KR20100021161A - Electrode assembly for processing plasma - Google Patents

Abstract

PURPOSE: An electrode assembly for a plasma process is provided to increase the lifespan of an electrode by protecting the electrode through a cap and a case. CONSTITUTION: An internal electrode(100) has a cylindrical shape. A dielectric is inserted into an outer circumference of the internal electrode. The dielectric is longer than the internal electrode. The external electrode is coated on the outer surface of the dielectric. The external electrode has the length corresponding to the internal electrode. A cap(400a,400b) is inserted into both sides of the dielectric. A case(500) is fitted to the outer surface of the dielectric with the cap. The internal electrode is made of the meal. The external electrode is made of the conductor. The dielectric is made of one of quartz, glass, and ceramic tube. The cap and the case are made of the plastic.

Description

Electrode assembly for plasma processing {ELECTRODE ASSEMBLY FOR PROCESSING PLASMA}

The present invention relates to an electrode assembly for plasma processing, and more particularly, to an electrode assembly for plasma processing improved to enable high-efficiency atmospheric plasma generation during odor removal and air purification.

As is well known, atmospheric plasma refers to a low temperature plasma generated at atmospheric pressure. For example, a high voltage is applied between two metal electrodes in the atmosphere, and electrons in one electrode jump out while emitting blue flashes to the other electrode. Corona discharge which is a phenomenon can be mentioned as a typical example.

As described above, when plasma is generated by inter-electrode discharge at atmospheric pressure, electrons collide with air molecules, and ionization is actively performed. Thus, anions such as OH ^- or O ₂ ^- are generated. It collides quickly, producing ozone, which is bactericidal.

Therefore, using these principles and phenomena, efforts have recently been made to apply atmospheric plasma in fields such as air purification and odor removal, and many products are on the market.

However, since the structure of the conventional plasma electrode assembly, namely, the structure of a plasma (Plasma Actor) for plasma generation and processing is mainly in the form of two plates spaced apart from each other, particularly, a bad smell generated during food waste treatment is introduced. It was very difficult to decompose and remove malodorous components, and the efficiency was very low.

For example, food waste, which is growing exponentially in recent years, has problems with its disposal, but the extreme odor generated during disposal has reached a level that can harm the residential environment.

However, there are very limited and expensive devices that can effectively remove and purify such odors by introducing such odors effectively, and most pipes used to introduce odors even when an atmospheric plasma is applied to remove odors. In contrast to the cylindrical shape, the structure of the plasma reactor has a disadvantage in that the plasma treatment efficiency is inferior because the majority of the structure of the plasma reactor does not fit with each other because of the difficulty of installation, as well as a simple plate-shaped electrode.

The present invention has been created in view of the above-mentioned problems in the prior art, and has been created in order to solve the problem. The structure is simple, easy to manufacture, and low in manufacturing cost, and is easy to install in a cylindrical pipe because it is formed in a cylindrical shape. A new type of plasma that is effective for removing odors, which can maximize plasma treatment efficiency even within a short time in a short time by increasing the discharge efficiency by forming the electrode structure in a net shape and protecting the electrode with a plastic case to extend the service life. There is a major problem in providing an electrode assembly for processing.

The present invention is a means for achieving the above object, the cylindrical internal electrode; A dielectric inserted into an outer circumferential surface of the inner electrode and having a length longer than that of the inner electrode; An external electrode applied to an outer surface of the dielectric and having a length corresponding to the internal electrode; Caps fitted to both ends of the dielectric; Provided is an electrode assembly for plasma processing, characterized in that the case is fitted to the outer surface of the dielectric including the cap to protect them.

At this time, the internal electrode is formed of a metal; The external electrode is formed of a conductor, and the dielectric is formed of any one selected from quartz, glass, and ceramic tubes, and the cap and the case are formed of plastic.

In this case, the metal forming the internal electrode is any one of SUS and Al; The conductor forming the external electrode is characterized in that any one of Ag, Cu, Al.

In addition, the coating thickness of the external electrode is preferably 5㎛-1mm.

In addition, the cap, which is assembled on the side where the air containing the malodor to be processed is introduced into the inner electrode side of the cap is characterized in that formed in a shape that narrows the diameter toward the inner electrode.

In addition, at least one heat dissipation hole is further formed on the outer surface of the case.

Furthermore, a groove is formed in a portion where the cap is fitted into the dielectric, and an inner diameter side of the cap is further protruded so that a protrusion is formed to contact the internal electrode.

According to the present invention, the electrode assembly for plasma generation for odor removal can be manufactured at low cost, and the structure is simple, so that the installation and disassembly and assembly are easy, the discharge efficiency is high, the odor removal efficiency is high, and the cap and case Since the electrode is protected, the service life is long.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

1 is an exemplary perspective view of an electrode assembly for plasma processing according to the present invention, FIG. 2 is an exploded perspective view of the electrode assembly for plasma processing according to the present invention, and FIG. 3 is a partial cutaway view of the electrode assembly for plasma processing according to the present invention. 4 is a cross-sectional view of an electrode assembly for plasma processing according to the present invention.

As shown in FIGS. 1 to 3, the electrode assembly for plasma processing according to the present invention includes a cylindrical inner electrode 100 and an outer electrode disposed to be fitted to the inner electrode 100 at intervals. 200, and a combination of these electrodes (100,200) to form a plasma reactor (Plasma Actor).

In this case, a dielectric material 300 is interposed between the internal electrode 100 and the external electrode 200.

Here, the dielectric 300 is preferably any one selected from quartz, glass, and ceramic tubes.

In addition, the dielectric 300 is used to increase the capacitance as a material that generates an electric polarization but does not generate a direct current when an electrostatic field is applied, and the above-described materials are preferable.

In addition, the internal electrode 100 is made of a metal such as SUS, Al, etc., and the external electrode 200 is made of a conductor such as Ag, Cu, Al, etc. In particular, the external electrode 200 is quartz, glass, It is preferably formed in a form that is applied to the outer surface of any one dielectric 300 selected from the ceramic tube.

In addition, the internal electrode 100 is particularly preferably manufactured in the form of a mesh (lattice) in order to increase the discharge efficiency during plasma generation.

As such, the reason for forming the internal electrode 100 in the form of a mesh is to increase the electric field by increasing a reverse line in a vertically orthogonal portion, whereby local discharge occurs intensively in such a portion. Since there are more than a few dozen, the discharge is induced throughout the internal electrode 100, and thus serves to improve the discharge efficiency.

Of course, in some cases, the external electrode 200 may also be configured in the form of a mesh so as to correspond to the internal electrode 100. In the present invention, the outer electrode 200 is coated with a uniform and uniform thickness along the outer surface of the cylindrical dielectric 300. This is preferred.

In this case, the coating thickness of the external electrode 200 is different depending on the diameter of the internal electrode 100, but usually 5㎛ ~ 1mm is preferred.

This is because the thinner the coating thickness, the output voltage is lowered, the efficiency is improved, but there is a problem that the durability is lowered at 5㎛ or less, the efficiency is greatly reduced at 1mm or more, so this range is preferable.

In addition, in the present invention, since the inner electrode 100 and the outer electrode 200 are in close contact with each other with the dielectric 300 interposed therebetween, the power efficiency is lower than the applied voltage applied to the conventional general plasma electrode assembly having a large separation distance. And advantageous in terms of plasma generation, but does not need to be particularly limited and may vary depending on the conditions of use, that is, the size of the electrode, the type of the workpiece, the distance between the electrodes, and the like.

In addition, as a power source to be used in the electrode assembly according to the present invention, pulse, sine wave, DC power can be used, but the most stable result can be obtained when AC voltage is applied, and the applied frequency is 0.5 ~ 100kHz The range is preferable, and the power supply and the specification of the high voltage transformer vary depending on the range of the applied frequency.

3 and 4, the internal electrode 100 and the external electrode 200 are disposed only on a part of the length of the dielectric 300, and caps 400a and 400b are formed at both ends of the dielectric 300. Is fitted.

The caps 400a and 400b serve to reliably support the electrode assembly according to the present invention, prevent damage to the electrodes, and further guide the flow of air to the internal electrode 100 to improve plasma processing efficiency. Is to maximize.

To this end, grooves 410 are formed at one end of the caps 400a and 400b, and end portions of the dielectric 300 are fitted into the grooves 410, respectively.

At this time, as the groove 410 is formed, the inner diameter side is more protruding than the outer diameter side is preferably formed in the protrusion 440, which is in contact with the inner electrode 100, the front end of the internal electrode (stable and stable) This is to prevent leakage through both ends of the internal electrode 100 while supporting the 100.

In addition, at the opposite ends of the grooves 410 of the caps 400a and 400b, a step 430 may be formed to fix the pipe.

In addition, a portion of the caps 400a and 400b face each other in the radial direction, and a pair of holes 420 are formed, and the holes 420 are for fixing the case 500 to be described later with bolts.

In addition, the drawing grooves H1 and H2 are formed at arbitrary positions corresponding to each other among the edges of the caps 400a and 400b facing each other, and the inner electrode 100 is formed through the drawing grooves H1 and H2. And lead wires for supplying power to each of the external electrodes 200.

In addition, any one of the caps 400a and 400b, preferably the side cap 400a into which the air to be treated including the odor is introduced, has a larger diameter on one side and a smaller diameter toward the other side. It may also be configured to have a conical shape.

This is to allow the flow of incoming air to be guided more smoothly without leakage toward the internal electrode 100.

Meanwhile, the outermost surface of the dielectric 300 to which the caps 400a and 400b are inserted, that is, the outer circumferential surface of the caps 400a and 400b, is spaced apart from the external electrode 200 as shown in FIGS. 1 and 4. The case 500 is fitted.

The case 500 is fitted outside the caps 400a and 400b, and bolts (not shown) inserted through the holes 520 are bolted to the holes 420 formed in the caps 400a and 400b. It is to be fixed, and to close the gap between the cap (400a, 400b) and the dielectric 300 coupled (part of the dielectric end is inserted) to minimize the leakage of current during discharge for plasma generation in particular desirable.

In addition, lead-out grooves H3 are formed at both ends thereof so that lead wires connected to each of the internal electrode 100 and the external electrode 200 can be drawn out.

In addition, at least one heat dissipation hole 510 is formed in a radial direction in the outer circumferential surface of the case 500 so that high heat generated during plasma processing can be cooled by air, thereby extending plasma treatment efficiency and life of the electrode body. Zoom in even better.

In addition, it is preferable that both the caps 400a and 400b and the case 500 described above are made of plastic in terms of cost and weight.

The operating relationship of the present invention made of such a configuration is as follows.

First, the electrode assembly according to the present invention is assembled as follows.

That is, the internal electrode 100 having a diameter of a predetermined size is provided, and the dielectric 300 having an inner diameter corresponding to the outer diameter of the inner electrode 100 is fitted to the outer circumferential surface of the inner electrode 100.

In this case, the internal electrode 100 is particularly preferably configured in a mesh shape, for example, it may be easily configured by fixing a curled end, for example, by rolling a rectangular mesh (reticle) electrode in a cylindrical shape.

In addition, an outer electrode 200 having a length corresponding to that of the inner electrode 100 is coated on an outer circumferential surface of the dielectric 300, that is, an outer surface thereof. It is especially preferable to apply | coat and form in shape.

In this case, the internal electrode 100 and the external electrode 200 are configured to be not disposed at both ends of the dielectric 300 so that the caps 400a and 400b may be fitted to both ends of the dielectric 300, respectively. This is preferred.

The caps 400a and 400b may be fitted to face each other with the dielectric 300 interposed therebetween, and may have the shape shown in FIG. 4.

In addition, if necessary, as shown in FIG. 3, one of the caps 400a and 400b may be formed to have a substantially conical shape and then inserted into one end of the dielectric body 300 in the same manner as described above.

In this case, the portion fitted to one end of the dielectric 300 is preferably a relatively small diameter, it is preferable that the air to be processed is installed on the side that is introduced toward the internal electrode (100).

In this way, when the assembly between the internal and external electrodes 100 and 200 and the dielectric 300 and the caps 400a and 400b is completed, the electrode assembly is completed by covering the case 500 with bolts and inserting holes for power supply. The lead assembly is inserted through the hole 420 and the hole 420, and then connected to the inner electrode 100 and the outer electrode 200, respectively, to finally complete the electrode assembly of the present invention.

The electrode assembly of the present invention having the structure as described above has an air purification function by inserting a pipe through which odor flows into the stepped jaw 430 formed at both ends of the caps 400a and 400b, and then applying a predetermined power to plasma treatment. In particular, the odor generated during food waste disposal can be easily and easily removed.

In addition, the simple structure makes installation and disassembly and assembly easy and inexpensive.

1 is an exemplary perspective view of an electrode assembly for plasma processing according to the present invention;

2 is an exploded perspective view of an electrode assembly for plasma processing according to the present invention;

3 is a partially cutaway perspective view of an electrode assembly for plasma processing according to the present invention;

4 is a cross-sectional view of an electrode assembly for plasma processing according to the present invention;

♧ description of the symbols for the main parts of the drawing ♧

100 .... Internal electrode 200 .... External electrode

300 ... dielectric 400a, 400b ... cap

500 .... case

Claims (7)

A cylindrical internal electrode 100; A dielectric 300 inserted into an outer circumferential surface of the inner electrode 100 and having a length longer than that of the inner electrode 100; An external electrode 200 applied to an outer surface of the dielectric 300 and having a length corresponding to that of the internal electrode 100; Caps 400a and 400b fitted to both ends of the dielectric 300; Plasma processing electrode assembly, characterized in that consisting of a case 500 that is bolted after being fitted to the outer surface of the dielectric 300 including the cap (400a, 400b). The method according to claim 1; The internal electrode 100 is formed of a metal; The external electrode 200 is formed of a conductor, and the dielectric 300 is formed of any one selected from quartz, glass, and ceramic tubes, and the caps 400a and 400b and the case 500 are formed of plastic. An electrode assembly for plasma processing. The method according to claim 2; The metal forming the internal electrode 100 is any one of SUS and Al; The conductor for forming the external electrode 200 is an electrode assembly for plasma treatment, characterized in that any one of Ag, Cu, Al. The method according to claim 1; The electrode assembly for plasma processing, characterized in that the coating thickness of the external electrode 200 is 5㎛-1mm. The method according to claim 1; Of the caps 400a and 400b, the cap 400a, which is assembled on the side into which air containing a malodor to be treated is introduced into the inner electrode 100, is formed in a shape in which the diameter narrows toward the inner electrode 100. An electrode assembly for plasma processing. The method according to claim 1; At least one heat dissipation hole (510) is further formed on an outer surface of the case (500), the electrode assembly for plasma processing. The method according to claim 1; A groove 410 is formed at a portion at which the caps 400a and 400b are inserted into the dielectric 300, and an inner diameter of the cap 400a and 400b is further protruded so as to contact the internal electrode 100. Electrode assembly for plasma processing, characterized in that formed.

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