JP3234239U - Air cleaner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air purifier for the purpose of deodorizing, deodorizing and sterilizing indoor air by a photocatalyst and inactivating various germs and coronavirus by using a deep ultraviolet LED light source. SOLUTION: The resin-based non-woven filter 3 to which a photocatalyst is attached is composed of a white ray LED, an ultraviolet / deep ultraviolet ray LED, and a housing provided with an irradiation power source in order to give an excitation effect to the resin-based non-woven filter 3. A housing provided with an air inflow portion 2a on one side and an air exhaust portion 2b on the other side, and white light and ultraviolet rays at positions where the air flowing into the housing passes through the resin-based non-woven filter 3 to which the photocatalyst is attached. It is characterized by having an irradiation power supply unit capable of irradiating deep ultraviolet (UVC) light, and air from the air inflow unit 2a of the air purifier passes through the turbulent air inside the non-woven filter 3 having a certain thickness, and the photocatalyst It is used for fan equipment that enhances the excitation effect and forms an air passage toward the air exhaust section. [Selection diagram] Fig. 2

Description

This idea relates to an air purifier, and is particularly configured by using a filter made of, for example, a resin-based non-woven fabric having a thickness of about 20 mm, which is attached by supporting and fixing a photocatalyst, and an LED (light emitting diode) light source, and is configured in the air. It relates to an air purifier for the purpose of deodorizing, deodorizing, sterilizing and inactivating various coronaviruses.

At present, it is very difficult to remove indoor odors even when operating air conditioners, etc., and some air conditioners have been tested for deodorizing and deodorizing effects, but this is not sufficient at this time. Therefore, various filters are also used depending on the model. In particular, in recent years, attention has been paid to air purifiers with photocatalyst and LED (light emitting diode) light source specifications that are energy-saving, have a long life, and consider the impact on the environment and health, and the development of air conditioners with such specifications is required. There is.

As the light source of the photocatalyst, a light source unit using an LED (light emitting diode) is attracting attention. In addition, with the advent and development of each light LED and photocatalyst, the indoor cleaning method of air purifiers is also evolving.
By utilizing the characteristics of the photocatalyst and LED light rays in the filter of the air purifier and configuring the air purifier, it is possible to save energy and prolong the life of the air, and to make a compact air purifier suitable for health.

Conventionally, as a new type of air purifier, for example, in Patent Document 1, a filter, ultraviolet rays, etc. An automobile air purifier that forms a light source, a photocatalyst filter provided with a photocatalyst surface, an activated carbon filter, a fan, and an exhaust b of clean air is described.

On the other hand, various devices are also known that can exhibit an air purifying function that eliminates various germs such as mold inside an air conditioner by using a photocatalyst and an LED beam as an air purifier.

JP 2006-007806

As mentioned above, in recent years, various air purifiers such as energy saving and long life of air conditioners have been demanded, and in order to realize them, if photocatalysts, filters and LED light sources are used, Deodorization, deodorization, sterilization, etc. of indoor odors are possible, and inactivation of mold, germs, coronavirus, etc. by an air purifier using the wavelength of a deep ultraviolet LED light source (200 nm to 300 nm) is a development issue. be.

Conventionally, various filters have been used for various indoor air purifiers, but in recent years, photocatalysts and LEDs have been used for energy saving, long life, and especially considering the effects on the environment and health such as mold and other germs. Air purifiers with light source specifications are attracting attention, and air purifiers with such specifications are required.

As the light source of the photocatalyst, a light source unit using an LED is attracting attention. In addition, with the advent and invention of each light LED and photocatalyst, the indoor cleaning method of air purifiers has also evolved.
By making the best use of the characteristics of the photocatalyst and the LED light beam in the filter of the air purifier and configuring the air purifier, it is possible to save energy and prolong the life of the air, and to make a compact air purifier suitable for health.

This idea was devised in view of the above-mentioned problems in order to solve the problems. A filter made of, for example, a resin-based non-woven fabric having a thickness of about 20 mm, to which a photocatalyst is supported and fixed, and an LED. The purpose of the present invention is to provide an air purifier that is configured by using a light source and has the purpose of deodorizing, deodorizing, sterilizing air, and inactivating various coronaviruses.

In order to achieve the above problems, the present invention constitutes a housing having an air inflow portion on one side and an air discharge portion on the other, and a photocatalyst is provided between the air inflow portion and the air discharge portion inside the housing. An air-permeable filter with the above is inserted, an LED light source is attached inside the air inflow portion side of the housing, and the photocatalyst attached to the filter is excited by irradiation from the LED light source and passes through the filter excited by the photocatalyst. The air discharged from the air discharging unit is a means for deodorizing, deodorizing, and sterilizing the air, and inactivating various germs and coronavirus.

According to the air purifier according to the present invention, which is a means for solving the problem, a filter having a photocatalyst attached is inserted between the air inflow part and the air discharge part inside the housing, and the air inflow part side of the housing is provided. An LED light source is installed inside, and the photocatalyst attached to the filter is excited by irradiation from the LED light source, and the air discharged from the air discharge section passes through the filter excited by the photocatalyst to deodorize and deodorize the air.・ Sterilize and enable inactivation of germs and coronavirus. In other words, when the photocatalyst attached to the filter is exposed to ultraviolet rays or visible light, OH radicals and O ₂ which are active oxygen are generated on the entire surface, inactivating viruses and bacteria, and malodorous components, air harmful substances, etc. Adsorbs and decomposes. This active oxygen has the advantage of a photocatalyst that has a strong oxidative decomposition power of "3 times that of chlorine", "2 times that of hypochlorous acid", and "1.5 times that of ozone". Further, by using a deep ultraviolet LED light source, it is possible to inactivate various germs, influenza virus, and coronavirus, and the like, which exerts extremely practical and beneficial effects.
Further, in the case of the configuration of claim 2, the air discharge portion of the housing of the air purifier is installed and used at the air intake port of, for example, an air conditioner such as a fan device forming an air passage toward the air exhaust portion. Purifies the air sucked into the air conditioner, and uses the air conditioner to deodorize, deodorize, and sterilize the indoor air through the cold air discharged from the air conditioner, and inactivates germs, coronaviruses, influenza bacteria, etc. Is possible.
In the case of the configuration of claim 3, since the filter is a resin-based non-woven fabric, the air from the air inflow portion passes through the eddy air inside the non-woven fabric filter having a certain thickness, the excitation effect is further enhanced, and the air discharge portion. It can also be easily inserted and removed from the inside of the housing and replaced.
In the case of the configuration of claim 4, it is possible to use a resin-based non-woven fabric filter in which it is difficult to fix the titanium oxide photocatalyst by using the original ceramics bonding technology and the film forming technology.
In the case of the configuration of claim 5, the light beam emitted from the LED light source is emitted from the air discharge part, but the air discharge part side is the air of, for example, an air conditioner such as a fan device forming an air passage toward the air exhaust part. Since it is attached to the suction port, the light beam emitted from the LED light source does not directly enter the eyes of people in the room, and it is safe without fear of damaging people's eyes.
In the case of the configurations of claims 6 and 7, white light and ultraviolet rays are irradiated from the LED light source to excite the photocatalyst attached to the filter to deodorize / deodorize / sterilize in air, viruses, bacteria, etc. Can be inactivated to adsorb and decompose malodorous components and air harmful substances.
In the case of the configuration of claim 8, deep ultraviolet rays are irradiated from the LED light source to excite the photocatalyst attached to the filter, which enables inactivation of germs, influenza, coronavirus and the like.
In the case of the configuration of claim 9, white light, ultraviolet rays and deep ultraviolet rays can be appropriately irradiated, and different light rays are used to excite the photocatalyst to deodorize / deodorize / sterilize in the air, virus, and malodor. It adsorbs and decomposes components and air harmful substances, and enables inactivation of germs, influenza, coronavirus, etc.
In the case of the configuration of claim 10, the power supply of the LED light source can be easily obtained.

It is a perspective view of the air purifier which shows the form for carrying out this invention. It is an exploded perspective view of the air purifier which shows the mode for carrying out this invention. (A) is an outer view of the air inflow side frame showing a mode for carrying out this device, (B) is an inner view of the air inflow side frame, and (C) is an air inflow side frame. It is a side view. (A) is an outer view of an air discharge side frame showing a mode for carrying out this invention, and FIG. (B) is a side view of the air discharge side frame. (A) is a plan view of a filter showing a mode for carrying out this invention, and FIG. (B) is a side view of the filter. It is a partially cutout plan view of the air purifier which shows the mode for carrying out this invention. It is a figure of the use example in the air conditioner of the air purifier which shows the mode for carrying out this invention.

Hereinafter, the device will be described in more detail based on the mode for carrying out the device described in the drawings.
In the figure, the air purifier 1 has a housing 2 having an air inflow portion 2a on one side and an air discharge portion 2b on the other side, and a filter 3 having a photocatalyst attached to the inside of the housing 2 is inserted. The housing 2 has a structure in which an LED light source 4 is attached.

In this air purifier 1, the photocatalyst attached to the filter 3 is excited by irradiation from the LED light source 4, and the air flowing in from the air inflow section 2a passes through the filter 3 excited by the photocatalyst and is transmitted from the air discharge section 2b. By being discharged, it is characterized by deodorizing, deodorizing, and sterilizing the air, and enabling inactivation of germs and coronavirus.

The housing 2 has a rectangular shape when viewed from a plane, and its thick portion through which air passes is thinner than the vertical width and the horizontal width. The housing 2 has a plurality of air inflow portions 2a formed on one flat surface side of the rectangular shape. Each of the plurality of air inflow portions 2a is formed, for example, from a rectangular opening hole elongated in the lateral direction, and the outside air flows into the inside of the housing 2 through each of the plurality of air inflow portions 2a.

Since the filter 3 is inserted into the housing 2, the housing 2 is formed with an air discharge portion 2b and a flat side on which the air inflow portion 2a is formed so that the filter 3 can be easily inserted. The inside is opened separately from the other flat side.

One flat side on which the air inflow portion 2a is formed is composed of the air inflow side frame 21. A side frame 21a perpendicular to the thickness direction of the housing 2 is formed on the rectangular peripheral edge of the air inflow side frame 21. Similarly, the other flat side on which the air discharge portion 2b is formed is composed of the air discharge side frame body 22. A side frame 22a perpendicular to the thickness direction of the housing 2 is formed on the rectangular peripheral edge of the air discharge side frame 22.

In the figure, the plane side of the air inflow side frame 21 in which the plurality of air inflow portions 2a of the housing 2 are formed is, for example, five horizontal girders on the left and right sides of one central vertical girder 21b and the central vertical girder 21b. Each is partitioned by 21c. Further, a rectangular frame girder 21d is formed on the peripheral edge of the air inflow side frame 21 of the housing 2 on the flat surface side so as to surround the central vertical girder 21b and the plurality of horizontal girders 21c. The side frame 21a is vertically formed on the peripheral edge of the rectangular frame girder 21d.

The housing 2 has a plurality of air discharge portions 2b formed on the other flat side of the rectangle that is opposite to the air inflow portion 2a. Each of the plurality of air discharge portions 2b is formed from, for example, a horizontally long rectangular opening hole. The air that has flowed into the housing 2 from the air inflow unit 2a is discharged to the outside of the housing 2 through each of the plurality of air discharge units 2b.

In the figure, the flat side of the air discharge side frame 22 on which the plurality of air discharge portions 2b of the housing 2 are formed is formed by, for example, five vertical girders 22b and the horizontal girders 22c on the left and right sides of the five vertical girders 22b. Each is partitioned. Further, a rectangular frame girder 22d is formed on the other peripheral edge of the housing 2 on the flat surface side so as to surround the plurality of vertical girders 22b and horizontal girders 22c. The side frame 21a is vertically formed on the peripheral edge of the rectangular frame girder 22d.

The air inflow side frame 21 and the air discharge side frame 22 constituting the housing 2 are vertically overlapped and fitted, and the side frame 21a on the peripheral edge of the air inflow side frame 21 is the air discharge side frame. It is formed slightly wider than the side frame 22a on the peripheral edge of the body 22. That is, when the air inflow side frame 21 and the air discharge side frame 22 are vertically fitted, the side frame 21a of the air inflow side frame 21 surrounds the outer peripheral side of the side frame 22a of the air discharge side frame 22. become.

When the filter 3 is inserted inside the housing 2 and the air inflow side frame 21 and the air discharge side frame 22 are fitted, a part of the side frame 21a is provided so that the two do not easily come off. A screw-type shooting 23 that penetrates the frames 21a and 22a on both sides and prevents them from coming off is attached. When opening the inside of the housing 2, the photograph 23 is turned to be removed, and the air inflow side frame 21 and the air discharge side frame 22 fitted vertically are separated vertically.

A breathable filter 3 is inserted inside the housing 2. For example, a resin-based non-woven fabric is used for the filter 3 so that air can easily pass through the inside. Further, the thickness of the filter 3 is thin, for example, about 20 mm so that air can easily pass through. Since the filter 3 is a resin-based non-woven fabric, the air from the air inflow portion passes through the turbulent air inside the non-woven fabric filter having a certain thickness, and the excitation effect is further enhanced.

A photocatalyst is attached to the filter 3 made of a resin-based non-woven fabric by supporting and fixing. For example, titanium oxide is used as the photocatalyst. Titanium oxide, a photocatalyst, exerts effects such as deodorization, antifouling, and sterilization when photoexcited. Our unique ceramics bonding technology and film formation technology enable adhesion of titanium oxide photocatalysts to resin-based non-woven fabrics, which have been difficult to fix.

The LED light source 4 irradiates the filter 3 to which the photocatalyst is supported and fixed with the LED light beam to photoexcite the photocatalyst. As the LED light source 4, for example, a white light LED light source 4a, an ultraviolet LED light source 4b, a deep ultraviolet LED light source 4c, and the like are used depending on the purpose. Further, these three LED light sources 4a, 4b, 4c are combined with one air inflow side frame 21 so that the white light LED light source 4a, the ultraviolet LED light source 4b, and the deep ultraviolet LED light source 4c can be used alternately as needed. May be installed.

The LED light source 4 is attached to the inner surface side of the air inflow side frame 21 which is the inside of the housing 2 so as to irradiate the filter 3 toward the filter 3. The LED light source 4 is attached to the inner surface of a plurality of cross girders 21c constituting the air inflow side frame 21 of the housing 2, that is, the side directly facing the filter 3.

Each of the plurality of LED light sources 4 is attached to an elongated mounting board 41. The mounting board 41 to which the LED light source 4 is attached is attached to the inner surface of the cross girder 22c of the air inflow side frame 21 of the housing 2. The mounting board 41 is narrower than the width of the cross girder 22c, and care is taken so that a part of the mounting board 41 does not protrude and block a part of the width side of each air inflow portion 2a.

Further, if necessary, the white light LED light source 4a, the ultraviolet LED light source 4b, and the deep ultraviolet LED light source 4c can be alternately used on the inner surfaces of the plurality of cross girders 21c of one air inflow side frame 21. Three LED light sources 4a, 4b, 4c are attached. Each LED light source 4a, 4b, 4c is controlled by the control panel 42. It is attached to the inner surface of the frame girder 22c on the end side of the air inflow side frame 21 of the housing 2.

Since the LED light source 4 requires a power source to irradiate the LED light beam, the power supply unit 43 of the LED light source 4 is provided in the housing 2. A connection terminal 43b of the power cord 43a of the power supply unit 43 is provided in a part of the side frame 21a of the air inflow side frame 21 of the housing 2.

Next, the use based on the configuration of the form for carrying out the above invention will be described below.
When using the air purifier 1, for example, titanium oxide as a photocatalyst is supported and fixed to the breathable filter 3 inserted inside the housing 2. Adhesion of titanium oxide to the filter 3 is achieved by a unique ceramic bonding technique and a film forming technique. For the filter 3 to which the photocatalyst is attached, for example, a thin resin-based non-woven fabric having a thickness of about 20 mm is used. The filter 3 has a thin rectangular parallelepiped outer shape so as to be inserted inside the housing 2.

The filter 3 to which the photocatalyst is attached is inserted into the housing 2. The housing 2 is composed of an air inflow side frame 21 and an air discharge side frame 22, and the air inflow side frame 21 and the air discharge side frame 22 are separated vertically and the inside is opened. A thin resin-based non-woven fabric having a thickness of about 20 mm is placed inside the air discharge side frame 22 of the opened housing 2 from above.

The peripheral edge of the air discharge side frame 22 is composed of a rectangular frame side frame 22a, and a plurality of rectangular air discharge portions 2b are formed vertically and horizontally on the inner bottom surface. A filter 3 to which a photocatalyst is attached is placed on the air discharge portion 2b on the bottom surface. In the thin rectangular parallelepiped filter 3, the peripheral edge of the rectangle is in contact with the inner surface of the side frame 22a of the rectangular frame of the air discharge side frame 22, and the filter 3 is prevented from freely moving inside.

The air discharge side frame 22 in which the filter 3 is inserted is covered with the air inflow side frame 21 and fitted. The side frame 21a formed on the peripheral edge of the air inflow side frame 21 is slightly larger than the side frame 22a formed on the peripheral edge of the air discharge side frame 22, and the inner side surface of the side frame 21a is the outer surface of the side frame 22a. It is fitted by touching.

After fitting, the shooting 23 is turned to integrate the air inflow side frame 21 and the air discharge side frame 22 so as not to come off. The upper side of the filter 3 inside the housing 2 is held on the inner surface side of the air inflow side frame 21, the lower side is held on the inner surface side of the air discharge side frame 22, and the thin peripheral edge is the air inflow side frame. It is held on the inner side surface of the side frame 21a of 21, and is held inside the housing 2.

A mounting board 41 on which the LED light source 4 is mounted is arranged on the cross girder 21c inside the air inflow side frame 21 that holds the upper side of the filter 3. In the drawing, a white light LED light source 4a, an ultraviolet LED light source 4b, and a deep ultraviolet LED light source 4c are attached to the cross girder 21c of the air inflow side frame 21, respectively. Each LED light source 4 is arranged so as to irradiate an LED light beam toward the surface of the filter 3.

Subsequently, the housing 2 in which the filter 3 is inserted is attached to the air intake port 51 of, for example, an air conditioner 5 such as a fan device forming an air passage toward the air exhaust portion. A plurality of air exhaust portions 2b of the housing 2 are attached so as to communicate with the air intake port 51 of the air conditioner 5. Then, the air conditioner 5 is operated.

Further, the end of the power cord 43a of the power supply unit 43 is connected to the connection terminal 43b of the housing 2 in advance, the remote control of the power supply unit 43 is turned on, and the white light LED light source 4a of the LED light source 4 is operated by the remote control operation. Each LED light source is irradiated from the ultraviolet LED light source 4b and the deep ultraviolet LED light source 4c.

By the operation of the air conditioner 5, a suction force is generated in the air suction port 51 of the air conditioner 5, and the suction force is transmitted to the air inflow part 2a through the air discharge part 2b and the filter 3 of the housing 2, and the suction force of the housing 2 The indoor air is sucked from the air inflow portion 2a.

The air that has flowed into the inside of the housing 2 through the air inflow portion 2a passes through the turbulent airflow inside the breathable filter 3 made of a resin-based non-woven fabric having a certain thickness, and the photocatalyst by the LED light source emitted from the LED light source 4 The excitation effect is further enhanced to form an air passage toward the air discharge portion 2b.

The air discharged from the air discharge unit 2b of the housing 2 becomes the air passing through the air suction port 51 of the air conditioner 5, and the LED light source emitted from the LED light source 4 enables deodorization, deodorization, and sterilization of indoor odors and the like. In addition, the purpose of inactivating germs, coronaviruses, influenza bacteria, etc. is achieved by the deep ultraviolet rays emitted from the deep ultraviolet LED light source 4c.

The air sucked from the air intake port 51 of the air conditioner 5 is cooled in the air conditioner 5, the cooled air is blown out from the air outlet 52 of the air conditioner 5 into the room, and the room is cooled with clean air.

It should be noted that this device is not limited to the form for carrying out the above device, and it goes without saying that various modifications can be made without departing from the spirit of this device.

1 Air purifier 2 Housing 2a Air inflow part 2b Air discharge part 21 Air inflow side frame body 21a Side frame 21b Central vertical girder 21c Horizontal girder 21d Frame girder 22 Air discharge side frame body 22a Side frame 22b Vertical girder 22c Horizontal girder 22d Frame girder 23 Shooting 3 Filter 4 LED light source 4a White light LED light source 4b Ultraviolet LED light source 4c Deep ultraviolet LED light source 41 Mounting board 42 Control panel 43 Power supply unit 43a Power cord 43b Connection terminal 5 Air conditioner 51 Air intake port 52 Air outlet

Claims (10)

A housing is configured to include an air inflow portion on one side and an air discharge portion on the other, and a breathable filter having a photocatalyst attached is inserted between the air inflow portion and the air discharge portion inside the housing, and the housing is provided. An LED light source is attached to the inside of the air inflow section, and the photocatalyst attached to the filter is excited by irradiation from the LED light source. An air purifier characterized by deodorizing, deodorizing, and sterilizing, and enabling inactivation of germs and coronavirus. The air purifier according to claim 1, wherein the air exhaust portion of the housing is installed and used at an air intake port of a fan device or the like that forms an air passage toward the air exhaust portion. The air purifier according to claim 1, wherein the filter to which the photocatalyst is attached is made of a resin-based non-woven fabric. The air purifier according to claim 1, wherein the photocatalyst attached to the filter is titanium oxide. The air purifier according to claim 1, wherein the LED light source is arranged so as to irradiate the inside of the housing on the air inflow portion side toward the air discharge portion side. The air purifier according to claim 1, wherein the LED light source is a white light LED light source that irradiates white light. The air purifier according to claim 1, wherein the LED light source is an ultraviolet LED light source that irradiates ultraviolet rays. The air purifier according to claim 1, wherein the LED light source is a deep ultraviolet LED light source that irradiates deep ultraviolet rays. The first aspect of claim 1, wherein each LED light source mounting substrate of a white light LED light source, an ultraviolet LED light source, and a deep ultraviolet LED light source is appropriately arranged so as to irradiate the inside of the housing on the air inflow portion side toward the air discharge portion side. Air cleaner. The air purifier according to claim 1, further comprising a power supply unit for the LED light source.

Images