KR20190055928A - Wearable Plasma Clothes - Google Patents

Abstract

The present invention provides wearable plasma clothes by combining a plasma pad equipped with a Plasma Emitting Diode (PED) element and a power supply unit with various clothes. Plasma clothes are in the form of plasma bandages, shoes, caps, panties and sanitary pads. The plasma clothes are environmentally friendly clothes for health using deodorization, regeneration of the human skin, blood coagulation and sterilization of pathogenic bacteria of the plasma.

Description

{Wearable Plasma Clothes}

The present invention relates to a wearable plasma garment using a PED (Plasma Emitting Diode) element, and more particularly, to a plasma pad, a plasma pad and a bandage, a plasma cap, a plasma shoe, and a plasma panty.

Plasma bio and medical research has been published in related journals over the past two decades.

Plasma has been proven to be effective in the treatment of chronic skin diseases due to the action of human skin cells and the killing of various pathogens. Besides, hemostatic effect by blood coagulation and deodorizing effect by decomposition of organic and inorganic compounds have been reported.

It has been reported that the microbial cells of various bacterial, fungal, and virus-like pathogens are contacted with plasma particles and sterilized by plasmas ruptured at the cell level of pathogens or killed by plasma radicals (mainly ROS series).

Since skin cells are surrounded by proteins in the form of proteins, they are not exposed to plasma, and skin cells are not killed, plasma energy is transferred through protein tissue, or plasma radicals (mainly RNS series) (Skin regeneration), preventing skin aging, and preventing skin hair loss and promoting hair growth have been studied as excellent hair health effects.

A wearable plasma pad was disclosed in the registered patent "Registration No. 10-1657895, Plasma Pad" and the patented "Plasma Pad-Kit System" invented by the present inventor and registered by the present applicant.

The features and problems of the plasma pad and the wearable plasma apparatus using the same are as follows.

(1) Plasma occurs over the entire range of proximity on the skin surface, and a high-voltage electrode is installed over the entire surface of the skin surface.

(2) Large amount of plasma is generated for a large-sized skin, proportionally, power source size is large, and power consumption is large. And there is a lot of ozone generation.

(3) It is difficult to make the above-mentioned patent portable portable battery using a rechargeable secondary battery. That is, the size of the secondary battery according to the high capacity is increased and the discharging time of the secondary battery is shortened according to the large power consumption, so frequent charging is required, which is not suitable for the portable wearable device.

(4) Since the size of a transformer, which is mainly used in a high-voltage power supply unit, increases in proportion to the amount of power, it is difficult to miniaturize the power supply unit.

(5) When a large amount of plasma generated in the large-area plasma apparatus is exposed near the skin, the problem of heat generation is also serious.

(6) Although the ozone is generated inside the closed structure, the problem of ozone emission during the removal process is also a problem to be considered.

The present invention aims at providing a portable wearable plasma garment. Specifically, a plasma pad, a plasma patch and a bandage, a plasma cap, a plasma shoe, and a plasma pant are practically used.

Problems to be solved for providing the plasma garment are as follows.

(1) When a battery charger dedicated secondary battery is used in a portable device, the time for which the secondary battery is discharged should be at least several tens minutes to one hour or more.

(2) It should be possible to wear clothes without discomfort by attaching to the clothing by downsizing the power supply device.

(3) User convenience and safety must be ensured in the configuration of the apparatus that matches the characteristics of the plasma garment.

The problem of the above (1) should take into consideration the commercial capacity of the secondary battery.

That is, a secondary battery having a small area that can be applied to clothes is usually 3 mm in thickness, 3 cm x 7 cm in area, and has an output DC voltage of 3.5 V and a relatively large capacity is usually 2000 mAH. In such a secondary battery, there is a risk of breakage and explosion due to heat generation in the secondary battery above the allowable current. According to the experiments conducted by the present inventors, when a current of 1000 mA flows in a secondary battery having an allowable current of 1000 mA or less and a capacity of 2000 mAH, the use time is 2 hours in terms of calculation (2000 mAH / 1000 mA = 2 H). But in practice it is about an hour. Therefore, in order to manufacture a portable device with a commercialized secondary battery, the power consumption of the device should be 3 W or less. At this time, the current is less than about 1000 mA with respect to the voltage of 3.5 V of the secondary battery, and it is required to be recharged after about 1 hour. Actually, the lower the current, the longer the use time. Therefore, plasma clothes are designed considering that the power consumption of the plasma source of the apparatus to be manufactured is preferably 3 W or less. Such a low-current plasma garment operation is impossible in the large-area wearable plasma apparatus proposed in the above-mentioned prior patents.

On the other hand, it is preferable that the consumed electric power of the plasma source PED (Plasma Emitting Diode) is 3 W or less, but the power source device can be downsized at a maximum of 5 W or less. Generally, the scale of the transformer corresponding to the power consumption of the 5 W class can be selected as the thickness of 1 cm or less and the size of about 1 cm of the length and the length, so it is possible to manufacture a power supply device having a thin and small- Do.

Therefore, it is a key consideration in the present invention that a core technology of providing portable wearable plasma clothing employing a secondary battery is to use a PED (Plasma Emitting Diode: PED) having a low power capacity.

Another challenge is ozone emission control. International ozone tolerance should be controlled below 0.05 ppm. The problem of ozone is easily controlled below the allowable value when the PED is for low power.

According to the present invention,

(1) Plasma emitting diode (PED) elements, which are invented by the present inventor and proposed in the patent application 10-2017-0132897 filed by the present applicant, are employed in the plasma garment.

The device is used for sterilization, skin activation, and odor removal by diffusion of the plasma emitted from the PED and radical action. The skin does not touch the electrode directly, and it is named as soft plasma because it is indirect plasma.

(2) Plasma clothes employ one or more low-power PEDs having a power consumption of 1 W or less in consideration of the capacity of the secondary battery.

(3) The power device of the low power PED can be downsized.

(4) As an implementation method for each plasma clothing apparatus, a plasma pad of a predetermined size is used as a basic unit, and one or more of these pads are used to provide various wearable plasma garments.

The basic form of the plasma pad is to arrange the PED element between the films of the upper and lower plates and to form a plurality of holes in the upper plate film from which the plasma is diffused and emitted. The discharged plasma is adsorbed on the skin to produce plasma clothes suitable for a predetermined purpose. One or more standardized plasma pads may be used in combination, and may be manufactured as disposable if necessary.

Plasma garments combine plasma pads on a substrate to create a wearable shape that surrounds the skin. A structure such as a compression bandage or an abdomen is formed on the edge of the garment made of the base material so as to be adhered to the skin, and a carbon nonwoven fabric is disposed on the inner surface of the base material to prevent ozone from being released.

The power supply unit and the circuit board etc. are made as small as possible with a minimum thickness to facilitate their installation on the substrate of the garment. The power supply unit may be a newly developed flexible battery.

Plasma patches or bandages are worn to form a closed internal space by wrapping the skin with double-sided adhesive tape or ribbon on the edges.

The plasma hood is provided with a plasma pad inside, and the power supply device is disposed at a proper position of the window or the rim of the cap, and the plasma is generated by the action of the switch only when worn.

Plasma shoes are applied to socks, slippers, shoes, and so on. A plasma pad is installed inside the shoe, and a power supply is installed on the outer surface.

The plasma panties are provided with a plasma pad on the inner surface and the power supply is mounted on the belt portion of the panties. When applied to a hygienic band or a sanitary napkin and a diaper, it can be manufactured as a disposable pad.

According to the present invention, commercialization of various types of plasma clothes is realized. By applying plasma to real-life clothing products, environmentally friendly products for skin health are provided. Especially, the plasma generated in the atmospheric state returns to the air again in a short time, and thus, an environmentally friendly product without pollutant discharge is provided.

The action and effect of the plasma garment produced by the combination of the standardized plasma pad equipped with the PED element are as follows.

Plasma patches or bandages show the effects of treatment of chronic bacterial skin diseases, wound and postoperative skin regeneration effects, and have a hemostatic effect in response to bleeding at an accident site, thus preventing first aid and secondary infection.

In addition to preventing hair growth and hair loss, plasma hats include scalp health and scalp disease treatments, and itching and dandruff treatment effects.

Plasma shoes have the effect of treating and preventing athlete's foot, treatment of toenail athlete's foot, psoriasis treatment and prevention.

Plasma panties have the effect of preventing skin eczema and psoriasis and preventing and deodorizing various bacterial diseases.

1 is an explanatory diagram of a plasma pad and a power supply apparatus according to the present invention.
1 (a) is a schematic view of a PED element 100 used in a plasma pad according to the present invention.
1 (b) is a cross-sectional view and an exploded perspective view showing the structure of the plasma pad 200 in a simple form of the PED element 100 of the present invention.
1 (c) is a cross-sectional view and an exploded perspective view showing the structure of the plasma pad 200 of the present invention.
1 (d) is a configuration diagram of a power supply device 300 for supplying power to the plasma pad 200 used in the present invention.
FIG. 2 is a block diagram of a plasma patch 400 or a plasma bandage of the present invention.
FIG. 2 (b) is a plan view of a plasma patch 400 in which two plasma pads 200 are disposed on a substrate 410.
3 is a view showing an internal configuration and an exterior of the plasma cap 500. As shown in FIG.
4 is a block diagram of the plasma shoe 600.
Fig. 5 is a configuration diagram of the plasma panty 700 and the plasma napkin 800. Fig.
6 shows a PED device configuration, and Fig. 7 shows a configuration for packaging a PED device.
8 is a mock-up photograph of the manufactured plasma pad.
9 is a mock-up photograph of a plasma cap equipped with a plasma pad.
10 is a mock-up photograph of a plasma cap using PED.
11 is a mock-up photograph of the fabricated plasma sock.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention provides various types of plasma clothes using a plasma pad manufactured using a PED element as a basic constitution.

1 is an explanatory diagram of a plasma pad and a power supply apparatus according to the present invention.

FIG. 1 (a) illustrates a PED element 100 used in the plasma pad of the present invention. The PED device is shown in detail in Applicant's patent 10-2017-0132897. The PED device shown in FIG. 1 (a), which is manufactured by packaging a plasma source as a chip-type source, is connected to a connector for connection to a power source, and includes a first terminal 111 and a second terminal 112 are installed. The size of the PED device is usually about 2 cm in length and about 2 cm in height and less than 0.6 cm in height. The above values may be somewhat modified depending on the application subject. And the plasma 120 is emitted by diffusion through the gap on the side surface. Since the power consumption of the PED device of the present invention is in the range of about 1 W to 3 W, it is possible to provide a configuration in which the configuration of the pad and the configuration of the power supply device do not inconveniently adhere to the clothes.

1 (b) is a plasma pad 200 according to the first embodiment of the present invention.

The PED element 100 is attached to the base material 210 and the gauze 250 is covered to constitute the plasma pad 20.

1 (c) is a plasma pad 200 according to the second embodiment of the present invention.

A first film (220) is attached on a base material (210)

The PED element 100 is disposed on the center plane of the film-1 220 and the spacer 230 having a height approximately equal to the thickness of the PED element is attached to several places (the height of the spacer may be slightly higher). And covers the second film 240 provided with a plurality of plasma discharge openings 241 thereon and covers the last gauze 250.

The plasma emitted from the PED element between the films is diffused to the periphery through the plasma discharge port 241 provided in the second film 240. The area of the plasma pad surface is determined according to the application, and usually about 5 cm x 7 cm is suitable for human skin application.

Although only one PED element is shown in the drawing, a plurality of PED elements can be arranged in some cases.

FIG. 1 (d) is a configuration diagram of a power supply device 300 for supplying power to the plasma pad 200 used in the present invention.

The high-voltage apparatus is divided into a power transformer unit 310 and a DC-power unit 32. A high voltage having a different polarity is output to the first terminal 311 and the second terminal 312 at both ends of the secondary coil of the transformer. The DC-power unit includes a control board 330, a secondary battery 340, and a charger 350. It is preferable to use a rechargeable secondary battery which is substantially rechargeable, although a general battery may be used or a general power source may be used by connecting it to an adapter.

Since the power of the plasma source PED is 1 to 3 W, it is preferable that the thickness of the power supply unit is 1 cm or less, which is the thickness of the transformer, and the thickness of the power supply substrate composed of other components is 1 cm or less.

2 is a view of a plasma patch 400 or a plasma bandage of the present invention. The plasma pad 200 of FIG. 1 (b) or 1 (c) is disposed on the base material 410 of the patch as shown in FIG. 2 (a), and the power source device 300 is placed on the back surface of the base material 410 . A double-sided adhesive tape 420 is provided on the edge of the patch so as to adhere the skin, and a ribbon cord 430 is provided for binding the patch so as to wrap the human body.

FIG. 2B is a plasma patch 400 in which two plasma pads 200 are disposed on a substrate 410.

3 is a plasma cap 500. Fig.

The carbon nonwoven fabric 510 is provided on the inner surface of the cap and the plasma pad 200 of Fig. 1 (b) or Fig. 1 (c) is provided thereon. The power source device 300 of Fig. 1 (c), another switch, the LED 370, and the charging socket 380 are installed on the cap of the cap. At least one switch 361, 362 on the cap is installed. When the hat is fastened by wearing a hat, the skin is pressed to switch on, the plasma pad is activated, and the LED emits light to recognize the operation.

4 is a plasma shoe 600. Gloves, socks, slippers, shoes or foot baths.

A carbon nonwoven fabric (510) is installed at an appropriate position inside the shoe to control the emission of ozone. It is preferable to dispose the plasma pad 200 on the toe portion and the sole portion of the shoe, respectively. In the power supply device 300, the DC-power device 320 is installed on the outer side of the band by installing a thick band on the ankle part of the shoe, and the power transformer 310 is installed outside the shoe of the foot part. A zipper 610 is installed on the band of the ankle according to need so that the internal switch-1 363 is turned on and the LED 370 is turned on at the same time when the shoe is worn, to be.

5 is a plasma panty 700 and a sanitary napkin 800. Fig.

A plasma pad 200 is provided at the lower end of the plasma panty 700 shown in Fig. 5 (a), and a power supply device 300 is provided at the belt 710 of the panty.

The plasma napkin 800 of FIG. 5 (b) is provided with a plasma pad 200 inside a conventional napkin. The power supply unit is installed in the belt 710 of the panty on which the sanitary napkin is placed, which is not shown in the drawing. The plasma pants of Fig. 5 and the plasma pad 200 of the sanitary napkin are made disposable.

In the plasma panties, the plasma pad is fixed to the panty surface, a power source device is installed on the belt portion of the panty, and an inner switch is provided on the inner surface of the belt to turn on the power source device by touching. do.

A main switch for switching the power source device on the outer surface of the panty belt, an LED for indicating the operation of the power source device, and a charging socket are provided so as to turn on / off the power source device by the main switch.

In the plasma sanitary napkin, the plasma pad is fixed between the inner napkins of the sanitary napkin, and a power supply is installed in the sanitary napkin.

A main switch for switching the power supply unit on the outer surface of the panty, an LED for indicating the operation of the power supply unit, and a charging socket are provided, and plasma can be generated or turned off in the sanitary napkin by the main switch, Able to know.

Hereinafter, the configuration of the PED element proposed in the patent application 10-2017-0132897 will be described.

6 (a) and 6 (b) are electrode structures of a double-sided electrode type plasma source. The thinner the thickness t of the dielectric layer, the lower the discharge voltage because the capacitance becomes larger. In the case of a ceramic material, the minimum thickness is preferably 100 μm or less in a range that does not damage the ceramic material. Since the polyimide film whose surface is reinforced with silicon is flexible, it is preferable to use a minimum of 25 [mu] m to 125 [mu] m in consideration of the commercialized film, and to laminate the films to each other as necessary. The distance d between the first electrode and the second electrode is preferably smaller than the thickness t of the dielectric layer (0? D? T).

The width w of the electrode affects the amount of plasma generated in the PED, so the input power applied is proportional to the electrode width w. According to the experiment of the present inventor, when the electrode width w = 1 mm, the consumed power of the PED is about 0.5 W (Watt), and about 1.5 W when w = 3 mm. A PED element having a power capacity that is usually proportional to the electrode width w can be provided.

Therefore, the characteristics of the PED device of the present invention, that is, the discharge voltage and the discharge efficiency depend on the dielectric constant K of the dielectric material and the thickness t of the dielectric layer, and the PED device for each power consumption can easily .

6 (c) is a structure suitable for micro-discharge of micro-discharge. It is preferable that the coplanar electrode structure is manufactured by a manufacturing method of a plasma display panel (PDP). An electrode is formed on a glass plate by a silver paste, and a ferroelectric such as PbO is applied to the dielectric layer. The thickness t of the dielectric layer and the spacing d between the electrodes in the coplanar polarized form are preferably the same scale (t ~ d), and in this embodiment, they are each made to have a size of 100 μm. t, d can be adjusted as necessary and can be from 10 to 1000 [mu] m.

The driving voltage of such micro-scale coplanar discharge can be discharged to a low voltage of usually 1 kV or less and can be provided as a PED element with a consumption power of 1 W or less.

6 (d) is a counter electrode type structure. A similar electrode structure is disclosed in our patent application No. 10-2016-0104031, 'High Efficiency Plasma Source'. Wherein the dielectric comprises three layers of dielectric (thickness t1, t2, t3, respectively). A first electrode under the dielectric layer t1, a spacer film in the dielectric layer t2, and a second electrode in the dielectric layer t3. And a discharge space is formed at the center of the dielectric layer t2 and the dielectric layer t3. A second electrode is formed above and below the opening edge of the center of the dielectric layer t3. According to the experiment of the present inventor, plasma generated with a thickness t of each dielectric layer of 100 μm has a plasma smoothly with respect to an input voltage of about 1 kV. However, when the second electrode is provided only on the lower surface of the dielectric layer t3, the discharge is not smooth with respect to the AC voltage of about 1 kV.

7 is a diagram of a PED-chip package module.

7 (a), a PED-chip is provided between an upper plate and a lower plate, and a spacer is provided between upper and lower plates to secure a discharge space. Fig. 7 (b) shows a package type of one-sided plasma. Place the PED-chip on the bottom plate and install the top plate so that the space between the chip and the top plate is several millimeters. 7 (c) is a package of a PED of a double-sided discharge method. A gap of several mm or more is secured between the face of the PED source and the upper plate and the lower plate to secure a space for generating the plasma and a space for spreading the plasma to the side of the package. The upper and lower plates and spacers are made of insulating material that does not affect high voltage, and plastics are preferred. The size of the PED-package is about 1 mm for the thickness of the top plate and the bottom plate for the minimum size of 2 cm x 1 cm of the chip, and the height of the spacer is 2 mm for each of the top and bottom. Therefore, the minimum size of the entire pakage module is 2 cm x 2 cm x 0.6 cm. The size of the PED is proportional to the amount of plasma generated by the power capacity. The figures are exemplary and may be made smaller or larger. It will provide the convenience of the user by presenting the applied voltage according to the size. Preferably, a small-sized packaged device is provided, and a plurality of devices are connected to be used by the user as needed.

The electrode structure of the DBD type having a shape other than the electrode structure of FIG. 6 shown in the embodiment of the present invention can be packaged to be PED. In this case, it is also necessary to provide a top plate, a bottom plate, and a spacer capable of ensuring a discharge space, which are components of the package, and a connector to be described later is also provided for convenience of use.

8 to 11 are mock-up devices of a plasma pad and a plasma garment having the plasma pad according to the present invention.

8 is a mock-up of the plasma pad of FIG. 1C. The size of the plasma pad 200 is 5 cm x 9 cm x 0.6 cm. The PED 100, which is a plasma source constituting the pad, consumes 1 W of power. The high-voltage power supply device for operating the plasma pad has a small size of 4 cm x 3 cm x 0.6 cm. The input terminal applies the DC voltage of the secondary battery 300 and the output terminal connects the high-voltage terminal of the PED 100. Since the pad is flexible and the power supply is small, it is easy to provide plasma clothes.

FIG. 9 is an actual mock-up of the plasma cap 500 on which the plasma pad 200 of FIG. 8 is mounted. The carbon nonwoven fabric 510 was attached to the center of the cap, the plasma pad 200 of FIG. 8 was mounted on the carbon nonwoven fabric 510, and the high voltage power supply of FIG. 8 was attached to the back of the pad. A secondary battery 300, a DC-power source substrate, and a charging socket were installed in the cap of the cap. A switch-1 (361) and a switch-2 (362) are installed inside the cap, and the cap is put on the head by the cap and any one of the switches is operated. When the plasma is generated by the switch operation, the LED 370 mounted on the tip of the cap informs the operation.

10 is a mock-up of a plasma cap 500 manufactured by mounting a plasma pad of a simple shape as shown in FIG. 1B inside the cap. Pads (100), which is a plasma source, were fabricated by using only the base material (210) and gauze (250) pieces and attached to the center of the hat. The cap of the cap breaks the installation part of the power supply device, installs the power supply device 300, the secondary battery 340, and the charging socket 380, and covers the vinyl of the transparent material. Thus, a picture of the power supply appears on the top and bottom of the cap. Like the hat shown in Fig. 9, two switches are installed inside the frame, and an LED indicating operation is lit by the switch pressing.

9 and 10, the plasma is generated for about one hour after being worn. After that, the cell phone charger terminal is plugged into the charging socket 380 and recharged.

11 is a modeling apparatus for plasma socks. The photo on the left is the foot of the sock, and the photo on the right is a picture of the bottom of the sock. A high-voltage device (4 cm in length, 3 cm in length, 0.6 cm in thickness) was attached to the instep portion of the sock. On the outside of the ankle of the sock, a DC-powered board, a secondary battery, a charging socket, and a switch were attached. The PED-pad 200 of FIG. 1 (b), which is a plasma source, was attached to the front lower portion of the sock. Plasma occurs outside the sock and spreads inside the sock.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that the invention may be practiced otherwise than as described. It is therefore to be understood that the embodiments described above are in all respects illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: plasma discharge diode element (PED),
200: plasma pad (PED-Pad),
300: power supply device, 400: plasma patch, 500: plasma cap, 600: plasma shoes,
700: Plasma panty, 800: Plasma sanitary napkin,
110: connector, 111: first terminal, 112: second terminal, 120: plasma discharge,
210: substrate material, 220: film-1, 230: spacer, 240: film-2, 241: plasma discharge port,
250: Gauze,
310: power transformer, 311: first terminal, 312: second terminal,
313: Switching terminal -1, 314: Switching terminal -2,
320: DC-power section, 330: control board, 340: secondary battery, 341:
350: charger, 360: switch, 361: switch-1, 362: switch-2, 363:
370: LED, 380: Charging socket,
410: base material, 420: double-sided adhesive tape, 430: ribbon cord,
510: carbon nonwoven fabric, 610: zipper, 710: belt, 810: background material, 820: sanitary napkin surface,

Claims (9)

Background material;
At least one plasma-emitting device (PED) disposed on the substrate; And
And a gauze covering the plasma discharge device. Background material;
A first film of a dielectric overlying the substrate;
At least one plasma-emitting device (PED) disposed on the first-film surface, and a spacer disposed around the plasma-emitting device;
A second film having a plurality of plasma discharge openings arranged on the first film and composed of a dielectric; And
And a disposable gauze detachable on the second film. A power supply apparatus for generating plasma by applying power to a PED of a plasma pad according to claim 1 or 2,
Wherein the plasma pad and the power supply device are mounted on a plasma garment. 4. The method of claim 3, wherein the backing material comprises one of cloth, leather, or polymer,
Wherein the power supply comprises a DC-AC inverter having a transformer, a switching circuit and a converter, wherein the power consumption of the power supply is less than 5 W and is mountable to the plasma garment. 4. The plasma pad of claim 3, wherein the backing material of the plasma pad comprises a second backing material to which an adhesive tape, ribbon or band for attaching to the human body is attached or to which an adhesive tape, ribbon or band is attached,
Wherein the power supply unit is mounted on a rear surface of a backing member having one or more plasma pads,
The power supply unit includes a power switch, an LED indicating operation of the power switch, and a charging socket,
Wherein the plasma pad is worn in the form of a patch or bandage with the plasma pad facing the human skin, so that the plasma is adsorbed on the skin. A wearable plasma garment,
Socks or shoes;
A carbon nonwoven fabric disposed inside the sock or the shoe;
The plasma pad according to claim 1 or 2, which is fixed on the carbon nonwoven fabric.
A band for pressing the ankle to the ankle of the sock or the shoe;
An internal switch configured on the inner surface of the band, the internal switch being capable of turning on the power supply by touch;
A power supply device installed on a surface of the sock or shoe; And
A main switch installed on the outer surface of the sock or shoe for switching the power source device, an LED for indicating the operation of the power source device, and a charging socket
Wherein the plasma is generated by wearing the sock or shoes. A wearable plasma garment,
panties;
The plasma pad according to claim 1 or 2, wherein the plasma pad is fixed to the panty surface.
A power supply unit provided on a belt portion of the panty;
An internal switch installed on the inner side of the belt and capable of turning on the power supply device by a touch; And
A main switch installed on a surface of the belt for switching the power source device, an LED for indicating the operation of the power source device, and a charging socket, wherein plasma is generated by wear of the panty. A wearable plasma garment,
Sanitary napkins;
A plasma pad according to claim 1 or 2 fixed between the inner napkins of the sanitary napkin;
A power supply unit installed in the panty for wearing the sanitary napkin; And
A main switch provided on a surface of the panty for switching the power supply device, an LED for indicating the operation of the power supply device, and a charging socket, wherein plasma is generated in the sanitary napkin. A wearable plasma garment,
hat;
A carbon nonwoven fabric disposed on the inner surface of the cap;
The plasma pad according to claim 1 or 2, wherein the plasma pad is fixed on the carbon nonwoven fabric and disposed inside the cap.
A power supply device installed on the ceiling of the cap or the inner surface of the cap;
Wherein at least one switch is provided on an inner rim of the cap so that the switch can be turned on when the cap is worn; And
A main switch, an LED, and a charging socket installed in the cap of the cap;
Wherein the wearable plasma garment is capable of turning on and off the power supply with the main switch when the cap is worn and the plasma is generated and the LED is turned on.

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