KR20220051945A - Air Purifying Device - Google Patents

Abstract

An air purification device of the present invention comprises: an air guide part having a semicircular cross-section or a polygonal shape with one side open and forming a spiral; a UV irradiating part forming a strip shape, and in which UV-C LEDs are arranged along the length, and the UV irradiating part is disposed along an open surface of the air guide part; and a tube body supporting the air guide part and the UV irradiating part.

Description

Air Purifying Device

The present invention relates to an air purifying device, and more particularly, to an air purifying device having a UV-C ultraviolet lamp and a photocatalyst to remove dust, microorganisms, viruses, and the like in the air.

Recently, as air pollution such as yellow dust and soot is getting worse, as well as the pandemic of viruses transmitted through droplets into the air like COVID-19, interest in air quality is growing more than ever.

Clean and purified air is required to be maintained not only in the interior of a house or apartment, but also in various enclosed spaces such as work spaces such as offices and factories, and boarding spaces in transportation means such as cars and trains.

The methods used to purify the air include a mechanical method using a HEPA filter or activated carbon, a wet method using water, a plasma method that removes harmful gases by generating positive/negative ions and radicals with plasma, and ultraviolet rays by irradiating a photocatalytic material with ultraviolet rays and a UV photocatalytic method by oxidation/reduction of OH radicals and active oxygen generated by a photocatalytic material.

In these air purification methods, purification is performed while the air passes through the inside of the air purifier, but the purification efficiency is often reduced because the passage of air is short or the processing capacity of the filter is insufficient.

In the case of an indoor sterilization system such as Republic of Korea Patent No. 10-1560084, a UV lamp about the length of the cylinder is installed in the center of the cylindrical body, and a spiral air guide part is installed along the circumference of the UV lamp inside the cylindrical body to allow air to proceed. The sterilization effect is increased by securing enough distance to do so.

Even in the case of the prior art, there is a limit in arbitrarily increasing the path due to the limitations of the length and output of the UV lamp, and also there is a problem in that UV rays are not uniformly irradiated to the air path due to the shape of the spiral air guide part.

KR 10-1560084 B1, 2015.10.13., Fig. 1

The present invention has been devised to solve the problems of the prior art as described above, can form an air path that is not limited to the length of the UV lamp, can uniformly irradiate UV rays, have a long service life, and purify the air Its purpose is to maximize efficiency.

The air purification mechanism of the present invention comprises:

an air guide part having a semicircular cross-section or a polygonal shape with one side open and forming a spiral;

UV-C LEDs in a strip shape are arranged along the length, and a UV irradiation unit disposed along the open surface of the air guide unit;

It is characterized in that it consists of a cylinder supporting the air guide part and the UV irradiation part.

When the cross-section of the air guide part is an open quadrangle, it is preferable that the angle between the bottom surface and the side extending from the bottom surface is in the range of 93 to 140 degrees.

The inner surface of the air guide part is preferably a glossy metal surface.

It is preferable that a photocatalytic coating is applied to the inner surface of the air guide part.

The photocatalytic coating is more preferably titanium dioxide coated in a nanowire shape.

The inner surface of the air guide part is preferably coated with an adsorbent and a photocatalyst.

It is preferable that the air guide unit further includes a vortex forming unit.

The cylindrical body preferably has a circular cross section.

It is also preferable that a temperature controller for adjusting the temperature of the air guide unit is further provided.

It is preferable that an ozone filter for removing ozone is attached to the outlet side of the air guide unit.

According to the present invention, the flow path required for air purification can be formed to a desired length, the intensity of ultraviolet rays in the flow path can be adjusted uniformly or arbitrarily, and a long service life and high air purification efficiency can be obtained.

1 is a view showing the shape of an air guide part according to an embodiment of the present invention.
Figure 2 is a view showing an embodiment of the present invention UV irradiation unit.
3 and 4 are views showing an assembled state according to an embodiment of the present invention.
5 is a cross-sectional view showing an air passage according to an embodiment of the present invention.
6 is a view showing another embodiment of the present invention.
7 is a cross-sectional view showing an air passage according to another embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings according to embodiments thereof.

The air purification mechanism of this embodiment disinfects air while spirally moving along the air guide unit 10 .

As shown in FIG. 1 , the air guide unit 10 has a rectangular shape with one side open.

The inner surface 13 of the air guide unit 10 is preferably made of a glossy surface to reflect light well. The air guide unit 10 may be manufactured by bending a metal plate.

The inner surface 13 of the air guide unit 10 is coated with a photocatalytic material such as titanium dioxide (TiO ₂ ). In addition, an adsorbent may be applied together to supplement the photocatalyst with a small reaction coefficient.

The photocatalytic coating is more preferably titanium dioxide coated in a nanowire shape.

A UV irradiation unit 20 as shown in FIG. 2 is attached to one open side of the air guide unit 10 .

The UV irradiation unit 20 is manufactured in a strip shape, and UV-C LEDs 22 are disposed along the length of the flexible substrate 21 .

In the present embodiment, the air guide unit 10 has an open surface sealed by the UV irradiation unit 20, and air moves through the passage between the air guide unit and the UV irradiation unit. Air can flow inside the air guide unit 10 by a separate fan (not shown) or the like. In addition to sterilization by UV-C ultraviolet rays, it is possible to decompose odor substances, viruses, bacteria, etc. by negative ions and OH radicals generated by irradiating UV-C to the photocatalyst. It is possible to decompose the organic material adhering to the inner surface 13 .

When the cross-section of the air guide unit 10 forms a square shape, the angle (a) between the bottom surface 11 and both side surfaces 12 extending from the bottom surface 11 is preferably in the range of 93 to 140 ° ( see Fig. 5). In the above angle range, the UV light generated by the UV irradiation unit 20 is best transmitted to the air guide unit 10 .

The air guide unit 10 may be formed in a semicircle shape instead of a square shape, or may be formed in various shapes of polygons.

The air guide unit 10 combined with the UV irradiation unit 20 is inserted into the cylinder 30 as shown in FIGS. 3 and 4 to maintain its shape. Such a cylinder may be provided separately to protect the shape of the air guide unit 10 , but may also be a housing of the air purifier. That is, when the air guide unit coupled to the UV irradiation unit is provided in the housing, the housing can be understood as a cylinder, and the shape of the cylinder does not have to be provided with a shape consistent with the outer surface of the air guide unit.

In addition, although the outer surface of the air guide unit is shown to form a circular column, it may form a column shape of various types such as a square column, a triangular column, and the like.

It is desirable to prevent the air from flowing in a laminar flow in order to increase the probability that particles or bacteria flowing in the air guide unit 10 will contact not only the wall inside the air guide unit but also negative ions or OH radicals in the air. Accordingly, as shown in FIGS. 5 and 7 , it is preferable to further include a vortex forming unit 40 such as a propeller inside the air guide unit.

It is possible to use various well-known shapes that can change the laminar flow air into a vortex shape, such as a protrusion shape protruding from the wall surface or a blade crossing the cross section of the passage, for the vortex forming part.

It is also preferable to further provide an ozone removal filter (not shown) capable of removing ozone generated by UV-C on the outlet side of the air guide unit.

In addition, since a photocatalyst usually reacts with light, it is not necessary to increase the temperature to increase the activity, but since it shows an optimal reaction in the range of 20 to 80 ° C, a temperature controller capable of adjusting the temperature inside the cylinder or the air guide part It would also be desirable to be The air guide part may be heated or cooled as the temperature rises or falls in the temperature controller and the air is supplied to the inside of the cylinder. If precise temperature control is required, it would be natural to attach a temperature sensor to the required location and adjust the temperature accordingly.

In the next embodiment, the open surface of the air guide unit 10 is closed with the inner wall of the cylinder 30 , and the UV irradiation unit 20 is attached along the position of the air guide unit 10 to the outer wall of the cylinder 30 , there is.

In this case, the contaminants in the passage through which the air flows are not attached to the UV irradiation unit 20, so that the service life of the UV irradiation unit 20 can be extended.

The cylindrical body in this embodiment is preferably formed of a transparent body so that UV light can pass well.

In a state in which the UV irradiation part is attached, it is preferable that a blocking layer is formed on the outside of the cylinder to block UV light that is scattered through the transparent body and radiated to the outside. The barrier layer may be formed by applying a paint or a synthetic resin tape.

Of course, in this embodiment as well, components added to the previous embodiment, such as a vortex forming unit in the air passage and a temperature controller, may be included.

10: air guide part 11: bottom 12: side 13: inner surface
20: UV irradiation unit 21: flexible substrate 22: UV-C LED
30: cylinder 40: vortex forming part

Claims (10)

an air guide part having a semicircular cross-section or a polygonal shape with one side open and forming a spiral;
A strip-shaped UV-C LED is arranged along the length, and a UV irradiation unit disposed along the open surface of the air guide unit;
An air purification mechanism comprising a cylindrical body supporting the air guide part and the UV irradiation part.
The method of claim 1,
When the cross-section of the air guide part is an open square, the angle formed by the bottom surface and the side extending from the bottom surface is in the range of 93 to 140 degrees.
The method of claim 1,
An inner surface of the air guide part is an air purification mechanism, characterized in that the glossy metal surface.
The method of claim 1,
The air purification mechanism, characterized in that the photocatalytic coating is applied to the inner surface of the air guide part.
5. The method of claim 4,
The photocatalytic coating is an air purification device, characterized in that titanium dioxide is coated in a nanowire shape.
The method of claim 1,
The air purification mechanism, characterized in that the photocatalyst and the adsorbent is added to the inner surface of the air guide part.
The method of claim 1,
The air purifying mechanism, characterized in that the air guide portion further comprises a vortex forming portion.
The method of claim 1,
Air purification mechanism, characterized in that the temperature controller for adjusting the temperature of the air guide part is further provided.
The method of claim 1,
An ozone filter for removing ozone is attached to the outlet side of the air guide unit.
The method of claim 1,
The cylinder is an air purification mechanism, characterized in that provided with a circular cross section.

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