JP6652806B2 - Air conditioning system - Google Patents

Description

  The present invention relates to an air conditioning system.

  2. Description of the Related Art In recent years, for example, a desiccant air conditioning system has been proposed as one of air conditioning systems that generates cooling air in a cooling area without using electric power (for example, see Patent Document 1).

In a desiccant air conditioning system, humidity is controlled by a desiccant rotor and a humidity control device thereof (hereinafter, simply referred to as a desiccant rotor device).
In general, in a desiccant rotor device, a desiccant rotor in which an adsorbent or a sorbent is carried on a cylindrical honeycomb structure rotates, and the air to be dehumidified is, for example, one of the first blowing ports of the rotating desiccant rotor being rotated. The water is passed through the semicircular part to adsorb and sorb the water. Further, in the desiccant rotor device, by passing heated air (air for regeneration) from the second blower port of the desiccant rotor to the other semicircular portion of the desiccant rotor to desorb moisture from the adsorbent and the sorbent, Regenerate adsorbents and sorbents. Thereby, the air is dehumidified.

JP-A-2002-126441

However, in general, in the air conditioning technology using the desiccant rotor, although the room to be air-conditioned is dehumidified, there is much room for improvement of the indoor air quality.
In particular, in so-called emerging countries where air pollution is becoming serious, it is not possible to directly supply outside air to a room, and the indoor air is utilized. However, since the active human emits carbon dioxide indoors, the amount of carbon dioxide in the air increases with time, and the discomfort of the indoor human increases. Therefore, a technique for removing carbon dioxide from indoor air is desired.

The present invention has been made in view of the above circumstances, and provides an air conditioning system capable of removing carbon dioxide in indoor air and improving air quality.
The inventors can absorb and desorb carbon dioxide from indoor air by using, for example, an amine-supported solid absorbent as an amine-based absorbent among conventionally used adsorbents / absorbents. Focusing on the principle, the present inventors have newly found a suitable configuration and conditions for performing air conditioning based on this principle, and have completed the present invention.

The air conditioning system according to claim 1, further comprising a carbon dioxide absorbent that is an amine-carrying solid absorbent, wherein the carbon dioxide contained in the air to be treated is absorbed by the absorbent when the air to be treated is passed through. Zone, and a rotor partitioned into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air when the regeneration air is ventilated, and indoor air as the air to be treated. A processing target air first supply unit that supplies the processing zone, a processing target air second supply unit that supplies the processing target air that has passed through the processing zone into the room, and outside air as the regeneration air is supplied to the regeneration zone. a reproduction air supply unit for supplying the a reproduction air discharge unit for discharging the reproduction air which has passed through the regeneration zone to the outdoor, and wherein the rotor is provided without being connected, empty the chamber And a fan coil unit for circulating the processed air into the first supply section, from the upstream side of the feed direction toward the downstream side, the total heat exchanger, the cooling device is sequentially provided, the air for regeneration The supply unit shares the total heat exchanger, and the regeneration air supply unit is provided with the total heat exchanger and the heating device in order from the upstream side to the downstream side in the supply direction, and is provided in the processing zone. The total heat exchanger, the cooling device, the heating device, and the fan coil unit such that an enthalpy difference between the supplied processing target air and the regeneration air supplied to the regeneration zone is 30 kJ / kg (DA) or more. There running, when the temperature and relative humidity of the ambient air is higher than in summer predetermined value respectively, wherein the total heat exchanger and the heating device OFF state, the and the cooling device and the fan coil unit O When the temperature and the relative humidity of the outside air are respectively lower than predetermined values in winter, the cooling device is turned off, and the total heat exchanger, the heating device, and the fan coil unit are turned on. When the temperature and the relative humidity of the outside air are values between the summer predetermined value and the winter predetermined value, respectively, the total heat exchanger, the cooling device, the heating device, and the fan coil unit are turned on. It is configured to be in a state .
FIG. 1 is a graph showing the relationship between the enthalpy difference between the air to be treated and the air for regeneration in the rotor having the above configuration, and the efficiency of removing carbon dioxide. As shown in FIG. 1, as the enthalpy difference between the air to be treated and the air for regeneration increases, the efficiency of removing carbon dioxide improves. If the enthalpy difference between the air to be treated and the air for regeneration is 30 kJ / kg (DA) or more, the carbon dioxide removal efficiency is at least 30% or more, and the achievement of carbon dioxide removal in a general building room is achieved. Can be expected.

  In the above air conditioning system, since the enthalpy difference between the processing target air supplied to the processing zone of the rotor and the regeneration air supplied to the regeneration zone of the rotor is secured to 30 kJ / kg or more, the amine-carrying solid absorbent is used. Carbon dioxide absorption performance is improved. Therefore, carbon dioxide is satisfactorily removed from the processing target air supplied to the rotor from the room by the processing target air first supply unit, and the air from which the carbon dioxide has been removed (hereinafter, also referred to as the processed air) is processed. It is returned to the room by the two supply units. By such air circulation, carbon dioxide in the indoor air is removed, and the air quality is improved.

請 Motomeko 2 air conditioning system according includes carbon dioxide absorber is an amine bearing solid sorbent, processed air to absorb carbon dioxide contained in the process target air when it is ventilated in the absorbent A processing zone, and a rotor partitioned into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air when the regeneration air is ventilated, and indoor air as the air to be treated. A processing target air first supply unit that supplies the processing zone, a processing target air second supply unit that supplies the processing target air that has passed through the processing zone into the room, and the regeneration zone that uses outside air as the regeneration air. A regeneration air supply unit, a regeneration air discharge unit that exhausts the regeneration air that has passed through the regeneration zone to the outside, and the rotor are provided without being connected to each other, and the air in the room is provided. And a fan coil unit for circulating, in the process target air first supply unit, a cooling device is provided, wherein the regeneration air supply unit, a heating device is provided, air in the chamber said heating The enthalpy difference between the processing target air supplied to the processing zone and the regeneration air supplied to the regeneration zone is configured to be able to be supplied to the regeneration air supply unit upstream of the apparatus. kg (DA) or more, the cooling device, the heating device, and the fan coil unit are operated, and the amount of room air supplied to the regeneration air supply unit is adjusted. And when the relative humidity is higher than the summer predetermined value, the room air is not supplied to the regeneration air supply unit upstream of the heating device, and the temperature and relative humidity of the outside air are not supplied to the room. There when less than the winter predetermined value respectively, all of air in the chamber is configured to be supplied to the regeneration air supply upstream of the heating device.
The air conditioning system according to claim 3 includes an absorbent for carbon dioxide, which is an amine-supported solid absorbent, and absorbs the carbon dioxide contained in the air to be treated when the air to be treated is ventilated. And a rotor divided into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air when the regeneration air is passed through. A process target air first supply unit that supplies the process zone with the process target air that has passed through the process zone, and a process target air second supply unit that supplies the process target air into the room. a reproduction air supply unit for supplying to the zone, and a regeneration air outlet, wherein for discharging the reproduction air to the outdoor passing through the regeneration zone, in the process target air first supply unit is provided From the upstream side to the downstream side in the direction, an air handling unit and a cooling device are provided, a part of the air supplied from the air handling unit is supplied to the room, and the air supplied from the air handling unit is The remainder is supplied to the cooling device, and the regeneration air supply unit is provided with an auxiliary heating device, a humidifier, and a heating device from the upstream side to the downstream side in the supply direction, and is supplied to the processing zone. The air handling unit, the cooling device, the auxiliary heating device, the humidifier, and the heating so that an enthalpy difference between the air to be processed and the air for regeneration supplied to the regeneration zone is 30 kJ / kg (DA) or more. When the device operates and the temperature and the relative humidity of the outside air are each higher than a predetermined value in summer, the air is supplied to the air handling unit. The condition of the air to be processed is changed, and the temperature of the outside air and the relative humidity are each lower than a predetermined value in winter, and the condition of the air to be processed supplied to the air handling unit is configured to be maintained. I have.
In addition, the air conditioning system according to claim 4 includes an absorbent for carbon dioxide, which is an amine-carrying solid absorbent, and absorbs carbon dioxide contained in the air to be treated when the air to be treated is ventilated. And a rotor divided into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air when the regeneration air is passed through. A process target air first supply unit that supplies the process zone with the process target air that has passed through the process zone, and a process target air second supply unit that supplies the process target air into the room. a reproduction air supply unit for supplying to a zone, a regeneration air discharge unit for discharging the reproduction air which has passed through the regeneration zone to the outdoor, and the rotor is provided without being connected, the chamber A fan coil unit for circulating the air, a compressor, an expansion valve, a first evaporator inflating the heat medium and the condenser for condensing the heat medium circulating between said compressor and said expansion valve and comprising a heat pump having a second evaporator, and the the regeneration air supply humidifier is provided in the processing target air first supply unit, the processed air through the first evaporator In the regeneration air supply section, the regeneration air sequentially passes through the condenser and the humidifier, and the regeneration air that has passed through the regeneration zone passes through the second evaporator, and the processing zone. The fan coil unit, the compressor, the expansion valve, and the enthalpy difference between the processing target air supplied to the regeneration zone and the regeneration air supplied to the regeneration zone are 30 kJ / kg (DA) or more. The compressor, the first evaporator, and the second evaporator are operated, and when the temperature and the relative humidity of the outside air are each higher than a predetermined value in summer, the condenser and the expansion valve are used by using the compressor and the expansion valve. When the condition of the first evaporator is changed and the temperature and the relative humidity of the outside air are respectively lower than predetermined values in winter, the condition of the condenser and the first evaporator is changed using the compressor and the expansion valve. The heat recovered by the first evaporator and the second evaporator is supplied to the condenser.
Further, in any of the air conditioning system of claim 4 according to claims 1, wherein, the enthalpy of the air in the chamber may be configured to be higher than the enthalpy of the outside air.

  In each of the above air conditioning systems, the enthalpy difference between the air to be treated and the air for regeneration is secured as described above in consideration of the existing or new building, indoor facilities, or the like, or A configuration for increasing the temperature difference with air is provided. Therefore, carbon dioxide in the indoor air is removed, and the air quality is improved.

  According to the air conditioning system of the present invention, since the enthalpy difference between the air to be treated and the air for regeneration is secured, the performance of absorbing carbon dioxide in the absorbent of the rotor is improved, and the carbon dioxide in the indoor air is removed. Thus, indoor air quality can be improved.

4 is a graph showing the relationship between the enthalpy difference between the air to be processed by the rotor and the air for regeneration provided in the air conditioning system according to the present invention and the efficiency of carbon dioxide removal. It is a schematic diagram of a rotor with which an air-conditioning system concerning the present invention is provided. It is a schematic diagram showing a first embodiment of an air conditioning system according to the present invention. It is a schematic diagram showing a second embodiment of the air conditioning system according to the present invention. It is a schematic diagram showing a third embodiment of the air conditioning system according to the present invention. It is a schematic diagram showing a fourth embodiment of an air conditioning system according to the present invention.

  Hereinafter, an air conditioning system and an embodiment thereof according to the present invention will be specifically described with reference to the drawings.

  The air conditioning system according to the present invention first includes, as shown in FIG. 2, a carbon dioxide absorbent which is an amine-supported solid absorbent, and removes carbon dioxide contained in the air to be treated when the air to be treated is passed. A rotor partitioned into a treatment zone 2 for absorption by the amine-carrying solid absorbent and a regeneration zone 4 for releasing carbon dioxide absorbed by the amine-carrying solid absorbent into the regeneration air when the regeneration air is passed through. 1 is provided.

  The rotor 1 is a honeycomb rotor, which is a cylindrical member obtained by corrugating (corrugating) a sheet and winding the sheet into a rotor shape, and rotates about an axis in a direction indicated by a black arrow shown in FIG. 2. Is configured. The rotor 1 includes an amine-carrying solid absorbent, specifically a solid absorbent composed of a weakly basic ion exchange resin having a primary amine and / or a secondary amine as a functional group.

Room air is supplied to the processing zone 2 of the rotor 1 as air to be processed by a blower (not shown) or the like. When the air to be treated is passed through the processing zone 2, the carbon dioxide contained in the air to be treated is absorbed by the amine-carrying solid absorbent in the rotor portion and separated from the air to be treated. Thereby, the concentration of carbon dioxide in the air to be treated is reduced.
The regeneration air is appropriately heated (and / or humidified) by a heater or the like and supplied to the regeneration zone 4 of the rotor 1. When the regeneration air is passed through the regeneration zone 4, the carbon dioxide absorbed by the amine-carrying solid absorbent in the rotor part is desorbed into the regeneration air, and the absorbent in the rotor part passing through the zone is regenerated.

Absorption and elimination of carbon dioxide by the amine-supported solid absorbent occur in the case of a primary amine (R-NH ₂ ) by the reaction of the following formulas (1) and (2), and the secondary amine (R ₁ R) _In the case of ( _2- NH), it is generated by the reaction of the equations (3) and (4).

It is presumed that when the above-mentioned reaction occurs, a continuous derivative model of an amine-carbon dioxide-water system is produced. That, HCO as solute ₃ ^- around the molecule can solvent as a continuous derivative, causing polarization in a solvent around the charge distribution of the solute molecules. In the continuous derivative model, the interaction between the solute solvents promotes the expressions (1) to (4) under lower temperature conditions, thereby increasing the reactivity such as the absorption rate and the emission rate. Therefore, if the regeneration temperature is low and the humidity is appropriate, the interaction between the solute solvents is promoted, and the carbon dioxide absorption rate of the amine-supported solid absorbent (that is, the carbon dioxide removal performance of the amine-supported solid absorbent) is improved. ) Will be higher.

The air-conditioning system according to the present invention supplies the rotor 1 described above, a processing target air first supply unit that supplies indoor air as processing target air to the processing zone 2, and supplies processing target air that has passed through the processing zone 2 to the room. A second air supply unit to be processed, a regeneration air supply unit for supplying outside air to the regeneration zone 4 as regeneration air, and a regeneration air discharge unit for discharging regeneration air passing through the regeneration zone to the outside of the room. The enthalpy difference between the processing target air supplied to the processing zone 2 and the regeneration air supplied to the regeneration zone 4 is configured to be 30 kJ / kg (DA) or more.
That is, in the air conditioning system according to the present invention, the difference in enthalpy between the air to be processed supplied to the processing zone 2 and the air for regeneration supplied to the regeneration zone 4 becomes 30 kJ / kg (DA) or more, so that the solute solvent Interaction is promoted, and the absorption rate of carbon dioxide in the amine-supported solid absorbent is increased. Thereby, the removal rate of carbon dioxide in the room becomes at least 30% or more. Further, when the enthalpy difference between the air to be treated and the air for regeneration is 45 kJ / kg (DA) or more, the indoor carbon dioxide removal rate becomes 40% or more, which is more preferable.
As described above, in order to make the enthalpy difference between the air to be treated and the air for regeneration at least 30 kJ / kg (DA) or more, for example, based on the humidity of the air for treatment and the air for regeneration, Is preferably set appropriately. Hereinafter, an embodiment of an air conditioning system configured so that the enthalpy difference between the air to be treated and the air for regeneration is 30 kJ / kg (DA) or more will be described.

(First embodiment)
First, a first embodiment of an air conditioning system according to the present invention will be described.
As shown in FIG. 3, the air conditioning system 10A according to the first embodiment includes a fan coil unit 12 that circulates air in the room R. However, the air conditioning system 10A of the first embodiment may be provided with equipment capable of circulating the air in the room R, such as a package air conditioner, instead of the fan coil unit 12.
The processing target air first supply unit 14 that connects the room R and the processing target air inlet (supply) side of the processing zone 2 of the rotor 1 has a total flow from the upstream side to the downstream side in the supply direction of the processing target air. A heat exchanger 16 and a cooling device 18 are sequentially provided. Examples of the cooling device 18 include a cold water coil and a cooling coil. The regeneration air supply unit 20 that connects the outdoor and the regeneration air inlet (supply) side of the regeneration zone 4 of the rotor 1 shares the total heat exchanger 16, and the regeneration air supply unit 20 The total heat exchanger 16 and the heating device 22 are sequentially provided from the upstream side to the downstream side in the supply direction. Examples of the heating device 22 include an electric heater, a hot water coil, a steam coil, a heating humidifier (a pan humidifier, a steam humidifier, and the like).
The air conditioning system 10A according to the first embodiment includes a processing target air second supply unit 24 that connects the processing target air outlet side of the processing zone 2 of the rotor 1 and the room R, and a processing target of the regeneration zone 4 of the rotor 1. A regeneration air discharge section 26 for connecting the air outlet side to the outside.
In the room R, the supply of the outside air and the exhaust from the room R are performed independently of the circulation of the processing target air by the processing target air first supply unit 14 and the processing target air second supply unit 24. Thereby, the air pressure and the like in the room R are appropriately adjusted. The flow rate of air in such ventilation is fixed.
However, the configuration of the air conditioning system 10A shown in FIG. 3 assumes a case where the enthalpy of the outside air is lower than the enthalpy of the air in the room R as in winter. When the temperature of the outside air is higher than the enthalpy of the air in the room R as in summer, the total heat exchanger 16 of the first air supply unit 14 to be treated is omitted. In the following description, it is assumed that the total heat exchanger 16 of the processing target air first supply unit 14 is provided, and the enthalpy of the outside air is lower than the enthalpy of the air in the room R.

In the air-conditioning system 10A of the first embodiment, the air in the room R is discharged to the processing target air first supply unit 14, and supplied to the total heat exchanger 16 as the processing target air by the processing target air first supply unit 14. . On the other hand, the outside air introduced from the outdoor is supplied to the total heat exchanger 16 as regeneration air by the regeneration air supply unit 20. In the total heat exchanger 16, total heat exchange (that is, exchange of sensible heat (temperature) and latent heat (humidity)) is performed between the air to be treated and the air for regeneration, and the enthalpy of the air to be treated is reduced. The enthalpy of the regeneration air increases.
The air to be treated whose enthalpy has been reduced by the total heat exchanger 16 is supplied to the cooling device 18 by the first air to be treated 14, and further cooled to a predetermined temperature to be introduced into the treatment zone 2 of the rotor 1. Is supplied to the processing zone 2. The regeneration air whose enthalpy has increased in the total heat exchanger 16 is supplied to the heating device 22 by the regeneration air supply unit 20 and further heated to a predetermined temperature to be introduced into the regeneration zone 4 of the rotor 1. It is supplied to the reproduction zone 4. The predetermined temperature of the air to be treated introduced into the processing zone 2 and the predetermined temperature of the regeneration air introduced into the regeneration zone 4 are such that the difference in enthalpy between the air to be treated and the regeneration air is at least 30 kJ / kg (DA). Set so as to be as described above.
In this way, with the enthalpy difference between the air to be processed and the air for regeneration provided, the air for processing is supplied to the processing zone 2 and the air for regeneration is supplied to the regeneration zone 4.

  In the processing zone 2 of the rotor 1, the carbon dioxide in the air to be processed is absorbed by the amine-carrying solid absorbent contained in the rotor 1 and separated and removed from the air to be processed. The portion of the rotor 1 containing the amine-carrying solid absorbent that has absorbed carbon dioxide moves to the region of the regeneration zone 4 by rotation, and the absorbed carbon dioxide desorbs into regeneration air that is passed through the regeneration zone 4. In this way, carbon dioxide is removed from the air to be treated, and the carbon dioxide is contained in the air for regeneration.

The processed air discharged from the processing zone 2 of the rotor 1 to the processing target air second supply unit 24 is supplied to the room R by the processing target air second supply unit 24. The regeneration air discharged from the regeneration zone 4 of the rotor 1 to the regeneration air discharge unit 26 is exhausted outside by the regeneration air discharge unit 26.
In consideration of the temperature of the processed air supplied to the room R by the processing target air second supply unit 24, the temperature of the room R is mainly adjusted by the fan coil unit 12, and the humidity of the room R is also adjusted as necessary. Adjusted. In addition, in the so-called intermediate period between winter and summer, in consideration of the level difference between the enthalpy of the air in the room R and the enthalpy of the outside air, the enthalpy difference between the air to be treated and the air for regeneration is at least 30 kJ / kg (DA). As described above, the settings of the cooling device 18 and the heating device 22 are appropriately changed.

An example of a setting condition in the air conditioning system 10A is shown. As specified in the Building Management Law, the concentration of carbon dioxide in the room R of an office or the like is set to 1000 PPM or less. For example, assume that the room R has a size of 1400 m ^{3 with} a floor area of 500 m ² × a height of 2.8 m, and that 75 people are active in the room R. The amount of carbon dioxide generated in such chamber R is ^{15m 3 /h(=0.02m} 3 / person · h × 75 people). By removing 30% of carbon dioxide in the room R at 3200 m ³ / h, the carbon dioxide concentration in the room R can be maintained at 1000 PPM or less.
In addition, it is assumed that the room R is supplied with outside air at 1150 CMH (m ³ / h) from a blower (not shown) at a carbon dioxide concentration of 500 PPM, and is exhausted from the room R to the outside under the same conditions.

Under the conditions described above, in the winter season, using a blower or the like (not shown), 3200 m ³ / h, a temperature of 22 ° C., and a relative humidity of 40% (enthalpy 39 kJ / kg ( It is assumed that the air to be treated in DA)) is discharged.
On the other hand, it is assumed that regeneration air is introduced from outside into the regeneration air supply unit 20 at a temperature of 3200 m ³ / h, a temperature of 0 ° C., and a relative humidity of 50% (enthalpy of 5 kJ / kg (DA)) using a blower or the like (not shown). I do. The total heat exchanger 16 reduces the enthalpy of the air to be treated to 14 kJ / kg (DA) and increases the enthalpy of the regeneration air to 29 kJ / kg (DA). The cooling device 18 is turned off, and supplies processing air having an enthalpy of 14 kJ / kg (DA) to the processing zone 2 of the rotor 1. The heating device 22 is turned on, the regeneration air having an enthalpy of 29 kJ / kg (DA) is heated to 45 ° C., the enthalpy is increased to 58 kJ / kg (DA), and supplied to the regeneration zone 4 of the rotor 1. Due to such an enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 becomes 39%, and the carbon dioxide concentration in the room R is reduced to 867 PPM.

Under the above-described conditions, in the summer season, a 3200 m ³ / h, a temperature of 26 ° C., a relative humidity of 50% (enthalpy of 52 kJ / kg (DA It is assumed that the air to be treated is discharged.
On the other hand, it is assumed that regeneration air is introduced into the regeneration air supply unit 20 from outside using a blower or the like (not shown) at 3200 m ³ / h, a temperature of 34 ° C., and a relative humidity of 60% (enthalpy of 86 kJ / kg (DA)). I do. As described above, heat exchange by the total heat exchanger 16 is not performed in summer. Therefore, the enthalpy of the air to be treated is 52 kJ / kg (DA), and the enthalpy of the air for regeneration is 86 kJ / kg (DA). The cooling device 18 is turned on, cools the air to be processed to 14 ° C., reduces the enthalpy to 38 kJ / kg (DA), and supplies the enthalpy to the processing zone 2 of the rotor 1. The heating device 22 is turned off to supply regeneration air having an enthalpy of 86 kJ / kg (DA) to the regeneration zone 4 of the rotor 1. Due to such an enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 becomes 41%, and the carbon dioxide concentration in the room R is reduced to 837 PPM. Therefore, even in the summer, the standard for setting the carbon dioxide concentration in the room R of an office or the like to be 1000 PPM or less is sufficiently achieved, as defined in the Building Management Law.

According to the air conditioning system 10A of the first embodiment described above, the enthalpy of the processing target air supplied to the processing zone 2 of the rotor 1 is reduced in the processing target air first supply unit 14, and the regeneration target air supply unit 20 The enthalpy of the regeneration air supplied to the regeneration zone 4 of the rotor 1 increases. Particularly in the winter season, the enthalpy of the air to be treated is reduced and the enthalpy of the air for regeneration is increased by operating the total heat exchanger 16. Thereby, an enthalpy difference is provided between the air to be treated and the air for regeneration. The enthalpy difference between the air to be treated and the air for regeneration is at least 30 kJ / kg (DA) while adjusting the settings of the total heat exchanger 16, the cooling device 18 and the heating device 22 in consideration of the temperature and relative humidity of the outside air. ) Above. As a result, the reactions of equations (1) to (4) in the rotor 1 are promoted, and the carbon dioxide absorption performance of the amine-supported solid absorbent contained in the rotor 1 is improved (see FIG. 1). Therefore, carbon dioxide is satisfactorily removed from the air to be processed, and the processed air is returned to the room R by the second air supply unit 24. By such air circulation, carbon dioxide in the air in the room R can be removed, and the air quality can be improved.
In addition, since the air conditioning system 10A of the first embodiment includes the total heat exchanger 16, the regeneration air (that is, outside air) is exchanged with the air to be treated (that is, room air) and enthalpy exchange (both temperature and humidity). I do. Therefore, the air-conditioning system 10A of the first embodiment can save power more than an air-conditioning system in which the air in the room R is simply mixed with the outside air, as in an air-conditioning system 10B of a second embodiment described later. Since the enthalpy difference between the air to be treated and the air for regeneration is particularly large in winter, the carbon dioxide removal performance in winter can be efficiently increased.

(Second embodiment)
Next, a second embodiment of the air conditioning system according to the present invention will be described. Note that, in the components of the air conditioning system 10B of the second embodiment, the same components as those of the air conditioning system 10A of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.
As shown in FIG. 4, in the air conditioning system 10 </ b> B of the second embodiment, a cooling device 18 is provided in the processing target air first supply unit 14, and a heating device 22 is provided in the regeneration air supply unit 20. A part of the air in the room R is configured to be supplied to the regeneration air supply unit 20 on the upstream side of the heating device 22. Specifically, an indoor exhaust unit 28 for exhausting air from the room R independently of the processing target air first supply unit 14 merges with the regeneration air supply unit 20 via the bypass unit 30. The indoor exhaust part 28, the bypass part 30, and the regeneration air supply part 20 are provided with dampers for adjusting the flow rate of air.

In the air conditioning system 10B of the second embodiment, the air in the room R is discharged separately to the first air supply unit 14 to be treated and the indoor exhaust unit 28. The air discharged to the indoor exhaust unit 28 can be directly supplied to the regeneration air supply unit 20 by the bypass unit 30. Depending on the season and the outdoor environment, all the air discharged to the indoor exhaust unit 28 is supplied to the regeneration air supply unit 20 in winter and the like, and all the air discharged to the indoor exhaust unit 28 is discharged outside in the summer and the like. Exhaust. The outside air introduced from outside the room is mixed with the air in the room R from the bypass unit 30 in the regeneration air supply unit 20, and the enthalpy increases.
The processing target air discharged from the room R is supplied to the cooling device 18 by the processing target air first supply unit 14, and is further cooled to a predetermined temperature introduced into the processing zone 2 of the rotor 1, the enthalpy is reduced, and 1 processing zone 2. The regeneration air mixed with the air in the room R and having increased enthalpy is supplied to the heating device 22 by the regeneration air supply unit 20 and further heated to a predetermined enthalpy introduced into the regeneration zone 4 of the rotor 1. Is supplied to the reproduction zone 4.
In this way, with the enthalpy difference between the air to be processed and the air for regeneration provided, the air for processing is supplied to the processing zone 2 and the air for regeneration is supplied to the regeneration zone 4.

  The exchange of carbon dioxide between the air to be treated and the air for regeneration in the rotor 1 and the flows of the treated air and the air for regeneration after passing through the rotor 1 are the same as in the air conditioning system 10A of the first embodiment.

An example of a setting condition in the air conditioning system 10B is shown. The conditions such as the size of the room R and the air supply / exhaust are the same as the example of the design condition of the air conditioning system 10A of the first embodiment.
Under the above-described conditions, in the winter season, the air to be treated is supplied from the room R to the first air supply unit 14 for treatment at 3200 m ³ / h, a temperature of 22 ° C., and a relative humidity of 40% (enthalpy of 39 kJ / kg (DA It is assumed that the air to be treated is discharged.
On the other hand, it is assumed that regeneration air is introduced from outside into the regeneration air supply unit 20 at 1250 m ³ / h, temperature 0 ° C., and relative humidity 50% (enthalpy 5 kJ / kg (DA)) using a blower or the like (not shown). I do. 100% of the air in the room R discharged into the room exhaust unit 28 is introduced into the bypass unit 30 and is supplied to the regeneration air supply unit 1 at 1150 m ³ / h, at a temperature of 22 ° C., and a relative humidity of 40% (enthalpy 39 kJ / kg (DA)). ). This increases the enthalpy of the regeneration air to 17 kJ / kg (DA). The cooling device 18 is turned on, cools the air to be processed to 9 ° C., reduces the enthalpy to 25 kJ / kg (DA), and supplies the enthalpy to the processing zone 2 of the rotor 1. The heating device 22 is also turned on, the regeneration air is heated to 45 ° C., the enthalpy is increased to 55 kJ / kg (DA), and the enthalpy is supplied to the regeneration zone 4 of the rotor 1. Due to such an enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 is reduced to 31%, and the carbon dioxide concentration in the room R is reduced to 968 PPM.

Under the above-described conditions, in the summer season, a 3200 m ³ / h, a temperature of 26 ° C., a relative humidity of 50% (enthalpy of 52 kJ / kg (DA It is assumed that the air to be treated is discharged.
On the other hand, it is assumed that regeneration air is introduced into the regeneration air supply unit 20 from outside using a blower or the like (not shown) at 3200 m ³ / h, a temperature of 34 ° C., and a relative humidity of 60% (enthalpy of 86 kJ / kg (DA)). I do.
In the summer, the air in the room R is not introduced into the bypass unit 30 from the indoor exhaust unit 28, and the air 3 introduced into the indoor exhaust unit 28 is exhausted by 100%. Then, similarly to the example of the design condition of the air conditioning system 10A of the first embodiment, the processing target air and the regeneration air are supplied to the rotor 1. Due to the enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 becomes 41%, and the carbon dioxide concentration in the room R is reduced to 837 PPM.

  According to the air conditioning system 10B of the second embodiment described above, the processing target air that is cooled by the cooling device 18 in the processing target air first supply unit 14 and is supplied to the processing zone 2 of the rotor 1, and the indoor exhaust unit 28 The enthalpy is increased by mixing with the air in the room R bypassed from, and the enthalpy is increased by the heating device 22 in the regeneration air supply unit 20 to increase the enthalpy and supplied to the regeneration zone 4 of the rotor 1 for regeneration. An enthalpy difference is given to the air. The enthalpy difference between the air to be treated and the air for regeneration should be at least 30 kJ / kg (DA) while adjusting the settings of the cooling device 18 and the heating device 22 in consideration of the temperature and relative humidity of the outside air. Can be. Therefore, the same effect as the air conditioning system 10A of the first embodiment can be obtained.

(Third embodiment)
Next, a third embodiment of the air conditioning system according to the present invention will be described. In the components of the air conditioning system 10C of the third embodiment, the same components as those of the air conditioning system 10A of the first embodiment or the components of the air conditioning system 10B of the second embodiment are denoted by the same reference numerals, The description is omitted.
As shown in FIG. 5, in the air conditioning system 10 </ b> C of the third embodiment, the air-handling unit 32 is provided to the processing target air first supply unit 14 from the upstream side to the downstream side in the supply direction of the processing target air. The device 18 is provided, a part of the air supplied from the air handling unit 32 is supplied to the room R, and the rest of the air supplied from the air handling unit 32 is supplied to the cooling device 18, and the regeneration air supply unit 20 is provided. Is provided with a heating device 22.
As the air handling unit 32, a unit generally used in an air conditioning system can be applied.
The regeneration air supply unit 20 is provided with a heating device 34 and a humidifier 36 on the upstream side of the heating device 22 from the upstream side in the supply direction of the regeneration air to the downstream side. Thus, even in winter, for example, generation of odor can be suppressed without shortening the life of the rotor 1 and the enthalpy difference between the air to be treated and the air for regeneration can be made 30 kJ / kg (DA) or more. .

In the air conditioning system 10 </ b> C of the third embodiment, the air in the room R is supplied to the air handling unit 32 by the processing target air first supply unit 14. A part of the processing target air discharged from the air handling unit 32 is returned to the room R. The temperature of the room R is adjusted mainly by the air returned from the air handling unit 32 to the room R, and the humidity of the room R is adjusted as necessary. In consideration of this point, it is preferable to appropriately set conditions such as the temperature and humidity of the air to be processed discharged from the air handling unit 32.
The remaining portion of the air to be treated discharged from the air handling unit 32 is supplied to the cooling device 18 by the first supply unit 14 for the air to be treated, and further cooled to a predetermined temperature to be introduced into the processing zone 2 of the rotor 1. Is supplied to the processing zone 2. On the other hand, the regeneration air is supplied to the heating device 22 by the regeneration air supply unit 20, further heated to a predetermined temperature introduced into the regeneration zone 4 of the rotor 1, and supplied to the regeneration zone 4 of the rotor 1.
In this way, with the enthalpy difference between the air to be processed and the air for regeneration provided, the air for processing is supplied to the processing zone 2 and the air for regeneration is supplied to the regeneration zone 4.

  The exchange of carbon dioxide between the air to be treated and the air for regeneration in the rotor 1 and the flows of the treated air and the air for regeneration after passing through the rotor 1 are the same as in the air conditioning system 10A of the first embodiment.

An example of a setting condition in the air conditioning system 10C is shown. The conditions such as the size of the room R and the air supply / exhaust are the same as the example of the design condition of the air conditioning system 10A of the first embodiment.
Under the above-mentioned conditions, in the winter, 13600 m ³ / h, temperature 22 ° C., relative humidity 40% (enthalpy 39 kJ / kg (DA It is assumed that the air to be treated is discharged.
On the other hand, it is assumed that regeneration air is introduced from outside into the regeneration air supply unit 20 at 2400 m ³ / h, temperature 0 ° C., and relative humidity 50% (enthalpy 5 kJ / kg (DA)) using a blower or the like (not shown). I do. The air handling unit 32 holds the condition of the processing target air supplied from the room R to the processing target air first supply unit 14. The cooling device 18 is turned on, and the air to be treated at 22 ° C. adjusted by the air handling unit 32 is cooled to 11 ° C. (enthalpy 27 kJ / kg (DA)) and supplied to the processing zone 2 of the rotor 1. . The heating device 34, the humidifier 36, and the heating device 22 are also turned on, and the enthalpy of the regeneration air is increased to 75 kJ / kg (DA) and supplied to the regeneration zone 4 of the rotor 1. Due to such an enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 is reduced to 41%, and the carbon dioxide concentration in the room R is reduced to 842 PPM.

  Under the above-mentioned conditions, in the case of summer, the conditions of the air to be processed supplied from the room R to the first air-to-be-processed supply unit 14 are appropriately changed in the air handling unit 32, and the air conditioning system 10A and The air to be treated and the air for regeneration are supplied to the rotor 1 as in the example of the summer design condition of the air conditioning system 10B of the second embodiment. Due to the enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 becomes 41%, and the carbon dioxide concentration in the room R is reduced to 837 PPM.

According to the air-conditioning system 10 </ b> C of the third embodiment described above, the processing target air first supply unit 14 passes through the air handling unit 32, is cooled by the cooling device 18, and is supplied to the processing zone 2 of the rotor 1. An enthalpy difference is given between the target air and the regeneration air supplied to the regeneration zone 4 of the rotor 1 by being heated by the heating device 34, the humidifier 36, and the heating device 22 in the regeneration air supply unit 20. You.
According to the air conditioning system 10C of the third embodiment, a part of the processing target air that has passed through the air handling unit 32 in the processing target air first supply unit 14 is returned to the room R, so that the air circulation in the room R is improved. Performed efficiently. Further, according to the air conditioning system 10C of the third embodiment, the total heat exchanger 16 is not used as in the air conditioning system 10B of the second embodiment, and in addition, the air handling unit 32 also has the function of the fan coil unit 12. Since the air conditioning system 10B also has a simple configuration, it is possible to further save the space of the air conditioning system 10B. Further, it is not necessary to use the fan coil unit 12.

(Fourth embodiment)
Next, a fourth embodiment of the air conditioning system according to the present invention will be described. Note that, in the components of the air conditioning system 10D of the fourth embodiment, the same components as those of the air conditioning system 10A of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.
As shown in FIG. 6, an air conditioning system 10D according to the fourth embodiment includes a fan coil unit 12, a compressor 42, an expansion valve 44, and a heat medium circulating between the compressor 42 and the expansion valve 44 (shown in FIG. 6). ) Is provided with a heat pump 40 having a condenser 46 for condensing the heat medium and an evaporator 48 for expanding the heat medium. In the air-conditioning system 10D, the processing target air passes through the evaporator 48 in the processing target air first supply unit 14, and the regeneration air passes through the condenser 46 in the regeneration air supply unit 20. .
As the heat pump 40, a heat pump generally used in an air conditioning system can be applied.

In the air conditioning system 10D of the fourth embodiment, the air in the room R is supplied to the evaporator 48 of the heat pump 40 as the air to be processed by the first air to be processed 14 and passes through the evaporator 48. The air to be processed is cooled to a predetermined temperature to be introduced into the processing zone 2 of the rotor 1 due to a decrease in the temperature of the heat medium expanded in the evaporator 48, and is supplied to the processing zone 2 of the rotor 1. On the other hand, the regeneration air is supplied to the condenser 46 of the heat pump 40 by the regeneration air supply unit 20, and passes through the condenser 46. The regeneration air is heated to a predetermined temperature to be introduced into the regeneration zone 4 of the rotor 1 by the heat of the heat medium condensed in the condenser 46, and is supplied to the regeneration zone 4 of the rotor 1.
With the temperature difference between the air to be processed and the air for regeneration provided in this way, the air for processing is supplied to the processing zone 2 and the air for regeneration is supplied to the regeneration zone 4. The compressor 42 can arbitrarily or optimally create an enthalpy difference between the air to be treated and the air for regeneration by adjusting the output by the inverter.

  As shown in FIG. 6, the humidifier 36 is provided downstream of the condenser 46 in the regeneration air supply unit 20, and the evaporator 50 of the heat pump 40 is also provided in the regeneration air discharge unit 26. Is preferred. In the heat pump 40, the heat is recovered from the evaporator 48 and the evaporator 50 while the amount is adjusted by the two-way valves 52 and 54, and the heat is supplied to the condenser 46. Also, the required amount of heat can be given to the regeneration air. Although the heating temperature of the condenser 46 has a limit in principle of the heat pump 40, humidification by the humidifier 36 can further increase the enthalpy of the regeneration air below the limit temperature. Thereby, the air to be treated is not excessively cooled, and the enthalpy difference between the air to be treated and the air for regeneration can be appropriately adjusted.

  The exchange of carbon dioxide between the air to be treated and the air for regeneration in the rotor 1 and the flows of the treated air and the air for regeneration after passing through the rotor 1 are the same as in the air conditioning system 10A of the first embodiment.

An example of a setting condition in the air conditioning system 10D is shown. The conditions such as the size of the room R and the air supply / exhaust are the same as the example of the design condition of the air conditioning system 10A of the first embodiment.
Under the above-described conditions, in the winter season, the air to be treated is supplied from the room R to the first air supply unit 14 for treatment at 3200 m ³ / h, a temperature of 22 ° C., and a relative humidity of 40% (enthalpy of 39 kJ / kg (DA It is assumed that the air to be treated is discharged. On the other hand, it is assumed that regeneration air is introduced into the regeneration air supply unit 20 from outside using a blower or the like (not shown) at 3200 m ³ / h, a temperature of 0 ° C., and a relative humidity of 50%. In the evaporator 48 (heat amount: 27 kJ / kg) of the heat pump 40, the air to be processed at 22 ° C. is cooled to 11 ° C. and supplied to the processing zone 2 of the rotor 1. The regeneration air at 0 ° C. is heated to 50 ° C. or higher by the condenser 46 of the heat pump 40 and supplied to the regeneration zone 4 of the rotor 1. Due to such an enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 becomes 30% or more, as in the example of the design condition of the air conditioning system 10A of the first embodiment.

  Under the above conditions, in summer, the conditions of the evaporator 48 and the condenser 46 are appropriately changed using the compressor 42 and the expansion valve 44 of the heat pump 40, and the air conditioning system 10A and the like of the first embodiment described above are used. The air to be processed and the air for regeneration are supplied to the rotor 1 as in the case of the example of the design conditions. Due to the enthalpy difference between the air to be treated and the air for regeneration, the carbon dioxide removal rate of the rotor 1 becomes 30% or more, similarly to the example of the design condition of the air conditioning system 10A and the like of the first embodiment described above. In other words, the conditions of the air to be treated and the air for regeneration are adjusted so that the removal rate of carbon dioxide from the rotor 1 becomes 30% or more.

According to the air conditioning system 10D of the fourth embodiment described above, the processing target air cooled in the evaporator 48 of the heat pump 40 in the processing target air first supply unit 14 and supplied to the processing zone 2 of the rotor 1, and the heat pump The enthalpy difference between the air to be treated and the air for regeneration is at least 30 kJ / kg (the enthalpy difference between the air for regeneration and the air for regeneration supplied to the regeneration zone 4 of the rotor 1 after being heated by the condenser 46 of the rotor 40). DA) or more. Therefore, the same effect as the air conditioning system 10A of the first embodiment can be obtained.
Further, for a building or the like in which a heat pump is already provided, by utilizing the heat pump as the above-described heat pump 40, the number of additional equipment can be reduced, the air conditioning system 10A can be installed later, and the room R Can be effectively removed.

As described above, the preferred embodiments of the present invention have been described in detail. However, the present invention is not limited to the specific embodiments, and various modifications may be made within the scope of the present invention described in the appended claims. Changes are possible.
For example, the configuration of the air-conditioning system according to the present invention is not limited to the above embodiments, and can be appropriately changed as long as the enthalpy difference between the air to be processed and the air for regeneration becomes 30 kJ / kg (DA) or more. . Further, the above embodiments may be appropriately combined depending on the facility of a building in which the air conditioning system according to the present invention is installed and various conditions.

DESCRIPTION OF SYMBOLS 1 Rotor 2 Processing zone 4 Regeneration zone 10A, 10B, 10C, 10D Air-conditioning system 14 Processing target air first supply part 16 Total heat exchanger 18 Cooling device 20 Regeneration air supply part 22 Heating device 24 Processing target air second supply part 26 Regeneration air discharge unit 32 Air handling unit 40 Heat pump 42 Compressor 44 Expansion valve 46 Condenser 48 Evaporator

Claims (5)

A processing zone that contains an absorbent of carbon dioxide that is an amine-carrying solid absorbent and absorbs carbon dioxide contained in the air to be treated when the air to be treated is ventilated, and regeneration air is ventilated. A rotor partitioned into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air,
A processing target air first supply unit that supplies room air to the processing zone as the processing target air,
A processing target air second supply unit that supplies the processing target air that has passed through the processing zone into the room,
A regeneration air supply unit for supplying outside air to the regeneration zone as the regeneration air,
A regeneration air discharge unit that discharges the regeneration air that has passed through the regeneration zone to the outside of the room,
A fan coil unit provided without being connected to the rotor and circulating air in the room;
With
In the processing target air first supply unit, a total heat exchanger and a cooling device are sequentially provided from the upstream side to the downstream side in the supply direction,
The regeneration air supply unit shares the total heat exchanger,
In the regeneration air supply unit, the total heat exchanger and a heating device are sequentially provided from an upstream side to a downstream side in a supply direction,
The total heat exchanger, the cooling device, and the heating device such that an enthalpy difference between the processing target air supplied to the processing zone and the regeneration air supplied to the regeneration zone is 30 kJ / kg (DA) or more . The fan coil unit operates ,
When the temperature and the relative humidity of the outside air are respectively higher than predetermined values in summer, the total heat exchanger and the heating device are in an OFF state, and the cooling device and the fan coil unit are in an ON state,
When the temperature and relative humidity of the outside air are each lower than a predetermined value in winter, the cooling device is in an OFF state, and the total heat exchanger, the heating device, and the fan coil unit are in an ON state,
When the temperature and relative humidity of the outside air are values between the summer predetermined value and the winter predetermined value, respectively, the total heat exchanger, the cooling device, the heating device, and the fan coil unit are turned on. Air conditioning system , which is configured as follows . A processing zone that contains an absorbent of carbon dioxide that is an amine-carrying solid absorbent and absorbs carbon dioxide contained in the air to be treated when the air to be treated is ventilated, and regeneration air is ventilated. A rotor partitioned into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air,
A processing target air first supply unit that supplies room air to the processing zone as the processing target air,
A processing target air second supply unit that supplies the processing target air that has passed through the processing zone into the room,
A regeneration air supply unit for supplying outside air to the regeneration zone as the regeneration air,
A regeneration air discharge unit that discharges the regeneration air that has passed through the regeneration zone to the outside of the room,
A fan coil unit provided without being connected to the rotor and circulating air in the room;
With
The processing target air first supply unit is provided with a cooling device,
The regeneration air supply unit is provided with a heating device,
The room air is configured to be able to be supplied to the regeneration air supply unit upstream of the heating device,
The cooling device, the heating device, and the fan coil unit are configured such that an enthalpy difference between the processing target air supplied to the processing zone and the regeneration air supplied to the regeneration zone is 30 kJ / kg (DA) or more. While operating, the amount of room air supplied to the regeneration air supply unit is adjusted,
When the temperature and relative humidity of the outside air are each higher than a summer predetermined value, the room air is not supplied to the regeneration air supply unit on the upstream side of the heating device,
An air conditioner configured so that when the temperature and the relative humidity of the outside air are each lower than a predetermined value in winter, all of the indoor air is supplied to the regeneration air supply unit upstream of the heating device. system. A processing zone that contains an absorbent of carbon dioxide that is an amine-carrying solid absorbent and absorbs carbon dioxide contained in the air to be treated when the air to be treated is ventilated, and regeneration air is ventilated. A rotor partitioned into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air,
A processing target air first supply unit that supplies room air to the processing zone as the processing target air,
A processing target air second supply unit that supplies the processing target air that has passed through the processing zone into the room,
A regeneration air supply unit for supplying outside air to the regeneration zone as the regeneration air,
A regeneration air discharge unit that discharges the regeneration air that has passed through the regeneration zone to the outside of the room,
With
The processing target air first supply unit is provided with an air handling unit and a cooling device from the upstream side to the downstream side in the supply direction,
Part of the air supplied from the air handling unit is supplied to the room,
The remainder of the air supplied from the air handling unit is supplied to the cooling device,
The regeneration air supply unit is provided with an auxiliary heating device, a humidifier, and a heating device from the upstream side to the downstream side in the supply direction,
The air handling unit, the cooling device, and the auxiliary heating device such that an enthalpy difference between the processing target air supplied to the processing zone and the regeneration air supplied to the regeneration zone is 30 kJ / kg (DA) or more. , The humidifier, the heating device operates,
When the temperature and the relative humidity of the outside air are each higher than a summer predetermined value, the condition of the processing target air supplied to the air handling unit is changed,
An air conditioning system configured to maintain a condition of the processing target air supplied to the air handling unit when a temperature and a relative humidity of the outside air are lower than predetermined values in winter, respectively . A processing zone that contains an absorbent of carbon dioxide that is an amine-carrying solid absorbent and absorbs carbon dioxide contained in the air to be treated when the air to be treated is ventilated, and regeneration air is ventilated. A rotor partitioned into a regeneration zone for desorbing the carbon dioxide absorbed by the absorbent into the regeneration air,
A processing target air first supply unit that supplies room air to the processing zone as the processing target air,
A processing target air second supply unit that supplies the processing target air that has passed through the processing zone into the room,
A regeneration air supply unit for supplying outside air to the regeneration zone as the regeneration air,
A regeneration air discharge unit that discharges the regeneration air that has passed through the regeneration zone to the outside of the room,
A fan coil unit provided without being connected to the rotor and circulating air in the room;
A compressor, an expansion valve, a heat pump having a condenser for condensing a heat medium circulating between the compressor and the expansion valve, and a first evaporator and a second evaporator for expanding the heat medium,
With
The regeneration air supply unit is provided with a humidifier,
In the processing target air first supply unit, the processing target air passes through the first evaporator,
In the regeneration air supply unit, the regeneration air sequentially passes through the condenser and the humidifier,
The regeneration air that has passed through the regeneration zone passes through the second evaporator,
The fan coil unit, the compressor, the expansion valve, and the enthalpy difference between the processing target air supplied to the processing zone and the regeneration air supplied to the regeneration zone are 30 kJ / kg (DA) or more . The condenser, the first evaporator and the second evaporator operate,
When the temperature and relative humidity of the outside air are each higher than a summer predetermined value, the condition of the condenser and the first evaporator is changed using the compressor and the expansion valve,
When the temperature and relative humidity of the outside air are lower than predetermined values in winter, respectively, the condition of the condenser and the first evaporator is changed by using the compressor and the expansion valve, and the first evaporator and the first evaporator are changed. (2) An air conditioning system configured to supply heat recovered by the evaporator to the condenser . The enthalpy of the room air is configured to be higher than the enthalpy of the outside air,
The air conditioning system according to any one of claims 1 to 4.

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