection step. Preferably, the diamond particles (d) having a toughness value of 52 to 58 Ti can be selected. More preferably, diamond particles (d) having a toughness value of 54 Ti may be selected. In the sieving step, the diamond particles (d) selected through the toughness value selection step may be accommodated inside a sieving machine having a mesh accommodating therein, and the sieving machine may be vibrated for sieving. That is, in the sieving step, the diamond particles (d) are accommodated in the sieving machine provided with the mesh network having fine holes, and the diamond particles (d) are classified by size by vibrating the sieving machine. can In one embodiment of the present invention, among the diamond particles (d) classified through the sieving step, only a preset size can be used, and through this, the reproducibility of the multi-layer diamond electrodeposition microtool (2) can be secured. . In the shape classification step, it is possible to classify the roughness of the diamond particles (d). That is, the shape classification step classifies the diamond particles (d) into nine grades in shape, and can remove the diamond particles (d) having a low grade, through which the multi-layer diamond electrodeposition microtool ( 2) machinability and tool life can be improved. In the step of removing the metallic particles, the diamond particles (d) may be classified using a magnetic wheel to select the diamond particles (d) having high magnetism. In general, when synthesizing the diamond particles (d), one or more metal elements among cobalt, manganese, nickel, iron, and chromium may be used as the catalyst metal. Diamond particles (d) containing a large amount of the metal element therein, that is, high magnetic, may cause scratches on the surface of the tool during the electrodeposition process, so it is preferable to remove it. As described above, by selecting and using the diamond particles (d) that satisfy the preset conditions, the machinability, machinability, and tool life of the multi-layer diamond electrodeposition microtool (2) can be improved. have.

Meanwhile, the diamond particles (d) according to an embodiment of the present invention may have a size of 150 micrometers or less. Preferably, the diamond particles (d) may have a size of 40 micrometers to 110 micrometers or less. More preferably, the diamond particles (d) may have a size of 50 micrometers to 100 micrometers or less.

FIG. 2 schematically shows a cross-section of the diamond electrodeposition layer 700 according to the operation of the floating part 400 , the voltage supply part 500 , and the rotation module 300 according to an embodiment of the present invention.

According to an embodiment of the present invention, in the electrodeposition device 1 , a voltage is applied to the plating material 200 and the shank 600 by the voltage supply unit 500 , and the floating unit 400 is a diamond electrodeposition mode in which the diamond particles (d) are suspended by the shank (600) and the shank (600) is rotated by the rotation module (300); and a plating electrodeposition mode in which a voltage is applied to the plating material 200 and the shank 600 by the voltage supply unit 500 and the shank 600 is rotated by the rotation module 300; alternately In operation, two or more diamond electrodeposition layers 700 may be formed on the shank 600 .

As shown in FIG. 2 , the formation of the two or more diamond electrodeposited layers 700 may vary according to the operations of the floating unit 400 , the voltage supply unit 500 , and the rotation module 300 . have.

FIG. 2A schematically shows a cross-section of the first diamond electrodeposition layer 710 according to the operation of the floating part 400 , the voltage supply part 500 , and the rotation module 300 . As described above, in the electrodeposition device 1 , a voltage is applied to the plating material 200 and the shank 600 by the voltage supply unit 500 , and the diamond particles are generated by the floating unit 400 . (d) floating, and the shank 600 is rotated by the rotation module 300, the diamond electrodeposition mode can be performed. That is, FIG. 2(A) schematically shows a state in which the electrodeposition device 1 operates in the diamond electrodeposition mode. In the diamond electrodeposition mode, the floating part 400, the voltage supply part 500, and the rotation module 300 may all be operated.

In the diamond electrodeposition mode, the diamond electrodeposition layer 700 including both the plating material 200 and the diamond particles d may be formed on the surface of the shank 600, according to an embodiment of the present invention. In FIG. 2A according to FIG. 2(A), the electrodeposition apparatus 1 performs the diamond electrodeposition mode to include both the plating material 200 and the diamond particles d on the surface of the shank 600. A diamond electrodeposition layer 710 may be formed. At this time, the first diamond electrodeposition layer 710 has a critical limit at which electrodeposition can be continued. can be done Preferably, in an embodiment of the present invention, the electrodeposition apparatus 1 performs the diamond electrodeposition mode for 30 to 120 minutes to deposit the diamond including the plating material 200 and the diamond particles d. Layer 700 may be electrodeposited. Preferably, the diamond electrodeposition mode may be performed for 40 to 80 minutes to electrodeposit the diamond electrodeposition layer 700 including the plating material 200 and the diamond particles (d).

Meanwhile, FIG. 2(B) schematically shows a cross-section of the first diamond electrodeposition layer 710 according to the operation of the voltage supply unit 500 and the rotation module 300, and in this case, the floating unit 400 ) does not work. As described above, in the electrodeposition device 1, a voltage is applied to the plating material 200 and the shank 600 by the voltage supply unit 500, and the shank ( 600) can perform a rotating plating electrodeposition mode. That is, FIG. 2(B) schematically shows how the electrodeposition device 1 operates in the electroplating mode. In the electroplating mode, the floating part 400 does not operate, and the voltage supply unit 500 , and the rotation module 300 may be operated.

In the electroplating mode, the diamond electrodeposition layer 700 including the plating material 200 may be formed on the surface of the shank 600 , and in FIG. 2B according to an embodiment of the present invention, , the electrodeposition apparatus 1 may perform the plating electrodeposition mode to continuously form the first diamond electrodeposition layer 710 including the plating material 200 on the surface of the shank 600 . At this time, the first diamond electrodeposition layer 710 has a critical limit at which electrodeposition can be continued. can be done Preferably, in one embodiment of the present invention, the electrodeposition apparatus 1 performs the plating electrodeposition mode for 10 to 60 minutes to electrodeposit the diamond electrodeposition layer 700 including the plating material 200. can Preferably, in one embodiment of the present invention, the electrodeposition apparatus 1 performs the plating electrodeposition mode for 15 to 30 minutes to electrodeposit the diamond electrodeposition layer 700 including the plating material 200. can Preferably, the plating electrodeposition mode is performed for a relatively shorter time than the diamond electrodeposition mode.

Meanwhile, FIG. 2(C) shows the first diamond electrodeposition layer according to the operation of the floating part 400, the voltage supply part 500, and the rotation module 300, similarly to FIG. 2(A). 710) and a cross-section of the second diamond electrodeposition layer 720 are schematically shown. In FIG. 2C , in the state in which the first diamond electrodeposition layer 710 has been previously formed, as the electrodeposition apparatus 1 performs a diamond electrodeposition mode, the plating material ( 200) and the second diamond electrodeposition layer 720 including both the diamond particles d may be newly laminated and electrodeposited. That is, the electrodeposition apparatus 1 according to an embodiment of the present invention sequentially performs the diamond electrodeposition mode, the plating electrodeposition mode, and the diamond electrodeposition mode to perform the plating on the first diamond electrodeposition layer 710 . The second diamond electrodeposition layer 720 including both the material 200 and the diamond particles d may be stacked.

At this time, the second diamond electrodeposition layer 720 has a critical limit at which electrodeposition can be continued. can be done Preferably, in an embodiment of the present invention, the electrodeposition apparatus 1 performs the diamond electrodeposition mode for 30 to 120 minutes to deposit the diamond including the plating material 200 and the diamond particles d. Layer 700 may be electrodeposited. Preferably, the diamond electrodeposition mode may be performed for 40 to 80 minutes to electrodeposit the diamond electrodeposition layer 700 including the plating material 200 and the diamond particles (d).

Meanwhile, FIG. 2(D) shows the first diamond electrodeposition layer 710 according to the operation of the voltage supply unit 500 and the rotation module 300, and the second The cross section of the diamond electrodeposition layer 720 is schematically shown, and in this case, the floating part 400 does not operate. In FIG. 2D , the second diamond electrodeposition layer 720 including the plating material 200 may be continuously formed on the first diamond electrodeposition layer 710 formed on the surface of the shank 600 . have.

At this time, the second diamond electrodeposition layer 720 has a critical limit at which electrodeposition can be continued. can be done Preferably, in one embodiment of the present invention, the electrodeposition apparatus 1 performs the plating electrodeposition mode for 10 to 60 minutes to electrodeposit the diamond electrodeposition layer 700 including the plating material 200 . can Preferably, in one embodiment of the present invention, the electrodeposition apparatus 1 performs the plating electrodeposition mode for 15 to 30 minutes to electrodeposit the diamond electrodeposition layer 700 including the plating material 200 . can Preferably, the plating electrodeposition mode is performed for a relatively shorter time than the diamond electrodeposition mode.

That is, the electrodeposition apparatus 1 according to an embodiment of the present invention can manufacture the multi-layer diamond electrodeposition microtool 2 by controlling the operation of the floating part 400 .

In another embodiment of the present invention, the floating unit 400 may include a control unit, and the operation of the floating unit 400 may be controlled by the control unit. Preferably, when the control unit turns on the operation of the floating unit 400 , the electrodeposition device 1 can perform the diamond electrodeposition mode, and the control unit turns off the operation of the floating unit 400 . , the electrodeposition apparatus 1 may perform the plating electrodeposition mode. As described above, two or more diamond electrodeposition layers 700 may be formed on the surface of the shank 600 by the electrodeposition apparatus 1 alternately operating the diamond electrodeposition mode and the plating electrodeposition mode. That is, as the electrodeposition apparatus 1 according to an embodiment of the present invention operates alternately in the diamond electrodeposition mode and the plating electrodeposition mode, the diamond electrodeposition layer 700 is formed on the surface of the shank 600 by a plurality of The effect of being able to manufacture the multi-layer diamond electrodeposition microtool 2 electrodeposited in layers can be exerted.

However, in one embodiment of the present invention, when the electrodeposition apparatus 1 performs the plating electrodeposition mode last to manufacture the multi-layer diamond electrodeposition microtool 2, the acute angle of the diamond particles d Since the protruding surface is small, the machinability of the multi-layer diamond electrodeposition microtool 2 may be deteriorated, and the electrodeposition device 1 performs the diamond electrodeposition mode last, so that the multi-layer diamond electrodeposition microtool 2 ), the tool life of the multi-layer diamond electrodeposition microtool 2 may be reduced because the holding force of the diamond particles d is low. Accordingly, the electrodeposition apparatus 1 according to an embodiment of the present invention preferably operates the diamond electrodeposition mode and the plating electrodeposition mode under conditions that can meet the tool use environment and user needs.

On the other hand, as a method of manufacturing a multi-layer diamond electrodeposition microtool 2 according to an embodiment of the present invention, a plating solution 800 and an electrodeposition tank in which the diamond particles d floating in the plating solution 800 are accommodated ( 100); a plating material 200 disposed inside the electrodeposition tank 100; The shank 600 of the microtool to be manufactured is disposed, the rotation module 300 for rotating the shank 600; a floating part 400 for suspending the diamond particles d in the plating solution 800; and a voltage supply unit 500 for applying a voltage to the plating material 200 and the shank 600; a diamond electrodeposition mode in which voltage is applied to the shank 600 , the diamond particles d are suspended by the floating part 400 , and the shank 600 is rotated by the rotation module 300 ; and a plating electrodeposition mode in which a voltage is applied to the plating material 200 and the shank 600 by the voltage supply unit 500 and the shank 600 is rotated by the rotation module 300; alternately In operation, two or more diamond electrodeposition layers 700 may be formed on the shank 600 .

That is, as described above, the electrodeposition apparatus 1 including the electrodeposition tank 100 , the plating material 200 , the rotation module 300 , the floating part 400 , and the voltage supply part 500 . ) to alternately operate in the diamond electrodeposition mode and the plating electrodeposition mode, thereby exhibiting the effect of manufacturing the multi-layer diamond electrodeposition microtool 2 . Preferably, the multi-layer diamond electrodeposition in which the diamond electrodeposition layer 700 is electrodeposited in multiple layers on the surface of the shank 600 by the electrodeposition device 1 alternately operating the diamond electrodeposition mode and the plating electrodeposition mode The effect of being able to manufacture the micro tool 2 can be exhibited.

Preferably, as the diamond electrodeposition layer 700 is electrodeposited on the shank 600 in multiple layers, truing is possible, thereby increasing the tool life and realizing the self-reliance effect.

3 schematically shows the multi-layer diamond electrodeposition microtool 2 according to an embodiment of the present invention.

According to an embodiment of the present invention, the electrodeposition apparatus 1 can manufacture a multi-layer diamond electrodeposition microtool 2 with a tip of the tool having a diameter of 1 millimeter or less.

As shown in FIG. 3 , the multi-layer diamond electrodeposition microtool 2 according to an embodiment of the present invention includes a shank 600 and the plating material 200 formed on the surface of the shank 600 and It may include two or more diamond electrodeposited layers including the diamond particles (d). Preferably, the multi-layer diamond electrodeposition microtool 2 may include the diamond electrodeposition layer 700 formed in 10 or less layers. More preferably, the multi-layer diamond electrodeposition microtool 2 includes the diamond electrodeposition layer 700 formed of 1 to 5 layers, and further includes a diamond electrodeposition layer 700 formed of about 0.1 to 1 layer. It may include a truing zone for truing.

Meanwhile, the diameter D of the tip of the multi-layer diamond electrodeposition microtool 2 on which the two or more diamond electrodeposition layers 700 are formed may be 1 millimeter or less. Preferably, the electrodeposition device 1 is capable of producing the multi-layer diamond electrodeposition microtool 2 with a tip of the tool having a diameter of 0.1 to 1 millimeter. In one embodiment of the present invention, the diameter (D) is the tip of the shank 600, the diamond electrodeposition layer 700 including the plating material 200 and the diamond particles d formed on the surface of the tip. It may be a diameter including all of them.

Hereinafter, detailed components of the rotation module 300 provided in the electrodeposition device 1 according to an embodiment of the present invention will be described.

4 schematically shows the rotation module 300 according to an embodiment of the present invention.

As shown in FIG. 4 , the rotation module 300 includes the motor unit 310 disposed outside the electrodeposition tank 100 and the first rotary die disposed inside the electrodeposition tank 100 . 330), the second rotary die 340, the first shaft support 320, and the through hole formed in the lower surface of the electrodeposition tank 100, the boundary between the inside and the outside of the electrodeposition tank 100 It may include a module plate 350 disposed on the. In an embodiment of the present invention, the motor unit 310 and the module plate 350 may be in the form of a hexahedron, but the motor unit 310 and the module plate 350 may be cylindrical or plate-shaped depending on the usage environment. ) can be any form that can perform the role of In addition, in an embodiment of the present invention, the first rotating die 330 and the second rotating die 340 may be in the form of a circular plate, but depending on the use environment, the first rotating die 330 such as a polyhedron and the The second rotary die 340 may be of any type capable of performing the role.

5 schematically shows a cross-sectional view of the rotation module 300 according to an embodiment of the present invention.

According to an embodiment of the present invention, the rotation module 300 includes a motor 312 and a motor power transmission means 313 for transmitting the power of the motor drive shaft 312.1 of the motor 312 to the outside. a motor unit 310; a first rotating die 330 rotating by the power transmitted from the motor 312; and a second rotation die 340 disposed on one surface of the first rotation die 330 and capable of rotating relatively with respect to the first rotation die 330; and the shank 600 is the It is fixed by the second rotary die 340 , and may rotate inside the electrodeposition tank 100 by the rotation of the first rotary die 330 and the rotation of the second rotary die 340 .

In addition, according to an embodiment of the present invention, the rotation module 300 is coupled to the motor power transmission means 313 and the first rotation die 330 , and by the power of the motor 312 , the a first shaft 360 for rotating the first rotary die 330; and a second shaft 370 capable of rotating by the rotation of the first shaft 360 and rotating the second rotary die 340; further comprising, by the motor power transmission means 313 The first shaft 360 rotates, and the first rotary die 330 and the second shaft 370 rotate by the rotation of the first shaft 360 , and the second shaft 370 rotates. As the second rotating die 340 rotates by rotation, the first rotating die 330 and the second rotating die 340 may rotate, respectively.

The motor unit 310, in an embodiment of the present invention, a motor 312, and a motor power transmission means 313 for transmitting the power of the motor drive shaft 312.1 of the motor 312 to the outside. can As shown in FIG. 5 , the motor unit 310 according to an embodiment of the present invention may include a motor housing 311 , the motor 312 , and the motor power transmission means 313 . . The motor 312 according to an embodiment of the present invention may have a motor driving shaft 312.1 on one side, and the motor driving shaft 312.1 may be coupled to the motor power transmitting means 313 on one side. The motor power transmitting means 313 may transmit the power of the motor 312 to the outside by coupling the motor driving shaft 312.1 to one side, and the first shaft 360 may be connected to the other side. Accordingly, when the motor 312 is operated, the power by the motor 312 is transmitted to the first shaft 360 by the motor power transmitting means 313 so that the first shaft 360 is can rotate The motor power transmission means 313 may include, but is not limited to, a conveyor belt, a gear, and a cog wheel, and any power transmission means capable of transmitting the power by the motor 312 to the outside may be used. have.

On the other hand, the first rotating die 330, in an embodiment of the present invention, may rotate by the power received from the motor 312. As shown in FIG. 5 , the first rotary die 330 has a coupling groove in the center thereof, and a portion of the first shaft 360 may be received and coupled to the coupling groove. In addition, the first rotating die 330 may accommodate the second shaft 370 therein, and according to an embodiment of the present invention, the second shaft 370 may include one or more. In addition, the first rotary die 330 receives the power from the first shaft power transmission means 331 for transmitting the power of the first shaft 360 to the outside, and the first shaft power transmission means 331 . The second shaft power transmission means 332 may be accommodated therein. The first shaft power transmission means 331 and the second shaft power transmission means 332 may include, but are not limited to, conveyor belts, gears, and cog wheels, and all power transmission capable of transmitting the power to the outside. means can be used. In addition, the number of the second shaft power transmission means 332 may be the same as the number of the second shafts 370 , and according to an embodiment of the present invention, the second power transmission means may include one or more.

On the other hand, the second rotary die 340, in an embodiment of the present invention, is disposed on one surface of the first rotary die 330, it can rotate relatively with respect to the first rotary die 330. . As shown in FIG. 5 , the second rotary die 340 may include a second shaft connection part 341 and a shank fixing part 342 to be described later. The second rotary die 340 may couple a part of the second shaft 370 accommodated in the first rotary die 330 to the second shaft connection part 341 , and the shank 600 is It may be fixed to the shank fixing part 342 . The shank 600 fixed to the second rotary die 340 may be rotated together with the second rotary die 340 , and the second rotary die 340 is the first rotary die 330 . ), the second rotary die 340 and the first rotary die 330 may rotate relative to each other.

In the above configuration, the shank 600 is fixed by the second rotating die 340 , and by the rotation of the first rotating die 330 and the rotation of the second rotating die 340 , It can rotate inside the electrodeposition tank 100 .

On the other hand, the first shaft 360, in an embodiment of the present invention, is coupled to the motor power transmission means 313 and the first rotary die 330, and by the power of the motor 312, the The first rotating die 330 may be rotated. As shown in FIG. 5 , the first shaft 360 is supported by the first shaft support 320 , and can be accommodated and coupled to the first rotary die 330 having a coupling groove in its center. have. In one embodiment of the present invention, the first shaft 360, the motor power transmission means 313 may be coupled to a part, and the power of the motor 312 by the motor power transmission means 313 may be transmitted to rotate the first rotating die 330 . On the other hand, the first shaft 360, the first shaft power transmission means 331 is coupled to the other part, it is possible to rotate the first shaft power transmission means 331. The first shaft power transmission means 331 transmits the power applied to the first shaft 360 by rotational motion to the second shaft power transmission means 332 to rotate the second shaft power transmission means 332 . can do it In one embodiment of the present invention, the number of the second shaft power transmission means 332 may be one or more, and when the number of the second shaft power transmission means 332 is plural, the first shaft power transmission means 331 includes a plurality of the The power may be transmitted to each of the second shaft power transmission means 332 .

Meanwhile, the second shaft 370 may rotate by the rotation of the first shaft 360 and the second rotation die 340 may be rotated in an embodiment of the present invention. As shown in FIG. 5 , the second shaft 370 may be partially coupled to the second shaft power transmission means 332 . As described above, the second shaft power transmission means 332 may rotate by receiving the power of the motor 312 by the first shaft power transmission means 331 . That is, as the second shaft 370 is defective with the second shaft power transmission means 332 , the second shaft 370 may be rotated by the rotation of the second shaft power transmission means 332 . Also, as described above, a portion of the second shaft 370 may be coupled to the second shaft connection part 341 provided in the second rotary die 340 . That is, the second rotation die 340 may be rotated by the rotation of the second shaft 370 . Preferably, the first shaft power transmission means 331 is rotated by the rotation of the first shaft 360, and the second shaft power transmission means 332 is rotated by the rotation of the first shaft power transmission means 331. This rotation, the second shaft 370 is rotated by the rotation of the second shaft power transmission means 332, and the second rotary die 340 is rotated by the rotation of the second shaft 370 can Preferably, the first shaft 360 is rotated by the motor power transmitting means 313 , and the first rotating die 330 and the second shaft ( 330 ) are rotated by the rotation of the first shaft ( 360 ). 370) rotates, and as the second rotation die 340 rotates by the rotation of the second shaft 370, the first rotation die 330 and the second rotation die 340 rotate, respectively. can do. According to the configuration as described above, the multi-layer diamond electrodeposition microtool (2) by uniformly dispersing and electrodepositing the diamond particles (d) by the rotation module 300 in which a plurality of rotation dies rotate respectively. It is possible to exert the effect of securing the reproducibility of

In addition, as shown in FIG. 5 , the rotation module 300 may include the module plate 350 and the first shaft support 320 .

The module plate 350, in an embodiment of the present invention, may be disposed on the upper surface of the motor unit 310, and serves as a passage for components including the first shaft 360. One or more through-holes may be provided. The component may include a member including a wire capable of applying a voltage to the first shaft 360 and the electrode 344 in contact with the shank 600 . In addition, the module plate 350 may be fitted into the through hole provided on the lower surface of the electrodeposition tank 100 , and the side surface of the module plate 350 in contact with the lower surface of the electrodeposition tank 100 is As it is finished by a finishing material containing silicon or welding, the plating solution 800 accommodated in the electrodeposition tank 100 may be prevented from leaking by hydraulic pressure.

On the other hand, the first shaft support 320, in an embodiment of the present invention, is disposed on the upper surface of the module plate 350 can accommodate the motor power transmission means 313 therein therein. . Also, the first shaft support 320 may receive and support the first shaft 360 connected to the motor power transmission means 313 therein.

In addition, as shown in FIG. 5 , the shank 600 may be fixed by the second rotation die 340 provided in the rotation module 300 . A part of the shank 600 may be disposed inside the second rotary die 340 provided in the rotary module 300 , and the electrode 344 disposed inside the rotary module 300 . A negative voltage may be applied from the voltage supply unit 500 through a connected wire (not shown). In one embodiment of the present invention, the electric wire (not shown) is connected to the electrode 344, the second rotary die 340, the first rotary die 330, the first shaft support 320, It may be accommodated in the module plate 350 and the motor unit 310 , and may be exposed to the outside through a hole provided at one side of the motor unit 310 to be connected to the voltage supply unit 500 .

In one embodiment of the present invention, the first rotary die 330 has an inner space between one side on which the second rotary die 340 is disposed and the other side on which the first shaft support 320 is disposed. to accommodate the electric wire (not shown) connected to the electrode 344 through the inner space, and the first shaft support 320 includes one side and the one on which the first rotary die 330 is disposed. An inner space is provided between the other side facing the side to accommodate the electric wire (not shown) connected to each of the one or more electrodes 344 through the inner space, and the module plate 350 has a through hole. The electric wire (not shown) can pass through the module plate 350 by providing a through hole in a part of the outer surface of the motor unit 310 so that the electric wire (not shown) passes through the electric wire ( (not shown) may be exposed to the outside of the electrodeposition tank 100 to be connected to the voltage supply unit 500 .

In another embodiment of the present invention, the first rotary die 330 has an inner space between one side on which the second rotary die 340 is disposed and the other side on which the first shaft support 320 is disposed. and can accommodate the electric wire (not shown) connected to the electrode 344 through the inner space, and the first shaft support 320 includes a side surface on which the first rotary die 330 is disposed and the An inner space is provided between the other side facing one side to accommodate the electric wire (not shown) connected to the electrode 344 through the inner space, and the module plate 350 has a through hole. As the electric wire (not shown) penetrates, the electric wire (not shown) is exposed to the outside of the electrodeposition tank 100 to be connected to the voltage supply unit 500 .

In another embodiment of the present invention, the first rotary die 330 has an inner space between one side on which the second rotary die 340 is disposed and the other side on which the first shaft support 320 is disposed. It can accommodate the electric wire (not shown) connected to the electrode 344 through the inner space, and has one or more through-holes in a part of the outer circumferential surface so that the electric wire (not shown) passes through the electric wire (not shown). time) may be exposed to the outside of the electrodeposition tank 100 to be connected to the voltage supply unit 500 .

In this way, by uniformly dispersing and electrodepositing the diamond particles d by the rotation module 300 in which a plurality of rotation dies rotate, respectively, the reproducibility of the multi-layer diamond electrodeposition microtool 2 is ensured. can be effective.

6 schematically shows a cross-sectional view of the second rotary die 340 according to an embodiment of the present invention.

As described above, according to an embodiment of the present invention, the rotation module 300 is a motor 312, and a motor power transmission means for transmitting the power of the motor drive shaft 312.1 of the motor 312 to the outside. a motor unit 310 including 313; a first rotating die 330 rotating by the power transmitted from the motor 312; and a second rotation die 340 disposed on one surface of the first rotation die 330 and capable of rotating relatively with respect to the first rotation die 330; and the shank 600 is the It is fixed by the second rotary die 340 , and may rotate inside the electrodeposition tank 100 by the rotation of the first rotary die 330 and the rotation of the second rotary die 340 .

The second rotary die 340 according to an embodiment of the present invention includes a second shaft connection part 341 that rotates on the first rotary die 330 by external power; a shank fixing part 342 coupled to the second shaft connection part 341 and having a first through hole therein; a sealing member 343 disposed inside the first through-hole and having a second through-hole fixing a part of the shank 600 therein; and an electrode 344 for applying a voltage to the shank 600 .

As shown in FIG. 6 , the second rotating die 340 includes the second shaft connection part 341 , the shank fixing part 342 , the sealing member 343 , and the electrode 344 . can do.

The second shaft connection part 341 may rotate on the first rotary die 330 by external power in an embodiment of the present invention. The second shaft connection part 341 according to an embodiment of the present invention may have a through hole formed at one end thereof, and the diameter of the through hole may be the same as that of the second shaft 370 . Accordingly, as described above, a portion of the second shaft 370 may be coupled to the second shaft connection part 341 provided in the second rotary die 340 . That is, as the second shaft connection part 341 is coupled to a portion of the second shaft 370 , it may rotate on the first rotation die 330 by the rotation of the second shaft 370 . Preferably, by the second shaft 370 coupled through the second shaft connection part 341 , the second rotary die 340 may rotate on the first rotary die 330 .

Meanwhile, the shank fixing part 342 may be coupled to the second shaft connection part 341 and a first through hole may be formed therein in an embodiment of the present invention. As shown in FIG. 6 , the shank fixing part 342 may be coupled to the second shaft connection part 341 having a screw thread formed on the inner circumferential surface and a screw thread formed on the outer circumferential surface. As the shank fixing part 342 is defective with the second shaft connection part 341 , it may rotate together by the rotation of the second shaft connection part 341 . In addition, the shank fixing part 342 may have a first through hole formed therein to be coupled to the sealing member 343 .

Meanwhile, the sealing member 343 may be disposed inside the first through hole, and a second through hole for fixing a part of the shank 600 may be formed therein. As shown in FIG. 6 , the sealing member 343 may be disposed inside the first through hole formed in the shank fixing part 342 to form the second through hole, and the second through hole It can be fixed by inserting a part of the shank (600). The sealing member 343 may be made of a silicon material, but is not limited thereto, and any material capable of fixing the shank 600 may be used. Accordingly, even if the specification including the length and thickness of the shank 600 varies, the shank 600 is fixed to the shank fixing part ( 342) can be fixed. In this case, the diameter of the second through hole is relatively smaller than the diameter of the first through hole, and it is preferable that the diameter of the body portion of the shank 600 is the same.

Meanwhile, the electrode 344 may apply a voltage to the shank 600 in an embodiment of the present invention. Preferably, the electrode 344 may receive the negative voltage applied from the voltage supply unit 500 through the electric wire (not shown).

In this way, as the second rotary die 340 includes the second shaft connecting portion 341 and the shank fixing portion 342 coupled to each other by a screw thread, the first rotary die by the external power ( 330), and by disposing the sealing member 343 inside the first through hole formed in the shank fixing part 342, the shank 600 can be fixed, and the shank 600 By rotating the shank 600 while electrodeposition is performed by the electrodeposition device 1 as the electrode 344 for applying a cathode voltage to the The dispersed diamond electrodeposition layer 700 may be electrodeposited. Preferably, as the shank 600 is fixed to the second rotary die 340, the diamond is placed on the surface of the shank 600 by rotating by the second rotary die 340 while electrodeposition is performed. It is possible to exhibit the effect of electrodepositing the diamond electrodeposition layer 700 in which the particles (d) are evenly dispersed. Preferably, the reproducibility of the multi-layer diamond electrodeposition microtool 2 is improved by uniformly dispersing and electrodepositing the diamond particles d by the rotation module 300 in which a plurality of rotation dies rotate respectively. achievable effects can be achieved.

7 schematically shows an embodiment of the second rotary die 340 according to an embodiment of the present invention.

As described above, according to an embodiment of the present invention, the rotation module 300 is a motor 312, and a motor power transmission means for transmitting the power of the motor drive shaft 312.1 of the motor 312 to the outside. a motor unit 310 including 313; a first rotating die 330 rotating by the power transmitted from the motor 312; and a second rotation die 340 disposed on one surface of the first rotation die 330 and capable of rotating relatively with respect to the first rotation die 330; and the shank 600 is the It is fixed by the second rotary die 340 , and may rotate inside the electrodeposition tank 100 by the rotation of the first rotary die 330 and the rotation of the second rotary die 340 .

According to an embodiment of the present invention, the rotation module 300 may include a plurality of the second rotation dies 340 with respect to one of the first rotation dies 330 .

As shown in FIG. 7 , the first rotating die 330 may include a plurality of the second rotating dies 340 . Fig. 7(a) schematically shows a front view of the first rotating die 330 having one of the second rotating dies 340, and Fig. 7(b) is three of the second rotating dies 340. ) schematically shows a front view of the first rotating die 330 having schematically shown. Each of the second rotary dies 340 may fix the shank 600 to the shank fixing part 342 provided on one side, and as the second rotary die 340 rotates, the shank 600 . can be rotated. In one embodiment of the present invention, the embodiment of the second rotating die 340 not shown in FIG. 7 may also be implemented, and the number of the second rotating dies 340 depends on the usage environment of the electrodeposition device 1 . and can be changed according to the needs of the user.

As such, as the rotation module 300 includes a plurality of the second rotation dies 340 with respect to one of the first rotation dies 330, the productivity of the multi-layer diamond electrodeposition microtool can be improved. possible effect can be exerted.

8 schematically shows an embodiment of a float 400 according to an embodiment of the present invention.

According to an embodiment of the present invention, the floating part 400 uses at least one of a method of injecting air, a method of circulating the plating solution 800, and a method of driving a fan by a motor to the diamond particles (d) can be floated.

FIG. 8( a ) schematically shows the electrodeposition device 1 provided with the floating part 400 in a manner of injecting air. Preferably, the method may include an air pump connected to the outside, and a hose for injecting air into the electrodeposition tank 100 by the air pump. As the air pump operates, the floating part 400 may inject air into the electrodeposition tank 100 through the hose, and as the air is injected, the plating liquid accommodated in the electrodeposition tank 100 inside. By inducing the flow of 800, the diamond particles d that have sunk in the electrodeposition tank 100 can be suspended.

FIG. 8( b ) schematically shows the electrodeposition apparatus 1 provided with the floating part 400 in a manner of circulating the plating solution 800 . Preferably, the method includes a circulation pump connected to the outside, a suction pipe for introducing the plating solution 800 accommodated in the electrodeposition tank 100 by the circulation pump, and the electrodeposition by the circulation pump drawn in from the suction pipe. A discharge pipe through which the plating solution 800 is discharged into the tank 100 may be included. As the circulation pump operates, the floating part 400 draws in the plating solution 800 through the suction pipe and discharges the plating solution 800 into the electrodeposition tank 100 through the discharge pipe, As the plating solution 800 circulates, the diamond particles d that have sunk in the electrodeposition tank 100 may be suspended.

FIG. 8( c ) schematically shows the electrodeposition device 1 provided with the floating part 400 in a manner of driving a fan by a motor. Preferably, the method may include the motor connected to the outside, and a fan disposed inside the electrodeposition tank 100 and operated by the motor. As the motor operates, the floating part 400 may circulate the plating liquid 800 through the fan, and as the plating liquid 800 circulates, the plating liquid 800 accommodated in the electrodeposition tank 100 is circulated. ) by inducing the flow, it is possible to suspend the diamond particles (d) sunk in the electrodeposition tank (100).

The floating part 400 according to an embodiment of the present invention may float the diamond particles d using the above-described method, but is not limited thereto, and the diamond particles are circulated by circulating the plating solution 800 . Any method capable of floating (d) may be used.

As described above, as the diamond particles d in the plating solution 800 are suspended by the floating portion 400, the diamond particles d are electrodeposited to have acute-angled projections, so that the multi-layer diamond electrodeposition microtool 2 ) can exhibit the effect of improving the workability.

According to an embodiment of the present invention, as the diamond particles in the plating liquid are suspended by the floating portion, the diamond particles are electrodeposited to have acute-angled protrusions, thereby improving the workability of the diamond electrodeposition microtool.

According to an embodiment of the present invention, diamond particles are uniformly dispersed and electrodeposited by a rotating module in which a plurality of rotating dies each rotate, thereby exhibiting the effect of securing the reproducibility of the multi-layer diamond electrodeposition microtool. can

According to an embodiment of the present invention, by selecting and using diamond particles satisfying a preset condition, the machinability, machinability, and tool life of the multi-layer diamond electrodeposited microtool can be improved.

According to one embodiment of the present invention, the electrodeposition apparatus alternately operates the diamond electrodeposition mode and the plating electrodeposition mode, so that a multi-layer diamond electrodeposition microtool in which the diamond electrodeposition layer is electrodeposited in multiple layers on the surface of the shank can be manufactured. can perform

According to an embodiment of the present invention, truing is possible by electrodepositing the diamond electrodeposited layer on the shank in multiple layers, thereby increasing the tool life and achieving the effect of realizing self-reliance.

According to one embodiment of the present invention, as the shank is fixed to the second rotary die, the diamond electrodeposition layer in which the diamond particles are evenly dispersed on the surface of the shank can be electrodeposited by rotating by the second rotary die while the electrodeposition is performed. can have an effect.

According to an embodiment of the present invention, as the rotating module includes a plurality of second rotating dies with respect to one first rotating die, it is possible to exhibit the effect of improving the productivity of the multi-layer diamond electrodeposition microtool. .

As described above, although the embodiments have been described with reference to the limited embodiments and drawings, various modifications and variations are possible by those skilled in the art from the above description. For example, the described techniques are performed in a different order than the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result. Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

1: electrodeposition device
2: Multi-layer diamond electrodeposition microtool
100: electrodeposition tank 200: plating material
300: rotation module
310: motor unit 311: motor housing
312: motor 312.1: motor drive shaft
313: power transmission means
320: first shaft support 330: first rotary die
331: first shaft power transmission means 332: second shaft power transmission means
340: second rotary die 341: second shaft connection part
342: shank fixing part 343: sealing member
344: electrode
350: module plate 360: first axis
370: second axis
400: floating unit 500: voltage supply unit
600: shank 700: diamond electrodeposition layer
710: first diamond electrodeposition layer 720: second diamond electrodeposition layer
800: plating solution d: diamond particles

Claims (8)

An electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool comprising:
an electrodeposition tank in which a plating solution and diamond particles floating in the plating solution are accommodated;
a plating material disposed inside the electrodeposition tank;
The shank of the micro tool to be manufactured is disposed, the rotation module for rotating the shank;
a floating part for suspending the diamond particles in the plating solution so that the diamond particles are electrodeposited to have acute-angled protrusions; and
a voltage supply unit for applying a voltage to the plating material and the shank;
The rotation module,
a motor unit including a motor and a motor power transmitting means for transmitting power of a motor driving shaft of the motor to the outside;
a first rotating die rotating by the power transmitted from the motor; and
and a second rotation die disposed on one surface of the first rotation die and capable of relatively rotating with respect to the first rotation die;
The shank is fixed by the second rotating die, and rotates inside the electrodeposition tank by the rotation of the first rotating die and the rotation of the second rotating die,
The second rotary die and the first rotary die rotate, respectively,
The electrodeposition device is
a diamond electrodeposition mode in which a voltage is applied to the plating material and the shank by the voltage supply unit, the diamond particles are suspended by the floating unit, and the shank is rotated by the rotation module; and
A voltage is applied to the plating material and the shank by the voltage supply unit, and a plating electrodeposition mode in which the shank is rotated by the rotation module is operated alternately to form two or more diamond electrodeposition layers on the surface of the shank Electrodeposition apparatus for manufacturing multi-layer diamond electrodeposition microtools that can be used.
The method according to claim 1,
wherein the electrodeposition device is capable of producing a multi-layer diamond electrodeposition microtool, wherein the tip of the tool has a diameter of 1 millimeter or less.
delete The method according to claim 1,
The rotation module,
a first shaft coupled to the motor power transmission means and the first rotating die, and rotating the first rotating die by the power of the motor; and
A second shaft capable of rotating by the rotation of the first shaft and rotating the second rotary die; further comprising,
The first shaft is rotated by the motor power transmission means, the first rotating die and the second shaft are rotated by the rotation of the first shaft, and the second rotating die is rotated by the rotation of the second shaft Accordingly, the first rotary die and the second rotary die can rotate, respectively, an electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool.
The method according to claim 1,
The rotary module comprises a plurality of the second rotary die for one of the first rotary die, the electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool.
The method according to claim 1,
The second rotary die,
a second shaft connection part rotating on the first rotary die by external power;
a shank fixing part coupled to the second shaft connection part and having a first through hole therein;
a sealing member disposed inside the first through hole and having a second through hole fixing a part of the shank therein; and
Electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool comprising; an electrode for applying a voltage to the shank.
The method according to claim 1,
An electrodeposition apparatus for manufacturing a multi-layer diamond electrodeposition microtool, wherein the floating part floats the diamond particles by using at least one of a method of injecting air, a method of circulating a plating solution, and a method of driving a fan by a motor .
A method of making a multi-layer diamond electrodeposition microtool comprising:
an electrodeposition tank in which a plating solution and diamond particles floating in the plating solution are accommodated;
a plating material disposed inside the electrodeposition tank;
The shank of the micro tool to be manufactured is disposed, the rotation module for rotating the shank;
a floating part for suspending the diamond particles in the plating solution so that the diamond particles are electrodeposited to have acute-angled protrusions; and
In the electrodeposition apparatus comprising a; a voltage supply for applying a voltage to the plating material and the shank,
The rotation module,
a motor unit including a motor and a motor power transmitting means for transmitting power of a motor driving shaft of the motor to the outside;
a first rotating die rotating by the power transmitted from the motor; and
and a second rotation die disposed on one surface of the first rotation die and capable of relatively rotating with respect to the first rotation die;
The shank is fixed by the second rotating die, and rotates inside the electrodeposition tank by the rotation of the first rotating die and the rotation of the second rotating die,
The second rotary die and the first rotary die rotate, respectively,
a diamond electrodeposition mode in which a voltage is applied to the plating material and the shank by the voltage supply unit, the diamond particles are suspended by the floating unit, and the shank is rotated by the rotation module; and
A voltage is applied to the plating material and the shank by the voltage supply unit, and a plating electrodeposition mode in which the shank is rotated by the rotation module is operated alternately to form two or more diamond electrodeposition layers on the surface of the shank A method of making a multi-layer diamond electrodeposition microtool that can be

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