JP2020065945A - Carbon dioxide removal device - Google Patents

Abstract

To provide a carbon dioxide removal device which can easily remove carbon dioxide in a closed space.SOLUTION: A carbon dioxide removal device 10 for use in a closed space 20 has: an absorbent holding part for holding a carbon dioxide absorbent; and air flow generating means which generates air flow and brings air in the closed space 20 into contact with the adsorbent holding part. The air flow generating means may be so configured as to suck air in the closed space 20 and bring air in the closed space 20 into contact with the adsorbent holding part. In addition, for example, the air flow generating means may be so configured as to deliver air in the closed space 20 and bring air in the closed space 20 into contact with the adsorbent holding part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a carbon dioxide removing device.

In recent years, various technologies have been proposed, and automobiles, oxygen capsules, shelters, and the like have been provided with higher functionality and at lower cost.
However, in a narrowly sealed space represented by an automobile, an oxygen capsule, a shelter, etc., a person spends a certain period of time, so that there is a problem that carbon dioxide concentration in the space becomes high due to carbon dioxide contained in exhaled breath. Therefore, conventionally, it is a problem to reduce the increased carbon dioxide concentration in the closed space.

As a method of removing carbon dioxide in the space, for example, ventilation can be mentioned.
However, when ventilating in a closed space, there are the following problems, for example.
In the case of a car, if the outside air is taken in when the air conditioner is turned on in summer or winter, the temperature control inside the car is disturbed. Further, when the air outside the vehicle such as a tunnel is polluted, the air inside the vehicle is polluted when the outside air is taken in.

  In the oxygen capsule, generally, outside air is sent into the oxygen capsule by a compressor or pump provided outside to raise the internal air pressure. At the stage of raising the atmospheric pressure, the amount of air that takes in outside air exceeds the amount of air that is discharged, so the atmospheric pressure rises. After reaching the target atmospheric pressure, the target atmospheric pressure is maintained by adjusting the intake air amount and the exhausted air amount to the same amount. If ventilation is performed for the purpose of lowering the carbon dioxide concentration in such a state, the air pressure inside the oxygen capsule will drop.

In addition, when the internal air pressure is increased, it is pushed back to the internal pressure, so that the amount of air taken in decreases. Therefore, it is difficult to decrease the carbon dioxide concentration by increasing the amount of air discharged from the inside while keeping the internal air pressure high. In addition, when the carbon dioxide concentration is lowered without increasing the amount of air to be discharged, it takes much time. When the process is carried out in a short time without taking time, it is necessary to increase the capacity of the compressor or the pump, but there is a problem that the compressor or the pump becomes large and the cost becomes high.
The same applies to the oxygen capsules described above, even for shelters, especially those with a positive pressure inside.

  For these reasons, it is difficult to reduce the carbon dioxide concentration by ventilation in a closed space such as an automobile, an oxygen capsule, and a shelter. High concentrations of carbon dioxide affect the human body and can cause life-threatening symptoms such as discomfort, drowsiness, lack of attention, irritability, headache, stiff shoulders, dyspnea and loss of consciousness. Especially, dozing driving in a car is very dangerous.

On the other hand, for example, Patent Document 1 describes a method of adsorbing carbon dioxide by bringing an adsorbent manufactured by a method of manufacturing an adsorbent used for removing carbon dioxide into contact with a gas to be treated. . Further, there is described an air conditioner in which a flow path is connected to a space to be air-conditioned, and a removal section in which an adsorbent is arranged is arranged in the flow path.
However, in Patent Document 1, it is necessary to prepare and install a flow path, a valve, an exhaust fan, and the like, which is very troublesome. In addition, since these flow paths, valves, exhaust fans, and removal parts are fixedly installed, it is difficult to cope with changes in specifications, and the places of use are also fixed. Further, since the removing unit is located outside the air-conditioned space, there is the inconvenience that the filter cannot be replaced unless it goes out of the space.

Japanese Patent Laid-Open No. 2018-65069

  In view of the above problems, an object of the present invention is to provide a carbon dioxide removing device that can easily remove carbon dioxide in a closed space.

  In order to solve the above-mentioned problems, the present invention is a carbon dioxide removing device used in a closed space, wherein an adsorbent holding part for holding a carbon dioxide adsorbent and a flow of air are generated, and in the closed space. Air flow generating means for bringing the air of (1) into contact with the adsorbent holding part.

  According to the present invention, carbon dioxide in a closed space can be easily removed.

It is a schematic diagram for demonstrating the example of arrangement | positioning of the carbon dioxide removal apparatus in a closed space. It is a schematic diagram for explaining an example of an air flow generation means. It is a schematic diagram for demonstrating the other example of an air flow generation means. It is a schematic diagram for demonstrating an example of a door sensor. It is a schematic diagram for explaining an example of a CO ₂ sensor. It is a schematic diagram for explaining another example of CO ₂ sensor.

  Hereinafter, a carbon dioxide removing device according to the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments described below, and other embodiments, additions, modifications, deletions and the like can be modified within the scope that those skilled in the art can contemplate, and any mode Also in the above, as long as the action and effect of the present invention are exhibited, it is included in the scope of the present invention.

  The present invention is a carbon dioxide removing device for use in a closed space, wherein an adsorbent holding part for holding a carbon dioxide adsorbent and an air flow are generated, and the air in the closed space is adsorbed by the adsorbent holding part. And an air flow generating means for contacting the. According to the present invention, carbon dioxide in a closed space can be easily removed. Further, according to the present invention, carbon dioxide in the closed space can be efficiently removed.

A schematic diagram for explaining the present embodiment is shown in FIG.
In FIG. 1, the carbon dioxide removing device 10 is installed inside a room 22 which is a closed space, and the reference numeral 20 indicates that it is inside the closed space.

The carbon dioxide removing device 10 has an air flow generating means (not shown in FIG. 1).
The airflow generating means generates a flow of air to bring the air in the closed space into contact with the adsorbent holding portion. Examples of the air flow generating means include a suction means and a blowing means.

  Although not shown in FIG. 1, the carbon dioxide removing device 10 is provided with an inlet for taking in air in the closed space and an outlet for sending out air from which carbon dioxide has been removed. The sizes and positions of the inlet and the outlet are not particularly limited, and can be changed as appropriate.

  The closed space in the present embodiment means that the amount of movement of air with the outside is less than or equal to a predetermined value, and when there is a human or animal, a device for generating carbon dioxide, etc., naturally. A space where carbon dioxide concentration rises. Note that the present invention also includes the case where a door, a ventilating port that can be opened and closed, and the like are provided.

Next, an example of the air flow generating means will be described. FIG. 2 shows a schematic diagram for explaining this example.
In FIG. 2, the inside of the carbon dioxide removing device 10a installed in the closed space 20 is schematically shown, and the cartridge 12 (adsorbent holding portion) and the suction means 14 (airflow generating means) are shown. The arrow (A) schematically shows the flow of air generated by the suction means 14.

  In the present embodiment, the suction means 14 is used as the air flow generation means, and the suction means 14 sucks the air in the closed space and brings the air in the closed space into contact with the cartridge 12. The suction means 14 is arranged downstream of the cartridge 12 in the direction of air flow (arrow (A)).

  In the present embodiment, by operating the suction means 14, the air in the closed space flows into the carbon dioxide removing device 10a and comes into contact with the carbon dioxide adsorbent filled in the cartridge 12. Then, it passes through the suction means 14 and is discharged into the closed space. As a result, carbon dioxide in the air in the closed space can be removed, and the carbon dioxide concentration in the closed space can be reduced.

  As the suction means 14, for example, a pump, a fan, a compressor or the like can be used. As the pump, fan, and compressor, commercially available products may be used, or commercially available products may be modified.

  Further, by operating the suction means 14, the air in the closed space is taken into the carbon dioxide removing device 10a, passes through the cartridge 12 and the suction means 14, and the air from which carbon dioxide has been removed is discharged. By taking in and discharging the air, the air in the closed space can be circulated and agitated, and the deviation of the carbon dioxide concentration in the closed space can be reduced.

  For example, in the case of a narrow space such as an oxygen capsule, carbon dioxide is likely to accumulate near the user's face inside the space, and the concentration tends to be biased. Particularly, the density is high near the face and tends to be low near the foot. Therefore, as described above, it is possible to obtain the effect that the uneven distribution of the carbon dioxide concentration in the closed space can be reduced by taking in and discharging the air.

  For the purpose of reducing the bias of carbon dioxide concentration in the closed space, a fan or the like may be provided separately from the carbon dioxide removing device to stir the air in the closed space.

Next, another example of the airflow generating means will be described. FIG. 3 shows a schematic diagram for explaining this example.
Similar to FIG. 2, FIG. 3 schematically shows the inside of the carbon dioxide removing device 10b installed in the closed space 20, and includes the cartridge 12 (adsorbent holding portion) and the blowing means 16 (airflow generating means). Is shown. The arrow (A) schematically shows the flow of air generated by the blowing unit 16.

  In the present embodiment, the air blowing means 16 is used as the air flow generating means, and the air blowing means 16 sends out the air in the closed space to bring the air in the closed space into contact with the cartridge 12. The blower 16 is arranged upstream of the cartridge 12 in the direction of air flow (arrow (A)).

  In this embodiment, by operating the air blowing means 16, the air in the closed space flows into the carbon dioxide removing device 10b and passes through the air blowing means 16. The air that has passed through the blowing unit 16 comes into contact with the carbon dioxide adsorbent filled in the cartridge 12 and then is released into the closed space. As a result, carbon dioxide in the air in the closed space can be removed, and the carbon dioxide concentration in the closed space can be reduced.

  As the blower means 16, for example, a pump, a fan, a compressor or the like can be used. As the pump, fan, and compressor, commercially available products may be used, or commercially available products may be modified.

The carbon dioxide adsorbent used in the present embodiment is not particularly limited and can be appropriately changed. Examples include soda lime and zeolite.
As the carbon dioxide adsorbent, an adsorbent that utilizes a neutralization reaction with carbon dioxide represented by soda lime can be appropriately used. For example, the following chemical reactions are included.
CO ₂ + Ca (OH) ₂ → CaCO ₃ + H ₂ O
CO ₂ + 2NaOH → Na ₂ CO ₃ + H ₂ O
CO ₂ + 2KOH → K ₂ CO ₃ + H ₂ O

Zeolite is used as a molecular sieve utilizing the pores of the material itself, and among them, zeolite 13X is preferably used.
In addition to the above, Yabashi lime manufactured by Yabashi Kogyo Co., Ltd. and lysolime manufactured by Allied Healthcare Co., Ltd. may be used.

  As the carbon dioxide adsorbent, it is preferable that the color changes depending on the amount of adsorbed carbon dioxide, and the change in color can be discriminated from the outside of the carbon dioxide removing device. As a result, the carbon dioxide adsorbent can be discarded and replaced at an appropriate timing, and it is possible to prevent the carbon dioxide adsorbent having a reduced adsorption effect from being continuously used.

As such a carbon dioxide adsorbent, for example, one having a property of changing color after a chemical reaction such as soda lime can be mentioned.
Further, for example, by making a part of the carbon dioxide removing device a transparent member, it is possible to make a structure in which the color change of the carbon dioxide adsorbent can be visually observed from the outside of the device.

The cartridge 12 is only required to be able to hold the carbon dioxide adsorbent, and may be appropriately changed in shape in order to efficiently remove carbon dioxide.
The amount of the carbon dioxide adsorbent held in the cartridge 12 can be changed as appropriate because it depends on the type of adsorbent, the consumption time, the shape of the cartridge, and the like.
Further, a filter for removing particles (for example, a HEPA filter or a ULPA filter for collecting fine particles) may be added to the cartridge. These filters may be provided separately from the cartridge.

  Further, in order to increase the adsorption efficiency of the adsorbent, a PSA method (Pressure Swing Adsorption) in which the pressure inside the cartridge is repeatedly raised and lowered may be adopted.

The cartridge 12 is preferably removable from the carbon dioxide removing device 10. Since the cartridge 12 is removable, the carbon dioxide adsorbent can be easily discarded or replaced. Further, it is only necessary to prepare the replacement of the cartridge in the space, and it is possible to replace the cartridge without leaving the closed space.
When exchanging the carbon dioxide adsorbent, the carbon dioxide adsorbent filled in the cartridge 12 may be exchanged, or the cartridge 12 itself may be exchanged.

The scale of the carbon dioxide removing device 10 shown in FIG. 1 does not necessarily represent an actual scale, and the size and weight of the carbon dioxide removing device 10 can be appropriately changed.
Further, the carbon dioxide removing device 10 of the present embodiment is preferably portable, and it is preferable that the installation place can be changed in the closed space. For example, it is preferable that the carbon dioxide removing device 10 has a size and weight that can be carried by human hands. By changing the installation location in the closed space, there are advantages that the layout in the space can be dealt with, and if there is a place where carbon dioxide is likely to accumulate, it can be dealt with appropriately.

  Further, since it is portable, it is possible to move the carbon dioxide removing device used in the shelter and use it in an automobile, for example. Therefore, the user does not need to prepare the device for each place of use, and the device can be reused, which is advantageous in terms of cost.

In order to obtain such a size and weight, for example, the arrangement of members in the carbon dioxide removing device 10 may be changed appropriately. For example, the device can be downsized by bringing the airflow generating means and the adsorbent holding portion into close contact with each other. Further, the size and weight of the carbon dioxide removing device 10 can be adjusted by appropriately changing the air flow generating means.
Since the flow path through which the air in the closed space flows is not required inside the carbon dioxide removing device of this embodiment, the device can be made compact.

The place where the carbon dioxide removing device of the present invention is used is not particularly limited as long as it is a closed space, and examples thereof include a room where people and animals come in and out, an automobile, an oxygen capsule, a shelter, and the like.
In the case of a car, since it is related to air conditioning, it is possible to improve fuel efficiency as compared with the case of taking in outside air. Further, even in the positive pressure chamber, since it is not necessary to increase the capacity of the compressor, the equipment can be kept compact as it is and the cost can be suppressed.
In addition, not only humans but also animals may stay in the closed space, and in addition to these, a device for generating carbon dioxide may be installed.

  Thus, according to the present embodiment, carbon dioxide in the closed space can be easily removed. Further, there is an excellent effect that the replacement of the cartridge, the operation and the maintenance of the apparatus can be performed in the closed space.

Next, another embodiment of the carbon dioxide removing apparatus according to the present invention will be described. Descriptions of matters common to the above embodiment will be omitted.
FIG. 4 shows a diagram for schematically explaining the present embodiment. FIG. 4 shows an example in which a carbon dioxide removing device is installed inside the shelter, and the carbon dioxide removing device 10c, the shelter main body 23, the door 24, the door sensor 26, and the compressor 28 are shown.

  The compressor 28 is an example of a pressurizing unit or a positive pressure applying unit, and is used to raise the pressure (atmospheric pressure) in the closed space and maintain the atmospheric pressure in the closed space at a predetermined value. To raise the air pressure in the closed space using the compressor 28, for example, outside air is sent into the closed space.

  As in the present embodiment, a state in which the internal atmospheric pressure is higher than the external atmospheric pressure is called positive pressure, and the shelter in the positive pressure state is also called positive pressure shelter. In addition, a space having a positive pressure inside is also referred to as a positive pressure chamber or the like. Although the inside of the closed space is shown by the reference numeral 20 as in the above-described embodiment, the inside may be positive pressure in the above-described embodiment.

  The positive pressure can prevent air outside the shelter from entering the inside. For example, when the air outside the shelter is contaminated, the contaminated air can be prevented from entering the shelter. In this case, it is preferable to use a contaminant removing member such as a filter for the compressor 28.

  The compressor 28 can also be used in an oxygen capsule or the like, and by blowing outside air into the closed space, the internal air pressure can be raised and the amount of oxygen in the closed space can be increased.

  Further, a detecting unit such as a sensor for detecting the atmospheric pressure in the closed space may be provided to control the operation of the compressor 28 according to the state of the atmospheric pressure detected by the detecting unit. In this case, unnecessary driving can be prevented.

Here, a case will be described in which ventilation is performed to reduce the carbon dioxide concentration in the positive pressure chamber without using the carbon dioxide removing device of the present invention.
First, in order to achieve the target atmospheric pressure in the room, air is blown (pressurized) by the compressor so that the amount of air taken in exceeds the amount of air discharged, and the atmospheric pressure in the room is raised. After reaching the target atmospheric pressure, the target atmospheric pressure is maintained by adjusting the intake air amount and the exhaust air amount to the same amount. If ventilation is performed in order to reduce the carbon dioxide concentration in such a state, the amount of air discharged exceeds the amount of air taken in, and the atmospheric pressure in the room falls.

  Further, when the internal atmospheric pressure is increased, the internal pressure is pushed back, so that the amount of air taken in at a high atmospheric pressure decreases compared to when the atmospheric pressure is low. Therefore, it is difficult to decrease the carbon dioxide concentration by increasing the amount of air discharged from the inside while keeping the internal air pressure high. Further, if the carbon dioxide concentration is lowered without increasing the amount of air to be discharged, the increase of carbon dioxide due to breathing from the internal user continues, so that it takes much time even if possible. If it is done in a short time without taking time, it is necessary to increase the capacity of the compressor or pump because there is no choice but to increase the emission amount, but problems such as the size of the compressor or pump becoming large and the cost becoming high will occur. .

According to the guidelines announced in the Ministry of Health, Labor and Welfare Construction Hygiene Management Study Group, the ventilation volume per person is required to be 30 m ³ per hour in order to keep the carbon dioxide concentration in the internal environment proper. When complying with this, for example, in the case of a capsule type for one person, a compressor of 500 liters or more per minute is required when the target atmospheric pressure is achieved. In addition to this, a room type for 2 people is 1000 liters per minute or more when the target air pressure is achieved. A room type for 4 people is 2000 liters or more per minute when the target air pressure is achieved. More than 4000 liters per minute compressor is required.

  Further, generally, an adult's breathing volume is about 500 ml per breathing, and since it breathes 10 to 20 times per minute, it is less than 10 liters per minute. Therefore, in order to maintain the indoor air pressure at the target atmospheric pressure, it is sufficient to secure an inflow rate of 10 liters per minute per person, but when performing ventilation to reduce the carbon dioxide concentration in the positive pressure room, Since a large inflow amount (for example, 500 liters per minute or more) is required, a large capacity compressor having a high capacity is required.

On the other hand, according to the carbon dioxide removal device of the present embodiment, since it is possible to remove the carbon dioxide in the room without ventilating the positive pressure chamber, a compressor having a high ability to maintain the target atmospheric pressure. There is no need to use a large compressor. Therefore, the carbon dioxide concentration can be reduced without increasing the capacity of the compressor (without increasing the displacement). Further, since it is only necessary to use a compressor capable of securing an inflow rate of 10 liters per minute per person, it is possible to reduce costs, and it is not necessary to use a large compressor, which leads to space saving.
As described above, the carbon dioxide removing device of the present invention can be particularly preferably used in the positive pressure chamber where the pressure is higher than the outside of the space.

  Further, the closed space in the present embodiment is provided with a door sensor 26 (opening / closing detection means) that detects opening / closing of the door 24, and the carbon dioxide removal device 10c receives the opening / closing detection result from the door sensor 26 and opens / closes the detection result. It has a control means 11 for controlling the air flow generation means in accordance with the above.

The door sensor 26 is not particularly limited and may be appropriately changed. For example, a commercially available product may be used. The position to be arranged is not limited to the position shown in FIG. 4 and can be changed as appropriate.
Further, the door sensor 26 and the carbon dioxide removing device 10c may be wired or wirelessly communicated with each other.

  How the control means 11 controls the air flow generating means can be appropriately changed. For example, when the door 24 is closed, the air flow generating means is operated, and when the door 24 is open, the air flow generating means. To stop. In addition to this, for example, when the door 24 is opened for a predetermined time, it is assumed that the carbon dioxide concentration in the interior is sufficiently lowered, and the door 24 does not operate for a predetermined time after the door 24 is closed. Control such as operating the generating means may be performed.

Generally, when the door 24 of the shelter is open, it does not form a closed space, and the carbon dioxide concentration does not rise easily. Therefore, even if the carbon dioxide removing device 10 is operated when the door 24 is open, the effect of removing carbon dioxide becomes small.
On the other hand, by controlling the carbon dioxide removing device 10 in conjunction with the opening and closing of the door 24 as in the present embodiment, useless operation can be suppressed and the internal carbon dioxide concentration can be lowered more efficiently. You can

  In the present embodiment, the operation or stop of the air flow generation means is described as the operation or stop of the carbon dioxide removal device 10.

  In addition to the above, the control unit 11 may operate or stop the carbon dioxide removing device in conjunction with the operation or stop of the pressurizing unit or the positive pressure applying unit used for the positive pressure chamber or the oxygen capsule. For example, the carbon dioxide removing device may be operated at the timing when the pressurizing means is operated, and the carbon dioxide removing device may be stopped at the timing when the pressurizing means is stopped.

  Further, the carbon dioxide removing device may be operated when the pressurizing means is operated with the door 24 closed. In such a situation, the carbon dioxide removing device may be stopped when the door 24 is opened or when the pressurizing means is stopped. When the device operates and stops only by opening and closing the door, it operates even when no one is present. Therefore, with the above configuration, this can be prevented.

Next, another embodiment of the carbon dioxide removing apparatus according to the present invention will be described. Descriptions of matters common to the above embodiment will be omitted.
In this embodiment, a carbon dioxide concentration detecting means for detecting the carbon dioxide concentration in the closed space is provided in the closed space. Further, the carbon dioxide removal device has a control means for receiving the concentration detection result from the carbon dioxide concentration detection means and controlling the air flow generation means according to the concentration detection result.

A schematic diagram for explaining this embodiment is shown in FIG. In FIG. 5, a carbon dioxide removing device 10d, a control unit 11, a CO ₂ sensor 18 (carbon dioxide concentration detecting unit), and a cable 19 are shown.

In FIG. 5, an example in which the carbon dioxide removing device 10d and the CO ₂ monitor 18 are connected by the cable 19 is shown, but the invention is not limited to a wired connection and may be a wireless connection.

The CO ₂ sensor 18 only needs to be able to detect the carbon dioxide concentration, and for example, a commercially available product may be used. Further, the detected carbon dioxide concentration value may be displayed.

Since carbon dioxide is tasteless and odorless, the increase in concentration is usually not noticed. Therefore, it may happen that the concentration increases to a level at which the human body is affected without noticing it.
Therefore, as in the present embodiment, by interlocking the CO ₂ sensor 18 and the carbon dioxide removal device 10d, it is possible to automatically operate the carbon dioxide removal device 10d when the concentration reaches an arbitrarily determined concentration. , Can reduce the carbon dioxide concentration in the space before it affects the human body.

Further, by interlocking the CO ₂ sensor 18 and the carbon dioxide removing device 10d, it is possible to automatically stop when the concentration falls below an arbitrarily determined concentration. In this case, unnecessary driving can be prevented.

In the case where the CO ₂ sensor 18 is not linked, for example, the carbon dioxide removing device may be regularly operated at an arbitrary interval, or of course, may be manually operated or stopped.

Here, in the above-described embodiment, the same reference numeral as the control means 11 that controls the airflow generating means in conjunction with the door sensor 26 is shown, but when the CO ₂ sensor 18 and the door sensor 26 are used together, The control means in 1) and the control means in this embodiment may be integrated, or may be configured separately.

Next, another embodiment of the carbon dioxide removing apparatus according to the present invention will be described. Descriptions of matters common to the above embodiment will be omitted.
The carbon dioxide removal device of the present embodiment receives a concentration detection result from the carbon dioxide concentration detection means for detecting the carbon dioxide concentration in the closed space and the carbon dioxide concentration detection means, and controls the air flow generation means according to the concentration detection result. And a control means for
In the above embodiment, the carbon dioxide concentration detecting means is provided outside the carbon dioxide removing device, but in the present embodiment, it is provided inside the carbon dioxide removing device.

FIG. 6 shows a schematic diagram for explaining the present embodiment. In FIG. 6, the carbon dioxide removal device 10e, the control means 11, and the CO ₂ sensor 18 (carbon dioxide concentration detection means) are shown. In the example shown here, the control means 11 and the CO ₂ sensor 18 are connected, and the concentration detection result detected by the carbon dioxide concentration detection means is exchanged.
By interlocking the CO ₂ sensor 18 and the carbon dioxide removing device 10e, the same effect as that of the example shown in FIG. 5 can be obtained.

When the present embodiment is applied to the carbon dioxide removing device shown in FIGS. 2 and 3, it is preferable to arrange the CO ₂ sensor 18 on the upstream side of the cartridge 12.

  As described above, although some embodiments have been described as examples, they are not independent of each other, and may be appropriately combined to form the carbon dioxide removing device of the present invention.

  Hereinafter, the present invention will be described in detail with reference to Examples, but the present invention is not limited to the following Examples.

(Example 1)
A carbon dioxide removing effect was tested by using the carbon dioxide removing apparatus having the configuration shown in FIG.
In this example, a plastic cartridge was filled with 200 g of soda lime manufactured by Fuji Film Wako Pure Chemical Industries, Ltd., and a commercially available pump was modified as the suction means. These were installed in the main body of the carbon dioxide removing device so that electric power could be supplied from a household power supply by a cable.
An oxygen capsule (manufactured by Time World Co., Ltd.) was prepared as a closed space in which the test of this example was conducted. The prepared oxygen capsule has an inside of about 900 m ³ and is equipped with a door. A compressor is provided outside the oxygen capsule, and the air pressure inside the oxygen capsule can be increased to 1.35 atm over 5 minutes to a positive pressure. Next, the tester entered the oxygen capsule and spent about 10 minutes, and as a result, the carbon dioxide concentration inside increased to 9634 ppm in the measuring instrument (Shibata Biotechnology).
Next, the carbon dioxide removing device of this example was installed in an oxygen capsule, and similarly, the tester was operated for 10 minutes in the oxygen capsule. As a result, the carbon dioxide concentration inside the shelter dropped to 5584 ppm.
As described above, the carbon dioxide removal device of this example could easily reduce the carbon dioxide concentration in the closed space.

10 Carbon Dioxide Removal Device 11 Control Means 12 Cartridge 14 Suction Means 16 Blower Means 18 CO ₂ Sensor 19 Cable 20 Sealed Space 22 Room 23 Shelter 24 Door 26 Door Sensor 28 Compressor

In order to solve the above-mentioned problems, the present invention is a carbon dioxide removing device used in a closed space, wherein an adsorbent holding part for holding a carbon dioxide adsorbent, and a flow of air are generated. And an air flow generating means for bringing the air into contact with the adsorbent holding portion, and is portable, and is not fixed to the closed space .

Claims (11)

A carbon dioxide removal device used in a closed space,
An adsorbent holding section for holding a carbon dioxide adsorbent,
A carbon dioxide removing device, comprising: an air flow generating unit that generates an air flow to bring the air in the closed space into contact with the adsorbent holding unit.   The airflow generation means sucks air in the closed space to bring the air in the closed space into contact with the adsorbent holding portion, and is arranged downstream of the adsorbent holding portion in the direction in which the air flows. The carbon dioxide removing device according to claim 1, wherein the carbon dioxide removing device is provided.   The airflow generating means sends out the air in the closed space to bring the air in the closed space into contact with the adsorbent holding portion, and is arranged upstream of the adsorbent holding portion in the direction in which the air flows. The carbon dioxide removal device according to claim 1, wherein   The carbon dioxide removal device according to claim 1, wherein the inside of the closed space has a higher pressure than the outside of the space. A door is provided in the closed space, and an opening / closing detection means for detecting opening / closing of the door is provided,
5. The carbon dioxide removing device further comprises control means for receiving an opening / closing detection result from the opening / closing detection means and controlling the airflow generating means in accordance with the opening / closing detection result. The carbon dioxide removing device according to 1. The closed space is pressurized by a pressure means,
6. The carbon dioxide removing device according to claim 1, further comprising control means for controlling the air flow generating means according to an operating condition of the pressurizing means. In the closed space, a carbon dioxide concentration detecting means for detecting the carbon dioxide concentration in the closed space is provided,
7. The carbon dioxide removing device further comprises control means for receiving a concentration detection result from the carbon dioxide concentration detection means and controlling the air flow generation means according to the concentration detection result. The carbon dioxide removing device according to any one of claims. The carbon dioxide removing device,
Carbon dioxide concentration detection means for detecting the carbon dioxide concentration in the closed space,
The control means which receives the concentration detection result from the said carbon dioxide concentration detection means, and controls the said air flow generation means according to the said concentration detection result, It further has. Carbon dioxide removal device.   The carbon dioxide removing device according to any one of claims 1 to 8, which is portable.   The carbon dioxide removal device according to any one of claims 1 to 9, wherein the adsorbent holding part is removable from the carbon dioxide removal device.   The color of the carbon dioxide adsorbent changes according to the amount of carbon dioxide adsorbed, and the color change can be discriminated from the outside of the carbon dioxide removing device. The carbon dioxide removal device described.