KR102527926B1 - Photocatalyst media module and air purifier using same - Google Patents

Abstract

The present invention is to provide a photocatalyst media module and an air purifier using the same.
That is, the photocatalyst media module of the present invention includes a photocatalyst drum 10, photocatalyst pins 20 vertically spaced apart inside the photocatalyst chamber 12 of the photocatalyst drum 10 and coated with a photocatalyst layer, and the photocatalyst chamber 12. (12) It is characterized in that it includes an ultraviolet lamp (30) installed inside to output ultraviolet light, and a first filter member (40) installed on the outer circumferential surface of the photocatalyst drum (10).
In addition, the air purifier using the photocatalytic media module includes a blowing nozzle 200 connected to cross the discharge passage 16 of the photocatalyst media module 100; a blowing fan 300 installed inside the blowing nozzle 200 and sucking air through the discharge passage 16 of the photocatalyst media module 100 and the intake port 210 of the blowing nozzle 200; and a second filter member 400 installed at the intake port 210 of the blowing nozzle 200 to filter the intake air.
The use of the photocatalyst media module and the air purifier using the same has the advantage of greatly increasing the amount of sterilized and purified air blown by improving the structure so that sterilized and purified air are simultaneously sucked in and mixed and output.

Description

Photocatalyst media module and air purifier using the same {Photocatalyst media module and air purifier using same}

The present invention relates to a photocatalytic media module and an air purifier using the same, and more specifically, to a photocatalytic media module capable of effectively sterilizing air using ozone and hydroxyl radicals generated by reacting with ultraviolet rays and an air purifier using the same.

In general, air purifiers purify polluted air generated in homes, offices, industrial sites, etc., a purifier body with an air inlet and an air outlet, and air that is loaded in multiple layers in the purifier body and filters the air introduced through the air inlet. It consists of a filter and an air fan built into the body of the purifier to introduce air from the outside into the body of the purifier and then induce a flow of air so that the air filtered by the air filter is discharged into the room through an air outlet.

Such an air purifying device is intended to purify air by relying on an air filter, but there is a limit to air purifying no matter how excellent an air filter is used. In other words, fine harmful substances pass through the filter as they are, and bacteria breed in the air filter to contaminate the purified air.

Accordingly, in the conventionally disclosed Patent Publication No. 10-2019-0024390, a base configured to have a blowing fan installed therein and to suck in air from an inlet hole formed in the upper center and discharge it along an outlet formed along a lower side; an ultraviolet ray generator composed of a support formed vertically above the inlet hole and a light emitting module installed outside the support to emit ultraviolet rays of a set wavelength; The first flow part is formed inwardly and the ultraviolet ray generating part is surrounded, and a plurality of through-holes are formed so that outside air can flow inward and flow through the inlet hole, and reacts with the ceramic coating layer and ultraviolet rays to generate ozone and hydroxyl radicals. a primary filter unit having a photocatalyst coating layer formed thereon; A second filter unit forming a second flow part inwardly and covering the first filter part and removing foreign substances from the air passing from the outside to the inside; a cylindrical case forming a third flow part inwardly and surrounding the secondary filter part; A technique consisting of a cover having a suction port covering the case from the upper side and sucking air upward and introducing it into the third flow unit has been previously proposed.

In addition, in another prior art registration room No. 20-0494084, an air inlet is formed on one end and an air outlet is formed on the other side of the housing; a suction fan installed inside the housing, sucking in air through the air inlet and discharging it through the air outlet; a circuit board having a plurality of first air flow ports through which the air passing through the air intake ports flows; It is interposed between the circuit board and the suction fan, and photocatalyst particles, which are titanium dioxide particles that decompose organic compounds by receiving ultraviolet rays, are applied to the surface of the plate facing the circuit board by chemical vapor deposition, a photocatalyst plate having a plurality of second air passages through which air flows; A filter member inserted into the filter insertion groove formed on the front surface of the housing and removing particulate matter from air sucked into the housing: and mounted on the circuit board while facing the photocatalyst plate, irradiating ultraviolet rays to the photocatalyst particles A technology including a plurality of UV LED elements has been pre-registered.

However, the prior art is intended to improve the air purification capacity using a photocatalyst filter, but since the air sterilization capacity is proportional to the size of the primary filter (photocatalyst plate) on which the photocatalyst coating layer is formed, there is a limit to increasing the sterilization capacity in a compact structure. In addition, there was a problem that the sterilization efficiency by the photocatalyst greatly decreased due to the structural characteristics of air being output through the primary filter unit (photocatalyst plate) on which the photocatalyst coating layer was formed.

KR 10-2019-0024390 A (2019.03.08.) KR 20-0494084 Y1 (2021.07.23.)

In the present invention, a new technology has been invented to solve the problems of the prior art, and a photocatalyst media module applied to an air purifier to sterilize air is structurally simplified to simplify manufacturing while improving sterilization and purification ability. Providing a module is a problem to be solved in the invention.

In addition, it is an object to be solved by the present invention to provide an air purifier using a photocatalyst media module in which sterilized air and filtered air are simultaneously sucked in and mixed and output, and the airflow rate of the sterilized air is highly increased.

In addition, by applying blades that rotate in opposite directions to each other, a vortex is generated in a compact structure, so the blowing output is highly improved, and the sterilized air and the filtered air are effectively mixed. A photocatalyst that can significantly increase the amount of sterilized air generated Its purpose is to provide an air purifier using a media module.

In addition, although not separately described, other objects within the scope that can be inferred in view of the specific contents and claims for carrying out the invention below are also included in the overall task of the present invention.

delete

delete

delete

As a specific means to achieve this purpose, an air purifier using a photocatalytic media is configured, but connected to cross the discharge passage 16 of the photocatalyst media module 100, and the intake port 210 and the discharge port 220 are open at both ends. Air is sucked through the blow nozzle 200 provided as much as possible, the discharge passage 16 of the photocatalyst media module 100 installed inside the blow nozzle 200, and the intake port 210 of the blow nozzle 200. It is characterized in that it includes a blowing fan 300 provided to output to the discharge port 220, and a second filter member 400 installed in the intake port 210 of the blowing nozzle 200 and provided to filter intake air. to be

The blowing fan 300 includes forward and reverse blades 320 rotating in different directions, and a vortex space 340 formed by spaced apart arrangement between the forward and reverse blades 320, the forward, It is characterized in that the blower moving along the reverse blade 320 is provided to be output while the wind direction is switched in the vortex space 340 .

In addition, the inner side blade 321 of the forward and reverse blades 320 is located on the upper side of the discharge passage 16 side of the photocatalyst drum 10, and the outer side blade 322 disposed adjacent to the discharge port 220 It is formed with a contrast wide width and is characterized in that it is provided to forcibly intake air that has been sterilized and purified in the photocatalyst chamber 12.

In addition, among the forward and reverse blades 320, the outer blade 322 disposed adjacent to the discharge port 220 compared to the inner blade 321 is characterized in that it is formed with high output.

According to specific means for solving the above problems, the photocatalyst media module of the present invention achieves structural simplification by integrally forming an air flow path and a photocatalyst pin by forming an open curved cut line on the outer surface of a photocatalyst drum and bending it inward. This can help reduce production costs and improve productivity.

In addition, the air filtered by the first filter member is provided to come into contact with the photocatalyst pin while being introduced through the air passage, thereby providing an improved sterilization and purification effect.

In the air purifier using the photocatalyst media module of the present invention, air that has been sterilized and purified is simultaneously sucked in and mixed and outputted, but by configuring the thickness of the inner (inner) blade to be thick, the airflow rate of the air that has been sterilized and purified is greatly increased. It works.

In particular, by applying forward and reverse blades rotating in opposite directions to each other, it is an invention with great expected effects such as generating vortices in a compact structure to overcome the pressure drop caused by the filter and increase the blowing output.

1 is an overall perspective view showing a preferred embodiment of a photocatalytic media module provided by the present invention.
FIG. 2 is a configuration diagram showing the photocatalyst drum in a state in which the first filter member is removed from FIG. 1;
3 is a configuration diagram showing the internal structure of FIG. 1 in plan view;
4 is a perspective view showing another embodiment of the photocatalytic media module provided by the present invention as a whole.
5 is a configuration diagram showing the photocatalytic drum of FIG. 4;
6 is a configuration diagram showing the internal structure of FIG. 4 in plan view;
Figure 7 is a block diagram showing the installation structure of the ultraviolet lamp of Figure 4;
8 is a configuration diagram showing a preferred embodiment of an air purifier using a photocatalytic media module provided by the present invention as a whole.
FIG. 9 is a disassembled configuration diagram of an air purifier using the photocatalytic media module of FIG. 8;
10 is a block diagram showing the internal structure of an air purifier using a photocatalytic media module according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail according to specific embodiments of the accompanying drawings. Technical terms used in this specification are terms selected in consideration of functions in embodiments, and the meanings of the terms may vary depending on specific embodiments of the invention. And throughout the specification, when a part is said to be "connected" to another part, this includes not only the case of being "directly connected" but also the case of being "indirectly connected" with another member interposed therebetween. do.

In addition, expressions indicating directions such as "up, down, front, back" used in the following description are defined based on the drawings, and the shape and position of each component are not limited by these terms.

1 is an overall perspective view showing a preferred embodiment of a photocatalyst media module provided by the present invention, FIG. 2 is a configuration diagram showing a photocatalyst drum in a state in which the first filter member is removed from FIG. 1, and FIG. 3 is a photocatalyst drum is a planar configuration diagram of

The present invention is to provide a photocatalytic media module capable of effectively sterilizing air by using ozone and hydroxyl radicals generated by reacting with ultraviolet rays. It consists of a main component including an ultraviolet lamp (30) and a first filter member (40).

First, the photocatalyst drum 10 according to the present invention has a photocatalyst chamber 12 coated with a photocatalyst layer therein, and a plurality of air passages 14 for introducing air into the photocatalyst chamber 12 on an outer circumferential surface thereof. In the photocatalyst chamber 12, a discharge passage 16 for discharging sterilized and purified air is formed.

As an example, the photocatalyst drum 10 is formed in a cylindrical shape with upper and lower portions open, a lower opening portion closed by a base plate, and a discharge passage 16 through which sterilized air is exhausted at the upper opening portion. do.

In addition, the air passages 14 are spaced apart in multiple layers while being arranged at regular intervals on the outer circumferential surface of the photocatalyst drum 10, and are formed in a long hole shape extending in the circumferential direction of the photocatalyst drum 10, and are formed in a first filter member 40 to be described later. ) is provided to introduce filtered air into the photocatalyst chamber 12.

A plurality of photocatalyst pins 20 according to the present invention are spaced apart vertically inside the photocatalyst chamber 12 of the photocatalyst drum 10, and a photocatalyst layer is coated on the outer surface.

One end of the photocatalyst pin 20 is connected to the inner circumferential surface of the photocatalyst drum 10 and the other end extends toward the center of the photocatalyst chamber 12 and is radially disposed.

At this time, the photocatalyst pin 20 is manufactured separately from the photocatalyst drum 10 and connected by a fixing means including welding or rivets, or, as shown in FIG. The photocatalyst pin 20 may be integrally formed at the end of the air passage 14 by forming a cut line having the same open curve shape and then bending it inward.

Also, the photocatalyst pin 20 is coated with a photocatalyst layer like the photocatalyst drum 10, and reacts with ultraviolet rays output from an ultraviolet lamp 30 to be described later to generate ozone and hydroxyl radicals.

As the photocatalyst fins 20 formed at the ends of each air passage 14 are radially spaced apart inside the photocatalyst chamber 12, the air introduced into the photocatalyst drum 10 through the air passage 14 is naturally provided to come into contact with the photocatalyst pin 20 to effectively sterilize and purify the inlet air.

On the other hand, as shown in FIG. 3 , the photocatalyst pins 20 are disposed radially toward the center of the photocatalyst drum 10 , and may be formed to have a waveform bending line 21 .

In the case of the above configuration, the contact area between the photocatalyst pin 20 and the air is expanded due to the corrugated bending line 21, so that the efficiency of generating ozone and hydroxyl radicals is improved, and the efficiency of air sterilization and purification by ozone and hydroxyl radicals is improved. .

In addition, the photocatalyst pin 20 has its own elasticity since its thickness is thin compared to the length protruding inwardly.

Accordingly, the photocatalyst pin 20 is provided to vibrate by colliding with and rubbing against the blowing air current moving through the photocatalyst chamber 12 by the protruding portion formed by the corrugated bending line 21 .

As such, since the wave-shaped bending line 21 vibrates with a very short period inside the photocatalyst chamber 12, the frequency and area of contact with the air of the photocatalyst pin 20 per unit time are increased, so that the ozone and hydroxyl radicals oxidize the air. There is an advantage that the sterilization purification efficiency is improved.

The UV lamp 30 according to the present invention is installed inside the photocatalyst chamber 12 to output ultraviolet rays and reacts with the photocatalyst layer coated on the photocatalyst chamber 12 and the photocatalyst pins 20 to generate ozone and hydroxyl radicals. equipped to do

The UV lamp 30 is blinked by a separate external power source, or is equipped with a battery placed inside a case installed to surround the photocatalyst drum 10 so that it can be used as a portable device in the absence of a constant power source.

4 to 6 are configuration diagrams showing another embodiment of the photocatalyst media module provided by the present invention, and FIG. 7 is a configuration diagram showing a UV lamp installation structure according to another embodiment.

As shown in FIG. 1, the UV lamp 30 is installed below the photocatalyst chamber 12 and is provided to output ultraviolet rays upward, or as shown in FIG. 4, the UV lamp 30 is a center installed in the center of the photocatalyst chamber 12. It is supported by the bar 31 and is provided to output ultraviolet rays from the center of the photocatalyst chamber 12 to the inner circumferential side of the photocatalyst drum 10 .

In addition, the ultraviolet rays output from the ultraviolet lamp 30 react with the photocatalyst layer coated on the photocatalyst chamber 12 and the photocatalyst pin 20 to generate ozone and hydroxyl radicals.

The first filter member 40 according to the present invention is installed to surround the outer circumferential surface of the photocatalyst drum 10 in order to filter outside air.

The first filter member 40 is formed in the same shape as the outer circumferential surface of the photocatalyst drum 10 in order to filter dust or foreign substances contained in the external air before sterilization of the air by the photocatalyst, so that the external air can be filtered in a 360° direction. can be filtered.

The photocatalyst media module 100 of the present invention configured as described above forms an open curved cut on the outer surface of the photocatalyst drum 10 and bends it inward, so that the air passage 14 and the photocatalyst pin 20 are integrally formed. While achieving structural simplification by forming a structure to reduce manufacturing costs and improve productivity, the air filtered by the first filter member 40 is introduced through the air passage 14 and is provided to contact the photocatalyst pin 20 It has the advantage of providing an improved sterilization and purification effect.

Hereinafter, a detailed configuration of an air purifier using the above-described photocatalytic media module will be described together with drawings.

8 is a configuration diagram showing a preferred embodiment of an air purifier using a photocatalytic media module provided by the present invention as a whole, and FIG. 9 is a configuration diagram showing an exploded view of an air purifier using a photocatalytic media module of FIG. 8 .

As shown, the air purifier using the photocatalytic media according to the present invention is largely composed of a photocatalyst media module 100, a blowing nozzle 200, a blowing fan 300, and a second filter member 400. . For the detailed configuration of the photocatalytic media module 100 according to the present invention, refer to the description of FIGS. 1 to 7 above.

The blowing nozzle 200 according to the present invention is connected to cross the discharge passage 16 of the photocatalyst media module 100, and the intake port 210 and the discharge port 220 are provided at both ends so as to be open.

The blowing nozzle 200 is formed in a cylindrical shape with a hollow inside, and is connected to the middle region so that the discharge passage 16 of the photocatalyst media module 100 communicates with it.

That is, the blow nozzle 200 is connected to the top of the photocatalyst media module 100 in a 'T' shape structure, and sterilized and purified air is output in the horizontal direction while supported by the photocatalyst media module 100. are provided

The blowing fan 300 according to the present invention is installed inside the blowing nozzle 200 and sucks air through the discharge passage 16 of the photocatalyst media module 100 and the intake port 210 of the blowing nozzle 200. It is provided to output to the discharge port 220 side.

At this time, the blowing fan 300 includes a pair of forward and reverse blades 320 rotating in different directions and a vortex space portion 340 formed by spaced apart arrangement between the forward and reverse blades 320 do.

The reason for forming a pair of blades 320 rotating in opposite directions with the vortex space 340 interposed therebetween is the first filter member 40 of the photocatalyst media module described above and the second filter member described later. This is because it is difficult to provide a sufficient volume of air flow due to the pressure drop due to the resistance of (400).

That is, as the wind moving along the forward and reverse blades 320 is output while the wind direction is switched in the vortex space 340, a strong vortex is generated in the output blowing compared to the blade rotating in the same direction, thereby reducing the resistance of the filter It can provide a strong wind volume to overcome.

Therefore, the structure of the blowing fan 300 of the present invention improves the intake efficiency of external air of the air purifier, improves the discharge pressure of the clean air, and extends the blowing distance of the discharged clean air through the photocatalyst chamber 12. There is an advantage in that the output capacity of the sterilizing and purifying air is increased while effectively mixing and outputting the supplied sterilized and purified air and the filtered air supplied through the second filter member 400 .

10 is a configuration diagram showing the internal structure of an air purifier using a photocatalyst media module according to an embodiment of the present invention, located at the upper part of the discharge passage 16 side of the photocatalyst drum 10 among the forward and reverse blades 320 The inner side blade 321 to be is formed with a wider width than the outer side blade 322 disposed adjacent to the discharge port 220 .

Since the width of the blade in the direction of the rotational axis is proportional to the volume of air discharged from the blowing fan (air volume), the wide inner blade 321 is installed in the area corresponding to the discharge passage 16 and is installed in the photocatalyst chamber 12. It serves to forcibly pump the sterilized and purified air, and the pumped sterilized and purified air is quickly discharged by the rotation of the outer blade 322.

Meanwhile, among the forward and reverse blades 320, the inner blade 321 positioned adjacent to the discharge passage 16 of the photocatalyst drum 10 is compared to the outer blade 322 disposed adjacent to the discharge port 220. It can be formed with high output.

At this time, the output of the forward and reverse blades 320 may be determined according to the rotational speed of the motor or the blade angle of the blade.

In this way, when the output of the outer side blade 322 is formed higher, vacuum pressure is created in the vortex space 340, and the sterilized and purified air supplied through the photocatalyst chamber 12 and the second filter member ( Since the filtered air supplied through 400) is effectively mixed and outputted by the pressure difference, the filtered air supplied through the second filter member 400 has air purification efficiency due to ozone and hydroxyl radicals included in the sterilized and purified air. this improves

The second filter member 400 according to the present invention is installed in the intake port 210 of the blowing nozzle 200 and is provided to filter intake air.

The second filter member 400 is formed in a tapered shape, the diameter of which increases toward the inside of the blow nozzle 200, so that the area for filtering the intake air is expanded.

In the air purifier using the photocatalyst media module of the present invention configured as described above, sterilized and purified air supplied through the photocatalyst chamber 12 by the operation of the blowing fan 300 is supplied through the second filter member 400. There is an advantage in that the blowing amount of the sterilized and purified air is highly increased while mixing and agitation with the filtered air is effectively performed.

As described above, the most preferred embodiment of the present invention has been described in the detailed description of the present invention, but various modifications may be made within a range that does not depart from the technical scope of the present invention. Therefore, the scope of protection of the present invention should not be limited to the above embodiments, but the scope of protection should be recognized from the techniques of the claims to be described later and from these techniques to equivalent technical means.

10: photocatalyst drum
12: photocatalyst chamber 14: air flow path 16: discharge flow path
20: photocatalyst pin 21: waveform bending line
30: UV lamp 31: center bar
40: first filter member
100: photocatalytic media module
200: blowing nozzle 210: intake port 220: discharge port
300: blowing fan
320: forward, reverse blade 321: inner side blade
322: outer side blade 340: vortex space
400 Second filter member

Claims (8)

delete delete delete delete A photocatalyst chamber 12 coated with a photocatalyst layer is formed therein, a plurality of air passages 14 are provided on the outer circumferential surface for introducing air, and a discharge passage for discharging sterilized and purified air in the photocatalyst chamber 12 ( 16), photocatalyst pins 20 spaced apart from each other up and down inside the photocatalyst chamber 12 of the photocatalyst drum 10 and coated with a photocatalyst layer, and the inside of the photocatalyst chamber 12 an ultraviolet lamp 30 provided to output ultraviolet rays and react with the photocatalyst layer coated on the photocatalyst chamber 12 and the photocatalyst pins 20 to generate ozone and hydroxyl radicals; and the photocatalyst drum 10 A photocatalyst media module 100 comprising a first filter member 40 installed to cover an outer circumferential surface of the photocatalyst;
a blowing nozzle 200 connected to cross the discharge passage 16 of the photocatalyst media module 100 and provided at both ends so that the intake port 210 and the discharge port 220 are open;
A blower installed inside the blower nozzle 200 and sucking air through the discharge passage 16 of the photocatalyst media module 100 and the intake port 210 of the blower nozzle 200 and outputting the air toward the discharge port 220. fan 300; and
A second filter member 400 installed in the intake port 210 of the blowing nozzle 200 and provided to filter the intake air; includes,
The blowing fan 300,
Forward and reverse blades 320 rotated in different directions;
An air purifier using a photocatalytic media module, characterized in that it includes a vortex space portion 340 formed by disposing the forward and reverse blades 320 apart from each other.
delete According to claim 5,
Among the forward and reverse blades 320, the inner side blade 321 is located on the upper side of the discharge passage 16 side of the photocatalyst drum 10 and has a wider width than the outer side blade 322 disposed adjacent to the discharge port 220. An air purifier using a photocatalyst media module, characterized in that it is provided to forcibly intake the air sterilized and purified in the photocatalyst chamber (12).
According to claim 5,
Among the forward and reverse blades 320, the outer blade 322 disposed adjacent to the discharge port 220 compared to the inner blade 321 is formed with high output,
Due to the relatively high output of the outer side blade 322, vacuum pressure is created in the vortex space 340, and the sterilized and purified air supplied through the photocatalyst chamber 12 and supplied through the second filter member 400 An air purifier using a photocatalyst media module, characterized in that the filtered air is provided to be mixed and output.

Images