JP2003232547A - Air cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air cleaner capable of miniaturizing the body thereof, and cleaning air in a further wide range indoors while minimizing sound leaking from the body. <P>SOLUTION: Ducts 13, 14 are attached to an inlet side of the body 11 having a blowoff port 12, and inlets 15, 16 are attached to a tip end of the ducts 13, 14. The inlet 15, 16 is made to separate from the blowoff port by an appropriate distance. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air cleaner for purifying air, and more particularly to an air cleaner for removing substances contained in the air, such as dust, bacteria and gas, which are harmful to the human body.

[0002]

2. Description of the Related Art An air purifier is installed for the purpose of purifying air in an indoor living space. For example, in a hospital,
It is installed to prevent nosocomial infections and odors in hospital rooms. In addition, it is used to remove the odor of cigarettes and prevent hay fever.

There are two types of air cleaners, one in which the main body is installed outdoors and one in which it is installed indoors. The type in which the main body is installed in the room is popular because the construction is easy and the cost is low. is doing. In an air cleaner of the type in which this main body is installed indoors, as shown in FIG. 8, for example, an air outlet 2 and an inlet 3 for air are provided on the front surface of the main body 1 and not shown inside. It is equipped with a dust collecting filter and a fan. The indoor air sucked from the suction port 3 by the fan is sent to the filter, dust is collected by the filter, and the air from which dust and the like has been removed by the dust is blown from the blowout port 2 to clean the room. ing.

[0004]

However, in the conventional air purifier, the air purifier body 1 is provided with the blow-out port 2 and the suction port 3, and the arrangement intervals thereof are close to each other. If the amount of air circulated by the method is small, the air blown out from the blowout port 2 is immediately sucked through the suction port 3, so that there is a problem that the air can be purified only in a narrow range near the air purifier.

In order to purify a wider range, the air circulation amount may be increased by increasing the air blowing amount of the fan. In this case, the driving sound of the fan and more air passing through the filter. There is a problem in that the noise caused by the turbulence and the like becomes louder, and the synthesized large noise leaks from the air cleaner to the outside as noise.

As described above, in order to increase the amount of air blown by the fan, it is necessary to use a large-capacity fan, and there is a problem that the main body becomes large accordingly.

Further, when the filter is a filter which collects dust with high performance, noise becomes louder. When the noise is loud as described above, it cannot be used in a place requiring quietness such as a patient room or a hotel room.

The present invention has been made in view of the above points, and it is possible to reduce the size of an air purifier body, and to purify a wider range of air in one room while the sound leaking from the body is as low as possible. An object of the present invention is to provide an air purifier capable of realizing the above.

[0009]

In order to solve the above-mentioned problems, the air purifier of the present invention is an air purifier that sucks in air, then purifies and blows it out. It is characterized in that it is provided with a duct having one or a plurality of arbitrary lengths attached to the side and an inlet port attached to the tip of the duct.

Further, the suction port is separated from the blowing port by an arbitrary distance.

The air outlet is separated from the air purifier body by extending it with a duct.

Further, the air inlet is provided in the air cleaner body, and the air outlet is separated from the air cleaner body by extending the air outlet with a duct.

Further, it is characterized in that any one of the suction port and the blowing port is arranged at either a low place or a high place.

In the air purifier body, a fan for sucking air from the suction port, a first filter for collecting particles in the air sucked by the fan, and a first filter for collecting the particles are included. A sterilizing light source for sterilizing bacteria corresponding to the collected particles by light irradiation, a porous medium, a photocatalytic filter that adsorbs gas in the air into the pores of this medium, and a gas adsorbed by the photocatalytic filter. It is characterized in that it is provided with a light source for a photocatalyst that is decomposed by light irradiation.

The photocatalyst light source is a violet light emitting diode.

A second filter for adsorbing large dust in the air is provided upstream of the first filter along the air flow.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below in detail with reference to the drawings.

(Embodiment) FIG. 1 is an external view showing a configuration of an air cleaner according to an embodiment of the present invention.

The air purifier shown in FIG. 1 has a main body 11
And the air outlet 12 provided in the main body 11.
And an elongated tubular duct 1 attached to the body 11.
3 and 14, and air inlets 15 and 16 attached to the tips of the ducts 13 and 14, respectively.

The first feature of this air purifier is that the ducts 13 and 14 allow the suction ports 15 and 16 to be connected to the outlet 1.
It is located at a position away from 2. In this way, the air outlet 12 is separated from the air inlets 15 and 16 so that the air in the room can be circulated in a wide range with a small amount of air blow.

As the second characteristic, as shown in FIG. 2, the main body 11, the pre-filter 21, the fan 22, the ultraviolet lamp 23, the antibacterial HEPA filter 24, and the purple L
ED (Light Emitting Diode) light sources 25a, 25b, 25
c and 25d and photocatalytic filters 26a and 26b are provided along the flow of the air flow indicated by arrows Y1 and Y2.

The prefilter 21 removes dust by adsorbing and removing large dust in the air. This is to prevent large dust from adhering to the first high-performance filter arranged in the subsequent stage and deteriorating the performance of the filter.
The high-performance filter is to prevent light from being blocked when dust adheres to the surfaces of the photocatalyst filters 26a and 26b arranged in the subsequent stage and the effect of the photocatalyst described below is deteriorated.

The fan 22 is for sucking the air in the room from the suction ports 15 and 16 and blowing it out from the discharge port 12, and is provided with a motor and an actuator (not shown).

As shown in the perspective view of FIG. 3, the ultraviolet lamp 23 has an elongated cylindrical shape and is arranged upstream of the antibacterial HEPA filter 24. This UV lamp 23
Radiates ultraviolet rays having a wavelength of 253.7 nm to sterilize the ultraviolet rays. Such ultraviolet sterilization is
Since the bacteria have no effect unless they are irradiated with ultraviolet rays for a predetermined time, the bactericidal effect is enhanced by combining them with the antibacterial HEPA filter 24. That is, the antibacterial HEPA filter 2
Bacteria were collected in step 4, and the collected bacteria were irradiated with ultraviolet rays.

As shown in FIG. 3, the antibacterial HEPA filter 24 has a rectangular frame 24a and a long rectangular paper made of glass fiber in the frame 24a. It is configured to include the pleated portion 24b which is woven and stored, and can collect 0.3 μm particles at a collection rate of 99.97% or more. This antibacterial HE
The PA filter 24 is used in combination with the ultraviolet lamp 23 as described above. However, since the ultraviolet light of the ultraviolet lamp 23 may not reach the inside of the pleated portion 24b, the pleated portion 24b should be antibacterial coated. Therefore, it does not become a hotbed of bacteria.

As shown in FIG. 3, the violet LED light sources 25a to 25d and the photocatalytic filters 26a and 26b are arranged between the violet LED light sources 25a to 25d.
6a and 26b are arranged.

The photocatalyst filters 26a and 26b are, for example, photocatalyst-coated ceramic honeycomb filters. This filter is made by attaching a metal frame to a ceramic having a honeycomb structure coated with titanium oxide, and the gas (odor) adsorbed in the pores of the porous ceramic is irradiated from the purple LED light sources 25a to 25d. Decomposes with 380 nm UV light. In addition to ceramics, porous materials such as activated carbon, zeolite, and silica gel are also used, and all have the advantage of being maintenance-free because they decompose by themselves.

Each of the purple LED light sources 25a to 25d is constructed by disposing a plurality of purple LED lamps 31 on a plane. As shown in FIG. 4, the purple LED lamp 31 is configured by arranging a plurality of spherical purple LEDs 31b inside a slender cylindrical glass tube 31a.

As shown in FIG. 4, the purple LED 31b has the lead 4 on the upper surface of the glass epoxy resin substrate 41.
2, 43 are formed, and the n-electrode 44 is formed on one lead 43.
Is formed, a p-electrode 46 and an n-electrode 47 are formed on the n-electrode 44 through the silicon 45, and on this member,
A member in which sapphire 49 is formed on the upper surface of the n-GaN layer 48 and a p-GaN layer 50 is formed on a part of the lower surface, the n-GaN layer 48 is connected to the n-electrode 47, and the p-GaN layer 50 is the p-electrode 46. The silicon 45 and the lead 42 are wire-bonded with the gold wire 51, and the respective members 42 to 51 on the glass epoxy resin substrate 41 are covered with the silicon resin 52.

Next, the operation of the air cleaner having such a structure will be described.

However, in the air purifier, for example, the main body 11 is installed on the wall of a rectangular parallelepiped room, and the suction ports 15 and 16 are provided at both corners of the wall facing the wall through the ducts 13 and 14, respectively. Install. That is, the suction ports 15 and 16 are connected to the main body 1
It is assumed that it is arranged at a position away from the blowout port 12 of 1.

First, when the fan 22 is driven, air is sucked from the suction ports 15 and 16, flows into the main body 11 through the ducts 13 and 14, and passes through the pre-filter 21. At the time of this passage, large dust in the air will pass through the pre-filter 2
It is adsorbed by 1 and removed. The air from which the dust has been removed passes through the antibacterial HEPA filter 24 via the fan 22.

In the antibacterial HEPA filter 24, microparticles such as bacteria in the air are collected by the pleat part 24b, and the collected bacteria are sterilized by the ultraviolet light emitted from the ultraviolet lamp 23.

The air thus passing through the antibacterial HEPA filter 24 further passes through the photocatalytic filters 26a and 26b. At this time, the base gas such as odor is adsorbed in the holes of the porous ceramics of the photocatalyst filters 26a and 26b. The adsorbed gas is decomposed by ultraviolet light of 380 nm emitted from each of the purple LED light sources 25a to 25d. That is, the odor is decomposed. in this way,
The air that has undergone dust removal, sterilization, and deodorization, that is, the air that has been purified, blows out from the outlet 12 into the room. The blown air flows in the blowing direction and is again sucked from the suction ports 15 and 16, and the dust removal, sterilization, and deodorization are performed by the above processing. By thus circulating the air in the room, the air is purified after a predetermined time.

In order to verify the cleaning effect (dust collection effect) of the air cleaner of the present embodiment, a comparative experiment with a conventional air cleaner as described below was conducted. Hereinafter, the air purifier of the present embodiment will be referred to as the present air purifier, and the conventional air purifier will be referred to as the conventional air purifier.

[0036] The air cleaner, installed in one room of the two room that leads separated by a door (volume 56m ³⁾ (volume 30m ^3), was in a state of opening the door to the next room (volume 26m ^3). However, the door separating from the other space in the adjacent room was closed. For the purification experiment, for example, a conventional air purifier was first installed and the experiment was conducted. After a lapse of a predetermined time, the air purifier was installed and the experiment was conducted under the condition that the room conditions were the same. The state of the air purifier is 8.4 m ³ / min for the conventional air purifier without duct, and less than half the air volume for the conventional air purifier with duct. It is set to 7 m ³ / min. Further, as a measuring device for measuring the amount of dust in the room, a particle counter capable of measuring particles having a particle diameter of 1 μm was installed, and the amount of dust was measured.

The relationship between the operating time min of each air purifier in the air purifier installation room and the amount of dust in the room obtained as a result is shown by curves 51a and 52a in FIG. The relationship between the operating time min of each air cleaner in the adjacent room and the amount of dust in the room% is shown in FIG.
b and 52b. However, the solid curves 51a and 51b are
It is a relationship curve between the operating time min by the present air cleaner and the indoor dust amount%, and the wavy curves 52a and 52b are relationship curves between the operating time min by the conventional air cleaner and the indoor dust amount%.

As can be seen from this result, the cleaning effect by the conventional air cleaner is slightly excellent up to 40 minutes, but there is almost no difference. However, after 40 or more minutes,
Particularly, in the adjacent room, the dust amount% shown by the curve 51b is significantly lower than the dust amount% shown by the curve 52b, and it is verified that the cleaning effect of this air cleaner is excellent.

As described above, according to the air cleaner of the present embodiment, the ducts 13 and 14 are attached to the suction side of the main body 11 having the blowout port 12, and the suction ports 15 and 16 are attached to the tips of the ducts 13 and 14. Attach the suction port 15, 16
Since it is set to be separated from the outlet 12 by an arbitrary distance, the air in the room can be circulated in a wide range with a small amount of outlet.

In this case, since a small blowing amount is sufficient,
The air volume of the fan 22 is small, and the small fan 22 can be used for that amount, and the driving noise can be reduced. Since the small fan 22 is sufficient, the air cleaner can be downsized. Further, since the driving sound of the fan 22 is low, the sound leaking from the main body 11 can be reduced.

Further, the above-mentioned fan 22 is attached to the main body 11,
An antibacterial HEPA filter 24 for collecting particles in the air sucked by the fan 22, an ultraviolet lamp 23 for sterilizing bacteria corresponding to the particles collected by the antibacterial HEPA filter 24 by light irradiation, and a porous Photocatalytic filters 26a and 26b having ceramics and adsorbing gas in the air into the holes of the ceramics, and the photocatalytic filter 2
Since the purple LED light sources 25a to 25d for decomposing the gas adsorbed on 6a and 26b by light irradiation are provided, dust removal, sterilization and deodorization are performed in parallel with the air circulation in the room by the air cleaner. It can purify the air.

Further, the purple LED light sources 25a to 25d are
Since the purple LED 31b is used, low power consumption and long life of the light source can be realized.

Further, the pre-filter 21 for adsorbing large dust in the air is provided on the upstream side of the fan 22 along the air flow.
Since it has been arranged, it is possible to adsorb and remove large dust in the air, and as a result, the antibacterial H to be arranged in the subsequent stage can be removed.
The antibacterial HEPA filter 24 prevents large dust from adhering to the EPA filter 24 and deteriorating the performance of the filter.
Further, the photocatalytic filters 26a and 26b arranged in the subsequent stage
It is possible to prevent the effect of the photocatalyst from being lowered due to the light being blocked by the dust adhering to the surface of the.

In addition to the above, even if the air purifier is attached to the ceiling of the room as shown in FIG. 7 and the outlet is extended from the main body by extending the duct, the same effect as described above can be obtained. Become. That is, the main body 71 provided with the suction port 72 is fixed to the ceiling, the elongated cylindrical ducts 73 and 74 attached to the main body 71 are extended to the ceiling, and the outlets 75 and 74 are provided at the tips of the ducts 73 and 74.
I attached 76. In addition, the suction port 72 and the blowing port 7
You may arrange | position so that it may be hidden behind 5 and 76 except the ceiling.

Further, either the inlet or the outlet may be arranged at either the low place or the high place. In this case, since the specific gravities are different, various gases concentrated in the upper, middle, and lower regions of the room can be efficiently inhaled and decomposed.

[0046]

As described above, according to the present invention,
A duct was attached to the suction side of the air purifier body having an outlet, and the inlet was attached to the tip of this duct so that the inlet was separated from the outlet by an arbitrary distance.
The air in the room can be circulated in a wide range with a small blowing amount. In this case, you need only a small amount of air,
A small amount of air is required for the fan, so a small fan can be used, and the drive noise can be reduced.
Since a small fan is sufficient, the air purifier can be downsized. Further, since the driving sound of the fan is low, the sound leaking from the main body can be reduced. Therefore, the main body of the air cleaner can be downsized, and a wider range of indoor air cleaning can be realized with the sound leaking from the main body being as low as possible.

[Brief description of drawings]

FIG. 1 is an external view showing a configuration of an air cleaner according to an embodiment of the present invention.

FIG. 2 is a diagram showing internal components of the air cleaner.

FIG. 3 is a perspective view showing an ultraviolet lamp, an antibacterial HEPA filter, a purple LED light source, and a photocatalytic filter among the internal components of the air cleaner.

FIG. 4 is a purple LED lamp used as the purple LED light source and a purple LED used in the purple LED lamp.
It is a figure which shows the structure of.

FIG. 5 is a diagram showing a relationship between the operating time min of both the conventional air cleaner and the air cleaner in the present embodiment in the air cleaner installation room and the amount of dust in the room.

FIG. 6 is a diagram showing the relationship between the operating time min and the indoor dust amount% of both the conventional air cleaner and the air cleaner in the room next to the air cleaner installation room.

FIG. 7 is an external view showing a configuration of an air purifier according to another embodiment.

FIG. 8 is an external view showing a configuration of a conventional air cleaner.

[Explanation of symbols]

1, 11, 71 Main body 2, 12, 75, 76 Blow-out port 13, 14, 73, 74 Duct 3, 15, 16, 72 Inlet port 21 Pre-filter 22 Fan 23 Ultraviolet lamp 24 Antibacterial HEPA filter 25a-25d Purple LED light source 26a, 26b Photocatalyst filter 24a Frame 24b Pleated part 31 Purple LED lamp 31a Glass tube 31b Purple LED 41 Glass epoxy resin substrate 42,43 Lead 44,47 n electrode 45 Silicon 46 p electrode 48 n-GaN layer 49 Sapphire 50 p-GaN Layer 51 Gold wire 52 Silicon resin 51a Curve 52a showing the relationship between the operating time min of the air purifier of the present embodiment in the air purifier installation room and the amount of dust in the room 52a Conventional air purifier in the air purifier installation room Shows the relationship between the operating time min and the amount of dust in the room% Curve 51b Curve 52b showing the relationship between the operating time min of the air cleaner of the present embodiment in the room next to the air cleaner installation room and the amount of dust in the room 52b The operation of the conventional air cleaner in the room next to the air cleaner installation room Curves Y1, Y2 showing the relationship between the time min and the amount of dust in the room% Y2 Air flow direction

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Toshiji Azuma             2-6-8 Mukoyama, Nerima-ku, Tokyo Hikari Co., Ltd.             Within the wave F-term (reference) 4C080 AA07 AA10 BB05 QQ17                 4D048 AB03 BA07X BA10X BA41X                       BB02 CC40 CC63 CD05 CD08                       EA01 EA04                 4D058 JA14 JB50 KB11 QA01 QA03                       QA11 QA13 QA21 TA02 TA06                       TA08 UA18 UA25

Claims (8)

[Claims] 1. An air purifier that sucks in air, purifies and blows it out, and a duct having one or a plurality of arbitrary lengths attached to the suction side of an air purifier body having an outlet, and a tip of the duct. An air purifier having a suction port attached to the. 2. The air purifier according to claim 1, wherein the inlet is separated from the outlet by an arbitrary distance. 3. The air purifier according to claim 1, wherein the air outlet is separated from the air purifier body by extending with a duct. 4. The air cleaner main body is provided with the suction port, and the air outlet is separated from the air purifier main body by extending the air outlet with a duct.
Air purifier according to. 5. The air purifier according to claim 1, wherein any one of the suction port and the blowout port is arranged at either a low place or a high place. 6. A fan for sucking air from the suction port, a first filter for collecting particles in the air sucked by the fan, and a trap for the first filter in the air purifier body. A sterilization light source for sterilizing bacteria corresponding to the collected particles by light irradiation, a photocatalytic filter having a porous medium and adsorbing gas in the air into the pores of the medium, and a gas adsorbed by the photocatalytic filter An air purifier according to any one of claims 1 to 5, further comprising a photocatalyst light source that is decomposed by light irradiation. 7. The air purifier according to claim 6, wherein the light source for the photocatalyst is a violet light emitting diode. 8. A second filter for adsorbing large dust in the air is provided on the upstream side of the first filter along the air flow. Air purifier as described.