KR102018180B1 - Skin treatment apparatus using plasma - Google Patents

Abstract

The present invention is a main housing formed an inner space; A galvanic housing installed at one side of the main housing and having a hollow portion; A plasma electrode installed in a hollow portion of the galvanic housing and emitting plasma toward a treatment site; An ozone discharge unit installed in an inner space of the main housing and discharging ozone generated from the plasma electrode to the outside; And a discharge housing installed at the other side of the main housing and having a plurality of discharge holes therethrough so that ozone can be discharged to the outside by the ozone discharge unit.

Description

Skin treatment apparatus using plasma {Skin treatment apparatus using plasma}

The present invention relates to a skin treatment apparatus using plasma, and more particularly, to a skin treatment apparatus capable of sterilizing various bacteria causing skin diseases by applying plasma to the skin and improving regeneration effect of skin tissue.

In order to improve skin's elasticity and improve various skin diseases such as acne, blotch, blemishes, pigmented lesions, which are problematic skin, a method of applying cosmetics composed of various ingredients to the skin is widely used.

However, under the epidermis constituting human skin, a protective barrier is formed with a thick protein protective layer, and the epidermal and dermis of the skin are separated from each other by this protein protective layer. Since it is common to not penetrate cosmetics deep, there is a limit to skin care using cosmetics.

As a result, there is a problem that the treatment for the improvement of effective skin tissue is not made efficiently. Therefore, a method of applying electrical stimulation, cold or hot stimulation or mechanical stimulation (for example, needle treatment) in a method that can dramatically increase the absorption rate of cosmetics in the skin layer for effective regeneration of skin tissue is being performed.

Accordingly, a skin care device that can conveniently perform the above-described method has been developed. In general, a skin beauty machine is used to develop a device that employs a method of managing the skin by performing negative pressure, ultrasonic waves, high frequency heating, or the like, or applying a stimulus such as steam, anion, cold or hot stimulation, or vibration stimulation. In addition, for example, as described in Korean Patent Laid-Open Publication No. 2003-0080507, a skin care device that can be combined with two or more of the above-described methods in one device is developed and used.

In addition to the physical means such as steam, anion, cold and hot stimulation, vibration stimulation described above, it has recently been found that plasma energy has a turbid effect on skin regeneration.

Plasma for skin regeneration transfers energy only to the tissue structure within the skin to be treated without direct contact with the skin, so that it does not damage the skin's epidermis, which acts as a protective layer until new skin is regenerated.

In addition, it is possible to see the effect of continuous improvement over time because skin is continuously regenerated rather than temporary.

Therefore, as a therapeutic effect, there is a remarkable wrinkle improvement, tightening the skin, and there is a comprehensive skin care treatment effect such as skin tone, texture and pigment improvement, and there is no pain during treatment, and the plasma energy is distributed evenly and effectively. This can provide a vertex for balanced treatment of curved skin shapes, especially around the mouth and around the cheekbones around the eyes.

In addition, the plasma is also used as a means for sterilizing the skin surface because it can perform a sterilization action to destroy microorganisms including highly resistant bacterial resistant spores.

However, plasma has a problem that ozone, which is harmful to a human body, is generated when used for a long time. The odor of ozone irritates the nose and throat, and high levels of ozone can cause respiratory distress or impaired lung function. In confined spaces, headaches can cause eye irritation.

Korean Laid-Open Patent No. 2003-0080507

The present invention was created in view of the above-mentioned problems in the prior art, and is applied to the skin to sterilize bacteria causing various skin diseases and improve the regeneration effect of the skin tissue by applying plasma to the skin. It is an object of the present invention to provide a skin treatment apparatus that can efficiently remove the ozone that follows and ensure the safety of the operator or the subject from the negative effects of ozone.

The present invention is a means for achieving the above object, the main housing formed an inner space; A galvanic housing installed at one side of the main housing and having a hollow portion; A plasma electrode installed in a hollow portion of the galvanic housing and emitting plasma toward a treatment site; An ozone discharge unit installed in an inner space of the main housing and discharging ozone generated from the plasma electrode to the outside; And a discharge housing installed at the other side of the main housing and having a plurality of discharge holes therethrough so that ozone can be discharged to the outside by the ozone discharge unit.

In addition, the ozone discharge unit, a catalyst module through which a plurality of catalyst tubes through which ozone passes from one side toward the other side; And an exhaust fan disposed at the other side of the catalyst module so as to suck the ozone generated from the plasma electrode into the catalyst tube and exhaust the ozone from the outside.

The apparatus may further include a vibration generating unit installed inside the main housing to vibrate the galvanic housing to apply vibration to the treatment area.

In addition, the inside of the main housing is characterized in that the guide piece is formed so that the ozone sucked by the exhaust fan is guided toward the catalyst module.

In addition, the guide piece is characterized in that it is provided in pairs to divide the internal space of the main housing into the first chamber, the second chamber and the third chamber.

In addition, at least one or more of the guide pieces provided as a pair is characterized in that the vortex forming protrusion is provided to form a vortex in the ozone gas sucked into the catalyst module by the exhaust fan.

Effects according to the present invention are as follows.

First, since the ozone discharge unit is interlocked while the plasma electrode is driven, the ozone generated by the plasma electrode can be sucked and decomposed immediately.

Second, since the catalyst module has an angular pipe shape extending from one side to the other direction, there is an effect that sufficient decomposition can be made while ozone sucked by the exhaust fan passes through the catalyst tube.

Third, the inner space of the main housing is partitioned by a pair of guide pieces, and the ozone is guided to the second chamber, which is an independent space, to be decomposed and exhausted, thereby greatly improving the performance of ozone decomposition. Since ozone gas is guided and flows only toward the second chamber without flowing into the first chamber or the third chamber, the ozone gas can be sucked more quickly.

Fourth, vortex or fluctuation is caused by the vortex forming protrusion formed on the guide piece when ozone gas is sucked by the exhaust fan, and then, when ozone gas is sucked into the catalyst tube of the catalyst module, the catalyst is caused by the occurrence of vortex or fluctuation. The contact area which contacts the inner peripheral surface of a pipe will increase. As a result, there is an effect that the ozone decomposition efficiency by the catalyst module can be significantly improved.

1 is a perspective view showing the appearance of the skin treatment apparatus according to the present invention.
Figure 2 is a schematic exploded perspective view of the skin treatment apparatus according to the present invention.
Figure 3 is a schematic cross-sectional view showing the internal configuration of the skin treatment apparatus according to the present invention.
4 is an exploded perspective view illustrating an exploded relationship between a galvanic housing, an insulation cap, a plasma electrode, and a support plate.
5 is a schematic cross-sectional view of the main housing according to the invention.
Figure 6 is a conceptual diagram for explaining the action of the ozone discharge in the skin treatment apparatus according to the present invention.
7 is a perspective view showing a first modification of the main housing according to the present invention;
8 is a schematic cross-sectional view of the main housing shown in FIG. 7.
9 is a perspective view showing a second modification of the main housing according to the present invention;
10 is a schematic cross-sectional view of the main housing shown in FIG. 9.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiment of the present invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

1 is a perspective view showing the appearance of the skin treatment apparatus according to the present invention, Figure 2 is a schematic exploded perspective view of the skin treatment apparatus according to the invention and Figure 3 is a schematic diagram showing the internal configuration of the skin treatment apparatus according to the present invention 4 is an exploded perspective view illustrating an exploded relationship between a galvanic housing, an insulating cap, a plasma electrode, and a support plate, and FIG. 5 is a schematic cross-sectional view of a main housing according to the present invention, and FIG. 6 is a skin treatment apparatus according to the present invention. This is a conceptual diagram for explaining the action of ozone emission.

Skin treatment apparatus according to the present invention is largely as shown in Figures 1 to 5 the main housing 100, the galvanic housing 200, the plasma electrode 300, ozone discharge unit 400 and the discharge housing 500 It is defined as containing.

The main housing 100 constitutes an appearance of the skin treatment apparatus according to the present invention, and may be any shape as long as it can accommodate a battery B, a substrate PCB, a high voltage power pack P, and the like. In addition, the main housing 100 is preferably made of a synthetic resin of the non-conductor in consideration of the safety of the operator from the voltage of the high voltage power pack (P). Meanwhile, in the present invention, as shown in FIG. 2, the main housing 100 is divided into two pairs and has an inner space.

The side of the main housing 100 may be a control switch 110 for controlling the overall operation of the skin treatment apparatus according to the present invention. The control switch 110 may be adopted in any manner as long as the user has a tactile feeling and manipulates the tactile manner. For example, a dome switch or a touch screen that can receive a command or information by a user's push or touch operation, a touch pad, or a wheel that rotates keys or a jog or a joystick can be implemented. Can be.

One side of the main housing 100 may have a first outside air suction opening 170 for introducing external air into the internal space of the main housing 100 by the action of the exhaust fan 420 to be described later. In addition, a pair of exhaust bases 141 spaced apart from each other may be formed in an inner space of the main housing 100, and an exhaust fan 420 is mounted between the pair of exhaust bases 141. The exhaust fan 420 mounted on the pair of exhaust bases 141 may be firmly supported even when an external shock is applied to the main housing 100.

In addition, in the case of the exhaust base 141 disposed on one side of the exhaust fan 420, one side of the exhaust fan 420 is covered so that ozone passes between the side of the exhaust fan 420 and the internal space of the main housing 100. It can prevent leakage. When ozone is induced only toward the exhaust fan 420 without leaking between the side of the exhaust fan 420 and the internal space of the main housing 100, the exhaust efficiency of the exhaust fan 420 can be maximized.

Next, the galvanic housing 200 is installed on one open side of the main housing 100 and accommodates the plasma electrode 300, the insulating cap 700, and the supporting plate 600 which will be described later. The galvanic housing 200 has a hollow portion penetrated from one side to the other side and may be detachably mounted at one side of the main housing 100. To this end, a plurality of elastic grooves 210 may pass through the outer circumferential surface of the galvanic housing 200, and elastic protrusions 120 corresponding to the elastic grooves 210 may protrude from one inner circumferential surface of the main housing 100. have.

The galvanic housing 200 is responsible for the 'galvanic action' to care for the skin by generating a very weak current having the same pole-like pushing property, for this purpose it is preferably implemented in a conductive material as a whole.

Again, as shown in FIG. 4, a hollow 220 of the galvanic housing 200 may include a seating plate 220 on which the supporting plate 600 to be described later is mounted.

Next, the plasma electrode 300 is installed in the hollow portion of the galvanic housing 200 and emits plasma toward the treatment site, and serves to remove various bacteria and contaminants remaining on the skin according to the emission of the plasma. . The plasma electrode 300 receives the power from the high voltage power pack P to generate plasma, while the plasma electrode 300 may use a known plasma generation and injection method, and may include necessary components. have.

For reference, the present invention illustrates a plasma electrode 300 having a two-dimensional ceramic plate structure in which a plate-shaped electrode is sealed in a dielectric tube.

Meanwhile, the skin treatment apparatus according to the present invention may further include a battery B and a high voltage power pack P for providing power to the plasma electrode 300 and the galvanic housing 200.

For convenience of description, illustration and description of wires for electrically connecting respective members such as the battery B, the high voltage power pack P, and the plasma electrode 300 will be omitted.

In addition, the battery B may be installed in the inner space of the main housing and may supply power required for operation of each component of the skin treatment apparatus such as the plasma electrode 300 and the galvanic housing 200. In addition, the high voltage power pack P is installed in the inner space of the main housing and receives the DC power of the battery B to provide the AC power of the high voltage toward the plasma electrode 300.

Skin treatment apparatus according to the present invention may further include a support plate 600 and the insulating cap 700 as shown in FIG.

The support plate 600 may be inserted toward the hollow portion of the galvanic housing 200 and may be fixed by the seating plate 220. Plasma electrode 300 is disposed on one side of the support plate 600. In addition, a plurality of through holes 610 may pass through the support plate 600 from one side toward the other direction, and ozone generated from the plasma electrode 300 passes through the through holes 610 to the ozone discharge unit 400. By decomposition or discharge.

The insulating cap 700 may be interposed between the galvanic housing 200 and the plasma electrode 300 to avoid electrical interference between the galvanic housing 200 and the plasma electrode 300. If the galvanic housing 200 and the plasma electrode 300 are energized with each other, a malfunction may occur or the treatment effect may be halved.

The coupling relationship between the galvanic housing 200, the support plate 600, the insulating cap 700, and the plasma electrode 300 will be described with reference to FIG. 4.

First, the support plate 600 is inserted toward the hollow portion of the galvanic housing 200. The insulating cap 700 is mounted toward the hollow portion of the galvanic housing 200 in a state where the support plate 600 is fixed by the seating plate 220 of the galvanic housing 200. The insulating cap 700 is similar to the galvanic housing 200 and has a hollow portion penetrated from one side to the other side. Finally, when the plasma electrode 300 is inserted into the hollow portion of the insulating cap 700, the coupling between the galvanic housing 200, the support plate 600, the insulating cap 700, and the plasma electrode 300 is completed.

Next, the ozone discharge unit 400 is installed in the inner space of the main housing 100 and discharges ozone generated from the plasma electrode 300 to the outside. Ozone generated from the plasma electrode 300 is generated in the form of gas, and when the ozone is not immediately discharged, it causes harm to the operator or the human body of the operator.

Skin treatment apparatus according to the present invention was to immediately discharge the ozone gas in the other direction of the main housing 100 to exclude the adverse effects directly on the skin of the subject.

To this end, the ozone discharge unit 400 is a plurality of catalyst tubes 411 through which ozone passes through the catalyst module 410 and the ozone generated from the plasma electrode 300 through the catalyst module 410 penetrating toward the other direction from the catalyst tube It is defined to include an exhaust fan 420 disposed on the other side of the catalyst module 410 to be sucked into the 411 and exhausted to the outside.

More specifically, the catalyst module 410 is approximately disposed in the center of the inner space of the main housing 100 and ozone generated from the plasma electrode 300 while the plasma electrode 300 is driven to the catalyst tube 411. Decomposition takes place as it is transported. 2 illustrates a catalyst module 410 having an angular pipe shape extending from one side to the other side. In this case, the catalyst module 410 is preferably implemented with a material such as manganese dioxide (MnO ₂ ).

The exhaust fan 420 is installed at the other side of the main housing 100 to suck ozone generated from one side of the main housing 100 in the direction of the catalyst module 410. That is, since the catalyst module 410 is disposed between the plasma electrode 300 and the exhaust fan 420, decomposition of ozone gas sucked by the exhaust fan 420 is immediately performed. On the other hand, the exhaust fan 420 is an electric fan provided with the blade which rotates by the rotational force of a motor.

After decomposition by the catalyst module 410, the gas containing a small amount of ozone is exhausted to the other direction of the main housing 100 by the action of the continuous exhaust fan 420.

At this time, the discharge housing 500 is installed on the other side of the main housing 100 and a plurality of discharge holes 510 through the ozone is discharged to the outside by the ozone discharge unit 400. The discharge hole 510 penetrates from one side to the other side and the gas is blocked by the discharge housing 500 so that the number of the discharge holes 510 is not limited. In addition, a terminal insertion hole 520 through which a charging terminal for charging the battery B may be inserted may pass through the discharge housing 500.

Meanwhile, a guide piece 160 may be formed in the main housing 100 such that ozone sucked by the exhaust fan 420 is guided toward the catalyst module 410. In this case, the guide pieces 160 are preferably provided in pairs to divide the internal space of the main housing 100 into the first chamber 130, the second chamber 140, and the third chamber 150.

In this case, the ozone discharge unit 400 is preferably installed in the second chamber 140. Referring to FIG. 5, the positional relationship of the first, second, and third chambers 130, 140, and 150 is schematically described with reference to the second chamber 140. Three chambers 150 may be located respectively.

Meanwhile, in the process of ozone being sucked into the catalyst tube 411 of the catalyst module 410, the catalyst module 410 may vibrate in the flow of the fluid and may impact the inner wall of the main housing 100. In this case, the noise of the skin treatment device is generated to reduce the concentration of the operator or the subject, as well as to lose the reliability of the skin treatment device.

In order to prevent vibration of the catalyst module 410, the second protrusion 140 of the main housing 100 has a contact protrusion 142 protruding a predetermined portion toward the inner space of the main housing 100 from one side along the other direction. Plural can be formed. The adhesion protrusion 142 allows the catalyst module 410 to be maintained at a predetermined distance from the inner wall of the main housing 100 so that the vibration energy of the catalyst module 410 is directly in the main housing 100. The noise generated can be minimized.

Meanwhile, the battery B and the high voltage power pack P are preferably installed in the first chamber 130 or the third chamber 150 except for the second chamber 140.

If the internal space of the main housing 100 is not partitioned by the guide piece 160, the members such as the battery B, the high voltage power pack P, and the ozone discharge unit 400 are mixed and installed. When the ozone gas is inhaled or discharged by the exhaust fan 420, the ozone gas may interfere with the members, thereby reducing the exhaust performance.

As described above, the inner space of the main housing 100 is partitioned by a pair of guide pieces 160, and the ozone is led to an independent space to be decomposed and exhausted, thereby greatly improving the performance of ozone decomposition.

In other words, when the plasma substrate PCB is driven, the exhaust fan 420 is interlocked to decompose and discharge ozone to exhaust ozone from one side of the main housing 100 toward the other side. In this process, ozone is decomposed while passing through the catalyst tube 411 of the catalyst module 410, and a small amount of remaining ozone is exhausted to the discharge hole 510 of the discharge housing 500.

3, the second chamber 140 and the first chamber 130 may partially communicate with each other by providing a distance W between the other end of the guide piece 160 and the discharge housing 500. This is to perform the cooling operation of the high voltage power pack P by allowing the suction force of the exhaust fan 420 to act on the first chamber 130 as well.

'자 형태로 절곡된 형상인 한 쌍의 가이드편(160)을 예시한다.Meanwhile, as illustrated in FIG. 5, ozone generated from the plasma electrode 300 may be efficiently sucked toward the catalyst module 410 disposed in the second chamber 140.

A pair of guide pieces 160 having a shape bent in a 'shape' is illustrated.

As a result, ozone gas generated at one side of the main housing 100 may be guided only toward the second chamber 140 without entering the first chamber 130 or the third chamber 150, and the ozone gas may be Since one side of the pair of guide pieces 160 flows, ozone gas may be sucked toward the catalyst module 410 more quickly.

In addition, at least one or more of the pair of guide pieces 160 may be provided with a vortex forming protrusion 161 to form a vortex in the ozone gas sucked into the catalyst module 410 by the exhaust fan 420. Can be.

The vortex forming protrusion 161 is preferably formed on one side of the guide piece 160 with a space therebetween. When the ozone gas is sucked to the catalyst module 410 by the exhaust fan 420, Contact is made.

More specifically, when the exhaust fan 420 is operated, a suction force is generated in the inner space of the main housing 100 toward the exhaust fan 420. Ozone gas generated at one side of the main housing 100 by the suction force flows to one side of the catalyst module 410 and flows into the catalyst tube 411 of the catalyst module 410. At this time, the ozone gas suspended on one side of the main housing 100 is in contact with the guide piece 160 by a sharp suction force, and thus suction to the catalyst module 410 side is made.

In this process, vortex or oscillation occurs by the vortex forming protrusion 161 formed in the guide piece 160, and then vortex when the ozone gas is sucked into the catalyst tube 411 of the catalyst module 410. Alternatively, the contact area increases with the inner circumferential surface of the catalyst tube 411 due to the generation of shaking. As a result, ozone decomposition efficiency by the catalyst module 410 can be significantly improved.

Next, the skin treatment apparatus according to the present invention may further include a vibration generating unit 800 installed inside the main housing 100 to vibrate the galvanic housing 200 to apply vibration to the treatment area.

The vibration generating unit 800 may be disposed at an appropriate place in the inner space of the main housing 100 so that the vibration generating unit 800 may be interlocked when the plasma electrode 300 is driven.

The vibration generating unit 800 may employ a vibration by a known motor, vibration by ultrasonic waves, and the like, and any means may be used as long as it can impart vibration to the skin treatment apparatus.

The vibration generating unit 800 may maximize the treatment efficiency by finely vibrating the skin surface, as well as provide reliability to the subject during the operation of the skin treatment apparatus according to the present invention depending on whether the skin treatment apparatus is normally driven. have.

Hereinafter, the operation of the skin treatment apparatus according to the present invention will be described.

First, when the surface of the plasma electrode 300 is placed on the treatment site and the control switch 110 is pressed, the controller (not shown) supplies the DC power from the battery B to the high voltage power pack P. The high voltage power pack P, which receives the DC power of the battery B, converts the DC power into AC power of high voltage high frequency and supplies the same to the plasma electrode 300.

Plasma having an even distribution is generated in the space between the plasma substrate (PCB) and the skin, and the generated plasma irritates and sterilizes the skin while gently tapping the treatment area.

The plasma gap between the plasma electrode 300 and the skin is generally between 0.5 and 5 mm. Electrodes for the treatment of a human or animal body typically have a surface area of about 0.1 to 10 cm ² . Therefore, in order to maintain the plasma gap at a constant interval, the plasma electrode 300 is preferably installed in a state in which it is recessed a predetermined depth toward the other side of the galvanic housing 200.

Due to the positional relationship between the galvanic housing 200 and the plasma electrode 300, the plasma active region in which the plasma is generated is isolated from the outside so that the plasma does not leak, thereby improving the therapeutic effect and maintaining the plasma constant. Can be distributed evenly.
In other words, the present invention provides a main housing 100 having an inner space, a galvanic housing 200 installed at one side of the main housing, and a seating unit 220 formed at a hollow part, and the galvanic housing 200. It is installed in the hollow portion of the plasma electrode 300 for emitting a plasma toward the treatment site, the ozone discharge unit 400 is installed in the inner space of the main housing to discharge the ozone generated from the plasma electrode 300 to the outside Is installed on the other side of the main housing 100, the discharge housing 500 through which a plurality of discharge holes penetrated so that ozone can be discharged to the outside by the ozone discharge unit 400, the hollow portion of the galvanic housing 200 Is inserted into the position is fixed by the seating rod, a plurality of passage holes for passing through the ozone generated in the plasma electrode 300 to be decomposed or discharged by the ozone discharge unit 400 is passed through In order to avoid electrical interference between the support plate 600 and the galvanic housing 200 and the plasma electrode 300 formed, the galvanic housing 200 and the plasma electrode 300 are installed between the plasma electrode 300 and the plasma electrode 300. An insulating cap 700 positioned to contact the upper portion of the galvanic housing 200 while surrounding the side circumference of the plasma electrode 300 and exposed to the upper portion of the galvanic housing 200 from the portion in contact with the upper circumference of the plasma electrode 300. It will include.
In addition, the plasma electrode 300 is installed in the recessed state at intervals by a portion where the insulating cap 700 is exposed from the upper portion of the galvanic housing 200, thereby providing the galvanic housing 200 and the insulating cap ( 700 maintains the gap between the plasma electrode 300 and the skin of the treatment area, and the plasma active region where the plasma is generated is isolated from the outside, thereby making it possible to maintain a constant plasma distribution without generating plasma leakage. It is.

Hereinafter, a first modified example of the main housing 100 will be described with reference to the accompanying drawings. The same or similar parts as in the above-described embodiment will be omitted in order to avoid duplication.

As shown in FIG. 7 to FIG. 8, the main housing 100 according to the present modification is the same as described above, but there is a difference in that the second outside air suction port 170 ′ is penetrated and the suction pipe 162 is formed. I will only focus on the differences.

First, the high voltage power pack P installed in the first chamber 130 has a characteristic of generating heat when the use time becomes long. When the high voltage power pack P generates heat, there is a risk of causing thermal damage to the peripheral members. Therefore, it is preferable to suppress the heat generation of the high voltage power pack P to prevent thermal damage of the peripheral members.

To this end, a second outside air suction port 170 ′ for sucking outside air into the first chamber 130 penetrates through the side of the main housing 100 according to the present modification. And the other side of the guide piece 160 may be formed in the suction pipe 162 extending in the direction of the exhaust fan 420 in contact with one side of the exhaust fan 420.

In this case, when the exhaust fan 420 is operated, the suction force of the exhaust fan 420 is transferred to the first chamber 130 through the suction pipe 162 to increase the temperature of the first chamber 130 by the high voltage power pack P. Suck the gas. As the gas in the first chamber 130 is sucked, air is supplied to the first chamber 130 through the second outside air suction opening 170 ′ of the main housing 100 to reduce the surface temperature of the high voltage power pack P. Will be.

'자 형태로 절곡된 형상인 가이드편(160)에 의해 승온된 기체가 보다 넓은 면적으로 가이드편(160)에 접촉이 이루어진다. 그 결과, 고전압 파워팩(P)의 발열에 대한 방열성능을 보다 향상시킬 수 있게 된다.In addition, since the suction pipe 162 is in contact with the exhaust fan 420, as well as preventing the flow of the exhaust fan 420, it is possible to immediately transfer the suction force of the exhaust fan 420 to the first chamber 130. It is possible to improve the suction efficiency. In addition, one side is approximately '

The gas heated by the guide piece 160 having a shape bent in a 'shape' forms a contact with the guide piece 160 in a larger area. As a result, the heat dissipation performance with respect to heat generation of the high voltage power pack P can be further improved.

Hereinafter, a second modified example of the main housing 100 will be described with reference to the accompanying drawings. The same or similar parts as the above-described embodiments or modifications will be omitted in order to avoid duplication.

9 to 10, the main housing 100 according to the present modification is the same as the first modification described above, but the difference in that the airflow generation zone 180 is further formed in the first chamber 130 is different. Therefore, only the above differences will be described.

A spiral airflow generation zone 180 may be formed in the first chamber 130 of the main housing 100 according to the present modification so that the gas supplied to the first chamber 130 forms a downward airflow.

When the gas supplied to the first chamber 130 forms a downdraft along the outer surface of the high voltage power pack P, the surface temperature of the high voltage power pack P may be reduced more quickly, and the first chamber 130 may be reduced. ), The heated gas may be rapidly sucked into the suction pipe 162.

Embodiments of the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents, and substitutes within the spirit and scope of the invention as defined by the appended claims.

100: main housing 200: galvanic housing 300: plasma electrode
400: ozone outlet 500: exhaust housing 600: support plate
700: insulation cap 800: vibration generating unit

Claims (5)

A main housing defining an inner space;
A galvanic housing installed on one side of the main housing and having a seating plate formed in the hollow part;
A plasma electrode installed in a hollow portion of the galvanic housing and emitting plasma toward a treatment site;
An ozone discharge unit installed in an inner space of the main housing and discharging ozone generated from the plasma electrode to the outside;
A discharge housing installed at the other side of the main housing and having a plurality of discharge holes therethrough to allow ozone to be discharged to the outside by the ozone discharge unit;
A support plate inserted into the hollow part of the galvanic housing and fixed by a seating plate, and having a plurality of passage holes through which ozone generated from the plasma electrode passes through the ozone discharge unit so as to be decomposed or discharged; And
An upper circumference of the plasma electrode disposed between the galvanic housing and the plasma electrode in order to avoid electrical interference between the galvanic housing and the plasma electrode, and positioned to contact the upper part of the galvanic housing while surrounding the side circumference of the plasma electrode. Insulating cap exposed to the outside from the portion in contact with the galvanic housing upper portion; including,
The plasma electrode is installed in a recessed state at intervals by a portion where the insulating cap is exposed on the upper part of the galvanic housing,
The gap between the plasma electrode and the treated skin is maintained by the galvanic housing and the insulating cap, and the plasma active region where the plasma is generated is isolated from the outside, so that the plasma is not leaked and the distribution of the plasma is kept constant. Skin treatment apparatus using a plasma, characterized in that. The method according to claim 1,
The ozone discharge unit,
A catalyst module through which a plurality of catalyst tubes through which ozone passes is passed from one side to the other direction; And
And an exhaust fan disposed at the other side of the catalyst module to suck ozone generated from the plasma electrode into the catalyst tube and to exhaust the ozone generated from the catalyst tube. The method according to claim 2,
Skin treatment apparatus using a plasma, characterized in that the guide piece is formed in the main housing to guide the ozone sucked by the exhaust fan toward the catalyst module. The method according to claim 3,
The guide pieces are provided in pairs to divide the internal space of the main housing into a first chamber, a second chamber, and a third chamber, and the ozone discharge part is provided in the second chamber. Device. The method according to claim 4,
At least one or more of the guide pieces provided as a pair is a skin treatment device using a plasma, characterized in that the vortex forming projections are provided to form a vortex in the ozone gas sucked into the catalyst module by the exhaust fan.

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