JP2871424B2 - Indoor air purification device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an indoor air purifying apparatus, and more particularly to an indoor air purifying apparatus useful for removing dust, smoke, odor, and the like from indoor air.

[0002]

2. Description of the Related Art As shown in FIG. 2, a conventional indoor air purifying apparatus has a duct (16) in which air flows from an air inlet (9) to an outlet (3), and air in the duct (16). Dust removing layer (11) provided after the suction port (9) for collecting dust of 1 mm or more, and the dust removing layer (1).
A coarse particle removing layer (12) provided after 1) for collecting a substance of 1000 nm or more, and an ultrafine particle removing layer provided after the coarse particle removing layer (12) for collecting a substance of 2 nm or less. (14) was provided.

[0003] However, the indoor air purification device as described above uses a medium-fine particle material of about 2 to 1000 nm that cannot be collected by the dust removal layer (11) or the coarse particle removal layer (12). Since it reaches (14), the ultra-fine particle removal layer (14) also captures medium fine particles, and the ultra-fine particle removal layer (14)
The trapping ability of the ultra-fine particle removal layer (14) is rapidly reduced, the odor collection efficiency is reduced, and the air cannot be sufficiently purified.

[0004]

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an indoor air purifying apparatus capable of improving odor collection efficiency and sufficiently purifying air.

[0005]

The indoor air purifying apparatus according to the present invention comprises: [1] a duct (16) in which an air flow is generated from an air inlet (9) to an outlet (3); [2] the duct ( 1
6) In the 1 provided after the air inlet (9)
Dust removal layer (11) for collecting dust of mm or more, [3]
1000 nm provided after the dust removal layer (11)
Coarse fine particle removal layer (12) for capturing the above substances, [4]
2 to 10 provided after the coarse particle removal layer (12)
A medium fine particle removing layer (13) for collecting a substance of 00 nm, and [5] 2n immediately after the medium fine particle removing layer (13).
ultrafine particle removal layer for collecting the following materials m (14) is provided, furthermore, [6] above in particulate removal layer (13) coarse fine
Moisture removal layer for removing moisture between the particle removal layers (12)
The provided wherein the Rukoto (17).

[0006]

According to the indoor air purifying apparatus of the present invention, since the duct (16) for generating an air flow from the air inlet (9) to the outlet (3) is provided, the air flows from the inlet (9). The dust removal layer (11) is sucked, blown out from the outlet (3), and provided in the duct (16) immediately after the air inlet (9). Collects dust of 1 mm or more in the sucked air.

Further, since the coarse particle removing layer (12) is provided after the dust removing layer (11), the coarse particle removing layer (12) cannot be completely collected by the dust removing layer (11). The substance of 1000 nm or more in trapped air is collected.

Further, after the coarse particle removing layer (12), a medium fine particle removing layer (13) for collecting a substance of 2 to 1000 nm and a substance of 2 nm or less after the medium fine particle removing layer (13) are collected. Since the ultra-fine particle removal layer (14) is provided, the ultra-fine particle removal layer (1) is used to collect the ultra-fine particles after the medium-fine particle removal layer (13).
In 4), the ultrafine particle removing layer (14) retains the odor-collecting ability of the ultrafine particle removing layer (14) for a long time without reaching the medium fine particles, and the purified air is blown out from the outlet (3). . In addition, the presence of the moisture removal layer (17) makes
The medium particle removal layer (1) provided after the removal layer (17)
3) Particles smaller than medium fine particles less than 1000 nm
In order to greatly improve the collection efficiency of
It is useful for removing necessary moisture in advance.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the drawings according to embodiments.

FIG. 1 is a perspective view of an indoor air purifying apparatus according to an embodiment of the present invention. The indoor air purification device of the present invention has a duct (16).
Is provided with a suction port (9) for sucking air. The duct (16) generates airflow from the air inlet (9) to the outlet (3). In the suction port (9),
Many slits are formed. A dust removal layer (11) is provided in the duct (16) after the air inlet (9). This dust removal layer (11)
Is formed by laminating porous fiber layers in layers. The dust removal layer (11) collects dust of 1 mm or more in the air taken in.

After the dust removal layer (11), a coarse particle removal layer (12) is provided. The coarse particle removal layer (12) may be a commonly used one such as an electric dust collector. When a filter made of a fibrous material such as an inorganic fiber is used as the coarse particle removing layer (12),
More effective. Here, the dust removal layer (1
Of the dust in the air that could not be collected in 1), 1
It collects substances of 000 nm or more and removes relatively fine dust in the air.

After the coarse particle removal layer (12), a medium particle removal layer (13) is provided. The medium particle removal layer (13) is a honeycomb formed of a fibrous material having pores, which captures a substance of 2 to 1000 nm, and the honeycomb formed of the fibrous material contains a liquid such as water. A fibrous honeycomb may be used. In the case of a honeycomb formed of a fiber having pores of 2 to 1000 nm, it is possible to reliably collect medium fine particles. Alternatively, a so-called concentration distribution occurs in a region where the medium fine particles are adsorbed in a portion containing another liquid and a region where the medium fine particles are not adsorbed. Therefore, in the trapping function part of the fibrous material having pores, the trapped substance moves in the direction of lower concentration, so that the trapping function part is cleaned and the trapping efficiency is restored.

It is more effective if the liquid contained in the fibrous honeycomb of the medium fine particle removal layer (13) is a surfactant aqueous solution, a basic aqueous solution, or an acidic aqueous solution. That is, in the case of a surfactant aqueous solution, it is effective in collecting lipophilic components, in the case of a basic aqueous solution, it is effective in collecting acidic components, and in the case of an acidic aqueous solution, it is effective in collecting basic components. It is a target. For example, soap water is used as the surfactant aqueous solution, calcium carbonate aqueous solution is used as the basic aqueous solution, and acetic acid aqueous solution is used as the acidic aqueous solution, but it is not particularly limited to these. Also,
When the medium fine particle removal layer (13) is composed of a lipophilic adsorbent, it is effective for collecting lipophilic substances. As the lipophilic adsorbent, it is preferable to use one containing at least one of an organic clay composite and an oil paper filter.

As shown in FIG. 1, a water removal layer (17) is provided between the medium particle removal layer (13) and the coarse particle removal layer (12) . The water removal layer (17) is used to remove the small particles smaller than 1000 nm or less than the medium particles, especially in the medium particle removal layer (13) provided after the water removal layer (17). It is useful for removing unnecessary water in advance. The water removal layer (17) may be composed of a substance such as silica gel that is commonly used, or may be simply cooled to cause dew condensation to remove water.

After the medium particle removing layer (13), an ultrafine particle removing layer (14) is provided. The ultra-fine particle removing layer (14) collects a substance causing an odor of 2 nm or less. Activated carbon is used for the ultrafine particle removal layer (14),
If the ultrafine particle removing layer (14) is a honeycomb formed of activated carbon, it is effective for collecting substances that cause odor, and the contact area with the inflowing air is improved, so that the collection efficiency is low. improves.

Further, zeolite is used for the ultrafine particle removing layer (14), and if the zeolite is a honeycomb,
It contributes to improving the efficiency of collecting substances that cause odor. If the zeolite has been subjected to a hydrophobizing treatment, moisture is adsorbed, and the substance causing odor is easily collected without being blocked by the moisture.

Activated alumina is used as the ultra-fine particle removing layer (14). If the activated alumina is a honeycomb, it is possible to improve the collection efficiency of substances causing odor, as in the case of activated carbon or zeolite. Contribute. If the activated alumina has been subjected to a hydrophobic treatment, water is adsorbed and, as in the case of zeolite, a substance causing an odor is easily collected without being blocked by the water.

When the ultrafine particle removing layer (14) has a double structure of a honeycomb of activated carbon and a honeycomb of activated alumina, and the activated alumina is placed in front of the activated carbon, the chance of contact with the inflowing air is increased, and the collection efficiency is improved. Is further improved. Similarly, when the ultrafine particle removal layer (14) has a double structure of a honeycomb of activated carbon and a honeycomb of zeolite, and the zeolite is placed in front of the activated carbon, the chance of contact with the inflowing air increases, and the collection efficiency is further improved. improves.

The ultra-fine particle removing layer (14) is composed of at least two kinds of activated carbon honeycombs having different numbers of cells per unit area. Increase the chance of contact with the air and the sieving effect as a multi-stage filter,
The collection efficiency is further improved. Similarly, the ultrafine particle removal layer (14) is formed of honeycombs of at least two or more types of zeolites having different numbers of cells per unit area. The increase in the chance of contact with air and the sieving effect as a multi-stage filter are added, and the collection efficiency is further improved.
The ultrafine particle removing layer (14) is formed of at least two or more kinds of activated alumina honeycombs having different numbers of cells per unit area. The increase in the chance of contact with air and the sieving effect as a multi-stage filter are added, and the collection efficiency is further improved.

The ultra-fine particle removing layer (14) is composed of at least two kinds of activated carbon honeycombs having different pore sizes,
If the pores are arranged in order of increasing diameter, the chance of contact with the inflowing air increases, and particles are effectively collected in order of increasing size, and the collection efficiency is further improved. Similarly,
The ultra-fine particle removing layer (14) is made of at least two kinds of zeolite honeycombs having different pore diameters. If the ultra-fine particle removing layer (14) is arranged in order from the one having the larger pore diameter, the chance of contact with the inflowing air is increased, and the one having a larger particle size is obtained. , And the collection efficiency is further improved. Further, when the ultrafine particle removing layer (14) is made of at least two kinds of activated alumina honeycombs having different pore diameters, and is arranged in order from the one having the larger pore diameter, the chance of contact with the inflowing air increases,
The particles are effectively collected in order from the largest particle, and the collection efficiency is further improved.

As the ultra-fine particle removing layer (14), a basic solid substance is used. If the basic solid substance is a honeycomb, NO _X and S which cannot be collected by the other removing layers are used.
O _X can be collected efficiently, the contact area with the inflowing air can be improved, and NO _X and SO _X can be collected more efficiently. Even if this basic solid substance is cement, cement foam, calcium carbonate, sodium carbonate, NO
_X and SO _X are collected.

A blower (15) is provided after the ultrafine particle removing layer (14). The blower (15) is provided behind the blower (15) while passing the air entering from the air suction port (9) between the dust removal layer (11) and the ultrafine particle removal layer (14). An airflow is generated that blows the purified air from the blowout port (3).

[0023]

According to the indoor air purification device of the present invention,
The odor collection efficiency is good, the odor collection ability is maintained for a long time, and the air can be purified.

[Brief description of the drawings]

FIG. 1 is a perspective view of an indoor air purification device according to an embodiment of the present invention.

FIG. 2 is a perspective view of an indoor air purification device according to a conventional example.

[Explanation of symbols]

 Reference Signs List 3 outlet 9 suction port 11 dust removal layer 12 coarse particle removal layer 13 medium particle removal layer 14 ultra-fine particle removal layer 15 blower 16 duct 17 moisture removal layer

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Naoji Nakagawa 1048 Kadoma Kadoma, Osaka Prefecture Matsushita Electric Works, Ltd. References JP-A-56-37019 (JP, A) JP-A-61-278323 (JP, A)

Claims (21)

(57) [Claims] [1] A duct (16) in which air flows from an air inlet (9) to an air outlet (3), [2] a duct provided after the air inlet (9) in the duct (16). A dust removing layer (11) for collecting dust of 1 mm or more, and [3] a 100 provided after the dust removing layer (11).
A coarse particle removing layer (12) for collecting a substance of 0 nm or more, [4] 2 provided after the coarse particle removing layer (12);
Medium particle removal layer (1
3) and [5] an ultra-fine particle removing layer (14) for trapping a substance of 2 nm or less is provided immediately after the medium fine particle removing layer (13) ;
In, [6] the fine particles removed layer (13) and the coarse particle removal layer
A moisture removal layer (17) for removing moisture is provided between (12).
Only indoor air purification device according to claim Rukoto. 2. The indoor air purifying apparatus according to claim 1, wherein the ultrafine particle removing layer is a honeycomb made of activated carbon. 3. The indoor air purifying apparatus according to claim 1, wherein the ultrafine particle removing layer (14) is a honeycomb made of zeolite. 4. The indoor air purifying apparatus according to claim 3, wherein the zeolite is subjected to a hydrophobic treatment. 5. The indoor air purifying apparatus according to claim 1, wherein the ultra-fine particle removing layer is a honeycomb made of activated alumina. 6. The indoor air purifying apparatus according to claim 5, wherein said activated alumina is subjected to a hydrophobic treatment. 7. The room according to claim 1, wherein the ultrafine particle removing layer has a double structure of a honeycomb of activated carbon and a honeycomb of activated alumina, and the activated alumina is placed before the activated carbon. Air purification equipment. 8. [1] The ultrafine particle removing layer (14) has a double structure of a honeycomb of activated carbon and a honeycomb of zeolite.
The indoor air purification device according to claim 1, wherein the zeolite is placed before the activated carbon. 9. [1] The ultra-fine particle removing layer (14) is made of at least two or more kinds of activated carbon honeycombs having different numbers of cells per unit area, and the number of cells per unit area is smaller. The indoor air purification device according to claim 1, wherein the air purification device is placed. 10. The ultrafine particle removing layer (14) is composed of at least two or more types of zeolite honeycombs having different numbers of cells per unit area, and the number of cells per unit area is smaller. The indoor air purification device according to claim 1, wherein the air purification device is placed. [1] The ultrafine particle removing layer (14) is made of at least two types of activated alumina honeycombs having different numbers of cells per unit area, and the number of cells per unit area is smaller. The indoor air purifying apparatus according to claim 1, wherein the indoor air purifying apparatus is placed in a room. 12. The method according to claim 1, wherein the ultra-fine particle removing layer (14) is formed of at least two kinds of activated carbon honeycombs having different pore diameters, and is arranged in order from one having a larger pore diameter. Indoor air purification device. 13. The ultrafine particle removing layer (14) is composed of at least two kinds of zeolite honeycombs having different pore diameters, and is arranged in front of the one having a larger pore diameter. Indoor air purification device. 14. The ultrafine particle removing layer (14) is formed of at least two kinds of activated alumina honeycombs having different pore diameters, and is arranged in order from the one having a larger pore diameter. An indoor air purification device as described in the above. 15. The indoor air purification apparatus according to claim 1, wherein the ultrafine particle removing layer is a honeycomb made of a basic solid substance. 16. The indoor air purifying apparatus according to claim 15, wherein the basic solid substance is cement, cement foam, calcium carbonate, or sodium carbonate. 17. The indoor air purifying apparatus according to claim 1, wherein said medium fine particle removing layer (13) is made of a lipophilic adsorbent. 18. The indoor air purifying apparatus according to claim 17, wherein the lipophilic adsorbent contains at least one of an organoclay composite and an oil paper filter. 19. The indoor air purifying apparatus according to claim 1, wherein the medium fine particle removing layer (13) is a honeycomb formed of fibrous material. 20. The method according to claim 19, wherein the fibrous honeycomb of the medium fine particle removal layer (13) contains any of water, a surfactant aqueous solution, a basic aqueous solution, and an acidic aqueous solution. Indoor air purification device. 21. The indoor air purifying apparatus according to claim 1, wherein the coarse particle removing layer (12) is a filter made of fibrous material.