KR20080056479A - An ion making device - Google Patents

Abstract

An ion generating device is provided to form a discharge electrode that has an optimized size that is able to generate a large amount of positive ions even if no large amount of voltage is applied. An ion generating device includes a positive ion generating portion(5) and a negative ion generating portion corresponding to the positive ion generating portion. An electric discharge electrode(9) having a thickness of 0.05-0.15mm is installed on the positive ion generating portion. The electric discharge electrode includes a pattern frame(9a), an electrode portion(9c) and one or more discharge needles(9b). The pattern frame constitutes a body of the discharge electrode and forms an electrode line. The electrode portion is installed on one side of the pattern frame. The discharge needles are formed on the pattern frame.

Description

An ion making device

1 is a perspective view of an ion generating device according to the present invention.

Figure 2 is an exploded perspective view of the cation generating unit according to the present invention.

3 is a plan view of a cation generating unit according to the present invention.

4 (a) to 4 (c) are plan views of discharge electrodes having different numbers of discharge needles.

5 is data of the cation emission amount according to the thickness of the discharge electrode according to the present invention.

Figure 6 is a side cross-sectional view showing the operation of the ion generating device according to the present invention.

* Description of symbols on the main parts of the drawings *

1: ion generator 5: cation generator

9: discharge electrode 11: induction electrode

13: ceramic plate

The present invention relates to an ion generating device, which aims to provide an ion generating device including a discharge electrode capable of inducing a large amount of cation release and suppressing the release of ozone as much as possible.

The ion generating device includes a cation generating unit for generating a cation and an anion generating unit for generating an anion, and a cation generating unit is usually provided with a ceramic plate, a discharge electrode and an induction electrode provided inside the ceramic plate, and an anion generating unit It is composed of a needle electrode.

Here, when a high voltage of the positive component is applied between the discharge electrode and the induction electrode, the cation and ozone (O3) of hydrogen ions (H +) are generated in the ceramic plate by plasma discharge.

In addition, when a high voltage of (-) component is applied to the needle electrode of the anion generator, a large amount of electrons are released into the air by plasma discharge. The electrons are combined with oxygen molecules (O2) in the air to form superoxide anion (O2). To generate negative ions.

When the hydrogen ions and the superoxide anions are supplied to the room, hydroxyl groups (OH) or hydrogen peroxide (H 2 O 2) are formed, and the substances are attached to the bacteria to cause an oxidation reaction to remove the bacteria.

Therefore, in order to improve sterilization performance, cations should be discharged in large quantities. However, if the voltage applied to discharge cations is increased, there is a problem that the peak value of the voltage is significantly increased. There is a need for this needless ionizer.

The present invention has been made to solve such a problem, and an object thereof is to provide a discharge electrode having an optimized standard capable of generating a large amount of cations even when a large applied voltage is not required.

The present invention for achieving this object is a cation generator; In the ion generator having an anion generator corresponding to the cation generator, the ion generator is provided with a discharge electrode having a thickness of 0.05 ~ 0.15mm in the cation generator.

The discharge electrode may include a pattern frame constituting a body and forming electrode lines; An electrode unit provided at one side of the pattern frame to apply a voltage; It characterized in that it comprises at least one discharge needle protruding from the pattern frame, the thickness of the pattern frame is characterized in that consisting of 0.05 ~ 0.15mm.

In addition, the cation generating unit and the ceramic coating provided on the upper surface of the discharge electrode;

An induction electrode provided below the discharge electrode and causing corona discharge with the discharge electrode; And a ceramic plate provided under the induction electrode, wherein the discharge electrode is provided with a discharge needle and an electrode line.

The present invention also includes a cation generator and an anion generator for generating cations and anions, respectively, by plasma discharge; Provided with the cation generator is provided an ion generating device characterized in that it comprises a discharge electrode consisting of a thickness of 0.05 ~ 0.15mm.

The discharge electrode may further include a pattern frame forming one or more electrode lines; It includes a discharge needle protruding from the pattern frame, the thickness of the pattern frame is characterized in that consisting of 0.05 ~ 0.15mm or less.

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

The ion generating device according to the present invention comprises a case (3), a cation generating portion (5) arranged in the form of a plate in the case (3), and an anion generating portion formed at a predetermined interval from the cation generating portion (5) It is composed of 15, the anion generator 15 is preferably composed of a needle electrode.

As shown in FIG. 2, the cation generator 5 includes a ceramic coating layer 7, a discharge electrode 9, a ceramic insulating layer 8, an induction electrode 11, and a ceramic plate 13. It is configured by laminating. Here, the ceramic coating layer 7 covers and protects the surface of the discharge electrode 9, and the ceramic insulating layer 8 is disposed between the discharge electrode 9 and the induction electrode 11 to insulate it.

Here, the discharge electrode 9 is provided on a pattern frame 9a forming a plurality of electrode lines, a discharge needle 9b protruding from the pattern frame 9a, and one side of the pattern frame 9a. The electrode part 9c to which a voltage is applied is included.

The discharge electrode 9 has a constant thickness t, where the thickness of the discharge electrode 9 is preferably 0.05 to 0.15 mm, and the reason for having such a thickness will be described later.

3 is a plan view showing a main portion of the cation generating unit according to the present invention, wherein the induction electrode 11 is fixed to the ceramic plate 13, and the discharge electrode 9 is disposed on the induction electrode 11. Is installed.

The discharge electrode 9 and the induction electrode 11 are printed with tungsten, which is a conductor, to generate corona discharge by generating high voltage across the electrodes to generate ions.

4 (a) to 4 (c) show various forms of the discharge electrodes of the present invention, the thicknesses of the discharge electrodes shown in these figures are the same, except that the number of discharge needles is provided differently. There are 16 discharge needles in (a), 10 in Fig. 4B, and 24 in Fig. 4C.

Hereinafter, the transition of the cation generation amount according to the change in the thickness of the discharge electrode shown in FIGS. 4 (a) to 4 (c) will be described.

The thickness of the discharge electrode of FIGS. 4 (a) to 4 (b) is in the range of 0.05 mm to 0.5 mm, and the relationship between the change in thickness and the amount of cations generated, the amount of discharge needles and the amount of cations generated Is shown in the data calculated in FIG.

The specification of the discharge needle used in the present invention was 25mm x 13mm in width and width, respectively, and the thickness of the pattern frame was thinned by 0.05mm from 0.5mm to 0.05mm, the applied voltage is 3.4kV, frequency Was tested under 230Hz and 20% condition.

As a result of the experiment, it can be seen that as the thickness of the pattern frame gradually decreases, the amount of discharge of the cation increases gradually. In particular, within the range of 0.20 mm to 0.50 mm, the air per 1 cc of air discharge needles is based on 16 discharge needles. From 250,000 to 410,000, the sequential changes were almost sequential, reaching an explosive increase in the amount of cations from 0.05mm to 0.15mm, reaching nearly 890,000 to 990,000 per cc of air.

As such, when the thickness of the pattern frame is within the range of 0.05 to 0.15 mm, a significant increase in the amount of cations generated is a common phenomenon even when the number of discharge needles varies.

Therefore, through these experimental results, it can be said that the factor which greatly influences the discharge amount of the cation is the thickness of the discharge electrode, in particular, the thickness of the pattern frame. I can not say.

The reason for the explosive increase as the thickness of the discharge electrode becomes thin is that when the energy generated by the corona discharge generated between the discharge electrode and the induction electrode is dispersed on the surface of the discharge electrode, when the thickness of the discharge electrode becomes thick, the total surface area is increased. This increases, so that the amount of energy is increased, and the concentration of energy for generating cations is relatively reduced, so that the amount of cations generated is reduced.

Therefore, as given in the experimental data, when the thickness of the discharge electrode is in the range of 0.05 to 0.15 mm, the amount of cation generated is greatly increased, thereby further enhancing the sterilization effect.

Such a discharge electrode is applied to the ion generating device, as shown in FIG.

The ion generating device is provided with a cation generator 5 and an anion generator 15 having a needle electrode on one side and the other side of the case 3, the discharge electrode 9 of the cation generator 5 And a spherical pulse generator 20 connected to an electric lead wire connected to the induction electrode 11 and a DC power generator 21 to an electric lead wire connected to the anion generator 15 and the ground electrode 17. .

The DC power generating unit 21 provides a predetermined DC power to the rectangular pulse generating unit 20, wherein the rectangular pulse generating unit 20 converts the DC power into a rectangular pulse and boosts the rectangular pulse to boost the voltage. A high voltage of one rectangular pulse is applied between the discharge electrode 9 and the induction electrode 11 through an electric lead wire.

When the spherical pulse high voltage is applied to the cation generator 5 and DC power is applied to the anion generator 15, hydrogen ions (H +) are generated in the cation generator 5, and the anion is generated. In the unit 15, electrons and superoxide anion (O2-) are generated.

Hydrogen ions generated in the cation generator 5 react with electrons generated in the anion generator 15 to form hydrogen atoms.

Hydrogen atoms and superoxide anions are formed to form hydroperoxy radicals (O-O-H), and the electrons of the superoxide anions cancel out the static electricity of bacteria. Hydroperoxy radicals also deplete hydrogen atoms from proteins that are components of bacterial cell membranes to make water.

Here, protein molecules of the cell membranes deprived of hydrogen atoms are destroyed, and bacterial cell membranes are also destroyed accordingly to sterilization.

According to the present invention including a discharge electrode having such a thickness, there is an advantage in that a large amount of cations can be induced, and thus a large amount of generated cations are combined with the anions generated in the anion generator to sterilize. As the amount of cations generated increases, the sterilization effect is greatly increased.

Claims (5)

A cation generator; In the ion generating device having an anion generating unit corresponding to the cation generating unit, The cation generator is characterized in that the discharge electrode having a thickness of 0.05 ~ 0.15mm is provided. The method of claim 1, The discharge electrode is a pattern frame constituting the body and forming an electrode line; An electrode unit provided at one side of the pattern frame to apply a voltage; It characterized in that it comprises at least one discharge needle protruding from the pattern frame, The thickness of the pattern frame is ion generating device, characterized in that consisting of 0.05 ~ 0.15mm. The method of claim 1, The cation generating unit and the ceramic coating provided on the upper surface of the discharge electrode; An induction electrode provided below the discharge electrode and causing corona discharge with the discharge electrode; It includes a ceramic plate provided below the induction electrode, The discharge electrode is ion generator characterized in that the discharge needle and the electrode line is provided. A cation generator and an anion generator for generating cations and anions, respectively, by plasma discharge; It is provided in the cation generator, the ion generating device comprising a discharge electrode consisting of a thickness of 0.05 ~ 0.15mm. The method of claim 4, wherein The discharge electrode may include a pattern frame forming one or more electrode lines; Including a discharge needle protruding from the pattern frame, The thickness of the pattern frame is ion generating device, characterized in that consisting of 0.05 ~ 0.15mm or less.

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