JP2020199434A - Air conditioner - Google Patents

Abstract

To provide an air conditioner which can adsorb carbon dioxide and utilize waste-heat.SOLUTION: An air conditioner 1 used for an air-conditioned space including a processing object gas containing carbon dioxide, includes a first flow passage 2a through which the processing object gas flows, a heat transport mechanism 10 which bi-directionally transports heat between the first flow passage 2a and another place other than the first flow passage 2a, and an adsorption agent 11 which is disposed in the first flow passage 2a, adsorbs the carbon dioxide when coming into contact with the processing object gas, and desorbs the carbon dioxide when heated.SELECTED DRAWING: Figure 1

Description

The present invention relates to an air conditioner.

Carbon dioxide emitted from humans and the like may increase the carbon dioxide concentration in the surrounding atmosphere of humans. It is known that carbon dioxide affects the physical condition of the human body (see, for example, Patent Documents 1 and 2). For example, a sleeping person may not be able to wake up comfortably due to an increase in carbon dioxide concentration in the surrounding atmosphere. In addition, people who are studying or working may become inefficient or drowsy due to an increase in the carbon dioxide concentration in the surrounding atmosphere.

As a solution to such a problem, for example, a method of separating and recovering carbon dioxide using a CO ₂ adsorbent such as zeolite (hereinafter, also simply referred to as “adsorbent”) (CO ₂ separation and recovery method) can be mentioned. (See, for example, Patent Document 3). The adsorbent described in Patent Document 3 adsorbs carbon dioxide by bringing it into contact with a gas, and desorbs carbon dioxide by heating it.

Japanese Unexamined Patent Publication No. 10-230131 JP-A-2015-018517 Japanese Unexamined Patent Publication No. 2000-140549

In order to use such an adsorbent as an air conditioner, carbon dioxide is adsorbed on the adsorbent, the adsorbent is heated to desorb carbon dioxide, and the adsorbent is cooled to adsorb carbon dioxide. It is necessary to return to the state where it can be done.

Therefore, when the air conditioner is installed indoors, how to perform the exhaust heat treatment is important. However, none of the above documents considers the exhaust heat treatment of the air conditioner at all.

Therefore, one aspect of the present invention is to provide an air conditioner capable of adsorbing carbon dioxide and utilizing exhaust heat.

One aspect of the present invention is an air conditioner used in an air conditioner target space containing a treatment target gas containing carbon dioxide, and the first flow path through which the treatment target gas flows is different from the first flow path and the first flow path. A heat transport device that can transport heat in both directions to and from the place, and an adsorbent that is placed in the first flow path and adsorbs carbon dioxide when it comes into contact with the gas to be treated and desorbs carbon dioxide when heated. , Equipped with.

In this air conditioner, since the adsorbent is arranged in the first flow path, carbon dioxide can be adsorbed and removed from the treatment target gas by passing the treatment target gas through the first flow path. Then, a heat transport device capable of bidirectionally transporting heat between the first flow path and a place different from the first flow path is provided. Therefore, by transporting heat from a place different from the first flow path to the first flow path by the heat transport device, the adsorbent is heated through the gas to be processed in the first flow path, and carbon dioxide is converted from the adsorbent. Carbon can be desorbed. On the other hand, by transporting heat from the first flow path to a place different from the first flow path by the heat transport device, the adsorbent is cooled through the gas to be processed in the first flow path, and the adsorbent is carbon dioxide. It can be returned to a state where carbon can be adsorbed. In this way, the exhaust heat of the air conditioner can be utilized by bidirectionally transporting heat between the first flow path and a place different from the first flow path by the heat transport device.

A second flow path through which the gas to be treated flows is further provided, the adsorbent is also arranged in the second flow path, and the heat transport device heats bidirectionally between the first flow path and the second flow path. It may be transportable.

In this air conditioner, an adsorbent is also arranged in the second flow path, and the heat transport device can transport heat in both directions between the first flow path and the second flow path. Therefore, by transporting heat from the second flow path to the first flow path by the heat transport device, the adsorbent is heated through the gas to be processed in the first flow path to remove carbon dioxide from the adsorbent. It can be separated, and in the second flow path, the adsorbent can be cooled through the flowing gas to be processed, and the adsorbent can be returned to a state where carbon dioxide can be adsorbed. On the other hand, by transporting heat from the first flow path to the second flow path by the heat transport device, the adsorbent is cooled through the gas to be processed in the first flow path, and the adsorbent adsorbs carbon dioxide. In the second flow path, the adsorbent can be heated via the circulating gas to be treated to desorb carbon dioxide from the adsorbent. In this way, the exhaust heat of the air conditioner can be utilized by bidirectionally transporting heat between the first flow path and the second flow path by the heat transport device.

The heat transport equipment is located between the first heat exchange section arranged in the first flow path, the second heat exchange section arranged in the second flow path, and the first heat exchange section and the second heat exchange section. It may have a heat transport unit capable of transporting heat in both directions. In this air conditioner, heat is transferred between the first heat exchange unit arranged in the first flow path and the second heat exchange part arranged in the second flow path, so that the air conditioner is arranged in the first flow path. The adsorbent and the adsorbent arranged in the second flow path can be suitably heated or cooled.

The first supply port and the second supply port to which the treatment target gas is supplied, the first discharge port and the second discharge port to which the treatment target gas is discharged, the first supply port, the second supply port, the first flow path, and the like. A first-choice communication device that selectively communicates with the second flow path, and a second-selection communication device that selectively communicates between the first discharge port and the second discharge port and the first flow path and the second flow path. May be further provided. In this air conditioner, the first supply port and the second supply port are selectively communicated with the first flow path and the second flow path by the first selection communication device, and the first discharge port and the second flow path are communicated by the second selection communication device. The second discharge port and the first flow path and the second flow path are selectively communicated with each other. That is, the supply port and the discharge port for lowering the carbon dioxide concentration by adsorbing carbon dioxide and the supply port for discharging the desorbed carbon dioxide by the first-choice communication device and the second-choice communication device. And the discharge port can be switched. Therefore, for example, the carbon dioxide concentration can be locally reduced by adjusting the directions of the first supply port and the first discharge port and the second supply port and the second discharge port.

A first gas transport device for circulating the gas to be processed in the first flow path and a second gas transport device for circulating the gas to be treated in the second flow path may be further provided. By providing the first gas transport device and the second gas transport device in this air conditioner, the gas to be processed can be forcibly circulated to the first flow path and the second flow path.

The heat transport device may include a Peltier element. In this air conditioner, since the heat transport device includes the Peltier element, the direction of heat transport by the heat transport device can be easily reversed by changing the direction of the current flowing through the Peltier element. Moreover, since the Peltier element can transport heat only by passing an electric current, it is excellent in quietness. Therefore, for example, it can be suitably used in a space such as a bedroom where quietness is required.

The heat transport equipment may include heat pipes. In this air conditioner, since the heat transport device includes a heat pipe, the heat transport direction by the heat transport device can be changed by changing the circulation direction of the working medium in the heat cycle of evaporation, compression, condensation, and expansion of the heat pipe. It can be easily inverted.

The adsorbent may include cerium oxide. Compared with other adsorbents, cerium oxide has excellent adsorptivity to carbon dioxide (CO ₂ adsorbability) when the carbon dioxide concentration is 1000 ppm or less, especially in a dry state where the gas to be treated does not contain water components. ) Tends to have. The tendency to have excellent adsorptivity to carbon dioxide (CO ₂ adsorbability) is particularly remarkable when the gas to be treated is in a moist state containing water components, and the concentration which is superior to other adsorbents is 1000 ppm. That is all. Therefore, this air conditioner tends to be excellent in carbon dioxide removal efficiency when used in a treatment target space containing a treatment target gas having such a carbon dioxide concentration. Further, the cerium oxide has excellent CO ₂ adsorbability as compared with other adsorbents, even when the gas to be treated contains water as described above. Therefore, a dehumidifying device is not required, and CO ₂ can be removed more efficiently.

According to one aspect of the present invention, carbon dioxide can be adsorbed and exhaust heat can be utilized.

It is a schematic diagram which shows the air conditioner of 1st Embodiment. It is a schematic diagram which shows the heat transport equipment including a Peltier element. It is a schematic diagram which shows the heat transport equipment including a Peltier element. It is a schematic diagram which shows the heat transport equipment including a heat pipe. It is a schematic diagram which shows the heat transport equipment including a heat pipe. It is a schematic diagram which shows the operation example of the air conditioner of 1st Embodiment. It is a schematic diagram which shows the operation example of the air conditioner of 1st Embodiment. It is a schematic diagram which shows the air conditioner of 2nd Embodiment.

Hereinafter, embodiments for carrying out the present invention will be described in detail. However, the present invention is not limited to the following embodiments.

[First Embodiment]
The air conditioner of the present embodiment is an air conditioner used in an air conditioner target space containing a process target gas containing carbon dioxide (CO ₂ ). That is, this air conditioner is used to remove carbon dioxide from at least a part of the air-conditioned space by adsorbing carbon dioxide.

[Configuration of air conditioner]
The air conditioner 1 shown in FIG. 1 includes a first pipe 2, a second pipe 3, a first supply pipe 4, a second supply pipe 5, a first discharge pipe 6, a second discharge pipe 7, and a first pipe. It includes a one-choice communication device 8, a second-choice communication device 9, a heat transport device 10, an adsorbent 11, an adsorbent 12, a first gas transport device 13, and a second gas transport device 14.

The first pipe 2 forms a first flow path 2a through which the gas to be treated flows. The second pipe 3 forms a second flow path 3a through which the gas to be treated flows. The first flow path 2a and the second flow path 2b are different flow paths and are not communicated with each other.

The first pipe 2 and the second pipe 3 may have any pipe shape. For example, the first tube 2 and the second tube 3 may be formed in a circular tubular shape or may be formed in a rectangular tubular shape. Further, the first pipe 2 and the second pipe 3 may extend in a straight line, may be curved and extend, or may be bent and extended. Further, the first pipe 2 and the second pipe 3 may be formed in the same shape or may be formed in different shapes. Further, the first pipe 2 and the second pipe 3 may be deformable pipes or non-deformable pipes. When the first pipe 2 and the second pipe 3 are deformable pipes, the first pipe 2 and the second pipe 3 may be formed in a bellows shape, for example, and are formed of an elastically deformable soft resin. You may be.

The first supply pipe 4 forms a flow path 4a through which the gas to be treated flows, and a first supply port 4b to which the gas to be treated is supplied at the tip thereof. The second supply pipe 5 forms a flow path 5a through which the gas to be processed flows, and a second supply port 5b to which the gas to be processed is supplied at the tip thereof. Therefore, the gas to be processed is supplied to the first supply pipe 4 and the second supply pipe 5 from the direction in which the first supply port 4b and the second supply port 5b are directed. The flow path 4a and the flow path 5a are different flow paths and are not communicated with each other.

The first supply pipe 4 and the second supply pipe 5 may have any pipe shape. For example, the first supply pipe 4 and the second supply pipe 5 may be formed in a circular tubular shape or may be formed in a rectangular tubular shape. Further, the first supply pipe 4 and the second supply pipe 5 may extend linearly, may be curved and extend, or may be bent and extended. Further, the first supply pipe 4 and the second supply pipe 5 may be formed in the same shape or may be formed in different shapes. Further, the first supply pipe 4 and the second supply pipe 5 may be deformable pipes or non-deformable pipes. When the first supply pipe 4 and the second supply pipe 5 are deformable pipes, the first supply pipe 4 and the second supply pipe 5 may be formed in a bellows shape, for example, and are elastically deformable and soft. It may be formed of a resin.

The first discharge pipe 6 forms a flow path 6a through which the gas to be treated flows, and a first discharge port 6b from which the gas to be treated is discharged is formed at the tip thereof. The second discharge pipe 7 forms a flow path 7a through which the gas to be treated flows, and a second discharge port 7b from which the gas to be treated goes out is formed at the tip thereof. Therefore, the gas to be treated is discharged from the first discharge pipe 6 and the second discharge pipe 7 in the direction in which the first discharge port 6b and the second discharge port 7b are directed. The flow path 6a and the flow path 7a are different flow paths and are not communicated with each other.

The first discharge pipe 6 and the second discharge pipe 7 may have any pipe shape. For example, the first discharge pipe 6 and the second discharge pipe 7 may be formed in a circular tubular shape or may be formed in a rectangular tubular shape. Further, the first discharge pipe 6 and the second discharge pipe 7 may extend linearly, may be curved and extend, or may be bent and extended. Further, the first discharge pipe 6 and the second discharge pipe 7 may be formed in the same shape or may be formed in different shapes. Further, the first discharge pipe 6 and the second discharge pipe 7 may be deformable pipes or non-deformable pipes. When the first discharge pipe 6 and the second discharge pipe 7 are deformable pipes, the first discharge pipe 6 and the second discharge pipe 7 may be formed in a bellows shape, for example, and are elastically deformable and soft. It may be formed of a resin.

The first selection communication device 8 includes a flow path 4a (first supply port 4b) of the first supply pipe 4, a flow path 5a (second supply port 5b) of the second supply pipe 5, and a first flow path of the first pipe 2. 2a and the second flow path 3a of the second pipe 3 are selectively communicated with each other. That is, the first selection communication device 8 communicates the flow path 4a (first supply port 4b) of the first supply pipe 4 with the first flow path 2a of the first pipe 2, and also communicates with the flow path of the second supply pipe 5. The first state in which 5a (second supply port 5b) and the second flow path 3a of the second pipe 3 communicate with each other, and the flow path 4a (first supply port 4b) of the first supply pipe 4 and the second pipe 3 Selectively select a second state in which the second flow path 3a is communicated with the second flow path 5a (second supply port 5b) of the second supply pipe 5 and the first flow path 2a of the first pipe 2 is communicated with each other. Switch. In such a selective switching, for example, the rotatable member is formed with the communication passage for the first state and the communication passage for the second state so as not to be communicated with each other, and the member is formed. It can be realized by rotating it.

The second selective communication device 9 includes a flow path 6a (first discharge port 6b) of the first discharge pipe 6, a flow path 7a (second discharge port 7b) of the second discharge pipe 7, and a first flow path of the first pipe 2. 2a and the second flow path 3a of the second pipe 3 are selectively communicated with each other. That is, the second selective communication device 9 communicates the flow path 6a (first discharge port 6b) of the first discharge pipe 6 with the first flow path 2a of the first pipe 2, and also communicates with the flow path of the second discharge pipe 7. The third state in which the 7a (second discharge port 7b) and the second flow path 3a of the second pipe 3 communicate with each other, and the flow path 6a (first discharge port 6b) of the first discharge pipe 6 and the second pipe 3 Selectively select a fourth state that communicates with the second flow path 3a and also communicates with the flow path 7a (second discharge port 7b) of the second discharge pipe 7 and the first flow path 2a of the first pipe 2. Switch. In such a selective switching, for example, the rotatable member is formed with the communication passage for the third state and the communication passage for the fourth state so as not to be communicated with each other, and the member is formed. It can be realized by rotating it.

The adsorbent 11 is an adsorbent arranged in the first flow path 2a of the first pipe 2. The adsorbent 11 may be arranged in the first flow path 2a by any means. For example, the first flow path 2a may be partitioned by a pair of net-like partition members, and the region partitioned by the pair of partition members may be filled with the adsorbent 11. The adsorbent 12 is an adsorbent arranged in the second flow path 3a of the second pipe 3. The adsorbent 12 may be arranged with respect to the second flow path 3a by any means. For example, the second flow path 3a may be partitioned by a pair of net-like partition members, and the region partitioned by the pair of partition members may be filled with the adsorbent 12.

The adsorbent constituting the adsorbent 11 and the adsorbent 12 has a function of adsorbing carbon dioxide when it comes into contact with the gas to be treated and desorbing the adsorbed carbon dioxide when heated. In this embodiment, the adsorbent contains a cerium oxide. Examples of the cerium oxide include CeOx (x = 1.5 to 2.0), and specific examples thereof include CeO ₂ and Ce ₂ O ₃ . The adsorbent may be a porous body such as zeolite, activated carbon, or MOF (Metal Organic Frameworks), and these porous bodies are filled with cerium oxide (for example, ceria) or these porous bodies are cerium-oxidized. It may be coated with a substance, or may be a ceria porous body (a porous body made of cerium oxide) modified or filled with amine. The binder may be, for example, a resin that binds to a cerium oxide by heat treatment, or a filler having a functional group that can bind to a cerium oxide such as a silanol group (for example, alumina, silica, etc.).

The shape of the adsorbent is not particularly limited, and may be, for example, powder-like, pellet-like, granular, honeycomb-like, or the like. When the adsorbent is formed as a granulated product, the shape and size of the granulated product, and the shape, size and specific surface area of the adsorbent are the required reaction rate, pressure loss, adsorbed amount of the adsorbent, and so on. It may be determined in consideration of the purity (CO ₂ purity) of the gas (adsorbed gas) adsorbed on the adsorbent. For example, the shape of the granulated product of the adsorbent may be a granular sphere, a pellet shape, a honeycomb shape, or the like.

The first gas transport device 13 circulates the gas to be processed in the first flow path 2a of the first pipe 2. As the first gas transport device 13, for example, a blower such as a fan can be used. The first gas transport device 13 may be arranged at any position as long as the gas to be processed can be circulated in the first flow path 2a. In the present embodiment, the first gas transport device 13 is arranged on the first flow path 2a on the upstream side of the adsorbent 11 in the flow direction of the gas to be treated. However, the first gas transport device 13 may be arranged on the first flow path 2a on the downstream side of the adsorbent 11 in the flow direction of the gas to be processed, or may be arranged at the same position as the adsorbent 11. Good. Further, since the flow path 4a, the flow path 5a, the flow path 6a, and the flow path 7a can also be communicated with the first flow path 2a by the first selection communication device 8 or the second selection communication device 9, the first gas transport device 13 May be arranged on the flow path 4a, the flow path 5a, the flow path 6a, or the flow path 7a.

The second gas transport device 14 circulates the gas to be processed through the second flow path 3a of the second pipe 3. As the second gas transport device 14, for example, a blower such as a fan can be used. The second gas transport device 14 may be arranged at any position as long as the gas to be processed can be circulated in the second flow path 3a. In the present embodiment, the second gas transport device 14 is arranged on the second flow path 3a on the upstream side of the adsorbent 12 in the flow direction of the gas to be treated. However, the second gas transport device 14 may be arranged on the second flow path 3a on the downstream side of the adsorbent 12 in the flow direction of the gas to be processed, and is arranged at the same position as the adsorbent 12. May be good. Further, since the flow path 4a, the flow path 5a, the flow path 6a, and the flow path 7a can also be communicated with the second flow path 3a by the first selection communication device 8 or the second selection communication device 9, the second gas transport device 14 may be arranged on the flow path 4a, the flow path 5a, the flow path 6a, or the flow path 7a.

The heat transport device 10 is capable of bidirectional heat transport between the first flow path 2a of the first pipe 2 and the second flow path 3a of the second pipe 3. The heat transport device 10 has a first heat exchange section 10a, a second heat exchange section 10b, and a heat transport section 10c.

The first heat exchange unit 10a is provided in the first flow path 2a of the first pipe 2 and exchanges heat with the gas to be processed flowing through the first flow path 2a. The first heat exchange unit 10a is arranged on the upstream side of the adsorbent 11 in the flow direction of the gas to be treated. However, the first heat exchange unit 10a may be arranged at the same position as the adsorbent 11 in the flow direction of the gas to be processed. The second heat exchange unit 10b is provided in the second flow path 3a of the second pipe 3 and exchanges heat with the gas to be processed flowing through the second flow path 3a. The second heat exchange unit 10b is arranged on the upstream side of the adsorbent 12 in the flow direction of the gas to be treated. However, the second heat exchange unit 10b may be arranged at the same position as the adsorbent 12 in the flow direction of the gas to be treated.

The heat transport unit 10c is connected to the first heat exchange unit 10a and the second heat exchange unit 10b. Then, the heat transport unit 10c transports heat in both directions between the first heat exchange unit 10a and the second heat exchange unit 10b. For example, at a certain timing, the heat transport unit 10c lowers the temperature of the first heat exchange unit 10a and lowers the temperature of the second heat exchange unit 10b by transporting heat from the first heat exchange unit 10a to the second heat exchange unit 10b. Raise the temperature. At another timing, the heat transport unit 10c raises the temperature of the first heat exchange unit 10a by transporting heat from the second heat exchange unit 10b to the first heat exchange unit 10a, and at the same time, the second heat exchange unit 10a. The temperature of 10b is lowered.

The heat transport device 10 includes, for example, a heat transport device 10A using a Peltier element as shown in FIGS. 2 and 3, or a heat transport device 10B using a heat pipe as shown in FIGS. 4 and 5. Can be used.

As shown in FIGS. 2 and 3, the heat transport device 10A using the Peltier element uses, for example, a metal plate provided in the first flow path 2a as the first heat exchange unit 10a, and uses the second heat exchange unit 10b. For example, a metal plate provided in the second flow path 3a is used, and as the heat transport section 10c, for example, a Peltier element section in which an N-type semiconductor and a P-type semiconductor are arranged in parallel is used.

In such a heat transport device 10A, as shown in FIG. 2, by passing a current from the P-type semiconductor side to the N-type semiconductor side, the temperature of the first heat exchange section 10a is lowered and the temperature of the second heat exchange section 10b is raised. Warm up. Then, in the first flow path 2a, the gas to be processed flowing through the first flow path 2a is cooled by the first heat exchange unit 10a and supplied to the adsorbent 11. As a result, the adsorbent 11 is cooled via the gas to be treated that flows through the first flow path 2a, and adsorbs carbon dioxide of the gas to be treated. On the other hand, in the second flow path 3a, the gas to be processed flowing through the second flow path 3a is heated by the second heat exchange unit 10b and supplied to the adsorbent 12. As a result, the adsorbent 12 is heated via the gas to be processed flowing through the second flow path 3a to desorb the adsorbed carbon dioxide.

On the other hand, as shown in FIG. 3, by passing a current from the N-type semiconductor side to the P-type semiconductor side, the temperature of the first heat exchange unit 10a rises and the temperature of the second heat exchange unit 10b decreases. Then, in the first flow path 2a, the gas to be processed flowing through the first flow path 2a is heated by the first heat exchange unit 10a and supplied to the adsorbent 11. As a result, the adsorbent 11 is heated via the gas to be processed flowing through the first flow path 2a to desorb the adsorbed carbon dioxide. On the other hand, in the second flow path 2b, the gas to be processed flowing through the second flow path 2b is cooled by the second heat exchange unit 10b and supplied to the adsorbent 12. As a result, the adsorbent 12 is cooled via the gas to be processed flowing through the second flow path 2b, and adsorbs carbon dioxide of the gas to be processed.

As shown in FIGS. 4 and 5, the heat transport device 10B using the heat pipe has heat transport section 10c, for example, an evaporation section 22 (evaporator) and a compression section 23 (expansion valve) connected by a circulation path 21. ), A heat pipe that circulates the working medium in the condensing section 24 (condenser) and the expanding section 25 (expander), and as the first heat exchange section 10a, for example, a metal connected to the condensing section 24 or the condensing section 24. A plate is used, and as the second heat exchange unit 10b, for example, a metal plate connected to the evaporation unit 22 or the evaporation unit 22 is used. As the heat cycle of the heat pipe, for example, the reverse Carnot cycle used for heating and cooling can be used.

In such a heat transport device 10B, as shown in FIG. 4, the first heat exchange section 10a (condensing section) is formed by circulating the working medium in the order of the expansion section 25, the condensing section 24, the compression section 23, and the evaporation section 22. As the temperature of 24) decreases, the temperature of the second heat exchange unit 10b (evaporation unit 22) rises. Then, in the first flow path 2a, the gas to be processed flowing through the first flow path 2a is cooled by the first heat exchange section 10a (condensing section 24) and supplied to the adsorbent 11. As a result, the adsorbent 11 is cooled via the gas to be treated that flows through the first flow path 2a, and adsorbs carbon dioxide of the gas to be treated. On the other hand, in the second flow path 3a, the gas to be processed flowing through the second flow path 3a is heated by the second heat exchange section 10b (evaporation section 22) and supplied to the adsorbent 12. As a result, the adsorbent 12 is heated via the gas to be processed flowing through the second flow path 3a to desorb the adsorbed carbon dioxide.

On the other hand, as shown in FIG. 5, by circulating the working medium in the order of the evaporation unit 22, the compression unit 23, the condensation unit 24, and the expansion unit 25, the temperature of the first heat exchange unit 10a (condensation unit 24) rises. The temperature of the second heat exchange section 10b (evaporation section 22) drops. Then, in the first flow path 2a, the gas to be processed flowing through the first flow path 2a is heated by the first heat exchange section 10a (condensing section 24) and supplied to the adsorbent 11. As a result, the adsorbent 11 is heated via the gas to be processed flowing through the first flow path 2a to desorb the adsorbed carbon dioxide. On the other hand, in the second flow path 3a, the gas to be processed flowing through the second flow path 3a is cooled by the second heat exchange section 10b (evaporation section 22) and supplied to the adsorbent 12. As a result, the adsorbent 12 is cooled via the gas to be treated that flows through the first flow path 2a, and adsorbs carbon dioxide of the gas to be treated.

[How to use the air conditioner]
An example of how to use the air conditioner 1 will be described with reference to FIGS. 6 and 7.

First, as shown in FIGS. 6 and 7, the air conditioner 1 is installed in the air conditioning target space (not shown). Then, the first supply port 4b of the first supply pipe 4 and the first discharge port 6b of the first discharge pipe 6 are directed to the region where the carbon dioxide concentration is desired to be reduced, and the second supply port 5b and the second supply pipe 5 of the second supply pipe 5 are directed. The second discharge port 7b of the second discharge pipe 7 is directed to a region where the carbon dioxide concentration does not have to be reduced. The region in which the carbon dioxide concentration is desired to be reduced is, for example, an region in which a person who sleeps, studies, works, or the like exists. Areas in which the carbon dioxide concentration does not have to be lowered are, for example, areas in which there are no people who sleep, study, or work. When a part of the air conditioner 1 can be taken out of the air conditioning target space, for example, the first supply port 4b and the first discharge port 6b are arranged in the air conditioning target space, and the second supply port 5b and the second discharge port are arranged. 7b may be arranged outside the air-conditioned space.

Next, as shown in FIG. 6, the first-choice communication device 8 communicates the flow path 4a (first supply port 4b) of the first supply pipe 4 with the first flow path 2a of the first pipe 2. The first state is such that the flow path 5a (second supply port 5b) of the second supply pipe 5 and the second flow path 3a of the second pipe 3 communicate with each other. Further, the second selective communication device 9 communicates the flow path 6a (first discharge port 6b) of the first discharge pipe 6 with the first flow path 2a of the first pipe 2, and also communicates the flow path of the second discharge pipe 7. A third state is set in which the 7a (second discharge port 7b) and the second flow path 3a of the second pipe 3 communicate with each other.

Further, by operating the heat transport device 10 and transporting heat from the first heat exchange section 10a to the second heat exchange section 10b by the heat transport section 10c, the temperature of the first heat exchange section 10a is lowered and the second heat exchange is performed. The temperature of part 10b is raised.

Further, the first gas transport device 13 and the second gas transport device 14 are operated to circulate the gas to be processed through the first flow path 2a of the first pipe 2 and the second flow path 3a of the second pipe 3. As a result, the gas to be processed supplied from the first supply port 4b flows through the flow path 4a, the first flow path 2a, and the flow path 6a, and is discharged from the first discharge port 6b. Further, the gas to be processed supplied from the second supply port 5b flows through the flow path 5a, the second flow path 3a and the flow path 7a, and is discharged from the second discharge port 7b.

At this time, in the first flow path 2a, the first heat exchange unit 10a cools the processing target gas flowing through the first flow path 2a, and the cooled processing target gas cools the adsorbent 11. As a result, the adsorbent 11 adsorbs the carbon dioxide of the gas to be treated flowing through the first flow path 2a, and lowers the carbon dioxide concentration of the gas to be treated. Then, the gas to be treated having a reduced carbon dioxide concentration is discharged from the first discharge port 6b. As a result, the carbon dioxide concentration in the region where the carbon dioxide concentration is desired to be reduced is reduced.

On the other hand, in the second flow path 3a, the second heat exchange unit 10b heats the gas to be processed flowing through the second flow path 3a, and the heated treatment target gas heats the adsorbent 12. As a result, the adsorbent 12 desorbs the adsorbed carbon dioxide and raises the carbon dioxide of the gas to be processed flowing through the second flow path 3a. Then, the gas to be treated having an increased carbon dioxide concentration is discharged from the second discharge port 7b. As a result, the carbon dioxide concentration in the region where the carbon dioxide concentration does not need to be decreased increases.

Next, as shown in FIG. 7, the first selective communication device 8 communicates the flow path 4a (first supply port 4b) of the first supply pipe 4 with the second flow path 3a of the second pipe 3. , The second state is such that the flow path 5a (second supply port 5b) of the second supply pipe 5 and the first flow path 2a of the first pipe 2 communicate with each other. Further, the second selective communication device 9 communicates the flow path 6a (first discharge port 6b) of the first discharge pipe 6 with the second flow path 3a of the second pipe 3, and also allows the flow of the second discharge pipe 7. A fourth state is set in which the road 7a (second discharge port 7b) and the first flow path 2a of the first pipe 2 communicate with each other.

Further, by operating the heat transport device 10 and transporting heat from the second heat exchange section 10b to the first heat exchange section 10a by the heat transport section 10c, the temperature of the first heat exchange section 10a is raised and the second heat is raised. The temperature of the exchange unit 10b is lowered.

Further, the first gas transport device 13 and the second gas transport device 14 are operated to circulate the gas to be processed through the first flow path 2a of the first pipe 2 and the second flow path 3a of the second pipe 3. As a result, the gas to be processed supplied from the first supply port 4b flows through the flow path 4a, the second flow path 3a, and the flow path 6a, and is discharged from the first discharge port 6b. Further, the gas to be processed supplied from the second supply port 5b flows through the flow path 5a, the first flow path 2a and the flow path 7a, and is discharged from the second discharge port 7b.

At this time, in the first flow path 2a, the first heat exchange unit 10a heats the gas to be processed flowing through the first flow path 2a, and the heated treatment target gas heats the adsorbent 11. As a result, the adsorbent 11 desorbs the adsorbed carbon dioxide and raises the carbon dioxide of the gas to be processed flowing through the second flow path 3a. Then, the gas to be treated having an increased carbon dioxide concentration is discharged from the second discharge port 7b. As a result, the carbon dioxide concentration in the region where the carbon dioxide concentration does not need to be decreased increases.

On the other hand, in the second flow path 3a, the second heat exchange unit 10b cools the processing target gas flowing through the second flow path 3a, and the cooled processing target gas cools the adsorbent 12. As a result, the adsorbent 12 adsorbs the carbon dioxide of the gas to be treated flowing through the first flow path 2a, and lowers the carbon dioxide concentration of the gas to be treated. Then, the gas to be treated having a reduced carbon dioxide concentration is discharged from the first discharge port 6b. As a result, the carbon dioxide concentration in the region where the carbon dioxide concentration is desired to be reduced is reduced.

As described above, in the air conditioner 1 of the present embodiment, since the adsorbent 11 and the adsorbent 12 are arranged in the first flow path 2a and the second flow path 3a, the first flow path 2a and the second flow path 3a By circulating the gas to be treated, carbon dioxide can be adsorbed and removed from the gas to be treated. A heat transport device 10 capable of bidirectionally transporting heat between the first flow path 2a and the second flow path 3a is provided. Therefore, by transporting heat from the second flow path 3a to the first flow path 2a by the heat transport device 10, the adsorbent 11 is heated through the gas to be processed in the first flow path 2a, and the adsorbent is heated. Carbon dioxide can be desorbed from 11, and in the second flow path 3a, the adsorbent 12 can be cooled via the circulating gas to be processed to return the adsorbent 12 to a state in which carbon dioxide can be adsorbed. it can. On the other hand, by transporting heat from the first flow path 2a to the second flow path 3a by the heat transport device 10, the adsorbent 11 is cooled through the gas to be processed in the first flow path 2a, and the adsorbent 11 is cooled. Can be returned to a state where carbon dioxide can be adsorbed, and in the second flow path 3a, the adsorbent 12 can be heated via the circulating gas to be processed to desorb carbon dioxide from the adsorbent 12. .. In this way, the exhaust heat of the air conditioner 1 can be utilized by bidirectionally transporting heat between the first flow path 2a and the second flow path 3a by the heat transport device.

Further, since heat is transported between the first heat exchange section 10a arranged in the first flow path 2a and the second heat exchange section 10b arranged in the second flow path 3a, it is arranged in the first flow path 2a. The adsorbent 11 and the adsorbent 12 arranged in the second flow path 3a can be suitably heated or cooled.

Further, the first supply port 4b and the second supply port 5b are selectively communicated with each other by the first selective communication device 8, and the first flow path 2a and the second flow path 3a are selectively communicated with each other. The discharge port 6b and the second discharge port 7b are selectively communicated with the first flow path 2a and the second flow path 3a. That is, the first-selection communication device 8 and the second-selection communication device 9 have a supply port and a discharge port for reducing the carbon dioxide concentration by adsorbing carbon dioxide, and a desorbed carbon dioxide for discharging the desorbed carbon dioxide. The supply port and the discharge port can be switched. Therefore, for example, the carbon dioxide concentration can be locally reduced by adjusting the directions of the first supply port 4b and the first discharge port 6b and the second supply port 5b and the second discharge port 7b.

Further, by providing the first gas transport device 13 and the second gas transport device 14, the gas to be processed can be forcibly circulated through the first flow path 2a and the second flow path 3a.

When the heat transport device 10 includes a Peltier element, the heat transport direction of the heat transport device 10 can be easily reversed by changing the direction of the current flowing through the Peltier element. Moreover, since the Peltier element can transport heat only by passing an electric current, it is excellent in quietness. Therefore, for example, it can be suitably used in a space such as a bedroom where quietness is required.

Further, when the heat transport device 10 includes a heat pipe, the heat transport direction by the heat transport device 10 can be facilitated by changing the circulation direction of the working medium in the heat cycle of evaporation, compression, condensation, and expansion of the heat pipe. Can be inverted to.

In addition, cerium oxide has excellent adsorptivity to carbon dioxide (CO ₂ ) when the carbon dioxide concentration is 1000 ppm or less, especially in a dry state where the gas to be treated does not contain water components, as compared with other adsorbents. It tends to have adsorptivity). The tendency to have excellent adsorptivity to carbon dioxide (CO ₂ adsorbability) is particularly remarkable when the gas to be treated is in a moist state containing water components, and the concentration which is superior to other adsorbents is 1000 ppm. That is all. Therefore, the air conditioner 1 tends to be excellent in carbon dioxide removal efficiency when used in a treatment target space containing a treatment target gas having such a carbon dioxide concentration. Further, the cerium oxide has excellent CO ₂ adsorbability as compared with other adsorbents, even when the gas to be treated contains water as described above. Therefore, a dehumidifying device is not required, and CO ₂ can be removed more efficiently.

[Second Embodiment]
The second embodiment is basically the same as the first embodiment, but is not provided with the second pipe 3 in which the second flow path 3a is formed, the adsorbent 12, and the second gas transport device 14. Different from one embodiment. Therefore, in the following, only the matters different from the first embodiment will be described, and the description of the parts different from the first embodiment will be omitted.

[Configuration of air conditioner]
As shown in FIG. 8, the air conditioner 1A has a first pipe 2, a first supply pipe 4, a second supply pipe 5, a first discharge pipe 6, a second discharge pipe 7, and a third selection communication. The device 15, the fourth-choice communication device 16, the heat transport device 10, the adsorbent 11, and the first gas transport device 13 are provided.

The third selective communication device 15 allows the flow path 4a (first supply port 4b) of the first supply pipe 4 or the flow path 5a (second supply port 5b) of the second supply pipe 5 to be the first flow of the first pipe 2. Selectively communicate with the road 2a. That is, the third selective communication device 15 has a fifth state in which the flow path 4a (first supply port 4b) of the first supply pipe 4 and the first flow path 2a of the first pipe 2 are communicated with each other, and the second supply pipe 5 The sixth state, which communicates the flow path 5a (second supply port 5b) of the above and the first flow path 2a of the first pipe 2, is selectively switched. In such a selective switching, for example, the rotatable member is formed so that the communication passage for the fifth state and the communication passage for the sixth state are not communicated with each other, and the member is formed. It can be realized by rotating it.

The fourth selective communication device 16 connects the flow path 6a (first discharge port 6b) of the first discharge pipe 6 or the flow path 7a (second discharge port 7b) of the second discharge pipe 7 to the first flow path of the first pipe 2. Selectively communicate with 2a. That is, the fourth selective communication device 16 has a seventh state in which the flow path 6a (first discharge port 6b) of the first discharge pipe 6 and the first flow path 2a of the first pipe 2 communicate with each other, and the second discharge pipe 7. The eighth state in which the flow path 7a (second discharge port 7b) and the first flow path 2a of the first pipe 2 communicate with each other is selectively switched. In such a selective switching, for example, the rotatable member is formed so that the communication passage for the seventh state and the communication passage for the eighth state are not communicated with each other, and the member is formed. It can be realized by rotating it.

The heat transport device 10 is capable of bidirectional heat transport between the first flow path 2a of the first tube 2 and a place different from the first flow path 2a. That is, the first heat exchange unit 10a is provided in the first flow path 2a. On the other hand, in the second embodiment, since the first flow path 2a of the first embodiment is not provided, the second heat exchange unit 10b is provided at an arbitrary place different from the first flow path 2a. The place where the second heat exchange unit 10b is provided is, for example, a place in the air-conditioned space where the second supply port 5b of the second supply pipe 5 and the second discharge port 7b of the second discharge pipe 7 are directed. Can be done.

[How to use the air conditioner]
An example of how to use the air conditioner 1A will be described.

First, as shown in FIG. 8, the air conditioner 1A is installed in the air conditioning target space (not shown). Then, the first supply port 4b of the first supply pipe 4 and the first discharge port 6b of the first discharge pipe 6 are directed to the region where the carbon dioxide concentration is desired to be reduced, and the second supply port 5b and the second supply pipe 5 of the second supply pipe 5 are directed. The second discharge port 7b of the second discharge pipe 7 is directed to a region where the carbon dioxide concentration does not have to be reduced.

Next, the third selective communication device 15 is set to the fifth state in which the flow path 4a (first supply port 4b) of the first supply pipe 4 and the first flow path 2a of the first pipe 2 are communicated with each other. Further, the fourth selective communication device 16 is set to the seventh state in which the flow path 7a (second discharge port 7b) of the second discharge pipe 7 and the first flow path 2a of the first pipe 2 are communicated with each other.

Further, by operating the heat transport device 10 and transporting heat from the first heat exchange section 10a to the second heat exchange section 10b by the heat transport section 10c, the temperature of the first heat exchange section 10a is lowered and the second heat exchange is performed. The temperature of part 10b is raised.

Further, the first gas transport device 13 is operated to circulate the gas to be processed through the first flow path 2a of the first pipe 2. As a result, the gas to be processed supplied from the first supply port 4b flows through the flow path 4a, the first flow path 2a, and the flow path 6a, and is discharged from the first discharge port 6b.

At this time, in the first flow path 2a, the first heat exchange unit 10a cools the processing target gas flowing through the first flow path 2a, and the cooled processing target gas cools the adsorbent 11. As a result, the adsorbent 11 adsorbs the carbon dioxide of the gas to be treated flowing through the first flow path 2a, and lowers the carbon dioxide concentration of the gas to be treated. Then, the gas to be treated having a reduced carbon dioxide concentration is discharged from the first discharge port 6b. As a result, the carbon dioxide concentration in the region where the carbon dioxide concentration is desired to be reduced is reduced.

Next, the third selective communication device 15 is set to the sixth state in which the flow path 5a (second supply port 5b) of the second supply pipe 5 and the first flow path 2a of the first pipe 2 are communicated with each other. Further, the second selective communication device 9 is set to the eighth state in which the flow path 7a (second discharge port 7b) of the second discharge pipe 7 and the first flow path 2a of the first pipe 2 are communicated with each other.

Further, by operating the heat transport device 10 and transporting heat from the second heat exchange section 10b to the first heat exchange section 10a by the heat transport section 10c, the temperature of the first heat exchange section 10a is raised and the second heat is raised. The temperature of the exchange unit 10b is lowered.

Further, the first gas transport device 13 is operated to circulate the gas to be processed through the first flow path 2a of the first pipe 2. As a result, the gas to be processed supplied from the second supply port 5b flows through the flow path 5a, the first flow path 2a, and the flow path 7a, and is discharged from the second discharge port 7b.

At this time, in the first flow path 2a, the first heat exchange unit 10a heats the gas to be processed flowing through the first flow path 2a, and the heated treatment target gas heats the adsorbent 11. As a result, the adsorbent 11 desorbs the adsorbed carbon dioxide and raises the carbon dioxide of the gas to be processed flowing through the second flow path 3a. Then, the gas to be treated having an increased carbon dioxide concentration is discharged from the second discharge port 7b. As a result, the carbon dioxide concentration in the region where the carbon dioxide concentration does not need to be decreased increases.

As described above, in the air conditioner 1A of the present embodiment, since the adsorbent 11 is arranged in the first flow path 2a, carbon dioxide is converted from the treatment target gas by flowing the treatment target gas through the first flow path 2a. Can be adsorbed and removed. Moreover, the heat transport device 10 capable of bidirectionally transporting heat between the first flow path 2a and a place different from the first flow path 2a is provided. Therefore, by transporting heat from a location different from the first flow path 2a to the first flow path 2a by the heat transport device 10, the adsorbent 11 is heated in the first flow path 2a via the gas to be processed. , Carbon dioxide can be desorbed from the adsorbent 11. On the other hand, by transporting heat from the first flow path 2a to a place different from the first flow path 2a by the heat transport device 10, the adsorbent 11 is cooled in the first flow path 2a via the gas to be processed. The adsorbent 11 can be returned to a state in which carbon dioxide can be adsorbed. In this way, the exhaust heat of the air conditioner 1A can be utilized by bidirectionally transporting heat between the first flow path 2a and a place different from the first flow path 2a by the heat transport device.

Although the air conditioner according to the present embodiment has been described above, the air conditioner according to the present embodiment is not limited to the above embodiment, and may be appropriately changed as long as the purpose is not deviated.

1,1A ... Air conditioner, 2 ... First pipe, 2a ... First flow path, 2b ... Second flow path, 3 ... Second pipe, 3a ... Second flow path, 4 ... First supply pipe, 4a ... Flow path 4, 4b ... 1st supply port, 5 ... 2nd supply pipe, 5a ... flow path, 5b ... 2nd supply port, 6 ... 1st discharge pipe, 6a ... flow path, 6b ... 1st discharge port, 7 ... 2nd Discharge pipe, 7a ... Flow path, 7b ... Second discharge port, 8 ... First selection communication device, 9 ... Second selection communication device, 10, 10A, 10B ... Heat transport equipment, 10a ... First heat exchange unit, 10b ... second heat exchange unit, 10c ... heat transport unit, 11, 12 ... adsorbent, 13 ... first gas transport equipment, 14 ... second gas transport equipment, 15 ... third choice communication device, 16 ... fourth choice communication Equipment, 21 ... circulation path, 22 ... evaporative part, 23 ... compression part, 24 ... condensing part, 25 ... expansion part.

Claims (8)

An air conditioner used in an air conditioner space containing carbon dioxide-containing treatment target gas.
The first flow path through which the gas to be processed flows and
A heat transport device capable of bidirectional heat transport between the first flow path and a place different from the first flow path,
An adsorbent, which is arranged in the first flow path and adsorbs carbon dioxide when it comes into contact with the gas to be treated and desorbs carbon dioxide when heated, is provided.
Air conditioner. Further provided with a second flow path through which the gas to be processed flows,
The adsorbent is also arranged in the second flow path,
The heat transport device is capable of bidirectional heat transport between the first flow path and the second flow path.
The air conditioner according to claim 1. The heat transport equipment includes a first heat exchange section arranged in the first flow path, a second heat exchange section arranged in the second flow path, the first heat exchange section, and the second heat exchange section. It has a heat transport unit capable of bidirectional heat transfer to and from the exchange unit.
The air conditioner according to claim 2. The first supply port and the second supply port to which the gas to be processed is supplied, and
The first and second outlets from which the gas to be treated is discharged, and
A first-choice communication device that selectively communicates the first supply port and the second supply port with the first flow path and the second flow path.
A second selective communication device for selectively communicating the first discharge port and the second discharge port with the first flow path and the second flow path is further provided.
The air conditioner according to claim 2 or 3. A first gas transport device that distributes the gas to be processed through the first flow path,
A second gas transport device for circulating the gas to be processed is further provided in the second flow path.
The air conditioner according to any one of claims 2 to 4. The heat transport device includes a Peltier element.
The air conditioner according to any one of claims 1 to 5. The heat transport device includes a heat pipe.
The air conditioner according to any one of claims 1 to 5. The adsorbent contains a cerium oxide,
The air conditioner according to any one of claims 1 to 7.

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