KR102163950B1 - Air Deodorizing Sterilizer with Zigzag Flow Channel Improved Contact Efficiency of Photo Catalysis - Google Patents

Abstract

The present invention relates to an air deodorizing sterilizer using a zigzag flow channel, having improved photocatalytic contact efficiency. The air deodorizing sterilizer comprises: a main body (10) which is an enclosed housing with an air inflow part (11) formed on a lower portion thereof and an air discharge part (12) formed on an upper portion thereof; an air blowing part (20) provided in the main body (10) and configured to suck in air to enable the air to be introduced into the air inflow part (11) and discharge the sucked air into the air discharge part (12); a filter part (30) provided in the air inflow part (11) of the main body (10) and configured to purify air sucked in by the air blowing part (20) and introduced into the air inflow part (11); and a sterilization part (40) provided on an upper portion of the filter part (30), configured to sterilize the air purified by the filter part (30) by emitting ultraviolet rays to the air, and configured to enable the sterilized air to flow into the air blowing part (20).

Description

Air Deodorizing Sterilizer with Zigzag Flow Channel Improved Contact Efficiency of Photo Catalysis}

The present invention relates to an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path that removes and purifies fine dust from air containing fine dust, etc., and sterilizes various bacteria contained in the air to supply pleasant air. will be.

In general, an air purifier is a device that supplies purified air by inhaling air and filtering and discharging fine dust contained in the inhaled air.

These air purifiers are effective in filtering dust and the like, but are insufficient to remove various bacteria contained in the air.

In order to sterilize and remove various kinds of bacteria, an air purifying sterilizer has been introduced in which a filter is coated with a photocatalyst and the coated photocatalyst is irradiated with ultraviolet rays to sterilize the bacteria contained in the air by the photocatalyst irradiated with ultraviolet rays.

At this time, there are various types of air purification sterilizers to increase the irradiation of ultraviolet rays to increase the bacteria sterilization effect of the photocatalyst, and air purification sterilizers to increase the bacteria sterilization removal efficiency by increasing the contact time with the filter coated with the photocatalyst. Air purifying sterilizers are being developed.

As an air purifying sterilizer for increasing the irradiation amount of ultraviolet rays to increase the bacteria sterilization effect of the photocatalyst, Korean Patent Laid-Open Publication No. 10-2018-0055984 (name of the invention: an air purifying sterilizer having an ultraviolet reflecting plate) has been disclosed. Shown.

The air purifying sterilizer includes: a housing 110 having an inlet 111 formed on one side and an outlet 112 formed on the other side; A suction fan 120 provided at one side of the inlet 111 to suck air through the inlet 111 and discharge the sucked air to the outlet 112; A photocatalyst coated nanotube filter 130 to sterilize and purify the air sucked from the suction fan 120; An ultraviolet lamp 140 formed in the center of the housing 110 in the longitudinal direction to irradiate ultraviolet rays in all directions to sterilize and purify the air sucked from the suction fan 120; And a reflective plate 150 formed on the entire inner surface of the housing to reflect the ultraviolet rays irradiated from the ultraviolet lamp 140 multiple times.

The air purifying sterilizer is to increase the amount of ultraviolet irradiation by reflecting the ultraviolet rays irradiated from the ultraviolet lamp 140 multiple times using the reflector 150 to increase the bacterial sterilization effect of the photocatalyst. In addition, a plurality of nanotube filters 130 are radially installed to increase the bacteria sterilization efficiency.

However, when air is blown by the suction fan 120, there is a problem in that the time for contacting the nanotube filter 130 coated with the photocatalyst is shortened, thereby deteriorating the bactericidal effect.

As an air purifying sterilizer to increase the efficiency of sterilizing bacteria by increasing the contact time with the filter coated with a photocatalyst, Korean Patent No. 10-1773371 (name of the invention: air sterilization and fine dust removal functions) Air purification device) has been disclosed, and is shown in FIG. 2.

The air purifying apparatus includes: a square cylinder or cylindrical air purifier body 100; An air suction filter 101 mounted at one end of the main body; A UV ultraviolet ray discharge tube 102 that emits ultraviolet rays to sterilize the air passing through the air intake filter, and a ring-shaped disk coated with titanium dioxide as a photocatalyst on the surface are stacked at regular intervals up and down to surround the UV ultraviolet ray discharge tube. Primary sterilization consisting of the formed photocatalyst 103, the UV ultraviolet discharge tube and the cathode mesh electrode 104 connected to the cathode so that the fine dust and bacteria in the air that have passed through the air intake filter are charged with a negative charge. A purification unit; A UV ultraviolet ray discharge tube 102 that emits ultraviolet rays to sterilize the air that has passed through the primary sterilization and purification unit, and a ring-shaped disk coated with titanium dioxide as a photocatalyst on the surface is stacked at regular intervals up and down to surround the UV ultraviolet ray discharge tube A photocatalyst part 103 formed of a photocatalyst part 103, an anode mesh electrode connected to the anode so as to be charged with a positive charge in order to collect negatively charged fine dust and bacteria in the air passing through the first sterilization and purification part while surrounding the UV ultraviolet ray discharge tube and the photocatalyst part A secondary sterilization and purification unit consisting of 104; A negative charge charging unit 108 comprising a negative mesh electrode connected to a negative electrode so that fine dust and bacteria that have lost negative charges passing through the secondary sterilization and purification unit are recharged with negative charges; An electric dust collecting unit 109 comprising an anode mesh electrode connected to an anode so as to be charged with a positive charge in order to electrostatically collect negatively charged fine dust and bacteria in the air passing through the negatively charged charging unit; And an air discharge fan 110 for discharging the sterilized and purified air that has passed through the electric dust collecting unit.

The air purifying apparatus is designed to increase the efficiency of sterilizing bacteria by extending the contact time with the filter coated with the photocatalyst by making the photocatalyst part spaced apart from each other to be installed double. However, since the contact between the photocatalyst part 103 and air is made in surface contact, the efficiency may be high when the air discharge speed by the air discharge fan 110 is low, but the air discharge speed by the air discharge fan 110 When is high, there is a problem in that the efficiency is also low.

The present invention has been devised to solve the above problems, and an object of the present invention is to increase the sterilization efficiency by allowing the photocatalyst to pass through the coated photocatalyst filter and increasing the contact time with the photocatalyst filter. It is to provide an air deodorizing sterilizer with improved photocatalytic contact efficiency.

The air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path of the present invention for achieving the above object is a case, and an air inlet 11 is provided at the lower part, and an air discharge part 12 is provided at the upper part. Main body 10; A blower 20 provided inside the main body 10 to suck air into the air inlet 11 and to discharge the sucked air to the air outlet 12; A filter unit 30 provided in the air inlet 11 of the main body 10 and for purifying the air that is sucked in by the blower 20 and introduced into the air inlet 11; A sterilization unit 40 provided above the filter unit 30 to sterilize the air purified by the filter unit 30 by irradiating ultraviolet rays and flow the sterilized air to the blowing unit 20; The sterilization unit 40 includes a sterilization unit 41 having a plurality of vertical pipes 41a formed of one to four vertical pipes 41a formed of one to four vertically formed by being hollow inside, and Each of the vertical pipes (41a) has a fixed portion 42 formed vertically at the center of the left and right, and fixed to the fixed portion 42 and installed vertically along the vertical pipe (41a) so that the vertical pipe The furnace 41a is partitioned back and forth, and the metal mesh 43 is coated with a photocatalyst such as titanium dioxide (TiO ₂ ) and has a flat plate shape, and consists of a pair of both front and rear sides partitioned around the metal mesh 43. Each of the vertical pipes (41a) is installed to form a zigzag flow path in the vertical pipe (41a), so that the first purified air passes through the metal mesh 43 when passing through the zigzag flow path. A plate 44 for forming a zigzag channel to sterilize bacteria contained in the first purified air, and a light irradiation unit provided inside the plate 44 for forming the zigzag channel and irradiating ultraviolet rays to the metal mesh 43 It characterized in that it consists of (45).

In addition, a control unit for adjusting the ultraviolet irradiation intensity of the light irradiation unit 45 is further provided, and the control unit adjusts the ultraviolet irradiation intensity of the light irradiation unit 45 according to the amount of air blown by the air blower 20. do.

In addition, the zigzag passage forming plate 44 and the vertical pipe 41 are made of a metal material, or the zigzag passage forming plate 44 and the inner side of the vertical pipe 41 are coated with a reflective material. It features.

In addition, the zigzag passage forming plate 44 connects at least two flat portions 44a in contact with the inner side surfaces of the vertical pipes 41a and the flat portions 44a to each other, and has a V shape inwardly. It is characterized in that the bent end is formed of an inclined portion 44b in contact with the metal mesh 43 to form a zigzag flow path.

The air deodorizing sterilizer with improved photocatalytic contact efficiency using the zigzag flow path of the present invention having the above configuration is contained in the air by allowing the photocatalyst coated metal mesh to pass through, unlike the conventional air purifying sterilizer in surface contact with the photocatalytic filter. It has the effect of supplying pleasant air by sterilizing various bacteria. In addition, by allowing the metal mesh coated with the photocatalyst to pass through the zigzag flow path, the sterilization efficiency can be improved by prolonging the contact time with the metal mesh coated with the photocatalyst. Since the entire metal mesh is involved in sterilization, the filter There is an advantage that can increase the efficiency of. In addition, there is an advantage of maintaining an appropriate sterilization power by allowing the intensity of ultraviolet irradiation of the light irradiation unit to be adjusted according to the amount of air blown.

1 and 2 are views showing a conventional air purification sterilizer.
3 is a view showing the internal structure of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.
4 is a view showing the overall appearance of a sterilizing unit of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.
5 is a view showing the air flow of the sterilization unit of the air deodorization sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.
6 is a longitudinal sectional view showing the internal structure of a sterilizing unit of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.
7 and 10 are exploded views of a sterilizing unit of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.
8 and 11 are views showing the coupling structure of the sterilizing unit of the air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.
9 and 12 are cross-sectional views of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.

Hereinafter, an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path of the present invention will be described in detail with reference to the drawings.

3 is a view showing the internal structure of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention, and FIG. 4 is a view showing the overall appearance of a sterilizing unit of an air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention. 5 is a view showing the air flow of the sterilization unit of the air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag passage according to the present invention, and FIG. 6 is a photocatalyst air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag passage according to the present invention 7 and 10 are exploded views of the sterilization unit of the air deodorization sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention, and FIGS. 8 and 11 are zigzag flow paths according to the present invention. Fig. 9 and 12 are cross-sectional views of the air deodorization sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention.

The air deodorization sterilizer with improved photocatalytic contact efficiency using a zigzag flow path according to the present invention includes a main body 10; A blower 20; A filter unit 30; It includes; sterilization unit 40.

The main body 10 is an enclosure, and an air inlet 11 is provided in the lower part, and an air discharge part 12 is provided in the upper part.

The blower 20 is provided inside the main body 10 and sucks air into the air inlet 11 to be introduced, and serves to discharge the sucked air to the air outlet 12. do.

The filter unit 30 is provided in the air inlet 11 of the main body 10 and serves to purify the air that is sucked in by the blowing unit 20 and introduced into the air inlet 11 .

The sterilization unit 40 is provided on the upper portion of the filter unit 30, and irradiates ultraviolet rays to the air purified by the filter unit 30 to sterilize the sterilized air to the blowing unit 20. It plays a role to flow. The sterilization unit 40 is made of a unit module, and a plurality of unit modules are coupled to each other by a coupling unit 50 to be described later so that the capacity can be changed according to the capacity of the air purification sterilizer, so that the capacity can be changed. The sterilized air is discharged to the air outlet 12 by the blower 20.

The filter unit 30 includes a pre-filter for firstly purifying the air introduced into the air inlet 11, and a HEPA filter for secondary filtering fine dust contained in the air that has been firstly purified by the pre-filter. It is preferably made of.

The pre-filter serves to remove relatively large dust particles in the air.

A carbon filter is provided between the pre-filter and the HEPA filter, so that odor particles in the air may be removed in advance.

The HEPA (High Efficiency Particulate Arrestor) filter filters out fine dust or bacterial particles of less than 0.3 micrometers in the air.

The coupling part 50 is provided outside each of the sterilizing parts 40, and each sterilizing part 40 is installed in any one selected from series, parallel, and series, thereby expanding the sterilization capacity. The sterilization units 40 adjacent to each other serve to maintain a coupled state. The coupling part 50 is formed to protrude in a "T" shape, and the protrusion 51 formed to be elongated in the longitudinal direction of the sterilizing part main body 41, and the protrusion coupling part to allow the protrusion 51 to be inserted and coupled. The sterilization unit 40 adjacent to each other is coupled to each other by being made of 52. The shape of the protrusion 51 of the coupling part 50 of the present invention has been described as a "T" shape, but any shape in which the protrusion 51 is inserted into the protrusion coupling part 52 can be modified.

8 and 9 and 11 and 12 are views showing a state in which a plurality of sterilization units 40 are coupled by the coupling unit 50.

Each sterilization unit 40 of the present invention includes a sterilization unit main body 41, a fixing unit 42, a metal mesh 43, a zigzag flow path forming plate 44, and a light irradiation unit 45. Done.

The sterilization unit body 41 is provided with a vertical pipe (41a) consisting of one to four hollow inside the vertically formed vertically.

8 and 9 show that the unit module sterilization unit 40 is formed of one vertical pipe 41a, and Figs. 11 and 12 show that the unit module sterilization unit 40 includes two vertical pipes. It shows that it is made into the furnace 41a.

The fixing part 42 is formed vertically in the left and right centers of each of the vertical pipes 41a. The left and right ends of the metal mesh 43 are fixed to the fixing part 42.

The metal mesh 43 is fixed to the fixing part 42 and installed vertically along the vertical pipe 41a to divide the vertical pipe 41a back and forth, and titanium dioxide (TiO ₂ ) and It is coated with the same photocatalyst and becomes a flat plate. The metal mesh 43 sterilizes and removes bacteria by the coated photocatalyst, and also removes odor particles.

The zigzag flow path forming plate 44 is formed in a pair and is installed in the vertical pipes 41a on both front and rear sides divided around the metal mesh 43 to be zigzag in the vertical pipes 41a. It is installed to form a flow path (see Figs. 5, 6, 7 and 10). At this time, the plate 44 for forming a zigzag flow path allows the first purified air to pass through the metal mesh 43 when passing through the zigzag flow path to sterilize bacteria contained in the first purified air.

7 and 10 are views showing a state in which the plate 44 for forming a zigzag passage is separated from the vertical pipe 41a.

The light irradiation part 45 is provided inside the plate 44 for forming the zigzag flow path and serves to irradiate the metal mesh 43 with ultraviolet rays. The light irradiation unit 45 is a plate-shaped LED module, and when it is installed in the sterilization unit body 41, the LED is exposed from the outside of the sterilization unit body 41 in the vertical pipe (41a). It is installed by fastening to the sterilization unit body 41 so that it can be (see Fig. 4). When the metal mesh 43 is irradiated with ultraviolet rays, electron-holes are generated on the metal surface by titanium dioxide, which is a photocatalyst coated on the surface, and they generate OH radicals by a reaction that combines oxygen and water molecules. This OH radical is an oxygen-anion-based substance that has an oxidizing power (sterilizing power) 180 times that of ozone. After sterilizing and neutralizing bacteria and organic compounds, it is converted into H₂O and CO₂, which are harmless to the human body. By this action, bacteria are sterilized. The light irradiation unit 45 uses an LED that irradiates ultraviolet rays, and uses UV-A and UV-C.

In addition, the zigzag passage forming plate 44 and the vertical pipe 41a are made of a metal material, or the zigzag passage forming plate 44 and the inner side of the vertical pipe 41a are coated with a reflective material. It is desirable. The zigzag passage forming plate 44 and the vertical pipe 41a are made of a metal material so that the light irradiated by the light irradiation unit 45 is reflected so that the irradiated light is transmitted to the metal mesh 43. Efficiency can be increased, and light is evenly transmitted to the metal mesh 43, thereby increasing sterilization efficiency by a photocatalyst.

In addition, it is preferable that each of the sterilization units 40 is replaceable.

In this way, when a plurality of the sterilizing units 40 made of modules are adjacent to each other and installed in series, parallel, or series in parallel, the sterilization capacity can be increased.

The zigzag flow path forming plate 44 and the inner surface of the vertical pipe 41a may be coated with a reflective material.

In addition, the present invention is further provided with a control unit for adjusting the ultraviolet irradiation intensity of the light irradiation unit 45, the control unit adjusts the ultraviolet irradiation intensity of the light irradiation unit 45 according to the amount of air blown by the blower 20 It is desirable to do.

When the blowing amount of the blowing unit 20 increases, the control unit increases the ultraviolet irradiation intensity of the light irradiation unit 45, and when the blowing amount of the blowing unit 20 decreases, the control unit turns on the ultraviolet rays of the light irradiation unit 45. By reducing the irradiation intensity, the ultraviolet irradiation intensity for maintaining an appropriate sterilizing power according to the amount of air blown by the air blower 20 is adjusted.

In addition, it is preferable that each of the sterilization units 40 is replaceable.

In this way, when a plurality of the sterilizing units 40 made of modules are adjacent to each other and installed in series, parallel, or series in parallel, the sterilization capacity can be increased.

The zigzag flow path forming plate 44 and the inner surface of the vertical pipe 41 may be coated with a reflective material.

In addition, the zigzag channel forming plate 44 connects at least two or more flat portions 44a in contact with the inner surface of the vertical pipe 41a and the flat portion 44a to each other, and has a V shape inwardly. It is preferable that the bent and bent end is formed of an inclined portion 44b in contact with the metal mesh 43 to form a zigzag flow path.

In addition, the air discharge part 12 of the main body 10 is radially provided in the main body 10, and the air blown by the blowing part 20 is supplied to the rear end of the blowing part 20. It is preferable that the bottom surface for guiding to the discharge part 12 is the same as the cross-sectional shape of the main body 10, and an air collision part 50 protruding downward is provided.

In addition, in the present invention, it is preferable that a sound source output unit (not shown) is provided inside the air discharge unit 12 to notify the operating state of the air deodorizing sterilizer with improved photocatalytic contact efficiency using a zigzag flow path.

The audio output unit may output an operating state such as a sterilization state, a blowing state, and a filter state as audio. In addition, the sound output unit may output a sound source and the like to cancel the noise of the air blown when the blowing unit 20 is operated.

The technical idea should not be interpreted as limited to the above-described embodiments of the present invention. As well as a variety of application ranges, various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, these improvements and changes will fall within the scope of protection of the present invention as long as it is apparent to those skilled in the art.

10: main body
11: air inlet 12: air outlet
20: ventilation unit 30: filter unit
40: sterilization unit 41: sterilization unit body
41a: vertical pipe 42: fixed part
43: metal mesh 44: plate for forming a zigzag flow path
44a: flat portion 44b: inclined portion
45: light irradiation unit 50: air collision unit

Claims (4)

A main body 10 comprising an enclosure and having an air inlet 11 at a lower portion and an air outlet 12 at an upper portion;
A blower 20 provided inside the main body 10 to suck air into the air inlet 11 and to discharge the sucked air to the air outlet 12;
A filter unit 30 provided in the air inlet 11 of the main body 10 and for purifying the air that is sucked in by the blower 20 and introduced into the air inlet 11;
A sterilization unit 40 provided above the filter unit 30 to sterilize the air purified by the filter unit 30 by irradiating ultraviolet rays and flow the sterilized air to the blowing unit 20; It is made including,
The sterilization unit 40 is made of a plurality,
The sterilization unit body 41 provided with a vertical pipe (41a) consisting of one to four lengthwise formed vertically by being hollow inside,
A fixing portion 42 formed vertically in the left and right centers of each of the vertical pipes 41a,
It is fixed to the fixing part 42 and installed vertically along the vertical pipe (41a) to partition the vertical pipe (41a) back and forth, coated with a photocatalyst such as titanium dioxide (TiO ₂ ), and formed into a flat plate shape. Metal mesh (43),
It consists of a pair and is installed in each of the vertical pipes 41a on both sides of the front and rear partitioned around the metal mesh 43 to form a zigzag passage in the vertical pipes 41a. A plate 44 for forming a zigzag flow path to sterilize bacteria contained in the primary purified air by allowing air to pass through the metal mesh 43 when passing through the zigzag flow path,
It is provided inside the zigzag flow path forming plate 44 and consists of a light irradiation part 45 that irradiates ultraviolet rays to the metal mesh 43,
The zigzag passage forming plate 44 connects at least two flat portions 44a in contact with the inner surface of the vertical pipe 41a and the flat portion 44a to each other and is bent in a V-shape. The bent end consists of an inclined portion 44b in contact with the metal mesh 43 so that the primary purified air passes through the metal mesh 43 in a zigzag manner to form a zigzag flow path,
The light irradiation part 45 is provided on the inside of the flat part 44a of the plate 44 for forming a zigzag channel to irradiate light to the metal mesh 43, which improves photocatalytic contact efficiency using a zigzag channel. Air deodorization sterilizer. The method of claim 1,
A control unit for adjusting the intensity of ultraviolet irradiation of the light irradiation unit 45 is further provided,
The control unit adjusts the ultraviolet irradiation intensity of the light irradiation unit 45 according to the amount of air blown by the air blower 20. The method according to claim 1 or 2,
The zigzag passage forming plate 44 and the vertical pipe 41a are made of a metal material, or the zigzag passage forming plate 44 and the inner side of the vertical pipe 41a are coated with a reflective material. Air deodorization sterilizer with improved photocatalytic contact efficiency using zigzag flow path. delete

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