JPH06210132A - Method and device for purifying air in room - Google Patents

Abstract

PURPOSE:To remove carbon dioxide and harmful components in air and to generate useful components such as oxygen by sending the air in the room to a container contg. photosynthesizing microorganisms to perform photosynthesis. CONSTITUTION:A diffuser pipe fitting part 11 is installed in the lower part of a transparent barrel-shaped vessel 10 made of acrylic resin, etc., and a purifying air discharge part 12 is installed in the upper part. And the side part 13 of the vessel 10 is made flat so that light energy from a light source 30 such as a fluorescent lamp may sufficiently be taken in it. The vessel 10 is filled in with culture solution 20, such as water and sea water and photosynthesizing microorganisms 22 such as chlorella. While light energy is given to over the entire area having a height of L of the side part 13 of the vessel 10, the air in the room is discharged from a diffuser pipe 40. Then carbon dioxide in the air is replaced with oxygen by photosynthesis and at the same time harmful materials in the air are removed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for purifying indoor air.

[0002]

2. Description of the Related Art Conventionally, as a technique for purifying indoor air, removal of components by a filter is known.

As a device for enriching oxygen, there is known a device for sieving air components by utilizing the difference in adsorption to zeolite.

[0004]

However, in the removal of components by the filter, it is necessary to frequently clean or replace the filter in order to maintain the purification performance, which is difficult to handle.

In addition, an apparatus for enriching oxygen using zeolite does not convert carbon dioxide into oxygen, and carbon dioxide and the like are discharged into the outdoor environment, which is not preferable.

The present invention has been made in order to solve the above-mentioned conventional problems, and the purpose thereof is to be able to continuously operate without maintenance of a filter or the like and to remove unnecessary components in indoor air. Another object of the present invention is to provide a method and an apparatus for purifying indoor air that can enrich useful components such as oxygen and that does not emit exhaust gas into the environment.

[0007]

According to a first aspect of the present invention, there is provided a method for purifying indoor air, wherein a container is filled with a culture solution and a photosynthetic microorganism and light energy is given to the photosynthetic microorganism while the room air is aerated. The carbon dioxide in the air is replaced by oxygen by photosynthesis and the harmful substances in the air are removed, and the purified air is returned to the room.

According to a second aspect, the culture solution is water, seawater, or artificial seawater. According to claim 3, the photosynthetic microorganism is chlorella. A room air purifying apparatus according to claim 4, wherein the container is filled with a culture solution and photosynthetic microorganisms, a light source for giving light energy to the photosynthetic microorganisms, an air diffuser attached to the container, and an indoor air intake communicating with the air diffuser. It is provided with a member and a purified air discharge part provided in the container.

According to a fifth aspect, the container is made of a transparent material. According to a sixth aspect, the light source is provided on the outer circumference or inside of the container made of a transparent material.

According to a seventh aspect of the present invention, the indoor air intake member comprises an air pump or blower and a pipe.

[0011]

In the method for purifying indoor air according to the first to third aspects, a culture solution such as water, seawater or artificial seawater is placed in a container and a photosynthetic microorganism such as chlorella is cultured. Light energy necessary for photosynthesis is given by a light source arranged inside or outside the container.

Then, the room air is taken into the container in an aerated state through the air diffuser. During aeration, carbon dioxide in the air is replaced by oxygen by photosynthesis, and at the same time, harmful substances in the air are removed.

The purified air accumulated in the upper part of the container is returned to the room. In the indoor air purifying apparatus according to the fourth aspect, a culture solution such as water, seawater, or artificial seawater is placed in the container to cultivate photosynthetic microorganisms such as chlorella. Light energy necessary for photosynthesis is given by a light source arranged inside or outside the container.

Then, the room air is taken into the container in an aerated state from the air diffuser via the room air intake member.
During aeration, carbon dioxide in the air is replaced by oxygen by photosynthesis, and at the same time, harmful substances in the air are removed.

The purified air accumulated in the upper part of the container is returned to the room from the discharge part of the container. In the room air purifying apparatus according to the fifth and sixth aspects, since the container is made of the transparent material, the light energy from the light source provided outside can be supplied into the container.

In the room air purifying apparatus according to the seventh aspect, the room air can be forcibly taken in.

[0017]

EXAMPLES The present invention will be described below based on examples.
FIG. 1 shows an embodiment of the method for purifying indoor air and the apparatus therefor according to claims 1 and 4.

In FIG. 1, reference numeral 10 is a barrel-shaped container formed of a transparent material such as acrylic resin. The container 10 is
The air diffuser mounting portion 11 is provided in the lower portion, and the purified air discharge portion 12 is provided in the upper portion.

The side portion 13 of the container 10 has a flat shape so that the light energy from the light source 30 such as a fluorescent lamp can be sufficiently taken in. Also, the container 10 has legs 14
Is standing up by.

The container 10 is filled with a culture solution 20 such as water, seawater or artificial seawater and a photosynthetic microorganism 22 such as chlorella. The light source 30 such as a fluorescent lamp has a length equal to the height L of the side portion 13 of the container 10 so that light energy can be applied over the entire height L of the side portion 13 of the container 10. Are arranged as follows.

Air diffuser mounting portion 11 provided at the bottom of the container 10.
An air diffuser 40 for generating fine bubbles such as a ceramic filter is attached to the. A pipe 51 of an indoor air intake member 50 is connected to the air diffuser 40.

The indoor air intake member 50 is composed of a pipe 51, an air pump or blower 52, and an indoor air intake port 53. Next, the operation of the present embodiment configured as described above will be described.

First, a culture solution 20 such as water, seawater or artificial seawater is placed in a container 10 and a photosynthetic microorganism 2 such as chlorella 2 is added.
Incubate 2. A light source 30 such as a fluorescent lamp disposed outside the container 10 provides light energy required for photosynthesis.

Then, the air pump or blower 52 of the indoor air intake member 50 is driven to take in the indoor air from the indoor air intake port 53, and aerate the air from the diffuser pipe 40 into the container 10 via the pipe 51.

During the aeration, carbon dioxide in the air is replaced by oxygen by photosynthesis by the photosynthetic microorganism 22 such as chlorella, and at the same time, harmful substances in the air are removed. The purified air accumulated in the upper part of the container 10 is
It is returned to the room from the purified air discharge section 12 of 0.

As described above, according to this embodiment, carbon dioxide and harmful components in the indoor air are removed by photosynthesis by the photosynthetic microorganism 22 such as chlorella, and returned to the room as useful components such as oxygen. Be done.

Further, according to this embodiment, as compared with the conventional purification method using a filter or the like, it is possible to continuously operate the filter and the like without maintenance. Furthermore, since the exhaust gas can be returned to the room as purified air,
Emission of exhaust gas into the environment unlike in the past is eliminated.

Furthermore, when a ceramic filter is used as the air diffusing tube 40, the room air is supplied into the container 10 as fine air bubbles, the residence time of the air can be lengthened, and the removal rate of pollutants can be improved. Can be increased.

Next, when the culture medium 20 made of artificial seawater and marine chlorella as the photosynthetic microorganism 22 are filled in the container 10 of FIG. 1 and air pollutants are taken in through the indoor air intake member 50 Table 1 shows the results of the experiment.

As shown in Table 1, in this experiment, the generation rate (increasing rate) of nitrogen dioxide, ozone, formaldehyde, benzpyrene, and a negative ion, which is a useful component, was also confirmed as pollutants. The removal rate was confirmed for the particulate matter.

As a result, comparing the pollutant concentration before passing through the container (reactor) 10 with the pollutant concentration after passing through the container (reactor) 10, nitrogen dioxide, ozone,
It was confirmed that formaldehyde, benzpyrene, and particulate matter were reliably removed, and that negative ions were increased.

[0032]

[Table 1]

The present invention is not limited to the above embodiment, and the following means can be taken to prolong the residence time of the room air taken into the container 10, for example. is there.

A large number of fins are provided on the inner wall surface of the container 10,
Create a stream of bubbles to increase the residence time of air. Attach a rotary blade in the container 10 to create a flow of bubbles,
Increase air retention time.

In order to prevent the photosynthetic microorganisms from adhering to the inner wall surface of the container 10, the inner wall surface of the container 10 is coated with Teflon. When microorganisms adhere to the inner wall surface of the container 10, the photosynthetic microorganisms adhered to the inner wall surface of the container 10 are separated by ultrasonic waves.

Furthermore, although the case where a fluorescent lamp is used as the light source 30 has been described, the sunlight may be carried by an optical fiber. In addition, it is desirable to monitor the degree of growth of photosynthetic microorganisms with a turbidimeter or the like, and to perform feedback concentration control such as withdrawing with a pump when they grow.

[0037]

As described above, according to the present invention, indoor air is sent to a container containing a photosynthetic microorganism such as chlorella, and carbon dioxide and harmful components in the air are removed by photosynthesis of the photosynthetic microorganism to remove oxygen. Useful components such as can be generated to improve the air in the room.

Further, according to the present invention, since carbon dioxide and harmful components in the indoor air are removed by photosynthesis by photosynthetic microorganisms, maintenance of filters and the like as in conventional purification methods using filters is performed. It can be operated continuously without the need.

Further, since the exhaust gas can be returned to the room as purified air, the exhaust gas is not released into the environment unlike the conventional purification method. Furthermore, since it is a photosynthetic reaction that uses light energy, solar energy can be used.

[Brief description of drawings]

FIG. 1 is an explanatory view showing an embodiment of a method for purifying indoor air and a device therefor according to claims 1 and 4.

[Explanation of symbols]

 10 Container 11 Air diffuser attachment part 12 Purified air discharge part 20 Culture solution 22 Photosynthetic microorganism 30 Light source 40 Air diffuser 50 Indoor air intake member 51 Tube 52 Air pump or blower 53 Indoor air intake

Claims (7)

[Claims] 1. A container is filled with a culture solution and a photosynthetic microorganism, and while supplying light energy to the photosynthetic microorganism, indoor air is taken into the container in an aerated state, and carbon dioxide in the air is replaced by oxygen by photosynthesis. A method for purifying indoor air, which comprises removing harmful substances in the air and returning the purified air to the room. 2. The method for purifying indoor air according to claim 1, wherein the culture solution is water, seawater, or artificial seawater. 3. The method for purifying indoor air according to claim 1, wherein the photosynthetic microorganism is chlorella. 4. A container filled with a culture solution and a photosynthetic microorganism, a light source for giving light energy to the photosynthetic microorganism, an air diffuser attached to the container, an indoor air intake member communicating with the air diffuser, and the container are provided. An indoor air purification device comprising: a purified air discharge part. 5. The room air purifying apparatus according to claim 4, wherein the container is made of a transparent material. 6. The room air purifying apparatus according to claim 4, wherein the light source is provided on the outer circumference or inside of the container made of a transparent material. 7. The apparatus for purifying indoor air according to claim 5, wherein the indoor air intake member is composed of an air pump or a blower and a pipe.