KR101350153B1 - Apparatus for production of metal nanopowder by wire explosion - Google Patents

Abstract

The present invention provides a metal nanopowder manufacturing apparatus by electroexplosion which lowers the pulse power causing the electrical explosion and makes the particle size of the nanopowder produced according to the position of the wire uniform. The apparatus includes a feeding part for supplying the metal wire to the high voltage electrode causing the electrical explosion by the high voltage pulse power, and a vibrator mounted on at least one side of the feeding part to impart vibration to the metal wire mounted on the feeding part. do.

Description

Apparatus for production of metal nanopowder by wire explosion

The present invention relates to an apparatus for producing metal nanopowder, and more particularly, to an apparatus for manufacturing metal nanopowder by electric shock by pulse power in air or in water.

As the high-tech industry develops, the performance and miniaturization of components and systems are progressing, and nanotechnology can overcome limitations of existing technologies. Nano powder has been suggested as an alternative to achieve the importance of nanotechnology, and researches on it have been actively carried out.

The nano powder as the ultrafine powder can exhibit the electromagnetic, mechanical and catalytic characteristics which can not be obtained by the conventional materials due to the increase of the surface area according to the miniaturization (about 100 nm or less). Therefore, It is expected to create new demand in the industry as a next-generation functional material applied to filters, batteries, catalysts and the like.

The method for producing nanopowders is known from various viewpoints, but among them, techniques for preparing metal nanopowders by an electric explosion method using pulse power have been actively studied. The method for producing metal nanopowders by the electric explosion method is very important in terms of industrial applications, and is economically advantageous over other methods. Conventional electric explosion method using pulse power has been developed by the air explosion method and the submerged electric explosion method.

The electroexplosion method is to produce a nanopowder by applying a pulsed power to the metal wire fed in the chamber to explode and vaporize the wire, then cooling / condensing it in an atmosphere gas or liquid. However, according to the electroexplosion method, there is a problem in that a high voltage pulse power causing an electroexplosion is required, and the particle size of the nanopowder produced is changed according to the position of the wire.

Therefore, the technical problem to be solved by the present invention is to provide an apparatus for producing metal nanopowder by the electrical explosion to lower the pulse power causing the electrical explosion, and uniformize the particle size of the nanopowder produced according to the position of the wire.

According to the metal nanopowder manufacturing apparatus of the present invention to achieve the above technical problem, a high voltage electrode causing the electrical explosion of the metal wire by a high voltage pulse power, a feeding part for supplying the metal wire to the high voltage electrode and the feeding part And a vibrator mounted on at least one side to impart vibration to the metal wire mounted to the feeding unit.

In the apparatus of the present invention, the feeding part may supply the metal wire in a vertical direction or a horizontal direction with respect to the high voltage electrode. In this case, the electric explosion may occur in liquid or air. In addition, the vibrator may be in the form of a donut surrounding a portion of the feeding unit or may be installed inside the feeding unit.

The vibrator of the present invention may use mechanical resonance of the metal wire or vibration of atoms / electrons of the metal wire, wherein the vibrator may be any one selected from a crystal oscillator or an LC oscillator.

According to the apparatus for producing metal nanopowders by the electric explosion of the present invention, by mounting the vibrator in the feeding portion, the pulse power causing the electrical explosion can be lowered, and the vibration of the electrons can be generated throughout the wire by the vibrator.

1 is a cross-sectional view showing a submerged electric explosion apparatus according to an embodiment of the present invention.
2 is a cross-sectional view showing a submerged electric explosion apparatus according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below can be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art.

An embodiment of the present invention provides a metal nanopowder manufacturing apparatus by electroexplosion to lower the pulse power to give an electric explosion by vibrating the metal wire, and to uniform the particle size of the nanopowder produced according to the position of the wire. Here, the electroexplosive device includes both an air explosion device for exploding and vaporizing a metal wire with pulse power, and then cooling / condensing it with an atmosphere gas and an underwater explosion device for cooling / condensing in a liquid. However, in the following embodiments, for the sake of convenience of explanation, the submerged electric explosion device will be mainly described.

1 is a cross-sectional view showing a submerged electric explosion apparatus 100 according to a first embodiment of the present invention.

Referring to FIG. 1, the first electroexplosive device 100 includes an upper space 110a and a lower space 110b inside the chamber 110 that provides a space in which the electrical explosion occurs, by an insulator 112 having a plate shape. Separated by. A metal wire feeding part is installed in the upper space 110a, and the wire feeding part receives the wire roll 120 on which the metal wire 102 is wound and the metal wire 102 released from the wire roll 120 in the lower space 102b. It consists of a pair of guide rollers 122 for feeding in the direction. An electric motor (not shown) providing a rotational force is connected to the rotation shafts of the wire roll 120 and the guide roll 122.

The lower space 110b is filled with a liquid 140 including a dispersion solvent, and the liquid 140 may be any one selected from oils, insulating oils, organic solvents of alcohols, distilled water, and other organic solvents. The ground electrode 126 is attached to the liquid 140, and the ground electrode 126 serves as a ground for electrical explosion. The high voltage electrode 130 is installed on the bottom surface of the chamber 110 of the lower space 110b.

The metal wire 102 fed by the guide roll 122 into the lower space 110b passes through the hollow wire guide 124 disposed through the insulator 112. In other words, the metal wire 102 is routed by the wire guide 124 and is fed to reach the vicinity of the high voltage electrode 130 in the lower space 110b. When pulse power is applied to the high voltage electrode 130, the pulse power is transmitted to the metal wire, and the metal wire causes an electrical explosion to vaporize. When the metal wire is vaporized, it may be cooled / condensed by the liquid 140 to obtain nanopowders.

However, the metal wire 102 may be deformed during the electric explosion, and the metal wire 102 vaporized by the explosion does not produce nanoparticles of a certain size. Failure to produce nanoparticles of a constant size means that the size of the nanopowders produced varies depending on the location of the metal wire 102. To solve this problem, an embodiment of the present invention presents a vibrator 150.

The vibrator 150 is a mechanical resonance phenomenon, using the vibration of atoms / electrons, crystal oscillator, LC oscillator and the like can be used. The vibrator 150 increases the vibration of the atoms constituting the metal wire 102 so that the metal wire 102 more easily electric explosion, the vibration of the atoms by the vibrator 150 to the entire wire 102 Happens across.

In the drawing, the vibrator 150 is installed in the wire guide 124 of the upper space 110a, but if necessary, may be mounted to the wire guide 124 of the lower space 110b. In addition, the vibrator 150 may be in the form of a donut surrounding the wire guide 124, the vibration of the vibrator 150 is more effectively transmitted to the wire 102, and the wire guide 124 to protect the vibrator 150. It can be installed through the wall of the. The type and size of the vibrator 150 may vary depending on the first electric explosion apparatus 100 used. Of course, although not shown, the installation of the portion for controlling the operation of the vibrator 150 is obvious.

2 is a cross-sectional view showing the submerged electric explosion apparatus 200 according to the second embodiment of the present invention. Here, the second submerged electroexplosive device 200 has a different structure for feeding a metal wire than the first submerged electroexplosive device 100. That is, the first device 100 supplies wires vertically with respect to the high voltage electrode, whereas the second device 200 supplies wires horizontally with respect to the high voltage electrode. However, the process of manufacturing the nanopowder by the electric explosion is the same as the first device 100 and the second device 200.

According to FIG. 2, the second device 200 includes an upper space 210a in which a main portion for feeding the metal wire 204 exists in the interior of the chamber 210 that provides a space in which the electrical explosion occurs. It is divided into a lower space 210b. The chamber 210 of the upper space 210a is provided with a slot 202 for loading the metal wire 204, which becomes nanopowder by electric explosion. Slot 202 may carry a plurality of metal wires 204 as shown. The metal wire 204 is mounted to the end of the robot arm 222 by the pickup 220. In this case, the pickup unit 220 may use an electromagnet or may have a structure in which the pickup unit 220 is mounted on the pickup unit 220 by the movement of the slot 202. Here, the pickup unit 220 serves to supply a metal wire like the feeding unit of the first device 100.

The robot arm 222 and the pickup 220 have a symmetrical shape with respect to the rotating machine 224 rotated by the drive motor 226. When the robot arm 222 mounted with the metal wire 204 is rotated 90 degrees by the operation of the driving motor 226, the metal wire 204 is introduced into the liquid 240 filled in the lower space 210b. The high voltage electrode 230 is installed on the bottom surface of the chamber 210 of the lower space 210b. The injected metal wire 204 is seated on the high voltage electrode 230. The high voltage electrode 230 is preferably a stepped shape in which both ends protrude as shown, so that the metal wire 204 can be properly seated.

The sliding door 228 is installed to smoothly perform the electric explosion. Specifically, when the sliding door 228 is closed, the lower space 210b in which the electric explosion occurs is isolated. Accordingly, it is possible to prevent the robot arm 222, the rotor 224, the metal wire 204, etc. in the slot 202 from being deformed by the shock wave by the electric explosion.

When the sliding door 228 is closed and the pulse power is applied to the high voltage electrode 230, the metal wire 204 seated on the high voltage electrode 230 is electrically exploded, and the sliding door 228 is opened after the electric explosion and the robot is opened. Arm 222 again rotates 90 degrees to continuously supply metal wire 204.

However, the metal wire 204 may be deformed during the electric explosion, and the metal wire 204 vaporized by the explosion does not produce nanoparticles of a certain size. Here, failing to produce a nano-size of a certain size means that the size of the nano-powder is produced according to the position of the metal wire 204. To solve this problem, an embodiment of the present invention presents a vibrator 250.

The vibrator 250 uses a mechanical resonance phenomenon and vibration of atoms / electrons, and may use a crystal oscillator, an LC oscillator, or the like. The vibrator 250 increases the vibrations of the atoms constituting the metal wire 204, so that the metal wire 204 is more easily electroexploded, the vibration of the atoms by the vibrator 250 to the entire wire 204 Happens across.

In the drawing, the vibrator 250 is preferably installed in the pickup unit 220, and may be installed in the pickup unit 220 to prevent the vibrator 250 from being damaged by the electric explosion. The type and size of the vibrator 250 may vary depending on the second electric explosion apparatus 200 used. Of course, although not shown, the installation of the portion for controlling the operation of the vibrator 250 is obvious.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the scope of the present invention. It is possible.

100; First submerged electric explosion device
102, 204; Metal wires 110 and 210; chamber
110a, 210a; Upper spaces 110b and 210b; Subspace
112; Insulator 120; Wire roll
122; Guide roll 124; Wire guide
126; Ground electrodes 130 and 230; High voltage electrode
140, 240; Liquid 150, 250; Oscillator
202; Slot 220; Pickup section
222; Robot arm 224; Rotator
226; Drive motor 228; Sliding door

Claims (7)

A high voltage electrode causing electrical explosion of the metal wire by high voltage pulse power;
A feeding unit supplying the metal wire to the high voltage electrode; And
And an oscillator mounted on at least one side of the feeding part to provide vibration to the metal wire mounted to the feeding part. The apparatus of claim 1, wherein the feeding part supplies the metal wire in a vertical direction or a horizontal direction with respect to the high voltage electrode. The apparatus of claim 1, wherein the vibrator uses mechanical resonance of the metal wire or vibration of atoms / electrons of the metal wire. The apparatus of claim 1, wherein the vibrator has a donut shape surrounding a portion of the feeding part. The apparatus of claim 1, wherein the vibrator is installed inside the feeding part. The apparatus of claim 1, wherein the vibrator is any one selected from a crystal oscillator or an LC oscillator. The apparatus of claim 1, wherein the electroexplosion occurs in liquid or in air.

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