KR102183640B1 - Electrode structure of activativg apparatus for target material - Google Patents

Abstract

The present invention relates to an electrode structure of a target material activating device, wherein the electrode structure of a target material activating device is in contact with the target material and generates a target material activator in a space spaced apart from the target material by a predetermined distance according to the dielectric barrier discharge principle. , An electrode portion that serves as a power electrode by inputting power, and a dielectric portion provided in contact with an end portion of the electrode portion, wherein the electrode portion has a hollow portion opened toward the dielectric portion at the terminal portion thereof. do.

Description

Electrode structure of target material activation device {ELECTRODE STRUCTURE OF ACTIVATIVG APPARATUS FOR TARGET MATERIAL}

The present invention relates to an electrode structure of a target material activating device, and more particularly, a target material activating device that is in contact with a target material and generates a target material activator in a space spaced apart from the target material by a predetermined distance according to the dielectric barrier discharge principle. It relates to an electrode structure.

Hereinafter, an apparatus for activating a target material is defined as a device for activating a target material by transferring energy to the surface of a specific target material or an internal structure wrapped around the surface. In addition, the target material refers to a medium that transfers a wave or physical action from one place to another as a medium, and it is assumed that it is a conductive material.

Examples of target substance activation devices include bioactive devices using high frequency, low frequency, plasma, and ultrasonic waves used in the field of skin care and biomedical, and waste treatment devices and water treatment devices are also used to deliver energy to specific target materials. Since it activates the target substance, it can be seen as another example of a target substance activation device.

In this case, the target material activation device applying the dielectric barrier discharge principle includes a power supply unit for supplying oscillation power, a transformer unit for changing the power supplied from the power supply unit, an electrode unit to which the power changed from the transformer unit is input, and the It is generally configured to include a dielectric portion installed to be positioned at an end portion of the electrode portion.

In this regard, as a prior art related to the target substance activation device, Korean Patent Publication No. 10-1667646 (Patent Document 1) has been disclosed.

Patent Document 1 relates to a plasma generator for living body skin using air discharge, a case in which an accommodation space is formed and separated into an upper and lower case, a control unit mounted on one side of the case, and a case mounted and charged in the receiving space of the case. Battery capable of discharging, a high voltage power supply that receives power from the battery and supplies low-frequency high voltage power according to the operation of the control unit, an electrode cover mounted on the front of the case, and a high voltage power supply mounted on the front of the electrode cover By including an electrode that generates plasma by receiving it, it is possible to remove organic substances and foreign substances while eradicating bacteria in the skin or pores of the human body through a plasma generator for living body skin that is easy to carry. There is an effect that can be used in places.

However, in the case of Patent Document 1, since the electrode includes an electrode conductor power supply unit connected to a high voltage power supply and an electrode conductor ground unit connected to the ground unit, a lower pair (ie, two) electrode configurations must be included. There is this.

In addition, in the case of Patent Document 1, there is a problem that not only does not disclose a technology using one electrode, but also does not disclose an electrode structure for improving power efficiency by minimizing power loss when composed of only one electrode. have.

Korean Registered Patent Publication No. 10-1667646

In solving the above-described problems, an object of the present invention is to provide an electrode structure of a target material activating device capable of activating a target material with only one electrode.

In addition, it is an object of the present invention to provide an electrode structure of a target material activating device that can activate a target material with only one electrode and present an electrode shape that improves power efficiency.

The electrode structure of the target material activating device according to an embodiment of the present invention is an electrode structure of a target material activating device that is in contact with a target material and generates a target material activator in a space spaced a predetermined distance from the target material according to a dielectric barrier discharge principle. In the following, the electrode portion that serves as a power electrode by inputting power, and a dielectric portion provided in contact with an end portion of the electrode portion, wherein the electrode portion is formed with a hollow portion opened toward the dielectric portion. It is characterized.

In this case, it is preferable that the dielectric portion is provided in contact with the end portion of the electrode portion while forming a contact surface excluding at least the opening area of the hollow portion.

In this case, the dielectric portion may have an annular contact surface and may be installed in contact with an end portion of the electrode portion.

In addition, the dielectric portion may have a branched contact surface formed from the center toward the outer side toward the side, and may be provided in contact with an end portion of the electrode portion.

Meanwhile, in a cross section when the dielectric part and the target material are in contact, it is preferable that the contact edge of the target material is located on the width of the contact surface of the electrode part and the dielectric part.

On the other hand, the target material activator is characterized by including active species, electrons and ions, emitting ultraviolet rays and visible rays, and forming an electromagnetic field.

Meanwhile, in the electrode structure of the apparatus for activating a target material according to an embodiment of the present invention, it is preferable that the target material is grounded.

As described above, the electrode structure of the apparatus for activating a target material according to the present invention enables the target material to be activated with only one electrode.

In addition, the electrode structure of the target material activation device according to the present invention enables the target material to be activated with only one electrode and at the same time presents a specific shape of the electrode to improve power efficiency.

1 is a block diagram illustrating an apparatus for activating a target substance according to an embodiment of the present invention.
2 is a cross-sectional view illustrating an electrode structure of an apparatus for activating a target material according to an exemplary embodiment of the present invention.
FIG. 3 is a diagram illustrating a contact surface of a dielectric part and an electrode part that is recognized when an electrode part is viewed from the target material side of FIG. 2.

In the present invention, the accompanying drawings may be shown as exaggerated expressions for the sake of discrimination and clarity from the prior art, and for convenience of understanding the technology. In addition, terms to be described later are terms defined in consideration of functions in the present invention, and may vary according to the intentions or customs of users and operators, so the definition of these terms should be made based on the technical contents throughout the present specification. will be. On the other hand, the embodiments are only exemplary matters of the constituent elements presented in the claims of the present invention, and do not limit the scope of the present invention, and the scope of the rights should be interpreted based on the technical idea throughout the specification of the present invention. .

1 is a block diagram illustrating an apparatus for activating a target material according to an exemplary embodiment of the present invention, and FIG. 2 is a cross-sectional view illustrating an electrode structure of an apparatus for activating a target substance according to an exemplary embodiment of the present invention. FIG. 3 is a diagram illustrating a contact surface of a dielectric part and an electrode part that is recognized when an electrode part is viewed from the target material side of FIG. 2.

1 to 3, the electrode structure of the target material activation apparatus 100 according to an embodiment of the present invention includes an electrode part 130 and a dielectric part 140.

In this case, the target material activation device 100 may be configured to further include a power supply unit 110, a transformer unit 120 and an electric circuit unit 150 in addition to the electrode unit 130 and the dielectric unit 140. have. The target material activating device 100 is in contact with the target material 1 (more specifically, the surface portion 1a of the target material 1) to be separated by a predetermined distance from the target material 1 according to the dielectric barrier discharge principle. It is a device that generates an active substance of a target substance in the space (2).

The power supply unit 110 serves to supply oscillation power to the target material activation device 100.

In this case, the power supply unit 110 may include a rechargeable battery. For example, the battery may be made of a lithium-polymer battery, may be installed inside the cover (not shown) of the target material activating device 100, or may be separately installed outside.

The power supply unit 110 is electrically connected to the transformer unit 120 and may be configured to selectively allow whether or not to supply oscillation power in a switching control method. In this case, the switching control method is configured by controlling the intensity of oscillation power from the power supply unit 110 to the transformer 120 or changing and controlling the power transformation ratio of the transformer 120 within a preset value range. Can be.

The transformer 120 serves to change the voltage level of power supplied from the power supply 110.

In this case, the transforming unit 120 may be configured to be input by varying the degree of transformation according to the characteristics of the target material 1.

The electrode unit 130 is electrically connected to the transforming unit 120 to receive the changed power from the transforming unit 120. The electrode unit 130 may be made of a metal material.

The electrode unit 130 serves as a power electrode in the dielectric barrier discharge principle applied to the target material activating device 100. As will be described later, the target material activation device 100 includes an electrode of a'power electrode (the electrode part 130)-a dielectric (the dielectric part 140)-a ground electrode (target material (1))' In combination, the target material activator according to the dielectric barrier principle is generated.

The electrode part 130 has the dielectric part 140 at its end part (the end part is named based on the left-right arrangement in FIG. 1, and specifically refers to the end of the dielectric part 140 side). It characterized in that the hollow portion 131 opened toward the formed.

In this case, the electrode part 130 is formed in a three-dimensional shape having a certain volume, and a non-contact surface with the dielectric part 140 is formed by a special shape having the hollow part 131 at its end. The effect of improving power efficiency is attained. In this case, the end portion of the electrode unit 130 may be configured in a hollow top shape having a three-dimensional hollow top shape or a plurality of branched wings facing outward with a plurality of weight loss spaces along the circumference. It can be configured in a form.

On the other hand, the electrode unit 130, when power is input through the power supply unit 110 and the transformation unit 120, the dielectric unit 140 and the target material (1) electrochemical interaction Through this, the target substance activator is generated.

A more detailed description of the electrode unit 130 will be described later together with a description of the dielectric unit 140.

The dielectric part 140 is provided in contact with an end part of the electrode part 130. It is preferable that the dielectric part 140 is detachably installed on the electrode part 130.

The dielectric part 140 may be made of a ceramic material, and, for example, include at least one of alumina (Al ₂ O ₃ ), zirconia (ZrO ₂ ), germanium (Ge), and cerium (Ce). Can be configured.

In this case, the dielectric unit 140, when power is input to the electrode unit 130 through the power supply unit 110 and the transformer 120, the electrode unit 130 and the target material (1) Through the electrochemical interaction with, the target substance activator is generated. More specifically, as shown in FIG. 2, the dielectric part 400 is in contact with the target material 1 and is placed in a space 2 spaced apart from the target material 1 by a predetermined distance according to the dielectric barrier discharge principle. A target substance activator is generated, and energy is transferred to and activated by the target substance 1 through the target substance activator. At this time, it is preferable that the target material 1 is grounded.

Accordingly, the target material activating device 100 may activate the target material 1 with only one electrode, unlike the conventional one.

The target substance activator is characterized by including active species, electrons, and ions, emitting ultraviolet rays and visible rays, and forming an electromagnetic field. That is, the target substance active substance generates light, heat, and electromagnetic fields by interactions (ionization, dissociation, ionization, recombination, etc.) of active species, electrons, and ions.

On the other hand, the dielectric part 140 is preferably installed in contact with the end of the electrode part 130 while forming a contact surface 140a excluding at least the opening area of the hollow part 131. With this electrode structure, at least the opening area of the hollow portion 131 or more forms a non-contact surface between the electrode portion 130 and the dielectric portion 140. In this case, compared to the case where the electrode part 130 does not have the hollow part 131 (for example, when it is formed in a three-dimensional shape of a top), at least the opening area of the hollow part 131 is'power electrode ( The target material is activated because it acts as a three-party surface contact blocking function that blocks current leaking into the electrode part 130)-dielectric (the dielectric part 140)-ground electrode (target material 1). It is possible to concentrate the current flow on the generation of the sieve, thereby improving power efficiency.

As an example related to this, when the end portion of the electrode part 130 is formed in a three-dimensional shape of a hollow top, the dielectric part 140 has an annular contact surface 140a-1 and the electrode part 130 It can be installed in contact with the end. (See Fig. 3(a))

As another example related to this, when the end portion of the electrode unit 130 is formed in a hollow top shape having a plurality of branched wings facing outward with a plurality of weight loss spaces along the periphery, the dielectric unit 140 Has a branched contact surface 140a-3 formed from the center toward the outer side toward the side, and may be installed in contact with the end portion of the electrode unit 130. (See FIG. 3(c)) In this case, it goes without saying that it is possible to change the shape of the end portion of the electrode unit 130 to have a contact surface 140a-2 further including an annular contact surface. (See Fig. 3(b))

Meanwhile, referring to FIG. 2, in a cross section when the dielectric part 140 and the target material 1 contact, the contact edge 1b of the target material 1 is the electrode part 130 and the dielectric part 140. ) Of the contact surface (140a) width (here, the width refers to the width in the left and right direction based on FIG. 2, and the length of the intersection of the auxiliary line and the contact surfaces 140a-1, 140a-2, 140a-3) of FIG. It is preferable to be positioned on the phase, and in this case, it was experimentally confirmed that the active substance of the target substance is most effectively generated.

As an example related to this, when the end portion of the electrode part 130 is formed in a three-dimensional shape of a hollow top, the dielectric part 140 has an annular contact surface 140a-1 and the electrode part 130 It can be installed in contact with the end. (See FIG. 3(a)) In this case, the contact edge 1b' of the target material 1 may be formed in an annular shape. (Of course, it may be formed in an annular shape cut off depending on the contact pattern of the target material 1. Therefore, the contact edge 1b' of the target material 1 has the edge of the contact portion where the target material active is generated. (Based on Fig. 2) This means that it is sufficient to be on the width of the contact surface 140a of the matching electrode unit 130 and the dielectric unit 140. Hereinafter, the contact edges 1b", 1b" of the target material 1 ') is the same.)

As another example related to this, when the end portion of the electrode unit 130 is formed in a hollow top shape having a plurality of branched wings facing outward with a plurality of weight loss spaces along the periphery, the dielectric unit 140 Has a branched contact surface 140a-3 formed from the center toward the outer side toward the side, and may be installed in contact with the end portion of the electrode unit 130. (See FIG. 3(c)) In this case, it goes without saying that it is possible to change the shape of the end portion of the electrode unit 130 to have a contact surface 140a-2 further including an annular contact surface. (See FIG. 3(b)) In this case, the contact edges 1b", 1b"' of the target material 1 may be formed in a divided band shape. In FIG. 3(b), the contact edge 1b ″ of the target material 1 may be formed in an annular shape (inside) or a mixed shape of an annular shape and a strip shape according to the contact pattern of the target material 1.

The electric circuit unit 150 serves to ground the target material 1 and receive a feedback signal. Accordingly, the electric circuit unit 150 may include a monitoring unit 151 that receives information on whether the target substance activating device 100 operates normally, that is, a feedback signal.

In this case, the electric circuit unit 150 may be directly electrically connected to the target material 1 as shown in FIG. 1, and is directly electrically connected to the cover of the target material activating device 100, so that the target material ( The target material 1 may be configured to be grounded by mutual conduction by contact between 1) and the cover.

Hereinafter, the operation method of the target substance activating device 100 will be briefly described.

When power is input to the electrode unit 130 through the power supply unit 110 and the transformation unit 120, the electrode unit 130, the electrode unit 140, and the target material (1) Through the interaction, the target substance activator is generated in a space 2 spaced apart from the target substance 1 by a predetermined distance, and energy is transmitted to the target substance 1 through the target substance activator to activate it. At this time, the target material 1 is grounded and functions as a ground electrode based on the principle of dielectric barrier discharge.

Since a hollow portion 131 opened toward the dielectric portion 140 is formed at a terminal end portion of the electrode portion 130, the dielectric portion 140 has at least the opening area of the hollow portion 131 Since the contact surface 140a except for the contact surface 140a is formed and is installed in contact with the end portion of the electrode unit 130, at least the opening area of the hollow part 131 acts as a non-contact surface, so that the power electrode (the electrode part 130 )))-Dielectric (the dielectric part 140)-ground electrode (target material 1)'. Accordingly, it is possible to concentrate the current flow on the generation of the target material activator, thereby improving power efficiency.

As described above, the electrode structure of the target material activation device according to the present invention enables the target material to be activated with only one electrode and at the same time presents a specific shape of the electrode to improve power efficiency.

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is only exemplary, and various modifications and equivalent other embodiments are possible based on common knowledge in the field to which the technology belongs. Must understand. Therefore, the true technical protection scope of the present invention is based on the claims to be described below, and should be determined based on the specific contents of the above-described invention.

The present invention relates to an electrode structure of a target substance activation device, and can be used in industrial fields related to activation of various target substances (eg, beauty field, biomedical field, waste treatment field, water treatment field, etc.).

1: target material
1a: surface portion
1b, 1b', 1b'', 1b''': contact edge
2: separating space
100: target substance activation device
110: power supply
120: transformer
130: electrode part
131: hollow part
140: dielectric part
140a, 140a-1, 140a-2, 140a-3: contact surface
150: electric circuit part
151: monitoring unit

Claims (7)

In the electrode structure of the target material activating device in contact with the target material to generate a target material activator in a space spaced apart from the target material by a predetermined distance according to a dielectric barrier discharge principle,
An electrode unit receiving power and performing the role of a power electrode; And
A dielectric portion provided in contact with an end portion of the electrode portion;
Including,
The electrode part,
Characterized in that a hollow portion opened toward the dielectric portion is formed at the end thereof,
The dielectric part,
It is characterized in that it is provided in contact with the end portion of the electrode portion while forming at least a contact surface excluding the opening area of the hollow portion,
The dielectric part,
The electrode structure of the target substance activating device, characterized in that it has a branched contact surface formed from the center toward the outer side toward the side, and is provided in contact with the end of the electrode part.
delete The method of claim 1, wherein the dielectric portion,
The electrode structure of the target substance activating device, further comprising an annular contact surface and being provided in contact with an end portion of the electrode part.
delete The method of claim 1,
The electrode structure of the target material activation device, wherein in a cross section when the dielectric part and the target material are in contact with each other, a contact edge of the target material is located on a width of a contact surface of the electrode part and the dielectric part.
The method of claim 1, wherein the target substance activator,
An electrode structure of an apparatus for activating a target substance, comprising active species, electrons and ions, emitting ultraviolet rays and visible rays, and forming an electromagnetic field.
The method of claim 1,
The electrode structure of the target material activation device, characterized in that the target material is grounded.

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