KR102186342B1 - A Module for Generating an Ion - Google Patents

Abstract

The present invention relates to an ion generator. The ion generator includes a gas inlet means 11 for introducing an external gas; An anode cylinder 121 through which external gas is introduced and guided to a predetermined path; A discharge electrode 122 disposed in an induction path formed in the anode cylinder 121; And an insulator 123 separating the anode cylinder and the discharge electrode 122 from each other.

Description

Ion Generator {A Module for Generating an Ion}

The present invention relates to an ion generator, and more particularly, to an ion generator for generating various types of ions including negative ions by corona discharge or plasma discharge.

Fresh air in the natural environment may contain a certain level of positive and negative ions, thereby advantageously affecting health. However, in the case of an urban environment or an indoor environment, the ratio of such cations or anions may be significantly lowered, and thus various types of health problems may occur due to ion imbalance. This allows air purifiers or similar devices to be equipped with various types of negative ion generating means. Various types of negative ion generating means are known in the art, and Patent Publication No. 10-2012-0056013 discloses an ion generating module. In addition, Patent Publication No. 10-2006-0021468 discloses an ion generator capable of suppressing ozone, nitrogen dioxide or electromagnetic waves generated in the discharge process while generating a large amount of negative ions. The generation level of anions must be appropriately adjusted according to the operating environment, ozone may be generated in the process of generating anions, and ozone needs to be appropriately adjusted according to the anion generating environment. However, the prior art does not disclose a means for generating anions suitable for such conditions.

The present invention has the following objects to solve the problems of the prior art.

Prior Art 1: Patent Publication No. 10-2012-0056013 (IM Healthcare Co., Ltd., published on June 1, 2012) Ion Generation Module Prior Art 2: Patent Publication No. 10-2006-0021468 (Michael Chai, 2006.03.08. Publication) Ion Generator

An object of the present invention is to provide an ion generator in which ions are generated at a discharge electrode through the introduction of external air, and the emission level of ozone generated during the ion generation process is controlled.

According to a preferred embodiment of the present invention, the ion generator includes a gas inlet means for introducing an external gas (; an anode cylinder through which an external gas is introduced and guided to a predetermined path; a discharge electrode disposed in an induction path formed in the anode cylinder; and an anode cylinder) And an insulator separating the discharge electrodes from each other.

According to another suitable embodiment of the present invention, at least a part of the discharge electrode is disposed inside the insulator.

According to another suitable embodiment of the present invention, it includes an ozone control unit in which a nozzle unit into which particulates including water are sprayed is disposed.

The ion generator according to the present invention is made in a modular structure and can be used in combination with an air cleaner, a personal computer, an electric vacuum cleaner, or a lighting stand. In addition, the ion generator according to the present invention may be independently installed indoors or installed in a workplace. The ion generator according to the present invention restricts ozone emission and allows negative ions, hydrogen ions, oxygen ions, or similar ions that have a beneficial effect on the human body to be maintained for a long time after being discharged to the outside.

1 shows an embodiment of an ion generator according to the present invention.
2 shows another embodiment of the ion generator according to the present invention.
3 shows another embodiment of the ion generator according to the present invention.

In the following, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments are for a clear understanding of the present invention, and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so if they are not necessary for the understanding of the invention, they will not be described repeatedly, and well-known components will be briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiment of.

1 shows an embodiment of an ion generator according to the present invention.

Referring to Figure 1, the ion generator includes a gas inlet means 11 for introducing an external gas; An anode cylinder 121 through which external gas is introduced and guided to a predetermined path; A discharge electrode 122 disposed in an induction path formed in the anode cylinder 121; And an insulator 123 separating the anode cylinder and the discharge electrode 122 from each other.

The ion generator can generate various types of ions such as hydrogen ions or oxygen ions including negative ions by corona discharge or plasma discharge from gas flowing from the outside, for example, incoming external air or various artificially injected ions. It can generate ions from the gas. The gas inlet means may include, for example, a forced inlet means such as a fan, an induction conduit for guiding the gas, or a filter for removing foreign substances. The gas inlet 11 may introduce external air or a predetermined amount of gas from a gas storage container. The gas inlet means 11 may be connected to the ion generating means 12, and various ions including negative ions may be generated in the ion generating means 12. The anode cylinder 121 may have a cylindrical or polyhedral structure in which the front part is connected to the gas inlet means 11 and the rear part is connected to the control unit 13. The anode cylinder 121 may have a hollow structure, and at least a portion may be made of a conductive material such as metal. The discharge electrode 122 may be disposed along the extending direction of the anode cylinder 121, and the discharge electrode 122 may have a linear structure. For example, the discharge electrode 122 may be disposed based on a center line along the length direction of the anode cylinder 121. The discharge electrode 122 may be made of various conductive materials, and if necessary, a discharge nucleus having a needle shape, a star shape, or a similar shape may be coupled to the peripheral surface of the discharge electrode 122. In addition, an insulator 123 may be disposed inside the anode cylinder 121 in a form surrounding the discharge electrode 122. The insulator 123 may be made of a porous material, and may include, for example, elvanite, zeolite, bentonite, silica, ceramic, or a similar material. In addition, the insulator 123 may include a material similar to nonwoven fabric, cotton fiber, or wood. Additionally, the insulator 123 may contain a nano clay component. For example an average particle size of 30 to 200 nm; Specific Surface Area 30 to 50 m 2 /g; And 1 to 10 wt% of a nanoclay component having a density of 0.8 to 1.2 g/cm 3. Nanoclays can be made from materials such as layered silicates, for example clay minerals. When the nanoclay is added to the insulator 123, the insulator 123 may have a filter function and a useful component may be generated. Optionally, a temperature control unit 124 may be disposed inside the insulator 123, and the temperature control unit 124 may include a temperature control means 15 such as a thermoelectric element. Heat or cold air generated through the temperature control means 15 may be transferred to the inside of the insulator 123, and the temperature control unit 124 may have a structure capable of flowing water or a similar fluid medium. By controlling the temperature of the insulator 123, the filter function, the discharge of the trapped material, or the flow pressure of the gas may be appropriately adjusted. The anode cylinder 121 and the discharge electrode 122 may be maintained at a voltage difference determined by the power source 14. Gas containing ions such as negative ions generated by the discharge electrode 122 may be discharged to one end of the anode cylinder 121 and introduced into the discharge control unit 13. The emission control unit 13 may have a function of removing substances such as ozone generated during the ion generation process. In addition, it may have a function of attaching ions to particulates so that ions are discharged to the outside and maintained for a long time. The emission control unit 13 may have a function of decomposing ozone by an ultraviolet ray generating unit, manganese dioxide, or a similar catalyst. Alternatively, water can be made in the form of particulates and formed in the form of ionic clusters together with ions to be released.

The discharge control unit 13 can be made in various structures and is not limited to the presented embodiment.

2 shows another embodiment of the ion generator according to the present invention.

Referring to FIG. 2, at least a portion of the discharge electrode 122 is disposed inside the insulator 123. The gas may flow in various ways inside the anode cylinder 121. The discharge electrode 122 may be installed in an intermediate portion along the length direction of the anode cylinder 121, and the insulator 123 surrounding the discharge electrode 122 may be disposed in a form that fills a part of the anode cylinder 121. I can. Accordingly, a gas flow path may be formed along the inner circumferential surface of the anode cylinder 121. The insulator 123 may be made of the material described above or a similar material. At least one discharge induction unit 21_1 to 21_N may be disposed in a direction perpendicular to the extending direction of the discharge electrode 122. One end of the discharge induction units 21_1 to 21_N may be connected to the discharge electrode 122 disposed inside the insulator 123, and the other end of the discharge induction units 21_1 to 21_N is outside the insulator 123. It can be exposed. Accordingly, a part of the discharge induction units 21_1 to 21_N may be exposed to the gas flow path formed in the anode cylinder 121. Each of the discharge induction units 21_1 to 21_N may be linear and may extend in the same or different directions. For example, each of the discharge induction units 21_1 to 21_N may extend at different angles at different positions of the discharge unit 122. As an alternative to the discharge induction units 21_1 to 21_N or together with the discharge induction units 21_1 to 21_N, a discharge net 22_K may be installed. The discharge net 22_K may have a net structure while being generally circular, and the discharge electrode 122 may penetrate through the center. The entire discharge net 22_K may be located inside the insulator 123 or a peripheral portion may be exposed to the outside. In the presented embodiment, the gas may flow along the gas flow path or the inside of the insulator 123. The discharging unit 122 may be made in various structures and is not limited to the presented embodiment.

3 shows another embodiment of the ion generator according to the present invention.

3, an ozone control unit 36 in which a nozzle unit 38 into which particulates including water are sprayed is disposed.

Referring to FIG. 3, an insulator unit 32 may be disposed inside the induction cylinder 31, and a discharge cylinder 33 having a cylinder shape or a similar shape may be disposed inside the insulator unit 32. The insulator unit 32 may be a filled shape or a hollow shape. Alternatively, the insulator unit 32 may be coupled to the outer peripheral surface of the discharge cylinder 33 by, for example, a coating or film adhesion method. The discharge generation units 34_1 to 34_N may be disposed inside the discharge cylinder 33, and the discharge generation unit 34_N may have a linear structure or a network shape described above. In the case of a linear structure, the discharge cylinder 33 may be perpendicular to the extending direction and may be extended at different angles according to the position of the discharge cylinder 33. A voltage is maintained between the induction cylinder 31 and the discharge cylinder 33, and gas can be guided along the interior of the discharge cylinder 33. Various types of ions including negative ions are generated by the discharge generating units 34_1 to 34_N inside the discharge cylinder 33, and gas containing ions may be guided into the ozone control unit 36. A nozzle unit 38 for generating particulates may be disposed inside the ozone control unit 36, and a supply unit 37 connected to the particulate generation unit 39 by a circulation tube T may be disposed below. The particulate generation unit 39 may be, for example, an ultrasonic vibrator or steam generating means, and a liquid such as water or hypochlorous acid may be supplied through the supply unit 37. As ozone is removed by particulates sprayed by the nozzle unit 38, anion clusters are generated and discharged to the outside. Optionally, an ozone removing means such as an ultraviolet light emitting device or manganese dioxide may be disposed inside the ozone control unit 36. The control of ozone can be made in various ways and is not limited to the examples presented.

The ion generator according to the present invention is made in a modular structure and can be used in combination with an air cleaner, a personal computer, an electric vacuum cleaner, or a lighting stand. In addition, the ion generator according to the present invention may be independently installed indoors or installed in a workplace. The ion generator according to the present invention limits ozone emission and allows negative ions to be maintained for a long time after being discharged to the outside.

The present invention has been described in detail above with reference to the presented embodiments, but those of ordinary skill in this field will be able to make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. . The present invention is not limited by such modifications and variations of the invention, but is limited by the claims appended below.

11: gas inlet means 12: ion generating means
13: control unit 14: power
21_1 to 21_N: discharge induction unit 22_K: discharge net
31: induction cylinder 32: insulator unit
33: discharge cylinder 34: discharge generation unit
36: ozone control unit 37: supply unit
38: nozzle unit 39: particulate generation unit
121: anode cylinder 122: discharge electrode
123: insulator 124: temperature control unit

Claims (3)

Gas inlet means 11 for introducing external gas;
An anode cylinder 121 having a cylindrical hollow structure in which external gas is introduced and guided to a predetermined path;
A discharge electrode 122 of a linear structure disposed in an induction path inside the anode cylinder 121 along the extending direction of the anode cylinder 121; And
Includes an insulator 123 disposed inside the anode cylinder 121 in a form surrounding the discharge electrode 122 to separate the anode cylinder and the discharge electrode 122 from each other,
It further includes at least one discharge induction unit (21_1 to 21_N) disposed in a direction perpendicular to the extension direction of the discharge electrode 122, and the discharge induction unit (21_1 to 21_N) has one end of the insulator 123 The gas is connected to the discharge electrode 122 disposed inside of and the other end is exposed to the outside of the insulator 123 so that a part of the discharge induction units 21_1 to 21_N is formed along the inner circumferential surface of the anode cylinder 121 Ion generator, characterized in that exposed to the flow path. delete The ion generator according to claim 1, comprising an ozone control unit (36) in which a nozzle unit (38) into which particulates containing water are sprayed.

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