KR101278493B1 - Device for manufacturing nanostructured powder by electric explosion - Google Patents

Abstract

The present invention relates to an apparatus for producing nanopowders by electroexplosion, and more particularly, to an apparatus for producing nanopowders by electroexplosion, which can produce nanopowders having a uniform size by causing collisions between nanopowders when generating nanopowders. will be.
Nano-powder manufacturing apparatus by an electric explosion according to the invention the chamber; A first high voltage electrode provided in the chamber, a first switch connected to the first high voltage electrode, a first capacitor connected to the first switch, and a first charging device configured to charge the first capacitor to a high voltage Electric explosion device; A second high voltage electrode provided to face the first high voltage electrode in the chamber, a second switch connected to the second high voltage electrode, a second capacitor connected to the second switch, and a second to charge the second capacitor to a high voltage A second electric explosion device including a charging device; And a controller for simultaneously turning on / off the first switch and the second switch.

Description

Device for manufacturing nanostructured powder by electric explosion

The present invention relates to an apparatus for producing nanopowders by electroexplosion, and more particularly, to an apparatus for producing nanopowders by electroexplosion, which can produce nanopowders having a uniform size by causing collisions between nanopowders when generating nanopowders. will be.

Recently, the development of nanostructured powder materials as a new material is very important because it can be applied as a foundation technology in a new field including nano devices.

The ultra fine powder material can exhibit unusual electro-magnetic, mechanical, and catalytic properties that cannot be obtained with conventional materials due to the finer material structure (100 nm or less) and the increase in surface area. Therefore, ultra-high strength parts, magnetic parts, Next-generation functional materials such as thermoelectrics, sensors, filters and catalysts are creating new demand throughout the industry.

With the development of the high-tech industry, high performance and miniaturization of parts and systems are in progress, and currently, a constituent factor of micron or submicron which is used to determine physical / chemical / biological characteristics is used.

Therefore, nanotechnology is a technology that can overcome the limitations of existing technologies for high performance and miniaturization of parts and systems, and also develop new products that are typical of future technologies because new performances can be expressed as the phenomenological length decreases. It is an essential element for.

At present, a variety of methods are known for producing a material from nanopowders, but among them, metal nanopowder production technology by electric explosion using pulse power is widely known and is being actively researched.

The nanopowder manufacturing method using pulse power not only has a very important meaning in terms of industrial applications, but is also economically advantageous compared to other methods of preparing nanopowders.

However, there is a problem that nanoparticles produced by such an electroexplosive method are not uniform in size.

In this regard, Korean Laid-Open Patent Publication No. 10-2007-0024041 (hereinafter referred to as 'prior art') discloses a method and apparatus for manufacturing nanopowders by submerged electroexplosion. Since the nanopowder collecting device is further provided for classifying nanoparticles having a non-uniform size by size, there is a problem in that the manufacturing apparatus becomes complicated and the manufacturing cost of the manufacturing apparatus increases accordingly.

Korean Patent Publication No. 10-2007-0024041

The present invention is to solve the problems as described above, so that it is not necessary to have a separate nano-powder collecting device for classifying the nano-powder by size, the nano-particles having a uniform size by causing a collision between the nano-powders It provides a nano-powder manufacturing apparatus by an electric explosion that can produce a powder.

According to an embodiment of the present invention, an apparatus for manufacturing nanopowders by electric explosion includes a chamber, a first high voltage electrode provided in the chamber, a first switch connected to the first high voltage electrode, and a first capacitor connected to the first switch. A first electric explosion device including a first charging device for charging the first capacitor to a high voltage, a second high voltage electrode provided to face the first high voltage electrode in the chamber, a second switch connected to the second high voltage electrode, A second electric explosion device including a second capacitor connected to the second switch, a second charging device for charging the second capacitor to a high voltage, and for simultaneously turning on / off the first switch and the second switch. It may include a control unit.

The first high voltage electrode and the second high voltage electrode may each include a central electrode connected to the metal wire, and a ground electrode extending to be spaced apart from the central electrode by a predetermined distance and maintained to be spaced apart from the metal wire by a predetermined distance.

In addition, the ground electrode may be provided to surround the metal wire. In this case, the ground electrode may be formed of a plurality of rods having a predetermined length provided in a state spaced apart from the center electrode by a predetermined distance.

The first high voltage electrode and the second high voltage electrode may further include an insulator coupled between the center electrode and the ground electrode, respectively.

In addition, the nano-powder manufacturing apparatus by the electro-explosion according to another embodiment of the present invention, the chamber and two high voltage electrodes provided to face each other in the chamber, a switch connected to the two high voltage electrodes, a capacitor connected to the switch, It may include an electric explosion device including a charging device for charging the capacitor to a high voltage.

In addition, the apparatus for producing nanopowders by electric explosion according to another embodiment of the present invention includes a chamber, a third high voltage electrode provided in a horizontal direction in the chamber, a third switch connected to the third high voltage electrode, and a third A third electric explosion device including a third capacitor connected to the switch, a third charging device for charging the third capacitor at a high voltage, and a fourth high voltage electrode provided in a vertical direction at a position opposite to the third high voltage electrode in the chamber; And a fourth switch connected to the fourth high voltage electrode, a fourth capacitor connected to the fourth switch, a fourth electric explosion device including a fourth charging device for charging the fourth capacitor at a high voltage, and the third switch and the fourth switch. It may include a control unit for simultaneously turning on and off the switch.

In this case, the third high voltage electrode includes a center electrode connected to the metal wire, and a third ground electrode extending to be spaced apart from the center electrode by a predetermined distance and maintained to be spaced apart from the metal wire by a predetermined distance, and the fourth high voltage electrode is a metal wire. It is preferable to include a central electrode connected to the fourth ground electrode which is grounded to the metal wire and serves as a ground for electrical explosion.

In addition, the nano-powder manufacturing apparatus by the electro-explosion according to another embodiment of the present invention, the chamber, two high-voltage electrodes facing each other in the chamber, one is provided in the horizontal direction and the other is provided in the vertical direction, 2 And an electric explosion device including a switch connected to the high voltage electrodes, a capacitor connected to the switch, and a charging device for charging the capacitor at a high voltage.

According to the nano-powder manufacturing apparatus by the electro-explosion according to the present invention, it is possible to produce a nano-powder having a uniform size, accordingly it is not necessary to provide a separate nano-powder collecting device for classifying the nano-powder by size There is an effect that the structure is simplified.

1 is a schematic view showing a nano-powder manufacturing apparatus by an electric explosion according to an embodiment of the present invention.
2 is a view schematically showing the operation of the nano-powder manufacturing apparatus of FIG.
3 is a plan view showing an embodiment of a high voltage electrode used in the present invention.
Figure 4 is a schematic diagram showing a nano-powder manufacturing apparatus by an electric explosion according to another embodiment of the present invention.
Figure 5 is a schematic diagram showing a nano-powder manufacturing apparatus by an electric explosion according to another embodiment of the present invention.
Figure 6 is a schematic diagram showing a nano-powder manufacturing apparatus by an electric explosion according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments introduced herein are provided to ensure that the disclosed subject matter is thorough and complete, and that the spirit of the invention will be fully conveyed to those skilled in the art.

1 is a schematic view showing a nano-powder manufacturing apparatus by an electric explosion according to an embodiment of the present invention.

As shown in Figure 1, the nano-powder manufacturing apparatus according to an embodiment of the present invention is composed of a chamber 10, the first electroexplosion apparatus 20, the second electroexplosion apparatus 30 and the like.

The chamber 10 is provided with a metal wire 12 therein to provide a space in which the nano powder is generated, and is provided to have a predetermined volume. The chamber 10 may be filled with air or an inert gas. Alternatively, it may be provided in a vacuum state.

In addition, although not shown in the drawings, the chamber 10 may further include a supply device for supplying the metal wire 12 into the chamber 10 and a discharge device for discharging the generated nanopowder to the outside.

The first electroexplosion apparatus 20 and the second electroexplosion apparatus 30 are each configured to generate nanopowders by applying the pulse power to the metal wires 12 to electroexplode the metal wires 12. The first electric explosion device 20 and the second electric explosion device 30 are provided to face each other, that is to face each other.

That is, the nanopowder manufacturing apparatus according to an embodiment of the present invention is provided such that the first electroexplosion apparatus 20 and the second electroexplosion apparatus 30 face each other so that the size of the nanopowder is uniformly generated. As such, when the first electroexplosion apparatus 20 and the second electroexplosion apparatus 30 are provided to face each other, collisions between the nanopowders may occur when the nanopowders are generated, thereby preparing nanopowders having a uniform size.

The first electroexplosion apparatus 20 includes a first high voltage electrode 22 provided in the chamber 10 and an first high voltage electrode 22 connected to the metal wire 12 to apply the pulse power to the electric explosion. A first switch 24, a first capacitor 26 connected to the first switch 24, a first charging device 28 for charging the first capacitor 26 at a high voltage, and the like.

The second electroexplosive device 30 includes a second high voltage electrode 32 provided in the chamber 10 and a second high voltage electrode 32 connected to the second high voltage electrode 32 to apply the pulse power to the metal wire 12 to cause the electrical explosion. 2 switch 34, a second capacitor 36 connected to the second switch 34, and a second charging device 38 for charging the second capacitor 36 at a high voltage.

The first high voltage electrode 22 and the second high voltage electrode 32 may be configured to face each other, that is, to face each other.

The first high voltage electrode 22 and the second high voltage electrode 32 are respectively connected to the metal wire 12 in order to apply electrical pulses to the metal wire 12 to explode. Since the second high voltage electrode 32 is configured to face each other, the metal wires 12 respectively connected to the first high voltage electrode 22 and the second high voltage electrode 32 also face each other. When the metal wires 12 are provided to face each other, the nanopowders generated when the first switch 24 and the second switch 34 are turned on and the pulse power is applied to the metal wires 12 momentarily are Each of them instantaneously moves in a direction facing each other, thereby causing collisions with each other, thereby making the size uniform.

In addition, the nano-powder manufacturing apparatus according to an embodiment of the present invention further comprises a control unit 40 for turning on (on / off) the first switch 24 and the second switch 34 at the same time. This is for the collision between the nanopowders generated in the first electroexplosion apparatus 20 and the second electroexplosion apparatus 30 to occur more effectively and smoothly.

Meanwhile, the first high voltage electrode 22 is spaced apart from the first center electrode 222 and the first center electrode 222 by a predetermined distance and spaced apart from the metal wire 12 by a predetermined distance. It is preferably composed of a first ground electrode 224 extending to maintain.

Similarly, the second high voltage electrode 32 is spaced apart from the second center electrode 322 connected to the metal wire 12 and the second center electrode 322 by a predetermined distance from the metal wire 12 by a predetermined distance. It is preferably composed of a second ground electrode 324 extending to maintain the.

As such, the first high voltage electrode 22 and the second high voltage electrode 32 are connected to the first central electrode 222, the second central electrode 322, the first ground electrode 224, and the second ground electrode 324, respectively. When configured, the first switch 24 and the second switch 34 is turned on (on) at the same time the movement of the nano-powder is generated more effectively in a direction facing each other, the collision between the nano-powder can be made more effectively and smoothly have.

This effect will be described in detail with reference to FIG. 2 as follows.

2 is a view schematically showing the operation of the nano-powder manufacturing apparatus of FIG.

As shown in FIG. 2, when the first switch 24 and the second switch 34 are turned on, pulse power is applied to the metal wire 12 connected to the first center electrode 222 and the second center electrode 322, respectively. Is applied to cause an electrical explosion, and the first nanopowder 14 generated from the first central electrode 222 and the second nanopowder 16 generated from the second central electrode 322 move in a direction facing each other. A conflict occurs.

At this time, since the first nanopowder 14, the first ground electrode 224, the second nanopowder 16, and the second ground electrode 324 have the same electric charges, the pushing force acts on each other.

Therefore, as shown in the arrow direction shown in FIG. 2, the first nanopowder 14 and the second nanopowder 16 are generally moved at the ends of the first ground electrode 224 and the second ground electrode 324, respectively. In the form of a beam, the movement in the direction facing each other is effectively generated, thereby generating a collision area 18 where collisions occur at approximately a center, and thus an effective and smooth collision can be achieved.

In more detail, the first high voltage electrode 22 according to the exemplary embodiment of the present invention is provided on the left side (on the drawing) sidewall of the chamber 10, and the second high voltage electrode 32 is the first high voltage electrode. Since the first nanopowder 14 and the second nanopowder 16 face each other, that is, the first nanopowder 14 in the drawing is disposed on the right (side) side wall so as to face 22. From left to right, the second nanopowder 16 moves from right to left.

In this case, as shown in FIG. 2, the first nanopowder 14 is diffused and has a motion that is collected again by the pushing force with the first ground electrode 224, and at the end of the first ground electrode 224. The mobility of the beam form, that is, the linear movement from the left to the right in the drawing is made.

Similarly, the second nanopowder 16 is also diffused and has a motion that is collected again by the pushing force with the second ground electrode 324, and at the end of the second ground electrode 324, i. The linear movement is made from upper right to left.

Accordingly, the first nanopowder 14 and the second nanopowder 16 may go straight in a direction facing each other and may effectively collide with each other at the central portion 18. Accordingly, the first nanopowder 14 and the first nanopowder 14 may be effectively formed. The size of the 2-nano powder 16 can be made uniform, as well as the fine first nano powder 14 and the second nano powder 16 of smaller size can be produced.

In this case, the first ground electrode 224 and the second ground electrode 324 may be provided to surround the metal wire 12. Then, the pushing force of each of the first nanopowder 14 and the second nanopowder 16, and each of the first ground electrode 224 and the second ground electrode 324 may be increased, so that the first nanopowder 14 may be increased. And the straightness of the second nanopowder 16 will be further enhanced, more effective collision will occur.

In addition, the first high voltage electrode 22 and the second high voltage electrode 32 are the first center electrode 222, the first ground electrode 224, the second center electrode 322, and the second ground electrode 324, respectively. The first insulator 226 and the second insulator 326 coupled therebetween may be further included.

This prevents contact between the first center electrode 222 and the first ground electrode 224, the second center electrode 322, and the second ground electrode 324, and prevents the first center electrode 222 and the first ground electrode. 224 and the second center electrode 322 and the second ground electrode 324 are firmly fixed, and the first insulator 226 and the second insulator 326 are preferably made of rubber packing.

3 is a plan view showing an embodiment of a high voltage electrode used in the present invention.

Referring to FIG. 3, the high voltage electrode 52 according to an embodiment of the present invention has a central electrode 522 provided at the center of the electrode and a predetermined length spaced apart from the central electrode 522 by a predetermined distance. The branch may include a ground electrode 524 formed of a plurality of rods, and an insulator 526 coupled between the center electrode 522 and the ground electrode 524. Here, the rod of the ground electrode 524 is preferably a copper rod.

Figure 4 is a schematic diagram showing a nano-powder manufacturing apparatus by an electric explosion according to another embodiment of the present invention.

As shown in Figure 4, the nano-powder manufacturing apparatus according to another embodiment of the present invention, the chamber 10, two high voltage electrodes 22, 32 provided to face each other in the chamber 10, Electricity including a switch 64 connected to two high voltage electrodes 22 and 32, a capacitor 66 connected to the switch 64, and a charging device 68 for charging the capacitor 66 at a high voltage. It consists of an explosion apparatus.

That is, the nano-powder manufacturing apparatus according to another embodiment of the present invention of Figure 4 is not made of two electro-explosive devices, like the nano-powder manufacturing apparatus according to an embodiment of the present invention of FIG. It consists of one electric explosion device having an electrode.

Therefore, as shown in FIG. 4, the apparatus for manufacturing nanopowders according to another embodiment of the present invention has a simpler overall configuration than the embodiment of FIG. 1.

Figure 5 is a schematic diagram showing a nano-powder manufacturing apparatus by an electric explosion according to another embodiment of the present invention.

As shown in FIG. 5, the nanopowder manufacturing apparatus according to another embodiment of the present invention includes a chamber 10, a third high voltage electrode 72 provided in a horizontal direction in the chamber 10, and a third high voltage. The third switch 74 connected to the electrode 72, the third capacitor 76 connected to the third switch 74, and the third charging device 78 for charging the third capacitor 76 at a high voltage. The third electric explosion apparatus 70 and the fourth high voltage electrode 82 and the fourth high voltage electrode 82 which are provided in a vertical direction at a position opposite to the third high voltage electrode 72 in the chamber 10. A fourth electric explosion device including a fourth switch 84 to be connected, a fourth capacitor 86 connected to the fourth switch 84, and a fourth charging device 88 to charge the fourth capacitor 86 to a high voltage 80, and the control part 40 for turning on / off the 3rd switch 74 and the 4th switch 84 simultaneously.

That is, the nano-powder manufacturing apparatus according to another embodiment of the present invention of Figure 5 is composed of two electro-explosive devices facing each other like the nano-powder manufacturing apparatus according to the embodiment of Figures 1 and 4 described above Instead, one electroexplosive device is shown in the horizontal direction and another electroexplosive device is shown in the vertical direction.

As described above, even in the case where the third electric explosion apparatus 70 and the fourth electric explosion apparatus 80 are configured in the horizontal direction and the vertical direction, as shown in FIG. As in the case where the two electroexplosion devices are configured to face each other, collisions between the nanopowders are generated when the nanopowders are generated, and thus nanopowders having a uniform size can be manufactured.

At this time, the third high voltage electrode 72 is spaced apart from the center electrode 722 connected to the metal wire 12 and the center electrode 722 by a predetermined distance and is extended to maintain a distance from the metal wire 12 by a predetermined distance. A third ground electrode 724 is included, and the fourth high voltage electrode 82 includes a center electrode 822 connected to the metal wire 12.

The fourth electric explosion device 80 may further include a fourth ground electrode 89 grounded to the metal wire 12 to serve as a ground for electrical explosion, and the third high voltage electrode 72 A third insulator 726 may be further included between the third central electrode 722 and the third ground electrode 724.

Figure 6 is a schematic diagram showing a nano-powder manufacturing apparatus by an electric explosion according to another embodiment of the present invention.

As shown in Figure 6, the nano-powder manufacturing apparatus according to another embodiment of the present invention is opposed to each other in the chamber 10, the chamber 10, one is provided in the horizontal direction and the other is provided in the vertical direction Two high voltage electrodes 72 and 82, a switch 94 connected to two high voltage electrodes 72 and 82, a capacitor 96 connected to the switch 94, and a capacitor 96 And an electric explosion device including a charging device 98 for charging at a high voltage.

That is, the nano-powder manufacturing apparatus according to another embodiment of the present invention of FIG. 6 is composed of one electric explosion device having two high voltage electrodes as in the embodiment of FIG. 4.

According to the nano-powder manufacturing apparatus by the electro-explosion according to the present invention, it is possible to produce a nano-powder having a uniform size, accordingly it is not necessary to provide a separate nano-powder collecting device for classifying the nano-powder by size The structure can be simplified.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate description of the present invention and to facilitate understanding of the present invention and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10: chamber 20: first electric explosion device
22: first high voltage electrode 24: first switch
26: first capacitor 28: first charging device
30: second electric explosion device 32: second high voltage electrode
34: second switch 36: second capacitor
38: second charging device 40: control unit
70: third electric explosion device 72: third high voltage electrode
74: third switch 76: third capacitor
78: third charging device 80: fourth electric explosion device
82: fourth high voltage electrode 84: fourth switch
86: fourth capacitor 88: fourth charging device

Claims (9)

chamber,
A first high voltage electrode provided in the chamber, a first switch connected to the first high voltage electrode, a first capacitor connected to the first switch, and a first charging device configured to charge the first capacitor to a high voltage; First electric explosion device comprising,
A second high voltage electrode provided to face the first high voltage electrode in the chamber, a second switch connected to the second high voltage electrode, a second capacitor connected to the second switch, and a high voltage of the second capacitor; A second electric explosion device including a second charging device for charging with a battery, and
A control unit for simultaneously turning on / off the first switch and the second switch
Nano powder manufacturing apparatus by an electric explosion comprising. The method of claim 1,
Each of the first high voltage electrode and the second high voltage electrode includes a center electrode connected to a metal wire, and a ground electrode spaced apart from the center electrode by a predetermined distance and extending to maintain a distance from the metal wire by a predetermined distance. Nano powder production apparatus by explosion. 3. The method of claim 2,
The ground electrode is nano-powder manufacturing apparatus by an electric explosion provided to surround the metal wire. 3. The method of claim 2,
The ground electrode is nano-powder manufacturing apparatus by an electric explosion consisting of a plurality of rods having a predetermined length provided in a state spaced apart from the center electrode by a predetermined distance from the radius. 3. The method of claim 2,
And the first high voltage electrode and the second high voltage electrode further comprise an insulator coupled between the center electrode and the ground electrode, respectively. Chamber, and
An electric explosion device including two high voltage electrodes provided to face each other in the chamber, a switch connected to the two high voltage electrodes, a capacitor connected to the switch, and a charging device for charging the capacitor at a high voltage;
Nanopowder manufacturing apparatus by an electric explosion comprising. chamber,
A third high voltage electrode provided in the chamber in a horizontal direction, a third switch connected to the third high voltage electrode, a third capacitor connected to the third switch, and a third to charge the third capacitor at a high voltage A third electric explosion device including a charging device,
A fourth high voltage electrode provided in a vertical direction at a position opposite to the third high voltage electrode in the chamber, a fourth switch connected to the fourth high voltage electrode, a fourth capacitor connected to the fourth switch, and A fourth electric explosion device including a fourth charging device for charging the fourth capacitor to a high voltage, and
A control unit for simultaneously turning on / off the third switch and the fourth switch
Nanopowder manufacturing apparatus by an electric explosion comprising. The method of claim 7, wherein
The third high voltage electrode includes a center electrode connected to the metal wire, and a third ground electrode extending to be spaced apart from the center electrode by a predetermined distance and maintained to be spaced apart from the metal wire by a predetermined distance.
The fourth high voltage electrode is a nano-powder manufacturing apparatus by an electric explosion comprising a central electrode connected to a metal wire, and a fourth ground electrode grounded to the metal wire to serve as a ground for electrical explosion. Chamber, and
Two high voltage electrodes facing each other in the chamber, one provided in a horizontal direction and the other provided in a vertical direction, a switch connected to the two high voltage electrodes, a capacitor connected to the switch, and the capacitor at a high voltage. An electric explosion device comprising a charging device for charging with a
Nanopowder manufacturing apparatus by an electric explosion comprising.

Images