KR20120033505A - Plasma device - Google Patents

Abstract

PURPOSE: A plasma apparatus is provided to prevent the occurrence of discharging voltage increasing problems due to the expanded gap of a discharging electrode and a ground electrode by parallelly arranging the discharging electrode and the ground electrode. CONSTITUTION: A plasma apparatus(100) includes an insulating body(120), a discharging electrode(130), and a ground electrode(140). The discharging electrode is expanded in a rod form from the end part of the insulating body. The ground electrode is parallelly expanded with the discharging electrode from the end part of the insulating body. The virtual expanded lines of the ground electrode and the discharging electrode form an angle less than 15 degrees. The discharging electrode and the ground electrode are parallelly arranged. An air path(126) is arranged in the insulating body. The apparatus includes an air supplying part compulsively supplying external air to the air path.

Description

Plasma Device {PLASMA DEVICE}

The present invention relates to a plasma apparatus, and more particularly, to a plasma apparatus that can be used to improve blood flow or prevent secondary infection of a wound.

Nitric oxide (N0) is known to have an effect of smoothing blood flow by expanding blood vessels in the body, and is automatically made as needed from endothelial cells in the walls of blood vessels to regulate the expansion of blood vessels. Therefore, in the case of living tissues around the burned skin, oxygen supply is not smooth due to blood vessels contracted by burns, blood vessels are contracted due to ulcers or tumors, or blood vessels contracted due to peripheral artery disease caused by diabetes. If the blood flow is not smooth, it is used for medical purposes to improve it. In other words, burns, ulcers, tumors, and peripheral arterial diseases caused by diabetes, endothelial cells are unable to operate normally, so nitrogen monoxide is not automatically created, and thus vasodilation is not automatically regulated, causing oxygen supply problems.

In order to generate the nitrogen monoxide described above, nitrogen monoxide is produced by using a plasma phenomenon outside the skin, and generated near the skin, so that nitrogen monoxide diffuses into the contracted blood vessel located directly below the skin. As a result, the contracted blood vessels can be expanded. Conventional plasma generators induce electric arc discharge by arranging two electrodes at predetermined intervals in a space for generating plasma and applying a high voltage of about 20 kv to one side, thereby inducing an arc discharge. To form a plasma. At this time, the oxygen molecules of the air surrounding the arc discharge may be ionized by ozone or combine with nitrogen to form nitrogen monoxide.

Electrodes used in plasma generators are generally made of tungsten, which has excellent conductivity and good heat resistance and strength. However, when used for a long time, tungsten also causes oxidation or corrosion. In particular, since the end of the electrode where the discharge occurs is severely oxidized or corroded, the length of the electrode is gradually shortened in the process of use, and the increase in the gap between the electrodes due to the change in the electrode length causes a problem of gradually increasing the voltage at which the discharge occurs.

In addition, in the plasma generator as described above, since the discharge occurs between the tips of the positive electrodes, the temperature of the positive electrode tips not only rises sharply but also the ambient temperature of the positive electrodes rises sharply. Therefore, since the temperature inside the plasma generating space rises to a high temperature, directly supplying nitrogen monoxide formed by the plasma phenomenon to the skin may cause a risk of burns.

For the above reason, the conventional plasma generator cannot directly supply nitrogen monoxide to the treatment target, and the conventional plasma generator has a separate cooling device or a relatively relatively space between the injection nozzle for supplying nitrogen monoxide to the plasma generating space and the skin. By connecting using a long hose, the nitrogen monoxide generated in the plasma generating space can be cooled while passing through the hose.

In addition, in the conventional plasma generating apparatus, plasma, radicals, nitrogen monoxide, etc. formed in the plasma generating space may be used for sterilization to prevent secondary bacterial infection on the skin by contacting the wounded skin. However, as mentioned above, plasma, radicals, nitrogen monoxide, etc. generated by discharge cannot be directly supplied to the treatment target because of high temperature, and must be used for therapeutic purposes only after the temperature is dropped through a separate cooling process. Can be.

The present invention provides a plasma apparatus capable of minimizing an increase in discharge voltage due to a gradual distance between electrodes where plasma discharge occurs.

The present invention provides an electrode in which a plasma discharge occurs and a plasma apparatus capable of preventing a rapid rise in the temperature around the electrode.

The present invention directly supplies the product to the skin without a separate device for cooling the product such as nitrogen monoxide, electrons, anions and cations generated by the reaction of the plasma and air, to increase the expansion of the contracted blood vessels and thus blood flow, It also provides a plasma device that can be used for the purpose of skin sterilization to prevent bacterial infection through the wound.

According to an exemplary embodiment of the present invention for achieving the above objects of the present invention, a plasma apparatus includes an insulating body, a discharge electrode exposed in a rod shape from an end of the insulating body, and an end of the insulating body facing the discharge electrode. And a ground electrode exposed side by side with the discharge electrode.

The meaning that the ground electrodes are arranged side by side with respect to the discharge electrode in this specification means that when the two electrodes are extended, the ground electrodes are at a small angle within about 15 degrees with respect to the discharge electrode so that they do not intersect with each other or are formed at considerably distant intersections. It may include arranged to form. In fact, the shortest distance between the two electrodes can always be constant or changed at about the same level.

When the discharge electrode and the ground electrode face each other and are arranged in parallel with each other, the discharge electrode has a plasma discharge as a whole between the part exposed from the insulating body and the ground electrode, and the temperature of the electrode is increased as in the case of plasma generation at both tips. Does not rise sharply

In addition, the discharge is not limited to occurring at the tip of the discharge electrode, the overall occurrence of the end of the discharge electrode is shortened due to oxidation or corrosion, and even if the length of the discharge electrode is short, the ground electrode is in the state facing the discharge electrode In the case of the parallel arrangement, there is no change in distance between the discharge electrode and the ground electrode. Therefore, when the plasma is generated at both tips, the discharge electrode is oxidized and the distance between the discharge electrode and the ground electrode is increased so that the discharge voltage increases. This does not happen.

Moreover, since the temperature of a discharge electrode or a ground electrode does not rise rapidly, nitrogen monoxide and electron which generate | occur | produced by reaction of plasma and air. Products such as anions and cations can be directly supplied to the skin, thereby realizing the expansion of blood flow or disinfection of wounds, and miniaturization of the device can be realized by eliminating the need for a separate device for cooling the plasma product.

In addition, when the discharge electrode and the ground electrode are exposed from the end of the insulating body, and both electrodes are arranged such that the imaginary lines extending from the end of the discharge electrode and the ground electrode form an angle within 15 degrees, the discharge electrode and the ground electrode Discharge may occur at the ends closest to each other in distance. At this time, even when the ends of the discharge electrode and the ground electrode are shortened by oxidation or corrosion, since the distance between the two electrodes is substantially unchanged, the discharge electrode oxidizes when the plasma is generated at both tips and the discharge electrode. The distance between the ground electrodes is increased to minimize the problem of increasing the discharge voltage.

Meanwhile, the ground electrode may also be provided in a rod shape like the discharge electrode, or may be provided in a plate shape. Even when the ground electrode is provided in a rod shape or a plate shape, when the ground electrode is disposed in parallel with the discharge electrode, the discharge does not occur locally between a specific point of the discharge electrode and the ground electrode, but between the discharge electrode and the ground electrode. Since the discharge occurs entirely between the discharge electrode and the ground electrode having a constant distance, the temperature of the electrode is prevented from rising rapidly. Also, even if the discharge electrode loses its end due to corrosion, the distance between the discharge electrode and the ground electrode does not occur because the ground electrode is disposed in parallel with the discharge electrode, which means that the ground electrode has approximately the discharge electrode. The same is true when tilting at an angle within 15 degrees. In some cases, the ground electrode may be provided in an arc shape, and in this case, the ground electrode may be provided so that the distance from the ground electrode to the discharge electrode is always the same in the cross section perpendicular to the parallel direction.

In the present invention, the meaning that the ground electrodes are disposed in parallel with the discharge electrodes may include the meaning that they do not cross each other when extending the electrodes. In other words, the virtual repair from the specific point of the discharge electrode toward the ground electrode may be performed. That is, the length of, ie, the distance closest to the ground electrode at any point of the discharge electrode may include the meaning that it is always kept constant.

In addition, an air flow path formed adjacent to the discharge electrode and the ground electrode may be formed in the insulating body, and a more smooth air supply may be made through the air flow path.

In addition, the plasma apparatus according to the present invention may include an air supply unit for forcibly supplying the outside air of the insulating body through the flow path of the air, which can constantly produce a plasma product through the smooth air supply, the temperature of the electrode You can also implement the effect of lowering.

On the other hand, the plasma apparatus according to the present invention may include a coupling cap for maintaining a constant distance between the discharge electrode and the ground electrode and the skin, to prevent the discharge electrode and the ground electrode to contact the skin.

In the plasma apparatus of the present invention, since the discharge electrode and the ground electrode are arranged side by side, the discharge electrode is oxidized and the distance between the discharge electrode and the ground electrode increases so that the discharge voltage increases as in the case of plasma generation at both tips. Does not occur. Specifically, when both electrodes are arranged in parallel, the discharge is not limited to occur at the tip of the discharge electrode and the ground electrode, and the phenomenon occurs as a whole and the end of the discharge electrode or the ground electrode is shortened by oxidation or corrosion. Even if the length of the electrode or the ground electrode is shortened, since the ground electrodes are arranged in parallel to the discharge electrode, the distance change between the discharge electrode and the ground electrode does not occur, and as in the case of plasma generation at both tips, the discharge Since the electrode is oxidized and the distance between the discharge electrode and the ground electrode is far, there is no problem of increasing the discharge voltage. Similarly, even when the discharge electrode and the ground electrode are arranged side by side while maintaining the angle within 15 degrees, even if the ends of the discharge electrode and the ground electrode are shortened, since the shortest mutual distance does not change significantly, the distance between the discharge electrode and the ground electrode The increase in the discharge voltage resulting from this distance is minimized.

In the plasma apparatus of the present invention, when the discharge electrode and the ground electrode are arranged in parallel, the discharge occurs evenly between the discharge electrode and the ground electrode, which is similar to the discharge between two electrodes with sharp ends at each other, as in the conventional plasma generator. Compared with the case where it occurs, it is possible to prevent the temperature of the electrode and the electrode surroundings from rising sharply.

Nitrogen monoxide and electrons generated by the reaction of plasma and air because the temperature of the discharge electrode or the ground electrode does not rise rapidly in the plasma apparatus of the present invention. Products such as anions and cations can be supplied directly to the skin, thereby realizing the expansion of blood flow or the disinfection of wounds.

The plasma apparatus of the present invention can realize miniaturization of the apparatus by eliminating the need for a separate apparatus for cooling the plasma product.

1 is an exploded perspective view of a plasma apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of the plasma apparatus of FIG. 1.
3 is a partial cross-sectional view of the plasma apparatus of FIG. 1.
4 are front views illustrating various discharge electrodes and ground electrodes applicable to the plasma apparatus according to the present invention.
5 is a perspective view of the disposable coupling cap applied to the plasma device of FIG.
6 is a front view illustrating a discharge electrode and a ground electrode in the plasma apparatus according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. For reference, in the present description, the same numbers refer to substantially the same elements, and may be described by quoting contents described in other drawings under such a rule, and the contents repeated or deemed apparent to those skilled in the art may be omitted.

1 is an exploded perspective view of a plasma apparatus according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the plasma apparatus of FIG. 1, and FIG. 3 is a partial cross-sectional view of the plasma apparatus of FIG. 1.

1 to 3, the plasma apparatus 100 includes a housing 110, an insulating body 120, a discharge electrode 130, a ground electrode 140, and an air supply unit 150.

The housing 110 is provided in a hollow so that the insulating body 120 can be inserted and mounted therein, and includes an upper housing 112 and a lower housing 114. The upper housing 112 and the lower housing 114 are manufactured to be screwed together. An insertion hole 113 is formed at an upper end of the upper housing 112 to allow an external power supply line 172 to enter and be connected to the discharge electrode 130, and the power supply line 172 is an external power supply unit 170. ) Can be powered. At the lower end of the lower housing 114, an outlet 115 is formed to discharge the product generated by the plasma to the outside of the housing 110.

The air supply hose 160 is connected to the insertion hole 113 of the upper housing 112 so that the air supplied from the external air supply unit 150 flows in, and the power supply line 172 described above is the air supply hose 160. It is arranged inside. The air supply unit 150 may use an air pump provided outside the housing 110, and in some cases, may be mounted inside the housing 110. In this case, the air supply 150 may be a fan operated by a small battery. May be provided. Plasma products may be constantly generated through a smooth supply of air supplied from the air supply unit 150, and the effect of lowering the temperature of the electrode may be realized.

The housing 110 may be manufactured by selecting various materials such as plastic, rubber, and metal, but the outer surface of the housing 110 is preferably covered with an insulating material such as plastic or rubber, and in this embodiment, the housing 110. ) Is manufactured using plastic.

The insulating body 120 may be manufactured using an insulating material, but may be manufactured using a ceramic material that can withstand a high temperature. The insulating body 120 may have an outer shape that may be tightly fixed to the inner surface of the housing 110. In addition, the insulating body 120 is formed with a discharge electrode mounting hole 122 and a ground electrode mounting hole 124 penetrated along the longitudinal direction of the insulating body 120, and is supplied from the air supply hose 152 described above. An air passage 126 is provided through which air may pass through the hollow inside the housing 110.

The insulating body 120 is a device for preventing plasma discharge from occurring in any part other than the discharge electrode 130 and the ground electrode 140, the insulating body 120 may be provided formed entirely of an insulator, The outer surface of the insulating body may be provided by coating with an insulating material.

The discharge electrode 130 is inserted into and fixed in the discharge electrode mounting hole 122 of the insulating body 120, and is exposed in a rod shape from an end of the insulating body 120. The upper end of the discharge electrode 130 is electrically connected to the power supply line 172 described above, and a high voltage current is supplied. Accordingly, the discharge electrode 130 is preferably manufactured using tungsten having excellent conductivity and good heat resistance and strength.

Meanwhile, the ground electrode 140 faces the discharge electrode 130 and is exposed from the end of the insulating body 120, but maintains parallel with the discharge electrode 130. The ground electrode 140 also uses tungsten having excellent conductivity and good heat resistance and strength.

The ground electrode 140 serves as a ground electrode. The ground electrode 140 may be grounded on the inner surface of the housing 110, and may be grounded to the housing 110 or to the outside through a separate wire. In the present embodiment, the housing 110 is used as the ground, and the inner surface of the housing 110 is coated with a conductive material that can be used as the ground of the ground electrode 140.

Since the above-described discharge electrode 130 and the ground electrode 140 face each other and are disposed in parallel, the discharge electrode 130 may generate a plasma discharge as a whole between the portion exposed from the insulating body 120 and the ground electrode 140. The temperature of the electrode does not rise sharply as in the case of plasma generation at both tips.

When the voltage is high enough to cause the discharge as a whole in a portion where the discharge electrode 130 and the ground electrode 140 face each other, a high-density high-temperature spark plasma is generated. In the plasma apparatus 100 according to the present invention, a spark is a spark generated intermittently. Typically, with a frequency of 1 Hz, the duration of the pulse is several microseconds. Using pulsed sparks at a frequency of 1 Hz, plasma can be generated at atmospheric pressure without additional cooling, where the plasma discharge is cold due to rapid expansion. Because of its cooling, it can generate plasma near the body and can be safely used directly on the skin.

In addition, when the frequency of plasma generation is 10 Hz or more, the temperatures of the discharge electrode 130 and the ground electrode 140 may increase. The reason for using frequencies above 10 Hz is to increase the intensity of the product of the plasma. In this case, by continuously inducing the flow of air to the air flow path 126 formed in the insulating body 120 through the air supply unit 150 described above, it is possible to prevent the electrode or its ambient temperature rise. That is, when the frequency of plasma generation is 1Hz, it is not necessary to use a separate cooling air, but when the frequency is increased by 10Hz or more, it is possible to protect the electrode by using a separate cooling air.

In addition, the discharge is not limited to occur at the tip of the discharge electrode 130, but occurs along the longitudinal direction as a whole, the phenomenon that the end of the discharge electrode 130 is shortened by oxidation or corrosion, and the discharge electrode 130 or ground Even if the lengths D1 and D2 of the electrode 140 are shortened, since the ground electrode 140 is disposed in parallel with the discharge electrode 130, the distance between the discharge electrode 130 and the ground electrode 140 ( no change occurs in h1). Thus, unlike the case where the plasma is generated at both tips, the distance h1 between the discharge electrode 130 and the ground electrode 140 is far from each other so that the discharge voltage does not increase.

In addition, since the temperature of the discharge electrode 130 or the ground electrode 140 does not increase rapidly, nitrogen monoxide and electrons generated by the reaction of plasma and air. Products such as anions and cations can be directly supplied to the skin, thereby realizing the expansion of blood flow or disinfection of wounds, and miniaturization of the device can be realized by eliminating the need for a separate device for cooling the plasma product.

Meanwhile, in the present embodiment, both the discharge electrode 130 and the ground electrode 140 use wires having a rod shape, but the shape of the ground electrode may be changed in some cases. It demonstrates in detail.

The ground electrode and the discharge electrode shown in FIGS. 4 (a) to 4 (e) are cross-sections cut vertically with respect to the longitudinal direction thereof. Referring first to FIG. 4 (a), the ground electrode 130 and the discharge electrode are shown. 140 uses a wire having a rod shape, and as shown in FIG. 4A, the ground electrode 130 and the discharge electrode 140 provided in the rod shape are disposed in parallel to face each other.

Accordingly, the discharge does not occur locally between the specific point of the discharge electrode 130 and the ground electrode 140, and the discharge electrode 130 having a constant distance h1 between the discharge electrode 130 and the ground electrode 140. Since the discharge occurs entirely between the ground electrodes 140, the temperature of the electrode is prevented from rising sharply, and even if the end is lost due to corrosion of the discharge voltage 130 or the ground electrode 140, the ground electrode 140 is discharge electrode. Since it is disposed in parallel with the state facing 130, the change in the distance h1 between the discharge electrode 130 and the ground electrode 140 does not occur.

In the present invention, the fact that the ground electrodes are arranged in parallel with the discharge electrodes includes the meaning that they do not cross each other when extending the electrodes, which means that the length of the virtual repair line toward the ground electrode at any point of the discharge electrode, that is, the discharge At any point of the electrode, the closest distance between the ground electrodes may mean always the same.

Each of the discharge electrodes 131 to 134 illustrated in FIGS. 4B to 4E is disposed in parallel with the ground electrodes 141 to 144, respectively, and thus, FIGS. 4B to 4E. The discharge electrodes 131 ˜ 134 and the ground electrodes 141 ˜ 144 shown in FIG. 4 are similar to the discharge electrode 130 and the ground electrode 140 shown in FIG. 4A, and the discharge electrodes 131 ˜ 134. Discharge occurs as a whole between each point of the ground electrodes 141 to 144 spaced apart at a predetermined distance h1 to h4 at each point along the longitudinal direction of.

Specifically, in Figure 4 (b) the discharge electrode 131 is provided in the form of a rod, the ground electrode 141 is provided in the form of a plate, in Figure 4 (c) the discharge electrode 132 is in the form of a rod, the ground The electrode 142 is provided in the form of an arc. In this case, when the ground electrode 142 is cut in the longitudinal direction of the ground electrode 142 of the ground electrode 142 in FIG. 4C, the ground electrode 142 is provided in a fan shape to discharge the electrode ( There are a myriad of shortest distances h2 towards 132. That is, the discharge electrode 132 is discharged entirely with the inner surface of the ground electrode 142 having the same distance. The ground electrode 143 shown in FIG. 4 (d) is also provided in the same arc shape as the ground electrode 142 shown in FIG. 4 (c), but the inner surface of the ground electrode 143 shown in FIG. The silver does not have the same distance as the discharge electrode 133 as a whole. However, at any point of the discharge electrode 133, the length h3 of the portion having the shortest distance from the ground electrode 143 is always the same, and in the present invention, both electrodes may be considered to be disposed in parallel. The ground electrode 144 of FIG. 4 (e) is provided in a V-shape, and at any point of the discharge electrode 134, the length of the shortest distance from the ground electrode 144 is always the same, and In the present invention, it can be seen that both electrodes are arranged in parallel.

On the other hand, when the plasma apparatus 100 is directly used in the affected part, as shown in FIG. 5, the lower housing 114 is not directly in contact with the affected part. It can provide a disposable coupling cap 180 for holding.

The inner side of the disposable coupling cap 180 is provided with a receiving portion corresponding to the shape of the outer surface of the lower housing 114 that is the outlet side end of the housing 110, so that the coupling cap 180 is fitted to the lower housing 114 Can provide.

Plasma products generated by the plasma generated at both electrodes 130, 140, ie, nitrogen monoxide, electrons, anions, and cations can be discharged through the hole 182 of the disposable coupling cap 180, and the new plasma product Can be supplied continuously or intermittently. As the material of the coupling cap 180, polytetrafluoroethylene, which is strong in heat, and hardly reacts with chemicals, may be used among synthetic resins, and by using the coupling cap 180, a new coupling cap 180 for each patient. By using, it is possible to prevent indirect infection between patients.

Hereinafter, a plasma apparatus according to another embodiment of the present invention will be described in detail. In the present embodiment, other components except for the discharge electrode and the ground electrode are substantially the same as those of the previous embodiment, and the detailed description thereof will be described in the foregoing. An example may be referred to. In this embodiment, the discharge electrode and the ground electrode which are different from the previous embodiment will be mainly described.

6 is a front view illustrating a discharge electrode and a ground electrode in the plasma apparatus according to another embodiment of the present invention.

Referring to FIG. 6, the discharge electrode 222 and the ground electrode 224 are exposed side by side from one end of the insulating body 220. At this time, the ground electrode 224 is inclined with respect to the discharge electrode 222 so that the imaginary lines extending from the ends of the discharge electrode 222 and the ground electrode 224 maintain the angle θ within 15 degrees. Exposed. In this case, plasma discharge may occur at the end of the ground electrode 224 from the end of the discharge electrode 222 forming the shortest distance between the two electrodes. Of course, the angle may be formed somewhat smaller or larger at 15 degrees.

In the discharge electrode 222 and the ground electrode 224 of the present embodiment, both tips may oxidize when plasma is generated, and thus the distance between the discharge electrode 222 and the ground electrode 224 may be increased. However, even when the length of the discharge electrode 222 or the ground electrode 224 is shortened, since the ground electrode 224 is inclined at a small angle θ within 15 degrees with the discharge electrode 222, the discharge electrode ( There is virtually no change in the distance h2 between the 222 and the ground electrode 224, thereby minimizing an increase in the discharge voltage that may occur due to the distance h2 between the discharge electrode 222 and the ground electrode 224.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: Plasma apparatus 110: Housing
112: upper housing 113: insertion hole
114: lower housing 115: outlet
120: insulated body 122: discharge electrode mounting hole
124: ground electrode mounting hole 126: air flow path
130: discharge electrode 140: ground electrode
150: air supply part 160: hose
170: power supply

Claims (10)

Insulated body;
A discharge electrode exposed in a rod shape from an end of the insulating body; And
A ground electrode facing the discharge electrode and exposed to the discharge electrode in parallel with the discharge electrode from the end of the insulating body;
Plasma device comprising a. The method of claim 1,
And each imaginary extension line extending the ground electrode and the discharge electrode forms an angle within 15 degrees. The method of claim 1,
And the discharge electrode and the ground electrode are disposed in parallel to each other. The method of claim 1,
And the ground electrode is provided in a rod shape. The method of claim 1,
And the ground electrode is provided in a plate shape. The method of claim 5,
And the ground electrode is provided in an arc shape. The method of claim 6,
In a cross section perpendicular to the parallel direction,
And the ground electrode has the same distance as the discharge electrode. The method of claim 1,
And an air flow path formed adjacent to the discharge electrode and the ground electrode. The method of claim 8,
And an air supply unit forcibly supplying external air of the insulating body through the air passage. The method of claim 1,
And a coupling cap configured to maintain a constant distance between the discharge electrode and the ground electrode and the skin so as to prevent the discharge electrode and the ground electrode from contacting the skin.

Images