KR100591343B1 - Sterilization module device - Google Patents

Abstract

A sterilizing module device according to the present invention includes a plate-shaped insulating dielectric; A discharge electrode formed of a pattern portion having a predetermined area on an upper surface of the insulating dielectric, the discharge electrode having at least one non-pattern portion formed without an electrode inside the portion where the pattern portion is formed; And a ground electrode having a needle-like structure disposed in a direction orthogonal to the insulating dielectric at a distance away from a bottom surface of the insulating dielectric, and purged as air passes through the space between the insulating dielectric and the ground electrode. By being configured so as to reduce the amount of ozone harmful to the human body and increase the amount of negative ions beneficial to the human body can improve the air cleaning efficiency.

Insulating Dielectric, Discharge Electrode, Ground Electrode, Pattern, Plasma, Ozone, Anion, Needle Shape

Description

Sterilization module device

1 is a plan view showing a conventional surface discharge type sterilization module device,

2 is a cross-sectional view taken along the line A-A of FIG. 1;

3 is a reference diagram showing a plasma discharge state of a conventional surface discharge type sterilization module device,

4 is a perspective view showing a sterilization module device according to the present invention;

5 is a cross-sectional configuration view showing a sterilization module device according to the present invention,

6 is a longitudinal sectional view showing the indoor unit of the air conditioner to which the sterilization module device according to the present invention is applied.

<Explanation of symbols for the main parts of the drawings>

50: sterilization module device 52: insulating dielectric

60: discharge electrode 61: pattern portion

63: tip portion 65: non-pattern portion

68 terminal terminal 70 ground electrode

73: needle tip 80: protective film

85: connection support

The present invention relates to a sterilization module device used for air purification, and more particularly, to a sterilization module device which can perform an air cleaning function which is more beneficial to the human body by reducing the amount of ozone generated and increasing the amount of negative ions generated.

In general, the surface discharge type sterilization module device uses a plasma chemistry treatment method of surface discharge, and is a high frequency discharge type using ceramic to form a strong plasma region on the surface of the device to generate a large amount of OH radicals and ozone and use the harmful gas Is the way to handle

1 is a plan view showing a conventional surface discharge type sterilization module device, Figure 2 is a cross-sectional view taken along the line A-A of FIG.

As shown in the drawing, in the conventional surface discharge type sterilization module device, a discharge electrode 12 is formed on an upper surface of an insulating dielectric 10 attached to two sheets in a substantially square plate shape, and between the two insulating dielectrics 10. The ground electrode 14 is formed. In addition, a coating layer 16 is formed on the top surface of the dielectric 10 to seal the discharge electrode 12 so that it is not directly exposed to the air.

The insulating dielectric 10 is generally made of a ceramic material, the discharge electrode 12 and the ground electrode 14 is configured so that one pole and the other pole of the power supply are connected to each other to receive power. AC power is used.

In particular, the discharge electrode 12 is composed of three main electrodes 12a arranged side by side and sub electrodes 12b protruding from the main electrodes 12a in an advanced structure, and the ground electrode 14 is The branch electrodes 14a are arranged side by side at positions opposite to the sub-electrodes 12b.

In the conventional surface discharge type sterilization module device configured as described above, when a power source having a starting voltage or more is applied to the discharge electrode 12 and the ground electrode 14, insulation breakdown occurs between the discharge electrode 12 and the ground electrode 14. Accordingly, a discharge phenomenon occurs on the surface of the insulating dielectric 10 to form a strong plasma region.

In the plasma discharge, a conductive path called a streamer is formed on the surface of the insulating dielectric 10, and a large amount of high energy electrons are generated through the streamer. The high energy electrons react with the surrounding gas by the electron collision to generate a large amount of ozone and a large amount of OH radicals and anions.

The ozone and OH radicals and anions generated as described above are oxidized and decomposed to purify pollutants such as harmful gases contained in the air.

However, in the conventional surface discharge type sterilization module device as described above, since the discharge electrode 12 is formed with an embossed structure on the upper surface of the insulating dielectric 10 to reduce the starting voltage and input energy for causing discharge. There is a limit, and accordingly, while OH radicals and anions generated a lot at low voltage are generated less, ozone harmful to the human body is generated a lot, and power consumption is also increased.

That is, the conventional creeping discharge type sterilization module device has a high charge concentration at the end E of the discharge electrode 12, as shown in FIG. 3, so that the streamer generation distribution is uniform in all regions of the dielectric. The voltage and input energy must be increased, and at this time, the thermal stress is locally increased at the end E of the discharge electrode 12, thereby heating the surrounding gas, thereby increasing the ozone generation amount, while reducing the OH radicals and anions. . In addition, the deterioration of the portion of the electrode proceeds quickly due to the local thermal stress increases the life of the device is shortened, there is a problem that the air purification performance is lowered due to a bad effect on the discharge safety.

In addition, the conventional surface discharge type sterilization module device has two insulating dielectrics 10, and the ground electrode 14 is formed therebetween, so that the overall structure is complicated and manufacturing costs are high.

The present invention has been made to solve the above problems, the discharge electrode is formed on the upper surface of the insulating dielectric, the ground electrode is configured at a distance away from the bottom of the insulating dielectric to reduce the amount of ozone generated and the amount of OH radicals and negative ions generated It is an object of the present invention to provide a sterilization module device that can increase the efficiency of air cleaning.

A sterilization module device according to the present invention for realizing the above object includes a plate-shaped insulating dielectric; A discharge electrode formed on an upper surface of the insulating dielectric; And a ground electrode disposed at a predetermined distance away from the bottom surface of the insulating dielectric.

The sterilization module device is configured to allow air to pass through the space between the insulating dielectric and the ground electrode.

 The discharge electrode may include a pattern portion having a predetermined area on an upper surface of the insulating dielectric, and at least one non-pattern portion having no electrode formed therein is formed in a portion where the pattern portion is formed.

The discharge electrode is configured to have a tip portion protruding from the pattern portion to an area of the non-pattern portion.

The tip portion is formed in a triangular shape.

The ground electrode has a needle-like structure disposed in a direction orthogonal to the insulating dielectric.

A connection support is provided between the insulating dielectric and the ground electrode to fix the position of the ground electrode.

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

4 is a perspective view showing a sterilization module device according to the present invention, Figure 5 is a cross-sectional view showing a sterilization module device according to the present invention.

As shown in the sterilization module device according to the present invention, as shown in Figure 4 and 5, the discharge electrode 60 is formed on the upper surface of the insulating dielectric 52, the discharge electrode 60 is the insulating It is protected by a protective film 80 coated on the surface of the dielectric 52. In addition, the ground electrode 70 is disposed at a distance away from the bottom surface of the insulating dielectric 52.

The sterilization module device of the present invention as described above is made so that air can be purified while passing between the insulating dielectric 52 and the ground electrode 70 as shown in FIG.

The insulating dielectric 52 is formed in a substantially rectangular flat plate structure having a predetermined thickness, and is formed of one plate body unlike the above-described conventional technology. The insulating dielectric 52 is preferably formed of a resin material having good oxidation resistance in an organic material or a material such as ceramic in an inorganic material. Here, the insulating dielectric 52 may be formed of a resin material or a ceramic, or may be formed of various materials and shapes according to design conditions without being limited to a square shape.

The discharge electrode 60 is formed of a pattern in which a conductive material of a metal material is printed on an upper surface of the insulating dielectric 52. The pattern shape is formed in a substantially rectangular sealed structure having a predetermined area.

Here, the discharge electrode 60 is formed in a pattern of an intaglio structure in which the input energy may be relatively low, unlike the discharge electrode of the prior art is formed in a pattern of both structures as shown in FIG. 1.

That is, the discharge electrode 60 is formed with a non-pattern portion 65 in which no electrode is formed inside the patterned portion (hereinafter referred to as a 'pattern portion') 61. The non-pattern portion 65 is formed in one long shape in the longitudinal direction of the pattern of the discharge electrode 60 and is formed in a sealed structure surrounded by the pattern portion 61.

In particular, the tip portion 63 protruding from the pattern portion 61 is formed in the non-pattern portion 65.

When the non-pattern portion 65 is formed to have a long shape as shown in FIG. 4, the tip portion 63 is symmetrically formed on both long sides of the non-pattern portion 65 at regular intervals. do. Of course, the tip portion 63 may be formed on the short side of the non-pattern portion 65.

Here, the tip portion 63 is illustrated to protrude in a triangular shape, it can be configured to form a variety, such as square or round depending on the implementation conditions.

The protective layer 80 is preferably made of a non-conductive material and a material that will not easily deteriorate and be damaged during plasma creepage discharge. The passivation layer 80 is formed on the upper surface of the insulating dielectric 52 in a square shape formed larger than the discharge electrode 60.

The passivation layer 80 has a structure in which a portion thereof is opened so that the discharge electrode 60 has a terminal terminal portion 68 connected to an external circuit.

The ground electrode 70 is formed of a needle shape, and is made of a conductive material made of a metal like the discharge electrode 60, and is disposed in a direction orthogonal to the insulating dielectric 52.

The ground electrode 70 is preferably disposed such that the needle tip 73 faces the center of the non-pattern portion 65 of the discharge electrode.

A connection support 85 may be provided between the insulating dielectric 52 and the ground electrode 70 to maintain a constant gap between the discharge electrode 60 and the ground electrode 70 as shown in FIG. 5. . The connection support 85 may include a base portion 86 to which the ground electrode 70 is fixed, and a connection portion 87 connecting the base portion 91 to the insulating dielectric 52.

Such a connection support 85 is omitted according to the structure for constructing the sterilization module device of the present invention as a set or the installation structure of the sterilization module device, and the insulating dielectric 52 and the ground electrode 70 have a constant gap. It is also possible to fix and install separately under conditions to have.

Referring to the operation of the sterilization module device according to the present invention configured as described above are as follows.

The sterilization module device of the present invention uses a common corona discharge or a discharge phenomenon not found in conventional DBD (Dielectric Barrier Discharge). In the related art, in order to generate a large amount of OH radicals and negative ions, the amount of ozone is also increased simultaneously. However, the sterilization module device of the present invention increases the amount of OH radicals and anions to the maximum while limiting the amount of ozone.

That is, when a high voltage is applied to the discharge electrode 60 and the ground electrode 70, an electric field is generated by the potential difference between the discharge electrode 60 and the ground electrode 70. In general, since the dielectric constant of the insulating dielectric 52 is larger than that of air, plasma discharge starts when the potential difference between the two electrodes 60 and 70 is greater than the dielectric strength of the insulating dielectric 52.

At this time, in the discharge electrode 60 provided on the upper surface of the insulating dielectric 52, a large amount of ozone and OH radicals are mainly generated by plasma discharge. On the other hand, in the ground electrode 70 having a needle-like structure, electrons having a negative electric charge from the needle tip 73 by the high energy process have energy enough to cause ionization. It is released at high speed and collides with molecules in the air to help form anions.

In addition, a uniform discharge may be obtained by maximizing a voltage efficiency applied by an AC power source by using a charge build-up phenomenon of the insulating dielectric 52. Such a sterilization module device of the present invention is capable of generating 100 to 1000 times more concentration of reactive active species (radical) than conventional vacuum plasma.

Therefore, although the sterilization ability of the sterilization module using the plasma discharge is mainly made by ozone, ozone is harmful to the human body, and thus the present invention is a space between the insulating dielectric 52 and the ground electrode 70 having a large amount of negative ions. By allowing the air to pass through, the optimization of the air cleaning function can be realized.

6 is a longitudinal sectional view showing the indoor unit of the air conditioner to which the sterilization module device according to the present invention is applied.

In general, the indoor unit 91 of the air conditioner is provided with a suction port 92 and a discharge port 93 so that indoor air is circulated, and a blower 94 is provided inside to force circulation of the air, and the heat passing through the air can be exchanged. Heat exchanger 95 is provided.

The sterilization module device 50 according to the present invention installed in the indoor unit 91 is installed inside the suction port 92 as shown in FIG. 7, but the upper portion of the insulating dielectric 52 having a relatively high amount of ozone generation is provided. Preferably, the air is disposed between the insulating dielectric 52 and the ground electrode 70 having a large amount of negative ions generated without passing through the air.

In addition, in the present embodiment has been illustrated that one sterilization module device 50 is installed, it is also possible to install a plurality of if necessary.

When the sterilization module device 50 according to the present invention is installed in the indoor unit 91 as described above will be described as follows.

As the air conditioner is operated, when the blower 94 is operated, indoor air is introduced into the indoor unit 91 through the inlet port 92, cooled while passing through the heat exchanger 95, and then through the discharge port 93. It is discharged indoors. At this time, when power is applied to the sterilization module device 50 for indoor air purification, some of the air introduced into the indoor unit 91 through the suction port 92 passes through the periphery of the sterilization module device 50. Pollutants are sterilized or decomposed and purified.

That is, when a power source having a starting voltage or more is applied to the discharge electrode 60 and the ground electrode 70 together with the air conditioner operation, a plasma discharge region is formed near the tip 63 of the surface of the discharge electrode 60 and the ground electrode is formed. (70) While a large amount of high energy electrons are generated in the vicinity, a small amount of ozone and a large amount of anions are generated by reaction with the surrounding gas by electron collision.

Therefore, a large amount generated in the space between the insulating dielectric 52 and the ground electrode 70 in which the discharge electrode 60 is formed is purified by oxidizing and decomposing pollutants such as harmful gases in which anions are contained in the indoor air. will be.

In the above, the sterilization module device of the present invention has been described by way of example applied to an indoor unit of an air conditioner. However, the present invention is not limited thereto.

The sterilization module device according to the present invention constructed and operated as described above has a discharge electrode formed on the upper surface of the insulating dielectric, and the ground electrode is formed at a distance away from the bottom of the insulating dielectric to purify the air passing therebetween. Since it is configured to be able to reduce the amount of ozone harmful to the human body and increase the amount of negative ions beneficial to the human body has the advantage of improving the air clean efficiency.

Claims (8)

A plate-shaped insulating dielectric; A discharge electrode formed on an upper surface of the insulating dielectric; A sterilization module device comprising a ground electrode disposed at a distance away from the bottom surface of the insulating dielectric. The method of claim 1, The sterilization module device is characterized in that the air is passed through the space between the insulating dielectric and the ground electrode device. The method of claim 1,  The discharge electrode is a sterilization module device comprising a pattern portion having a predetermined area on the upper surface of the insulating dielectric, at least one non-pattern portion having no electrode formed inside the portion where the pattern portion is formed. The method of claim 3, wherein And the discharge electrode has a tip portion protruding from the pattern portion to an area of the non-pattern portion. The method of claim 4, wherein Sterilization module device characterized in that the tip portion is formed in a triangular shape. The method according to any one of claims 1 to 5, The ground electrode is a sterilizing module device, characterized in that made of a needle-like structure disposed in a direction orthogonal to the insulating dielectric. The method of claim 6, A sterilization module device between the insulating dielectric and the ground electrode is provided with a connecting support for fixing the position of the ground electrode. A plate-shaped insulating dielectric; A discharge electrode formed of a pattern portion having a predetermined area on an upper surface of the insulating dielectric, the discharge electrode having at least one non-pattern portion formed without an electrode inside the portion where the pattern portion is formed; It comprises a ground electrode made of a needle-like structure disposed in a direction orthogonal to the insulating dielectric at a distance away from the bottom surface of the insulating dielectric, A sterilization module device, characterized in that configured to be purified as the air passes through the space between the insulating dielectric and the ground electrode.

Images