KR101068761B1 - Electrode unit using for high frequency treatment - Google Patents

Abstract

The present invention relates to an electrode unit for radio frequency treatment, and more particularly, includes a plurality of applied electrodes and a plurality of energizing electrodes, which are generated by dispersing deep heat in a wide area of the body, and which may be caused by poor contact between the electrode unit and the body. The present invention relates to an electrode unit for radiofrequency therapy that can protect a user from dangers such as shock.

The electrode unit according to the present invention includes a plurality of applied electrodes and a plurality of conducting electrodes, so that deep heat is widely distributed in the body, and one side of the plurality of applied electrodes and the plurality of conducting electrodes contacting the body are curved. Deep deep heat can occur. In addition, the electrode unit according to the present invention is disposed by spaced apart at equal intervals on the circumference of the plurality of applied electrodes and the plurality of conducting electrodes formed on the basis of the center of the housing, the body due to the mistake of the administrator or the bending of the body Even when the and the electrode units do not completely contact, generation of an image or shock can be prevented.

Radiofrequency Therapy, Deep Fever, Monopolar, Bipolar

Description

Electrode unit using for high frequency treatment

The present invention relates to an electrode unit for radio frequency treatment, and more particularly, includes a plurality of applied electrodes and a plurality of energizing electrodes, which are generated by dispersing deep heat in a wide area of the body, and which may be caused by poor contact between the electrode unit and the body. The present invention relates to an electrode unit for radiofrequency therapy that can protect a user from dangers such as shock.

In general, the high frequency treatment system converts energized high frequency power into bioenergy by energizing high frequency power to the human body and promotes fat metabolism and muscle movement through deep heat generated by using such bioenergy to treat obesity, strengthen muscle, It is a medical device used for skin care, hair promotion or pain relief.

Since the high frequency power source has a very short vibration width when energizing human tissue, almost no ion movement occurs and there is no electrochemical reaction or electrolysis. When the high frequency power is energized in the human body, heat is generated in the tissue, which is called deep heat. The reason why the deep heat is generated is that whenever high-frequency electric energy is applied, the molecules constituting the tissue vibrate and rub against each other when the direction of the power source is changed, thereby causing the bio-heat to be caused by rotational motion, twisting and collision motion. Because it is generated.

High-frequency power can heat certain parts of body tissues without causing discomfort or muscle contraction in the body, and the deep heat generated increases the temperature of tissues to enhance cell function and increase blood flow. Do it. As a result, the metabolism and muscle movement of the human body is promoted, and the effects of obesity treatment, muscle strengthening, skin care, hair promotion or pain relief can be obtained.

Referring to FIG. 1, the monopolar radio frequency treatment system according to the related art is constructed, and includes a main body 10 and a treatment electrode device for generating and outputting a high frequency power source. The therapeutic electrode device is applied to the applied electrode part 20 for applying the high frequency power generated in the main body 10 to the body part to be managed and the energizing electrode part for energizing the high frequency power applied as the part to the contacted body part. (30). At this time, the applying electrode portion 20 is composed of the applying electrode 21, the handle 23 and the cable 25, the conducting electrode portion 30 is composed of the conducting electrode 31 and the cable 33.

The applying electrode 21 is brought into contact with the affected part such that the applied electrode 21 of the applied electrode part 20 and the conducting electrode 31 of the energized electrode part 30 face each other, and the conducting electrode 31 is placed on the opposite side of the affected part. , The main body 10 is operated. Then, the high frequency power is generated in the main body 10, and the high frequency power is energized through the human body placed between the applying electrode 21 and the conducting electrode 31, and thus, between the applying electrode 21 and the conducting electrode 31. Deep fever develops inside the body.

As described above, the application electrode 21 and the conduction electrode 31 are formed separately, and the high frequency treatment system generates deep heat by contacting the conduction electrode 31 on the opposite side of the body to face the application electrode 21. Is referred to as the modopolar type.

Referring to FIG. 2, the conventional bipolar radio frequency treatment system will be described in more detail. The high frequency power generated from the main body 10 and the high frequency power generated by the main body 10 are energized by a part of the body, thereby deepening heat in the affected part of the body. It consists of the therapeutic electrode device 40 which generate | occur | produces. The therapeutic electrode device 40 includes a high frequency power cable 41, a reference power cable 43, an integrated cable 44 and a handle 45 and an electrode unit in which the high frequency power cable 41 and the reference power cable 43 are integrated. It consists of 47. On the other hand, look at the configuration of the electrode unit 47 in more detail, one application electrode 47-2 and one conducting electrode 47-3 is inserted horizontally adjacent to each other in the electrode unit housing 47-1. It is arranged.

In this way, the applying electrode 47-2 and the conducting electrode 47-3 are arranged horizontally adjacent to each other, and the applying electrode 47-2 and the conducting electrode 47-3 are integrally formed in one housing. A type of high frequency therapeutic electrode system that produces thin deep heat in the body is referred to as a bipolar type.

Referring to FIGS. 2 and 3, the treatment method using the conventional bipolar radiofrequency treatment system will be described in detail. After the main body 10 is operated, the core heat of the user's body is measured as shown in FIG. The electrode unit 47 is brought into contact with the body part to be generated and managed. When the applied power switch 46 provided on the handle 45 is turned on, the high frequency power applied to the body through the applied electrode 47-2 is horizontally disposed adjacent to the applied electrode 47-2. The current is supplied to the energized electrode 47-3.

Referring to Fig. 3 (b) which shows a contact section of the body and the electrode unit 47, it is energized with the applying electrode 47-2 disposed horizontally adjacent in the electrode unit housing 47-1. One side of the electrode 47-3 is in contact with the body to be managed. The high frequency power applied to the body through the applying electrode 47-2 is energized through the conducting electrode 47-3, and thin deep heat is generated in the A and B regions of the body. Looking at the size of the deep heat generated between the applying electrode 47-2 and the conducting electrode 47-3, the distance characteristic between the applying electrode 47-2 and the conducting electrode 47-3 is low in the A region. Deep fever occurs, and high fever is concentrated in the A region.

Unlike the conventional bipolar therapeutic electrode device described above, the conventional bipolar therapeutic electrode device does not require a separate conducting electrode to contact the body against the applied electrode, and thus has an advantage of easy management / treatment.

However, in the conventional bipolar type therapeutic electrode device, as shown in FIG. 3 (b), the deep heat is concentrated in the region B between the applying electrode 47-2 and the energizing electrode 47-3. There is a problem that it does not occur due to the distribution of the deep heat in a large area.

In addition, in the conventional bipolar type therapeutic electrode device, as shown in FIG. When the electrode unit is not completely in contact with the body in the middle curved body part, the current is applied with the applying electrode 47-2 in the region C of the applying electrode 47-2 and the conducting electrode 47-3 that contacts the body. The high frequency power supplied between the electrodes 47-3 is concentrated to generate a high core heat momentarily. Therefore, there is a problem that the user is in danger of being burned or shocked due to the high core heat.

Accordingly, an object of the present invention is to provide an electrode unit for a radiofrequency treatment device which is generated by distributing deep heat to a body part to be managed.

Another object of the present invention is to provide an electrode unit for radio frequency treatment apparatus that can prevent the risk of burns, shocks, etc., even if the electrode unit and the body is not in complete contact due to the administrator's mistake or body bending.

It is another object of the present invention to overcome the limitations of the bipolar type electrode unit, that is, the application electrode and the conducting electrode are arranged horizontally adjacent to each other so that deep heat can be generated only at the thin depth of the affected part. It is to provide an electrode unit for a radiofrequency treatment device that can generate deep heat at a deep depth.

The electrode unit for a radio frequency treatment apparatus according to the present invention includes a plurality of application electrodes for applying high frequency power to the body, and a plurality of energizing electrodes and a plurality of application electrodes for energizing the high frequency power applied through the plurality of application electrode units to the body. It includes a housing for placing one side and one side of the plurality of conducting electrodes horizontally to each other.

One side of the plurality of applied electrodes and one side of the plurality of conducting electrodes are arranged horizontally to contact the body, and the plurality of applied electrodes and one side of the plurality of conducting electrodes contacting the body are curved. do. Preferably, one side of the plurality of application electrodes and the plurality of conducting electrodes in contact with the skin is concave or convexly curved.

Each of the plurality of applying electrodes and the plurality of conducting electrodes is an even number, and the plurality of applying electrodes and the plurality of conducting electrodes are spaced apart at different intervals on a circle circumference formed with respect to the center of the housing, or at equal intervals from each other. Spaced apart or, characterized in that arranged to be spaced apart from each other.

The electrode unit for a radiofrequency treatment device according to the present invention has various effects as compared with the conventional monopolar or bipolar type radiofrequency treatment electrode unit.

First, the electrode unit according to the present invention is provided with a plurality of applied electrodes and a plurality of energizing electrodes in one electrode unit, so that deep heat is widely distributed in the body.

Second, in the electrode unit according to the present invention, since one side surface of the plurality of applied electrodes and the plurality of energizing electrodes contacting the body are curved, deep heat may be generated in the affected part.

Third, the electrode unit according to the present invention is disposed by being spaced apart at equal intervals on the circumference of the plurality of applied electrodes and the plurality of conducting electrodes formed on the basis of the center of the housing, the body due to the mistake of the administrator or the bending of the body Even when the and the electrode units do not completely contact, generation of an image or shock can be prevented.

Hereinafter, an electrode unit for radio frequency treatment device according to the present invention will be described in detail with reference to the accompanying drawings.

5 illustrates a perspective view of a bipolar type therapeutic electrode device, in accordance with one embodiment of the present invention.

Referring to Figure 5, the treatment electrode device according to an embodiment of the present invention, the handle unit 50, the electrode unit support portion 60 is formed on one side of the lower surface of the handle portion 50, the electrode unit support ( It consists of an integrated cable 80 connected to one side of the electrode unit 70 and the handle portion 50 is mounted to the lower end of the 60. The integrated cable 80 is a high frequency power cable 81 for providing the high frequency power output from a main body (not shown) generating high frequency power to the electrode unit 70 and a reference power supply for providing the reference power to the electrode unit 70. The cable 83 is provided, and the high frequency power cable 81 and the reference power cable 83 are surrounded by a cable cover 85.

The electrode unit 70 is fixed to the lower end of the electrode unit support 60. A plurality of mounting holes 250 for inserting and mounting the plurality of application electrodes 200 and the plurality of energizing electrodes 300 are formed on the lower surface of the electrode unit 70, and the plurality of application electrodes 200 and the plurality of application electrodes 200 are formed. The conducting electrode 300 of the plurality of mounting holes 250 are spaced apart from each other by a fixing means such as a screw is mounted horizontally.

The other end of the lower surface of the handle 50 is provided with a switch 55 for controlling the high-frequency power and the reference power provided from the high-frequency power cable 81 and the reference power cable 83, respectively. When the manager controls the switch 55 on, the high frequency power supply and the reference power supply are applied from the high frequency power cable 81 and the reference power cable 83 to the plurality of applying electrodes 200 and the plurality of energizing electrodes 300, respectively. do. When the electrode unit 70 is adhered to the body part and the switch is turned on, the high frequency power applied to the body through the plurality of application electrodes 200 is arranged in parallel with the application electrode 200. 300 is energized, and the core heat is widely distributed between the plurality of applied electrodes 200 and the plurality of conductive electrodes 300.

6 shows a longitudinal cross-sectional view of the electrode unit support portion and the electrode unit in the A-A 'direction.

Referring to FIG. 6, the electrode unit support part is mounted on the mounting surface on which the electrode unit support part 60 and the electrode unit 70 are mounted, that is, the bottom surface of the electrode unit support part 60 and the top surface of the electrode unit 70, respectively. A fixing unit for fixedly mounting the 60 and the electrode unit 70 is formed. Looking at the fixing unit in more detail, an insertion hole 67 is formed at the lower end surface of the electrode unit support part 60 toward the upper end surface of the electrode unit support part 60, and the insertion hole 67 is inserted into the insertion hole 67. The fixing hole 68 in the vertical direction is formed. Meanwhile, an insertion member 111 having a radius corresponding to the insertion hole 67 is formed on the upper end surface of the electrode unit 70, and an insertion protrusion 113 is formed in a direction perpendicular to the insertion member 111. When the electrode unit 70 is mounted on the electrode unit supporter 60, the fixing protrusion 113 of the insertion member 111 is elastically compressed and passes through the insertion hole 67 to be elastically restored in the fixing hole 68. The support 60 and the electrode unit 70 are fixed. Depending on the field to which the present invention is applied, the electrode unit support 60 and the electrode unit 70 may be fixedly mounted in various fixed units, which is within the scope of the present invention.

In the housing 61 of the electrode unit support part 60, a first through hole 63 and a second through hole 65 are formed from the handle part 50 to the electrode unit 70, and the electrode unit 70. The upper housing 110 has a third through hole 115 and a fourth through hole 117 extending from the first through hole 63 and the second through hole 65. The high frequency power cable 81 connected to the handle 50 is a substrate disposed between the upper housing 110 and the lower housing 130 through the first through hole 63 and the third through hole 115. It is soldered to one side of 120. Meanwhile, the reference power cable 83 connected to the handle 50 is soldered to the other side of the substrate 120 through the second through hole 65 and the fourth through hole 117.

One side of the substrate on which the high frequency power cable 81 is soldered is formed with a high frequency power supply wiring for providing a high frequency power to the plurality of application electrodes 200, and the other side of the substrate on which the reference power cable 83 is soldered. In the plurality of conducting electrodes 300, a wiring for a reference power source for providing a reference power source is formed. The mounting means 140 for mounting the application electrode 200 to the application electrode mounting hole 131 formed in the lower housing 130 is formed of a conductive material, and the wiring and the lower housing for the high frequency power supply of the substrate 120. It penetrates 130 and is fastened to the application electrode insertion hole 201. On the other hand, the mounting means 145 for mounting the conduction electrode 300 to the conduction electrode mounting hole 133 formed in the lower housing 130 is formed of a conductive material, and the reference power wiring of the substrate 120 and It passes through the lower housing 130 and is fastened to the conducting electrode insertion hole 301. Preferably, the fixing means (140, 145) is a screw through the thread formed in the insertion hole (201, 301) the application electrode 200 or the conducting electrode 300 to the mounting hole (131, 133). Here, the fixing means serves to fix the application electrode 200 or the energizing electrode 300 to the mounting holes 131 and 133 of the lower housing 130, and the high frequency power source and the reference power source flowing through the high frequency power line wiring or the reference power line wiring. The role of providing to the applying electrode 200 and the conducting electrode 300, respectively.

FIG. 7 is a view illustrating an arrangement state of a plurality of applied electrodes and a plurality of energizing electrodes in a bipolar type electrode unit according to an embodiment of the present invention, and FIG. 8 is a diagram of a bipolar type according to an embodiment of the present invention. In the case of using the electrode unit is a diagram for schematically illustrating the distribution of deep heat generated in the body.

Referring to FIG. 7, three applying electrodes 200-1, 200-2, and 200-3 are applied to the applying electrode mounting hole and the conducting electrode mounting hole formed in the lower housing 130 of the electrode unit. Electrodes 300-1, 300-2 and 300-3 are inserted. The three applying electrodes 200-1, 200-2, 200-3 and the three conducting electrodes 300-1, 300-2, and 300-3 have a radius r based on the center O of the lower housing. Are spaced apart at different intervals or at the same interval d from each other on the circle circumference C formed by). Preferably, the three applying electrodes 200-1, 200-2, 200-3 and the three conducting electrodes 300-1, 300-2, 300-3 are formed based on the center O of the lower housing. They are arranged so as to cross each other on the circle circumference C to be spaced apart from each other or at equal intervals.

Referring to FIG. 8, a distribution diagram of deep heat generated in the body is shown. The high-frequency power applied to each of the applied electrodes 200-1, 200-2, and 200-3 is adjacent to the energized electrodes 300-1, 300-. 2, 300-3) through the body to generate deep fever. That is, the high frequency power applied to the body from the first applying electrode 200-1 is energized to the body through the adjacent first conducting electrode 300-1, and the first applying electrode 200-1 is energized with the first. Deep heat is generated in the body between the electrodes 300-1. In addition, the high frequency power applied to the body from the first applied electrode 200-1 is energized to the body through the adjacent third conducting electrode 300-3, and the first applied electrode 200-1 and the third applied to the body. Deep heat is generated between the energizing electrodes 300-3. Similarly, the high frequency power applied to the second applying electrode 200-2 and the third applying electrode 200-3 is energized to the body through the adjacent conducting electrode, and thus, in the body between the adjacent conducting electrodes. Causes deep fever.

On the other hand, the application electrode and the energizing electrode which oppose each other, ie, the 1st application electrode 200-1 and the 2nd electricity supply electrode 300-2, the 2nd application electrode 200-2 and the 3rd electricity supply electrode 300- 3) and deep heat also occurs in the body between the third applied electrode 200-3 and the first conducting electrode 300-1. That is, the high frequency power applied to the body from the first applying electrode 200-1 is energized to the body through the facing second conducting electrode 300-2, and the second applying current is applied to the first applying electrode 200-1. Deep heat is generated in the body between the electrodes 300-2. Similarly, the high frequency power applied to the second applying electrode 200-2 and the third applying electrode 200-3 is energized to the body through an opposite conducting electrode to the second applying electrode 200-2 or Deep heat occurs in the body between the third application electrode 200-3 and the energizing electrode facing the third application electrode 200-3.

As shown in FIG. 8, the bipolar type electrode unit according to the present invention has a plurality of applied electrodes and a plurality of conducting electrodes arranged horizontally to each other in the lower housing 130, so that the body of the body that is in contact with the electrode unit. Deep fever is evenly distributed over a wide range. In addition, even when only a part of the electrode unit comes into contact with the body due to an administrator's mistake or the body's bending, deep heat is distributed to the plurality of applied electrodes and the plurality of conducting electrodes to prevent a risk of burns or shocks.

FIG. 9 is a view for explaining another example of an arrangement state of a plurality of applied electrodes and a plurality of energizing electrodes in a bipolar type electrode unit according to the present invention. In FIG. 9, the applying electrode is shown in black, and the energizing electrode is shown in white.

Referring to FIG. 9 (a), two applied electrodes and two conducting electrodes cross each other on a circle circumference C formed at a predetermined radius with respect to the center O of the lower housing 130 to be equally spaced apart from each other. Spaced apart. Referring to FIG. 9 (b), four applied electrodes and four conducting electrodes are equally spaced apart from each other on a circle circumference C formed at a predetermined radius with respect to the center O of the lower housing 130. Spaced apart.

Referring to FIG. 9 (c), a plurality of applied electrodes and a plurality of energizing electrodes are formed on different circle circumferences C1 and C2 formed at different radii with respect to the center O of the lower housing 130. They are arranged to cross each other and be spaced at equal intervals. Referring to FIG. 9 (d), a plurality of circle circumferences C1, C2, and C3 having a plurality of applied electrodes and a plurality of energizing electrodes formed at different radii with respect to the center O of the lower housing 130 may be described. , C4, ..) are arranged to be spaced apart from each other at equal intervals. Preferably, the electrode unit illustrated in FIG. 9 (d) is an electrode unit used for scalp management, and a plurality of applied electrodes and a plurality of conducting electrodes are spaced apart from each other to correspond to the scalp hair spacing.

The arrangement state of the applying electrode and the conducting electrode shown in FIG. 9 is one example, and two or more applying electrodes and the two or more conducting electrodes are spaced apart from each other or at the same interval on the same circle circumference C. They may be arranged or spaced apart at equal intervals or different intervals crossing each other on the same circle circumference (C). In addition, the two or more applied electrodes and the two or more energizing electrodes are arranged or spaced apart from each other or at the same interval on the plurality of circle periphery (C1, C2, C3, ...) formed at different counter-space On the circumference of the circle (C1, C2, C3, ...) may be disposed to be spaced apart from each other by equal intervals or different intervals.

10 is a longitudinal cross-sectional view of a bipolar type electrode unit according to another embodiment of the present invention. Components shown in the longitudinal cross-sectional view of FIG. 10 are the same as those shown in the longitudinal cross-sectional view of FIG. 6, except that only the applying electrode 210 and the conducting electrode 310 are different from each other. Therefore, hereinafter, only the applying electrode 210 and the conducting electrode 310 will be described.

As shown in FIG. 10, the plurality of applying electrodes 210 and the plurality of conducting electrodes 310 are provided in the plurality of applying electrode mounting holes 131 and the plurality of conducting electrode mounting holes 133 formed in the lower housing 130. ) Is inserted and mounted. The bottom surface of the inserted electrode 210 and the conducting electrode 310, that is, the surface in contact with the body is curved. Preferably, the bottom surfaces of the applying electrode 210 and the conducting electrode 310 are convex or concavely curved.

When using the bipolar electrode unit according to another embodiment of the present invention with reference to FIG. 11 which shows the distribution of deep heat generated in the body, the electrode unit 70 to the body 400 to be managed In the case of contact, since the applying electrode 210 and the conducting electrode 310 are convexly curved, the body part contacting the applying electrode 210 or the conducting electrode 310 is concavely curved. Therefore, since the high frequency power applied to the applying electrode 210 passes through the deep portion of the body and is energized by the conducting electrode 310, deep deep heat occurs in the body. Depending on the depth to generate the deep heat can be used to apply the curved application electrode 210 or the energizing electrode 310 at different counterattack, which is within the scope of the present invention.

 Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Accordingly, the various embodiments of the present invention described above are only one reference in determining the scope of the present invention, and the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1 is a perspective view for explaining a monopolar radio frequency treatment system according to the prior art.

2 is a perspective view illustrating a bipolar radiofrequency treatment system according to the prior art.

3 is a perspective view illustrating a treatment method using a conventional bipolar radiofrequency treatment system.

Figure 4 is a perspective view for explaining the incorrect use of the conventional bipolar radiofrequency therapy system.

5 illustrates a perspective view of a bipolar type therapeutic electrode device, in accordance with one embodiment of the present invention.

6 illustrates a longitudinal cross-sectional view of a bipolar type electrode unit according to an embodiment of the present invention.

FIG. 7 is a view illustrating an arrangement state of a plurality of applied electrodes and a plurality of energizing electrodes in a bipolar type electrode unit according to an exemplary embodiment of the present invention.

FIG. 8 is a diagram schematically illustrating a distribution of deep heat generated in a body when using a bipolar type electrode unit according to an exemplary embodiment of the present disclosure.

FIG. 9 is a view for explaining another example of an arrangement state of a plurality of applied electrodes and a plurality of energizing electrodes in a bipolar type electrode unit according to the present invention.

10 is a longitudinal cross-sectional view of a bipolar type electrode unit according to another embodiment of the present invention.

FIG. 11 is a diagram schematically illustrating a distribution of deep heat generated in a body when using a bipolar electrode unit according to another exemplary embodiment of the present disclosure.

Description of the main parts of the drawing

10: main body 50: handle portion

60: electrode unit support 63: first through hole

65: second through hole 67: insertion hole

68: fixing hole

80: integrated cable 81: high-frequency power cable (81)

83: reference power cable (83) 85: cable cover

110: upper housing 111: insertion member

113: insertion protrusion 115: third through hole

117: fourth through hole 120: substrate

130: lower housing 200, 210: application electrode

300, 310: energized electrode 201: applied electrode insertion hole

301: energizing electrode insertion hole

Claims (10)

In the electrode unit for generating a deep heat by applying a high frequency power to the body, An upper housing having a plurality of through holes, each receiving a high frequency power cable for applying a high frequency power and a reference power cable for applying a reference power; A lower housing having a plurality of application electrode mounting holes and a plurality of conducting electrode mounting holes; A substrate disposed between the upper housing and the lower housing, the substrate having a high frequency power wiring connected to the high frequency power cable and a reference power wiring connected to the reference power cable; A plurality of application electrodes inserted into the plurality of application electrode mounting holes for applying high frequency power to the body; A plurality of conducting electrodes inserted into the plurality of conducting electrode mounting holes for conducting high frequency power applied through the plurality of applying electrodes to the body; A plurality of applying electrode mounting means formed of a conductive material and coupled to the applying electrode through the substrate to fix the applying electrode to the applying electrode mounting hole and to connect to the high frequency power wiring; And And conductive electrode mounting means formed of a conductive material and coupled to the conductive electrode through the substrate to secure the conductive electrode to the conductive electrode mounting hole and to be connected to the reference power supply wiring. The method of claim 1, wherein one side of the plurality of application electrodes and one side of the plurality of conducting electrodes are horizontally disposed to contact the body, The electrode unit, characterized in that one side of the plurality of applied electrodes and the plurality of energizing electrodes in contact with the body is curved. 3. The electrode unit according to claim 2, wherein one side of the plurality of application electrodes and the plurality of energizing electrodes contacting the body are concave or convexly curved. The method according to claim 1 or 2, The electrode unit, characterized in that the plurality of applied electrodes and the plurality of conducting electrodes are each even The method according to claim 1 or 2, The plurality of application electrodes and the plurality of energizing electrodes are disposed on the circumference formed based on the center of the electrode unit spaced apart from each other or at the same intervals, the electrode unit, characterized in that The method of claim 5, And the plurality of applying electrodes and the plurality of energizing electrodes are disposed to cross each other on the circumference of the electrode unit. The method according to claim 1 or 2, The plurality of applied electrodes and the plurality of energizing electrodes are disposed at different intervals or at equal intervals around a plurality of circles formed at different radii with respect to the center of the electrode unit. The method of claim 7, wherein And the plurality of application electrodes and the plurality of energizing electrodes are arranged to be spaced apart from each other around the plurality of circles. The method of claim 7, wherein the electrode unit Electrode unit, characterized in that it is used for scalp management delete

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