KR20050020065A - Air purifier - Google Patents

Abstract

PURPOSE: To provide an air purifier which includes a semi-permanent photocatalytic filter capable of removing contaminants from air through fibrous titanium dioxide photocatalyst, thereby providing purified air. CONSTITUTION: The air purifier comprises an inlet (12) which inhales contaminated air, a pre-filter (13) which is able to be attached to and detached from the inner side of the inlet and removes large-sized contaminants from the contaminated air, a fan (15) which compulsorily inhales the contaminated air, a titanium dioxide fiber (17) which is received at the inner side of a filtration chamber (20) to purify the contaminated air filtered through the pre-filter, a UV lamp (16) which activates the titanium dioxide fiber, sterilizes and purifies the contaminated air and irradiates ultraviolet rays, and an outlet (18) which discharges the purified air.

Description

Air Purifier {Air purifier}

The present invention relates to an air purifier, and more particularly, to an air purifier equipped with a semi-permanent photocatalyst filter capable of providing clean air by removing contaminants in the air through a fibrous titanium oxide photocatalyst.

Various types of air purifiers have been developed by adopting various types of filters to remove various contaminants such as bacteria, dust and odors in the air and to provide a healthy and comfortable space.

In general, an air purifier drives a blower and forcibly circulates the air to remove and remove inhaled air by filtering and adsorbing pollutants by a filter. It can cause odors or pollute the air, rather than onset.

Such filter type purifiers include pre-filters, hepa filters, electrostatic filters, activated carbon filters, etc., and can filter out dust and dust, but have a disadvantage in that they are difficult to sterilize or remove bacteria, organic substances and harmful substances in the air.

It is inconvenient to change the filter that pollutants are contaminated frequently, and the maintenance cost to change the expensive filter is expensive, but there is an anion generator to solve this problem. Therefore, it is difficult to process a large space, ozone type air purifier has a disadvantage that is harmful to the human body rather than a certain concentration.

In addition, a substance called allergen in the dust of the house dust mite has a disadvantage that can only be filtered and decomposed by the conventional anion method or filter method.

On the other hand, researches applying photocatalysts have found that titanium oxides can decompose difficult-decomposable organic substances when exposed to ultraviolet light, and have been recognized as a clean technology that can solve environmental problems. The air purifier using titanium dioxide photocatalyst that solves the shortcomings has the excellent hole ability and the ability to decompose various organic materials.

As a photocatalyst, expensive metals such as pure copper, platinum, rhodium, and palladium are used as catalysts as main active sites, but they are expensive and difficult to mass-produce.

Titanium dioxide can be used semi-permanently because it doesn't change even when it receives light, and since it oxidizes most organic materials and decomposes them into carbon dioxide and water, it is less secondary pollution and effective for removing bleach and odor. Therefore, considering the activity of oxide film on photocatalytic reaction As a result, titanium dioxide has emerged as a representative material in the photocatalyst field.

However, titanium dioxide in the form of a photocatalyst powder form using conventional titanium oxide is mixed with paper mineral and titanium dioxide powder to make a carrier in the form of a corrugated cardboard and coated with titanium dioxide powder using a binder, and titanium dioxide is not fixed. Because it is separated from a slight impact and made of paper, it is weak in moisture and air humidity generated during decomposition.

In addition, the conventional photocatalyst using titanium dioxide has a problem that there is a limit to the area in contact with air because the effective surface area is small and only a flat form can be made because the binder is cheap.

The present invention has been made to solve the above-mentioned disadvantages and problems, the object of the present invention is to maximize the surface area without being limited by the shape of the catalytic reactor, the reaction efficiency is dramatically improved and can be used semi-permanently An air purifier adopting a photocatalyst made of fibers is provided.

The fibrous titanium oxide photocatalyst (TiO2) photocatalyst and its manufacturing method are described in detail in Korean Patent Laid-Open Publication No. 2002-0009524 which relates to a fibrous titanium oxide photocatalyst capable of maximizing a specific surface area and being semipermanently used. It is explained.

Still another object of the present invention is to provide a filter barrel capable of fully utilizing an ultraviolet sterilization lamp capable of assisting the activity of the titanium dioxide photocatalyst and capable of sterilization.

The characteristics of the present invention for achieving the above object is the intake port for sucking contaminated air, the pre-filter for removing the large contaminants in the removable intake air inside the contaminated air, and forced intake of the contaminated air A blower fan, a titanium dioxide fiber seated inside the filtration chamber to purify the contaminated air filtered through the prefilter, and an ultraviolet lamp that activates the titanium dioxide fiber, sterilizes and purifies the contaminated air, and emits ultraviolet rays. And an outlet for discharging the purified air.

Hereinafter, preferred embodiments of the air purifier according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of an embodiment of an air purifier according to the present invention.

2 is a front perspective view of an embodiment of an air purifier according to the present invention.

3 is a rear perspective view of an embodiment of an air purifier according to the present invention.

1,2 and 3 simultaneously, the air purifier of the present invention includes a case 10 and a pedestal 11 of a rectangular parallelepiped. The outer surface of the case 10 is provided with an intake port 12 configured at the lower rear side to suck air into the inside, and the intake port is detachably mounted to the case 10, and consists of an intake grill. (12) Inside, the prefilter 13 is detachably attached. The inlet 12 communicates with the blower chamber 14, and a blower fan 15 is provided in the blower chamber. There is a flow path 23 communicating with the blower chamber 14 inward, and the flow path 23 communicates with the filtration chamber 20, and an ultraviolet lamp 16 is formed at the center of the filtration chamber, and supports the ultraviolet lamp. The support 22 is installed up and down so that the UV lamp 16 is stably positioned, and the titanium dioxide fiber 17 is seated in the filtration chamber 20, and the discharge grill is formed in the upper direction connected continuously. The outlet 18 is provided. Reflecting surface 19 is formed on the wall surface of the filter chamber so that the light of the ultraviolet lamp 16 can be reflected, and the reflecting surface 19 may be made of aluminum or silver foil having economical efficiency.

On the other hand, the front of the case 10 has a front panel 20, the front panel has a control box, the pollution sensor is configured, the display panel constituting the front panel displays the operation status and indoor pollution of the air purifier To make it possible.

The front surface of the case is provided with a lamp window 21 and the lamp window may be configured to increase the aesthetics at night by coating a fluorescent material.

The bottom pedestal 11 of the air purifier is detachably installed and serves to support the air purifier of the present invention, and is configured to be detachable during repair or maintenance.

The air purifier purifies the contaminated indoor air by circulating the air from the bottom to the top. The inhaled air is purified and sterilized as it goes to the top, and is changed to clean air when discharged.

The front lamp window 21 of the case 10 allows the naked eye to check the operating state of the lamp and to paint the fluorescent material to have an aesthetic feeling.

The rear of the case 10 of the present invention is to be fastened with a bolt, a nut so as to separate the case.

Referring to the operation and function of the present invention in detail, the pre-filter is mounted on the inner side of the intake port located at the bottom rear, the pre-filter serves to filter lint, hair, dust and dust in advance and according to the condition of the pre-filter Replaceable.

The contaminated air flowing into the lower rear part is forcibly raised upward by the blower fan 15 of the blower chamber 14 through the pre-filter, and the air introduced into the filter chamber 14 through the flow path 23 is discretized. The titanium fiber 17 sterilizes the bacteria contained in the air and decomposes and oxidizes fine dust, dust and organic substances in the contaminated air. Odor is deodorized in this process.

The ultraviolet lamp 16 located in the center of the filtration chamber 14 activates the photocatalytic fiber. The optical fiber according to the present invention fills the filtration chamber to an appropriate degree, and the concentration is such that the light of the centrally located ultraviolet lamp can be transmitted. The reflective wall 19 is projected on the wall of the filtration chamber to project a place where the ray of the lamp does not reach. In order to improve the reflecting ability of the reflecting surface, it is preferably composed of aluminum or silver foil. The reflecting surface 19 provides the maximum efficient function for activating the photocatalyst fiber by reflecting the light beam projected from the lamp 16 from all directions.

Since the lamp located in the center of the filtration chamber 20 may be about 30 centimeters or more, one support may be installed up and down so that the lamp is stably positioned and protected during movement or transportation.

The inlet port of the lower portion of the rear rear of the outlet can be made into a grille that does not enter the hand of a child and is formed in an aesthetic shape but can exert a function.

The UV lamp itself has a sterilization and deodorization function and is configured as one in the embodiment of the present invention, but two or more can be installed vertically or horizontally to improve performance.

The purpose of the UV lamp is to help sterilization and photocatalyst activity, and to sterilize all kinds of bacteria and viruses, and the photocatalyst method is determined by the size and effective surface area of photocatalyst particles and the time of contact with air. Photocatalyst fiber has 10 ~ 20nm size photocatalyst attached three-dimensionally, which has wide surface area, and because it is not a method of fixing photocatalyst with binder, its effective surface area is more than 7 times wider than coating photocatalyst. In the filtration chamber 20, titanium dioxide fibers 17 having a surface area of about 10 times the width of the soccer field can be constructed. Existing conventional filter barrel is only about 5cm, but the present invention can be significantly improved the area and time to contact because the intake air passes through the filter chamber of 33cm or more. It also has the advantage of being not affected by moisture in the form of fibers. On the other hand, since the titanium dioxide photocatalyst in the conventional air purifier is coated on corrugated cardboard, it is weak in humidity and may be deteriorated.

Titanium dioxide fiber in the filtration chamber is formed in the form of wires and freezes, and may be installed to the extent that the rays of the ultraviolet lamp are sufficiently projected to activate the photocatalytic fibers.

Titanium dioxide fiber 17 is a titanium oxide film is formed on the surface is about 10-500 μm in diameter.

A catalyst is a chemical reaction that does not change itself and changes the reaction rate or initiates a reaction. A photocatalyst is a kind of catalyst that is catalyzed by light energy. ZnO, CdS, WO ₃ , TiO _2, among which titanium dioxide (TiO 2) is the most active. That is, when light is irradiated to the catalyst, the catalyst receives light energy, causing electrons to move in the catalyst, and the moved electrons cause a strong chemical reaction (oxidation and reduction). At this time, the strong chemistry of the electrons is to oxidize the contaminated material and change it into a harmless material. In this way, when light is irradiated to the photocatalyst, it decomposes harmful substances in the air or water and transforms them into harmless materials. The mechanism of action varies depending on where the photocatalyst is applied, but the conclusion is that it breaks down harmful compounds into H2O and CO2. Therefore, the application range of the photocatalyst is very wide and the photocatalyst fiber of the present invention can be used semi-permanently even without replacement like the conventional HEPA filter, and can be used for a long time without any deterioration in functions such as sterilization, purification and decomposition.

The titanium dioxide photocatalyst of the present invention is an n-type semiconductor, and when electrons are irradiated with ultraviolet rays (400 nm or less), electron hole bands are formed to generate hydroxy radicals (* OH) and O ₂ − having strong oxidation power. This oxidizing power decomposes organic matter into carbon dioxide (CO ₂ ) and water to remove pollutants in the air, sterilization, anti-corruption and deodorization.

Hydroxide radicals (OH) and peroxygen ions (O ₂ −) generated by titanium dioxide photocatalysts can adhere to bacterial cell membranes, oxidize and decompose, destroy cell membranes, and can be sterilized and deodorized.

Therefore, it has the function of sterilizing more than 99% of various pathogens and various bacteria such as MRSA and O-157.

General antimicrobials are effective when bacteria come into contact with an antimicrobial substance or its surroundings, but titanium dioxide photocatalysts receive light energy from the surface of titanium dioxide and electrons continue to move, so holes are not formed in one place only.

Therefore, radicals generated by holes and peroxygens generated by electrons are more likely to come into contact with bacteria because they occur all over the titanium dioxide surface. Therefore, the antibacterial, antiseptic, and deodorizing ability is superior to the purifier and the antimicrobial agent according to the prior art.

In general, the antimicrobial agent is deteriorated over time, the antibacterial activity, photocatalytic fibers are semi-permanent, so once installed, the antibacterial activity is maintained steadily, maintenance / repair costs are very innovative. When applied to the space where a large number of bacteria are present, it is possible to sterilize bacteria existing in the hospital without regular disinfection and sterilization, which is hygienic and low maintenance costs.

Titanium dioxide photocatalyst not only decomposes various organic materials by the excellent oxidizing power of holes, but also has an excellent effect in removing NOx and SOx. In addition, it can remove 80 ~ 90% by oxidizing and precipitation of heavy metals such as lead and mercury which are extremely harmful to human body by peroxygen ion.

The process of oxidizing lead ions is as follows.

Pb + + 2O _2- → PbO ₂ + O ₂ or Pb ₂ + + 2O _2- → PbO + 3 / 2O ₂

Air passing through the filtration chamber 20 is finally discharged through the outlet 18 of the upper case 10.

4 is a test result (1) of the photocatalyst fiber deodorization rate (%) by the gas detection tube method.

5 is a test result (2) of the photocatalyst fiber deodorization rate (%) by the gas detection tube method.

The test results according to the request from Korea Yarn Textile Testing Institute are as follows.

Test substance (time) 5 minutes 15 minutes 30 minutes 60 minutes ammonia 95.0 97.5 98.7 > 98.7 Formaldehyde 85.0 90.0 94.4 > 94.4 Trimethylamine 90.0 92.0 94.4 > 98.8 Methyl Melcaptan 86.7 91.7 95.5 > 98.0 Acetaldehyde 89.3 92.9 96.3 > 99.2

<Table 1> relates to the results of the photocatalyst fiber deodorization rate (%) test by the gas detection tube method, and the deodorization rate (%) = (Cb-Cs) / Cb x 100, where Cb is in the test container after each time. It represents the concentration of test gas remaining, and Cs is the sample, which is also the concentration remaining in the test container after each time.

According to the above table, the ammonia substance is introduced into the filtration chamber according to the present invention, and after 5 minutes of injecting, 95.0% of ammonia is deodorized, and after 15 minutes, 97.5% is deodorized, and after 30 minutes, 98.7% is deodorized. After 60 minutes it can be seen that more than 98.7% deodorization.

As described above, one embodiment of the present invention has been described, and the scope of the present invention is not limited to the above description and may be changed and modified by those skilled in the art. It belongs to the scope of rights.

As described above, the air purifier according to the present invention removes dust and particles with a pre-filter and then expands the maximum air contact area and improves the reaction efficiency with a filter employing titanium dioxide fibers, and improves organic matter, dust, dust, etc. It can be used semi-permanently without removing and replacing the titanium dioxide filter.

1 is a cross-sectional view of an embodiment of an air purifier according to the present invention.

2 is a front perspective view of an embodiment of an air purifier according to the present invention.

3 is a rear perspective view of an embodiment of an air purifier according to the present invention.

4 is a test result (1) of the photocatalyst fiber deodorization rate (%) by the gas detection tube method.

5 is a test result (2) of the photocatalyst fiber deodorization rate (%) by the gas detection tube method.

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

10: case 11: stand

12: Intake vent 13: Prefilter

14: blower room 15: blower fan

16: ultraviolet lamp 17: titanium dioxide fiber

18: outlet 19: reflecting surface

Claims (4)

An intake port for sucking contaminated air, A pre-filter detachable inside the inlet and removing contaminants with large particles in the contaminated air; A blower fan forcibly sucking contaminated air, Titanium dioxide fibers seated inside the filtration chamber to purify the contaminated air filtered through the prefilter, An ultraviolet lamp for activating the titanium dioxide fiber, sterilizing and purifying polluted air, and emitting ultraviolet light; An air purifier comprising an outlet for discharging purified air. The method of claim 1, Air purifier, characterized in that provided with a reflective surface consisting of aluminum or silver foil in order to maximize the performance of the ultraviolet lamp. The method of claim 1, The titanium dioxide fiber is a titanium oxide film is formed on the surface of the air purifier, characterized in that the diameter of about 10-500 μm. The method of claim 1, The ultraviolet lamp is air purifier, characterized in that the length is more than 30 centimeters.