KR20050093029A - Underwater air purification system from the by-product of photocatalyst - Google Patents

Abstract

The present invention relates to a photocatalytic underwater air purifying apparatus, wherein a photocatalyst liquid 14 formed by mixing titanium dioxide and water is stored in a case 2; Purifiers 20, 30 and 40 are installed inside the case 2 in which the photocatalyst liquid 14 is stored; A microbubble generating unit 12 is further installed below the purifier 20, 30, 40; After the air supplied by the first blower 10 is microbubbles while passing through the hose 11 and the microbubble generating unit 12, the purifiers 20, 30, 40 and the photocatalyst liquid 14 are removed. It is to be discharged to the outside to pass through, it was provided with a photocatalytic underwater air purifier that is further provided with a nipple 13 in the hose 11 to increase the total length of the hose by connecting a separate hose further.

Therefore, when the outside air is supplied to the hose 11 by the first blower 10, the microbubble generation unit 12 is divided into a myriad of microbubbles and introduced into the purifier 20, 30, 40, The microbubbles introduced into the purifiers 20, 30 and 40 are continuously contacted with the photocatalyst liquid 14 by buoyancy, and then pass through a plurality of filters and UV sterilization lamps. 40 is discharged to the upper side, and again discharged to the outside through the photocatalyst liquid 14 and the top receiving filter 16 in the case (2), so that the contaminated air passes through several layers of filters and a plurality of ultraviolet sterilization lamps While being purified, as well as the photocatalyst 14 is sufficiently and continuously in contact with the purification more reliably, the purification effect by titanium dioxide can be maximized.

In addition, according to the present invention, since the nipple 13 is provided at one side of the hose 11, the total length of the hose can be arbitrarily adjusted by attaching a separate hose to this, so that the installation position of the first blower 10 can be freely opened. Since the moisture of the photocatalyst 14 naturally evaporates when the photocatalytic underwater purifier is driven, it is necessary to install a separate humidifier because it supplies a proper amount of water through the pitcher 7. There will be no.

Description

Photocatalytic Underwater Air Purifier {Underwater air purification system from the by-product of photocatalyst}

The present invention relates to an air purifier, and more particularly, to a photocatalytic underwater air purifier.

In general, photochemical reactions using photocatalysts can completely disintegrate various types of harmful substances in air at room temperature and atmospheric pressure to be harmless, and also sterilize microorganisms in the air.

As described above, the photochemical reaction using the photocatalyst can use only the light source for the reaction and use the photocatalyst semi-permanently, so that unlike other environmental pollution treatment technologies, there is no problem of generating a second harmful substance.

In addition, titanium dioxide (TiO₂) used as a photocatalyst has a merit that can be widely used in general life as a material harmless to the human body widely used as a white dye in toothpaste, underwear, paper, and the like.

Therefore, in recent years, researches for treating environmental pollutants by photochemical reactions using such titanium dioxide photocatalysts have been actively conducted.

In one example, an air purifier using such a photocatalyst has been developed, in which a photocatalyst is coated on a metal plate filter and embedded in an air purifier to purify harmful substances such as dust inhaled in the air.

When the fan is operated by a built-in motor, external air is sucked into the air through the inlet of the air purifier, and the sucked air passes through the metal plate filter coated with the photocatalyst to remove the air. Antibacterial, will deodorize.

However, the air purifier using the conventional photocatalyst has a small effect because a large amount of air is discharged to the outside after passing the photocatalyst-coated filter once, and eventually, a large amount of contaminated air is discharged again without being properly filtered. Therefore, the air purification efficiency was not very high.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide a photocatalytic underwater air purification apparatus which can reliably purify contaminated air.

In accordance with one aspect of the present invention, there is provided a photocatalytic underwater air purifying apparatus including a filter and an ultraviolet sterilization lamp installed inside a case, a blowing fan for blowing air to the filter side, and a motor for driving the blowing fan. In the case, the photocatalyst liquid which is mixed with titanium dioxide and water is stored in the case; A purifier is installed inside the case in which the photocatalyst liquid is stored; A microbubble generating unit is further installed below the purifier; After the air supplied by the first blower is microbubble while passing through the hose and the microbubble generating unit, it is characterized in that it is discharged to the outside through the purifier and the photocatalyst liquid.

Another feature of the photocatalytic underwater air purifier of the present invention is that a nipple is further installed on the hose so as to increase the total length of the hose by further connecting a separate hose.

Another feature of the photocatalytic underwater air purifying apparatus of the present invention is that, in the purifier, a plurality of filters are installed in the purifier case filled with the photocatalyst liquid and spaced at equal intervals, and ultraviolet sterilization lamps are installed under the respective filters. As a result, the microbubbles generated from the microbubble generating unit pass through the photocatalyst liquid, the plurality of UV sterilization lamps, and the plurality of filters, and are discharged to the upper portion thereof.

Therefore, when external air is supplied to the hose by the first blower, the microbubble generation unit differentiates into numerous microbubbles and flows into the purifier, and the microbubbles introduced into the purifier continuously contact the photocatalyst liquid by buoyancy. After passing through a number of filters and UV sterilization lamps, they are discharged to the upper part of the purifier, and again through the photocatalyst liquid and the top receiving part filter to the outside, so that contaminated air is discharged to multiple layers of filters and multiple UV sterilization lamps. Of course, the purification as well as, the photocatalyst liquid is sufficiently and continuously contacted with more clarity, so there is an effect that can maximize the purification effect by titanium dioxide.

In addition, the photocatalytic underwater air purifying apparatus of the present invention is provided with a nipple on one side of the hose, so that the total length of the hose can be arbitrarily adjusted by combining a separate hose therewith, so that the installation position of the first blower can be freely changed, and the photocatalytic underwater purification of the present invention is provided. Since the moisture of the photocatalyst liquid naturally evaporates when the device is driven, supplying an appropriate amount of water through the pitcher acts as a humidifier, so there is no need to install a separate humidifier.

Specific features and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings.

Figure 1 is a schematic cross-sectional view showing a photocatalytic underwater air purifying apparatus of the present invention, Figure 2 is an excerpt sectional view showing a purifier according to the present invention, which is coupled to the case 2 on the lower case 3, the cover thereon (4) is combined to form the appearance of the photocatalytic underwater air purifying apparatus of the present invention.

The microbubble generating unit 12 is installed at the center of the lower case 3, and a plurality of holes are formed so that air breaks into a myriad of small microbubbles when the air passes through the microbubble generating unit 12. The hose 11 is connected, and the first blower 10 made of a blowing fan and a motor is connected to the end of the hose 11 so as to supply external air to the microbubble generating unit 12 side.

And on the hose 11, a nipple 13 is further installed to increase the total length of the hose by further connecting a separate hose.

On the other hand, a plurality of ultraviolet sterilization lamps 6 are installed at the inner circumference of the case 2, an upper receiving part filter 16 is installed at the upper part of the case 2, and a cover 4 to be described later is provided at the upper circumference of the case 2. The packing 18 is installed to increase the bonding force between them and to maintain airtightness when they are coupled thereto.

The cover 4 is provided with a second blower 17 on one side thereof, and a plurality of vents 5 are formed around the cover 4 so that the air purified when the second blower 17 is driven is vented. (5) is discharged to the outside smoothly.

The case 2 is filled with a photocatalyst liquid 14 formed by mixing a photocatalyst (TiO₂) and water, and a purifier 20 is installed inside the case 2 in which the photocatalyst liquid 14 is stored. Accordingly, the air supplied by the first blower 10 is microbubble while passing through the hose 11 and the microbubble generating unit 12, and then passes through the purifier 20 and the photocatalyst liquid 14 to the outside. It is intended to be discharged.

The purifier 20 includes a purifier case 21 in which the photocatalyst liquid 14 is filled, a first filtration filter 22, and a second filtration filter 23 arranged at equal intervals in the purifier case 21. And a third filtration filter 24 and a first ultraviolet sterilization lamp 25, a second ultraviolet sterilization lamp 26, and a third ultraviolet sterilization lamp 27 which are respectively installed under the filters.

Therefore, the microbubbles generated from the microbubble generating unit 12 are discharged to the upper part after passing through the photocatalyst liquid 14 and ultraviolet sterilization lamps, filters in the purifier 20.

Reference numeral 19 is an ultraviolet sterilization lamp installed inside the cover 4.

In the photocatalytic underwater air purifying apparatus of the present invention having such a configuration, when external air is supplied to the hose 11 by the first blower 10, the microbubble generating unit 12 is differentiated into a myriad of fine bubbles to purify the purifier 20. The first ultraviolet sterilization lamp 25 and the first filtration filter 22 while the microbubbles introduced into the inside and the inside of the purifier 20 are purged while continuously contacting the photocatalyst liquid 14 by buoyancy. As it passes by, it cleanses again.

The microbubble that has passed through the first filtration filter 22 is purified again while passing through the photocatalyst liquid 14, the second ultraviolet sterilization lamp 26, and the second filtration filter 23, as described above. The photocatalyst 14, the third ultraviolet sterilization lamp 27, and the third filtration filter 24 are purified again.

The fine bubbles thus sufficiently purified are raised and purified again while continuously contacting the photocatalyst liquid 14 inside the case 2 while being affected by the ultraviolet sterilization lamp 6 inside the case 2 again. After passing through the upper receiving portion filter 16 is blown to the outside by the second blower (17).

The photocatalytic underwater air purification apparatus of the present invention has various advantages as follows.

First, since the outside polluted air is purified by passing through several layers of filters and several ultraviolet sterilization lamps in the purifier 20 and the ultraviolet sterilization lamps and the top receiving filter 16 inside the case, the purifying power is improved. .

Second, in particular, the present invention, the photocatalyst liquid 14 is filled in the purifier 20 and the case 2, a large amount of air in the photocatalyst liquid 14 in the purifier 20 and the case 2 Since air supplied from the outside is not temporarily supplied but passed through the microbubble generation unit 12 into the microbubbles and then supplied into the purifier 20 and the case 2, the contaminated external air and the photocatalyst are supplied. The contact amount and the connection time between the liquids 14 are maximized.

Therefore, the outside contaminated air is differentiated into fine bubbles and slowly passes through the photocatalyst liquid 14 inside the purifier 20 and the case 2 by buoyancy so that the air purification by the photocatalyst liquid 14 is performed reliably. do.

Therefore, unlike a conventional air purifying device in which a large amount of air passes through the photocatalyst-coated filter once, it is possible to maximize the purifying power of air by titanium dioxide.

Third, since the nipple 13 is installed in the hose 11, a separate hose may be further connected therebetween to increase the length of the hose 11, and thus the installation position of the first blower 10 may be increased. Can be changed freely.

That is, by placing the first blower 10 in a place where air purification is required in the room and preparing a separate hose according to its length, and connecting it to the nipple 13, it is possible to purify the air in a desired place among various places in the room. have.

In this case, the photocatalytic underwater air booting apparatus of the present invention can be utilized as follows, since the first blower 10 is transported and installed to a specific closed place in the room, and those who want to smoke indoors go to the place and smoke. It will be possible to properly purify the cigarette smoke while the indoor air is not contaminated.

Fourth, when the first blower 10 and the second blower 17 is driven, the moisture of the photocatalyst liquid 14 naturally evaporates, thereby humidifying the room, thereby eliminating the need to install a separate humidifier.

However, as the amount of water mixed in the photocatalyst liquid 14 gradually decreases as the water evaporates, an appropriate amount of water may be supplied by the amount of water reduced through the pitcher 7.

Fifth, since the packing 18 is installed around the upper end of the case 2, when the cover 4 is coupled thereto, the coupling force between them is increased, and airtightness between them is maintained.

Sixth, the photocatalytic underwater air purifying device of the present invention can be separated and replaced as necessary, but the filter is replaced or disinfected inside the case by the ultraviolet sterilization lamp and the photocatalyst.

Seventh, since the photocatalyst liquid 14 is a liquid, it is very easy to mix with other liquids. Therefore, a separate inorganic disinfectant or functional perfume that does not cause a chemical reaction with the photocatalyst is added to the photocatalyst liquid 14, and thus it is very easy to use. It is convenient.

On the other hand, if it is provided with a photocatalytic pellet (PB) of a predetermined size and put into the purifier 20, the photocatalyst pellets (PB) are moved up and down by the microbubbles that rise due to buoyancy and smoothly contact with the microbubbles to increase the air purification effect. do.

3 and 4 are schematic perspective views and cross-sectional views showing another embodiment of the purifier according to the present invention. The purifier 30 includes a purifier case 31 filled with a photocatalyst liquid 14 and a purifier case ( 31. The first filtration filter 32 and the second filtration filter, which are installed at equal intervals inside the semicircular first grooves 33, the second grooves 35, and the third grooves 37, respectively formed on both sides thereof. 34), the third filtration filter 36, the lamp case 38 is installed in close contact with the grooves of the respective filters, and the ultraviolet sterilization lamp 39 is provided with a coupling inside the lamp case 38.

Compared to the purifier 20 of FIGS. 1 and 2, the purifier 30 differs only in the shape of the filters and the installation position of the UV sterilization lamps, and the effect thereof is the same as described above.

5 and 6 are schematic perspective views and cross-sectional views showing still another embodiment of the purifier according to the present invention. The purifier 40 includes a purifier case 41 filled with a photocatalyst liquid 14 therein; The first filtration filter 42 and the first through hole 43, the second through hole 45, and the third through hole 47 are arranged in the purifier case 41 at equal intervals, respectively. A second filtration filter 44, a third filtration filter 46, a lamp case 48 coupled to the through-holes of the respective filters, and an ultraviolet sterilization lamp 49 coupled to the inside of the lamp case 48. Is done.

This purifier 40 is also the same as the purifier 30 of FIGS. 3 and 4, compared to the purifier 20 of FIGS. 1 and 2, only the shape of the filters and the installation position of the UV sterilization lamp are different. Same as one.

On the other hand, the filter of the purifier shown and described in Figures 1 to 6 is not limited to three, it can be arranged below or more, as required by those skilled in the art.

According to the photocatalytic underwater air purifying apparatus according to the present invention as described above, when external air is supplied to the hose 11 by the first blower 10, the microbubble generating unit 12 is differentiated into a myriad of microbubbles. The microbubbles introduced into the purifiers 20, 30 and 40, and the microbubbles introduced into the purifiers 20, 30 and 40 are continuously contacted with the photocatalyst liquid 14 by buoyancy, and thus, a plurality of filters. After passing through the UV sterilization lamps, the purifiers 20, 30, 40 are discharged to the upper part, and are discharged to the outside through the photocatalyst liquid 14 and the top receiving part filter 16 in the case 2, and thus, contaminated air. Is purified as it passes through several layers of filters and a plurality of UV sterilization lamps, as well as more reliably purged with continuous and sufficient contact with the photocatalyst 14, thereby maximizing the purification effect by titanium dioxide. .

In addition, according to the present invention, since the nipple 13 is provided at one side of the hose 11, the total length of the hose can be arbitrarily adjusted by attaching a separate hose to this, so that the installation position of the first blower 10 can be freely opened. Since the moisture of the photocatalyst 14 naturally evaporates when the photocatalytic underwater purifier is driven, it is necessary to install a separate humidifier because it supplies a proper amount of water through the pitcher 7. There is no such effect.

1 is a schematic cross-sectional view showing a photocatalytic underwater air purifying apparatus of the present invention.

Figure 2 is a cross-sectional view of the main portion of Figure 1

3 and 4 are schematic perspective views and cross-sectional views showing another embodiment of the purifier according to the present invention.

5 and 6 are schematic perspective views and cross-sectional views showing yet another embodiment of the purifier according to the present invention.

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

2 ; Case 10; First blower

11; Hose 12; Micro bubble generator

13; Nipple 14; Photocatalyst

16; Upper inlet filter 18; packing

20,30,40; Purifier

Claims (5)

In the air purifier comprising a filter and ultraviolet sterilization lamp installed in the case, a blowing fan for blowing air to the filter side, and a motor for driving the blowing fan, A photocatalyst liquid 14 formed by mixing titanium dioxide and water is stored in the case 2; Purifiers 20, 30 and 40 are installed inside the case 2 in which the photocatalyst liquid 14 is stored; A microbubble generating unit 12 is further installed below the purifier 20, 30, 40; After the air supplied by the first blower 10 is microbubbles while passing through the hose 11 and the microbubble generating unit 12, the purifiers 20, 30, 40 and the photocatalyst liquid 14 are removed. Photocatalytic underwater air purification apparatus, characterized in that the pass through and discharged to the outside. The method of claim 1, Photocatalytic underwater air purifier, characterized in that the nipple (13) is further installed in the hose (11) to increase the total length of the hose by further connecting a separate hose. According to claim 1, In the purifier 20, The first filtration filter 22, the second filtration filter 23, and the third filtration filter 24 are installed at equal intervals in the purifier case 21 filled with the photocatalyst liquid 14. The first ultraviolet sterilization lamp 25, the second ultraviolet sterilization lamp 26, and the third ultraviolet sterilization lamp 27 are respectively installed below the filters. Photocatalytic underwater air purification apparatus, characterized in that the micro-bubbles generated from the microbubble generating unit 12 is discharged to the upper portion after passing through the photocatalyst liquid (14), the ultraviolet sterilization lamps, the filters. The purifier (30) of claim 1, The first filtration filter 32 in which the semicircular first grooves 33, the second grooves 35, and the third grooves 37 are formed at both sides in the purifier case 31 filled with the photocatalyst liquid 14, respectively. , The second filtration filter 34, the third filtration filter 36 is installed spaced apart at equal intervals, Lamp cases 38 are tightly installed in the grooves of the respective filters. Photocatalytic underwater air purification apparatus, characterized in that the UV sterilization lamp (39) is coupled to each other in the lamp case (38). The purifier (40) of claim 1, The first filtration filter 42, the second filtration filter 44, and the third filtration filter 46 each having a first through hole 43, a second through hole 45, and a third through hole 47 formed in the center thereof. ) Are installed at equal intervals inside the purifier case 41, Lamp case 48 is coupled to the through holes of the respective filters, Photocatalytic underwater air purification apparatus, characterized in that the UV sterilization lamp 49 is coupled to the lamp case (48).