JP4258481B2 - Air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve quick cooling or heating in starting a system in the air conditioning system composed of a latent heat load treating system having an adsorption heat exchanger and mainly treating indoor latent heat load, and a sensible heat load treating system having an air heat exchanger and mainly treating indoor sensible heat load. <P>SOLUTION: This air conditioning system 1 comprises latent heat system use-side refrigerant circuits 10a, 10b and sensible heat system use-side refrigerant circuits 10c, 10d. The latent heat system use-side refrigerant circuits 10a, 10b have the adsorption heat exchangers 22, 23, 32, 33 provided with adsorbent on their surfaces. The sensible heat system use-side refrigerant circuits 10c, 10d have the air heat exchangers 42, 52 and perform heat exchange between the refrigerant and the air. In this air conditioning system 1, the air after heat exchange by the air heat exchangers 42, 52 is supplied indoors in starting the system, and the outdoor air is not allowed to pass through the adsorption heat exchangers 22, 23, 32, 33. <P>COPYRIGHT: (C)2006,JPO&amp;NCIPI

Description

  The present invention relates to an air conditioning system, and more particularly to an air conditioning system that processes indoor latent heat load and sensible heat load by performing a vapor compression refrigeration cycle operation.

  Conventionally, an air conditioner that performs indoor cooling and dehumidification is known (see, for example, Patent Document 1). Such an air conditioner includes a vapor compression refrigerant circuit having an outdoor heat exchanger as a heat source side heat exchanger and an indoor heat exchanger as an air heat exchanger, and the refrigerant circuit includes a refrigerant. Refrigeration cycle operation by circulating This air conditioner dehumidifies indoors by setting the evaporation temperature of the refrigerant in the indoor heat exchanger to be lower than the dew point temperature of the indoor air and condensing the moisture in the indoor air.

On the other hand, a dehumidifying device including a heat exchanger having an adsorbent on the surface is also known (see, for example, Patent Document 2). Such a dehumidifying device includes two heat exchangers provided with an adsorbent, and performs an adsorption operation in which one of the two heat exchangers adsorbs moisture in the air to dehumidify, and performs two heat exchanges. A regenerating operation for desorbing moisture adsorbed on the other side of the vessel is performed. At that time, water cooled by the cooling tower is supplied to the heat exchanger that adsorbs moisture, and hot waste water is supplied to the regenerated heat exchanger. And this dehumidification apparatus supplies the air dehumidified by adsorption | suction operation | movement and reproduction | regeneration operation | movement indoors.
International Publication No. 03/029728 Pamphlet JP-A-7-265649

  In the former air conditioner, the evaporating temperature of the refrigerant in the indoor heat exchanger is set lower than the dew point temperature of indoor air, and the indoor latent heat load is processed by condensing moisture in the air. In other words, even if the evaporation temperature of the refrigerant in the indoor heat exchanger is higher than the dew point temperature of the indoor air, the sensible heat load can be processed, but in order to handle the latent heat load, the refrigerant in the indoor heat exchanger The evaporation temperature has to be set to a low value. For this reason, there is a problem that the difference between high and low pressures of the vapor compression refrigeration cycle is increased, the power consumption in the compressor is increased, and only a low COP (coefficient of performance) can be obtained.

In the latter dehumidifier, the cooling water cooled by the cooling tower, that is, the cooling water having a temperature not much lower than the indoor temperature is supplied to the heat exchanger. Therefore, this dehumidifier has a problem that the sensible heat load cannot be processed even if the indoor latent heat load can be processed.
In contrast, the inventor of the present application has invented an air conditioner including a vapor compression refrigerant circuit having a heat source side heat exchanger and an adsorption heat exchanger as a use side heat exchanger (for example, (See Japanese Patent Application No. 2003-351268.) This air conditioner performs adsorption heat exchange by alternately performing an adsorption operation for adsorbing moisture in the air to an adsorption heat exchanger with an adsorbent on the surface and a regeneration operation for desorbing moisture from the adsorption heat exchanger. The air passing through the vessel can be supplied indoors to handle indoor sensible heat load and latent heat load. In other words, the moisture in the air is not condensed and the air is dehumidified as in the former air conditioner, but the moisture in the air is adsorbed by the adsorbent to dehumidify the air. It is not necessary to set the temperature lower than the dew point temperature of the air, and the air can be dehumidified even if the evaporation temperature of the refrigerant is set to be equal to or higher than the dew point temperature of the air. For this reason, according to this air conditioning apparatus, even when air is dehumidified, the evaporation temperature of the refrigerant can be set to a higher temperature than before, and the high / low pressure difference of the refrigeration cycle can be reduced. As a result, power consumption in the compressor can be reduced, and COP can be improved. In addition, when air is dehumidified, the indoor sensible heat load can also be processed by setting the temperature lower than the evaporation temperature of the refrigerant required in the adsorption heat exchanger.

  The inventor of the present application uses the air conditioner using the adsorption heat exchanger described above as a latent heat load processing system that mainly processes indoor latent heat loads, and has an air heat exchanger, I would like to construct an air conditioning system that combines a sensible heat load treatment system that handles heat load. In such an air conditioning system, it is desirable that cooling or heating can be performed quickly when the system is activated.

  An object of the present invention is to provide a latent heat load processing system having an adsorption heat exchanger and mainly processing an indoor latent heat load, and a sensible heat load processing system having an air heat exchanger and mainly processing an indoor sensible heat load. In the air conditioning system configured, the object is to enable rapid cooling or heating when the system is started.

  An air conditioning system according to a first aspect of the present invention is an air conditioning system for processing an indoor latent heat load and a sensible heat load by performing a vapor compression refrigeration cycle operation, the first usage side refrigerant circuit, 2 utilization side refrigerant circuit. The first usage-side refrigerant circuit has an adsorption heat exchanger having an adsorbent on its surface, and functions as a refrigerant evaporator to adsorb moisture in the air to the adsorbent, It is possible to dehumidify or humidify the air by alternately switching between a regeneration operation in which moisture in the air is desorbed from the adsorbent by functioning as a condenser. The 2nd utilization side refrigerant circuit has an air heat exchanger, and can perform heat exchange with a refrigerant and air. The air conditioning system can supply the air that has passed through the adsorption heat exchanger indoors, and can supply the air that has passed through the air heat exchanger indoors. The air conditioning system supplies the air heat-exchanged in the air heat exchanger indoors when the system is started, and prevents outdoor air from passing through the adsorption heat exchanger.

  In this air conditioning system, the latent heat load (hereinafter referred to as the required latent heat treatment capacity) that must be processed as the entire air conditioning system and the sensible heat load (hereinafter referred to as the required sensible heat processing capacity) that must be processed as the entire air conditioning system. And the sensible heat load processing system including the second usage side refrigerant circuit and the sensible heat load processing system including the second usage side refrigerant circuit.

  And in this air conditioning system, at the time of system start-up, the sensible heat treatment is mainly performed by supplying the air heat-exchanged in the air heat exchanger indoors, and the outdoor air is not allowed to pass through the adsorption heat exchanger. Therefore, it is possible to prevent the introduction of a heat load from outside air when the air conditioning capability of the latent heat load processing system is not being demonstrated when the system is started. The target temperature of air can be reached quickly. Thereby, it is comprised from the latent heat load processing system which has an adsorption heat exchanger, and mainly processes an indoor latent heat load, and the sensible heat load processing system which has an air heat exchanger and mainly processes an indoor sensible heat load. In an air conditioning system, cooling or heating can be performed quickly when the system is started.

  An air conditioning system according to a second aspect of the present invention is an air conditioning system for processing an indoor latent heat load and a sensible heat load by performing a vapor compression refrigeration cycle operation, the first usage side refrigerant circuit, 2 utilization side refrigerant circuit. The first usage-side refrigerant circuit has a plurality of adsorption heat exchangers having adsorbents provided on the surface thereof, an adsorption operation for functioning as a refrigerant evaporator and adsorbing moisture in the air to the adsorbents; It is possible to dehumidify or humidify the air by switching between a regeneration operation in which the moisture in the air is desorbed from the adsorbent by functioning as a refrigerant condenser. The 2nd utilization side refrigerant circuit has an air heat exchanger, and can perform heat exchange with a refrigerant and air. The air conditioning system can supply the air that has passed through the adsorption heat exchanger indoors, and can supply the air that has passed through the air heat exchanger indoors. The air conditioning system exhausts outdoor air after passing through one of the plurality of adsorption heat exchangers in a state where the switching of the adsorption operation and the regeneration operation of the plurality of adsorption heat exchangers is stopped when the system is started. In addition, the indoor air is supplied to the indoor again after passing through an adsorption heat exchanger different from the adsorption heat exchanger that allows outdoor air to pass among the plurality of adsorption heat exchangers.

  In this air conditioning system, the latent heat load (hereinafter referred to as the required latent heat treatment capacity) that must be processed as the entire air conditioning system and the sensible heat load (hereinafter referred to as the required sensible heat processing capacity) that must be processed as the entire air conditioning system. And the sensible heat load processing system including the second usage side refrigerant circuit and the sensible heat load processing system including the second usage side refrigerant circuit.

  And in this air conditioning system, at the time of system start-up, the sensible heat treatment is mainly performed by supplying the air heat-exchanged in the air heat exchanger indoors, and the outdoor air is adsorbed by the adsorption heat exchanger and Since the sensible heat treatment is mainly performed by passing it through the adsorption heat exchanger in the state where the switching of the regeneration operation is stopped and then discharging it to the outdoors, the sensible heat treatment is promoted indoors when the system is started. The target temperature of air can be reached quickly. Thereby, it is comprised from the latent heat load processing system which has an adsorption heat exchanger, and mainly processes an indoor latent heat load, and the sensible heat load processing system which has an air heat exchanger and mainly processes an indoor sensible heat load. In an air conditioning system, cooling or heating can be performed quickly when the system is started.

  An air conditioning system according to a third aspect of the present invention is an air conditioning system for processing an indoor latent heat load and a sensible heat load by performing a vapor compression refrigeration cycle operation, the first usage side refrigerant circuit, 2 utilization side refrigerant circuit. The first usage-side refrigerant circuit has a plurality of adsorption heat exchangers having adsorbents provided on the surface thereof, an adsorption operation for functioning as a refrigerant evaporator and adsorbing moisture in the air to the adsorbents; It is possible to dehumidify or humidify the air by switching between a regeneration operation in which the moisture in the air is desorbed from the adsorbent by functioning as a refrigerant condenser. The 2nd utilization side refrigerant circuit has an air heat exchanger, and can perform heat exchange with a refrigerant and air. The air conditioning system can supply the air that has passed through the adsorption heat exchanger indoors, and can supply the air that has passed through the air heat exchanger indoors. In the air conditioning system, when the system is started, the switching time interval between the adsorption operation and the regeneration operation of the adsorption heat exchanger is made longer than that during normal operation.

  In this air conditioning system, the latent heat load (hereinafter referred to as the required latent heat treatment capacity) that must be processed as the entire air conditioning system and the sensible heat load (hereinafter referred to as the required sensible heat processing capacity) that must be processed as the entire air conditioning system. And the sensible heat load processing system including the second usage side refrigerant circuit and the sensible heat load processing system including the second usage side refrigerant circuit.

  In this air-conditioning system, at the time of system startup, the target temperature of indoor air can be reached quickly by mainly performing sensible heat treatment with the switching time interval in the adsorption heat exchanger being longer than in normal operation. Thereby, it is comprised from the latent heat load processing system which has an adsorption heat exchanger, and mainly processes an indoor latent heat load, and the sensible heat load processing system which has an air heat exchanger and mainly processes an indoor sensible heat load. In an air conditioning system, cooling or heating can be performed quickly when the system is started.

An air conditioning system according to a fourth aspect of the present invention is the air conditioning system according to any one of the first to third aspects of the invention, and the operation at the time of system startup is canceled after a predetermined time has elapsed since the system startup.
In this air conditioning system, after a sufficient time has elapsed for the sensible heat treatment from the system start-up, the outdoor air is passed through the adsorption heat exchanger to perform the latent heat treatment or the adsorption heat. By switching the adsorption operation and regeneration operation of the exchanger, or by reducing the switching time interval of the adsorption heat exchanger, it is possible to quickly shift to a normal operation for processing indoor latent heat load and sensible heat load. .

An air conditioning system according to a fifth aspect of the present invention is the air conditioning system according to any one of the first to third aspects of the present invention, wherein the operation at the time of system startup is the temperature between the indoor air target temperature and the indoor air temperature. It is canceled after the difference becomes equal to or less than the predetermined temperature difference.
In this air conditioning system, the operation at the time of system start-up is performed after the sensible heat treatment is sufficiently performed after the temperature difference between the indoor air target temperature and the indoor air temperature is less than the predetermined temperature difference. Latent heat treatment indoors by passing latent heat through the adsorption heat exchanger, starting adsorption / regeneration switching of the adsorption heat exchanger, and reducing the switching time interval of the adsorption heat exchanger. It is possible to promptly shift to normal operation for processing the load and the sensible heat load.

  The air conditioning system according to a sixth aspect of the present invention is the air conditioning system according to any one of the first to fifth aspects of the present invention, wherein the indoor air target temperature and the indoor air are When the temperature difference between the indoor air target temperature and the indoor air temperature is less than the predetermined temperature difference, it is determined whether the temperature difference with the temperature is less than the predetermined temperature difference. Do not perform the operation.

  In this air conditioning system, before starting the operation of preferentially processing the indoor sensible heat load according to any one of the first to third inventions when the system is started, The determination is based on the temperature of the air. Thereby, at the time of system start-up, it is possible to promptly shift to the normal operation for processing the indoor latent heat load and the sensible heat load without performing the operation for preferentially processing the indoor sensible heat load unnecessarily.

As described above, according to the present invention, the following effects can be obtained.
In the first aspect of the invention, at the time of system startup, the sensible heat treatment is mainly performed by supplying the air heat-exchanged in the air heat exchanger indoors, and the outdoor air is not allowed to pass through the adsorption heat exchanger. Since the introduction of outside air is not performed, it becomes possible to prevent the introduction of a heat load from outside air when the air conditioning capability of the latent heat load processing system is not being demonstrated at the time of system startup. The target temperature can be quickly reached.

  In the second invention, at the time of starting the system, the air heat-exchanged in the air heat exchanger is supplied indoors to mainly perform sensible heat treatment, and the outdoor air is adsorbed and regenerated by the adsorption heat exchanger. Since the sensible heat treatment is mainly performed by passing the heat through the adsorption heat exchanger in the state where the switching is stopped and then discharging it to the outdoors, the target temperature of indoor air can be reached quickly.

In the third invention, at the time of starting the system, the target time of indoor air can be reached quickly by mainly performing the sensible heat treatment with the switching time interval in the adsorption heat exchanger being longer than that in the normal operation.
In the fourth aspect of the invention, the operation at the time of starting the system is performed after the time sufficient for performing the sensible heat treatment from the start of the system to perform outdoor heat treatment by passing outdoor air through the adsorption heat exchanger, By switching the adsorption operation and regeneration operation of the exchanger, or by reducing the switching time interval of the adsorption heat exchanger, it is possible to quickly shift to a normal operation for processing indoor latent heat load and sensible heat load. .

  In the fifth aspect of the invention, when the system is started, the temperature difference between the indoor air target temperature and the indoor air temperature is equal to or lower than the predetermined temperature difference, and the sensible heat treatment is sufficiently performed. Latent heat treatment indoors by performing latent heat treatment by passing air through the adsorption heat exchanger, starting the switching of adsorption operation and regeneration operation of the adsorption heat exchanger, and reducing the switching time interval of the adsorption heat exchanger It is possible to promptly shift to normal operation for processing the load and the sensible heat load.

  In 6th invention, at the time of system start-up, without performing the operation | movement which preferentially processes indoor sensible heat load unnecessarily, it transfers to normal operation which processes indoor latent heat load and sensible heat load quickly. Can do.

Hereinafter, embodiments of an air conditioning system according to the present invention will be described with reference to the drawings.
[First Embodiment]
(1) Configuration of Air Conditioning System FIG. 1 is a schematic refrigerant circuit diagram of an air conditioning system 1 according to a first embodiment of the present invention. The air conditioning system 1 is an air conditioning system that processes a latent heat load and a sensible heat load in a building or the like by performing a vapor compression refrigeration cycle operation. The air conditioning system 1 is a so-called separate type multi-air conditioning system, and mainly includes a plurality of (in this embodiment, two) latent heat system utilization units 2 and 3 that are connected in parallel to each other. A plurality of (in this embodiment, two) sensible heat system utilization units 4 and 5, a heat source unit 6, a latent heat system utilization unit 2 and 3, and a sensible heat system utilization unit 4 and 5 and a heat source connected in parallel Connecting pipes 7, 8, 9 for connecting the unit 6 are provided. In the present embodiment, the heat source unit 6 functions as a heat source common to the latent heat system use units 2 and 3 and the sensible heat system use units 4 and 5. In the present embodiment, only one heat source unit 6 is provided. However, when there are a large number of latent heat system use units 2, 3 and sensible heat system use units 4, 5, etc., a plurality of units are connected in parallel. It may be.

<Latent heat system use unit>
The latent heat system utilization units 2 and 3 are installed in an indoor ceiling of a building or the like by being hung or suspended, by a wall or the like, or in a space behind the ceiling. The latent heat system use units 2 and 3 are connected to the heat source unit 6 via the connection pipes 8 and 9, and constitute a refrigerant circuit 10 with the heat source unit 6. The latent heat system use units 2 and 3 perform a vapor compression refrigeration cycle operation by circulating the refrigerant in the refrigerant circuit 10 to mainly process a latent heat load indoors (also in the following description). When the term “latent heat load processing system” is used, it functions as a combination of the latent heat system use units 2 and 3 and the heat source unit 6).

  Next, the configuration of the latent heat system use units 2 and 3 will be described. Since the latent heat system utilization unit 2 and the latent heat system utilization unit 3 have the same configuration, only the configuration of the latent heat system utilization unit 2 will be described here. The configuration of the latent heat system utilization unit 3 will be described below. Reference numerals in the 30th order are assigned instead of reference numerals in the 20th order indicating the respective parts of 2, and description of each part is omitted.

The latent heat system utilization unit 2 mainly constitutes a part of the refrigerant circuit 10 and includes a latent heat system utilization side refrigerant circuit 10a capable of dehumidifying or humidifying air. This latent heat system utilization side refrigerant circuit 10a mainly includes a latent heat system utilization side four-way switching valve 21, a first adsorption heat exchanger 22, a second adsorption heat exchanger 23, and a latent heat system utilization side expansion valve 24. I have.
The latent heat system use side four-way switching valve 21 is a valve for switching the flow path of the refrigerant flowing into the latent heat system use side refrigerant circuit 10a, and the first port 21a thereof is connected to the heat source unit 6 via the discharge gas communication pipe 8. The second port 21b is connected to the suction side of the compression mechanism 61 of the heat source unit 6 via the suction gas communication pipe 9, and the third port 21b is connected to the discharge side of the compression mechanism 61 (described later). 21 c is connected to the gas side end of the first adsorption heat exchanger 22, and the fourth port 21 d is connected to the gas side end of the second adsorption heat exchanger 23. The latent heat system use side four-way switching valve 21 connects the first port 21a and the third port 21c and connects the second port 21b and the fourth port 21d (first state, using the latent heat system of FIG. 1). 1), the first port 21a and the fourth port 21d are connected, and the second port 21b and the third port 21c are connected (second state, latent heat system of FIG. 1). It is possible to perform switching that refers to the broken line of the use side four-way switching valve 21).

  The first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 are cross fin type fin-and-tube heat exchangers configured by heat transfer tubes and a large number of fins. Specifically, the first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 include a large number of aluminum fins formed in a rectangular plate shape, and a copper heat transfer tube penetrating the fins. Yes. The first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 are not limited to cross-fin fin-and-tube heat exchangers, but other types of heat exchangers such as corrugated fin-type heat exchangers. It may be a heat exchanger or the like.

  In the first adsorption heat exchanger 22 and the second adsorption heat exchanger 23, an adsorbent is supported on the surface of the fin by dip molding (immersion molding). The method for supporting the adsorbent on the surfaces of the fins and the heat transfer tubes is not limited to dip molding, and the adsorbent may be supported on the surface by any method as long as the performance as the adsorbent is not impaired. . As this adsorbent, functionalities such as zeolite, silica gel, activated carbon, organic polymer polymer material having hydrophilicity or water absorption, ion exchange resin material having carboxylic acid group or sulfonic acid group, temperature sensitive polymer, etc. A polymer material or the like can be used.

  The first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 function as a refrigerant evaporator while allowing air to pass outside thereof, so that moisture in the air is adsorbed by the adsorbent supported on the surface of the first adsorption heat exchanger 22 and the second adsorption heat exchanger 23. Can be made. In addition, the first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 function as a refrigerant condenser while allowing air to pass through the outside of the first adsorption heat exchanger 22 and the second adsorption heat exchanger 23. Can be desorbed.

The latent heat system use side expansion valve 24 is an electric expansion valve connected between the liquid side end of the first adsorption heat exchanger 22 and the liquid side end of the second adsorption heat exchanger 23, and serves as a condenser. Depressurizing the refrigerant sent from one of the functioning first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 to the other of the first adsorption heat exchanger 22 and the second adsorption heat exchanger 23 functioning as an evaporator. Can do.
Further, although not shown in detail, the latent heat system utilization unit 2 is configured to suck outside air (hereinafter referred to as “outdoor air OA”) into the unit, and to discharge the air from the inside to the outside. , An indoor air inlet for sucking indoor air (hereinafter referred to as indoor air RA) into the unit, and an air blown indoors from the unit (hereinafter referred to as supply air SA) The air flow path for switching the air flow path, the exhaust fan disposed in the unit so as to communicate with the exhaust port, the air supply fan disposed in the unit so as to communicate with the air inlet, And a switching mechanism including a damper or the like. As a result, the latent heat system utilization unit 2 sucks the outdoor air OA from the outside air inlet into the unit, passes the first or second adsorption heat exchangers 22 and 23, and then supplies the air SA supplied indoors from the inlet. Or the outdoor air OA is sucked into the unit from the outside air inlet and passed through the first or second adsorption heat exchangers 22 and 23, and then discharged as exhaust air EA from the outlet to the outside. The air RA is sucked into the unit from the inside air suction port, passed through the first or second adsorption heat exchangers 22 and 23, and then supplied indoors as the supply air SA from the air supply port, or the indoor air RA is sucked into the room air. After being sucked into the unit from the mouth and passed through the first or second adsorptive heat exchangers 22 and 23, the air can be discharged from the exhaust port to the outside as exhaust air EA.

  Furthermore, the latent heat system utilization unit 2 includes an RA intake temperature / humidity sensor 25 that detects the temperature and relative humidity of the indoor air RA sucked into the unit, and the temperature and relative humidity of the outdoor air OA sucked into the unit. OA intake temperature / humidity sensor 26 to detect, SA supply temperature sensor 27 to detect the temperature of supply air SA supplied indoors from within the unit, and latent heat system to control the operation of each part constituting the latent heat system utilization unit 2 And a use side control unit 28. The latent heat system use side control unit 28 includes a microcomputer and a memory provided for controlling the latent heat system use unit 2, and passes through the remote controller 11 and a heat source side control unit 65 of the heat source unit 6 described later. In addition, it is possible to exchange input signals for the target temperature and target humidity of indoor air, and to exchange control signals and the like with the heat source unit 6.

<Sensible heat system use unit>
The sensible heat system utilization units 4 and 5 are installed in a ceiling or the like by embedding or hanging in an indoor ceiling of a building or the like, or by hanging on a wall or the like. The sensible heat system utilization units 4, 5 are connected to the heat source unit 6 via the connection pipes 7, 8, 9 and the connection units 14, 15, and constitute a refrigerant circuit 10 with the heat source unit 6. . The sensible heat system use units 4 and 5 function as a sensible heat load processing system that mainly processes indoor sensible heat loads by circulating a refrigerant in the refrigerant circuit 10 and performing a vapor compression refrigeration cycle operation. (In the following description, the term “latent heat load processing system” refers to a combination of the latent heat system utilization units 2 and 3 and the heat source unit 6). The sensible heat system utilization unit 4 is installed in the same conditioned space as the latent heat system utilization unit 2, and the sensible heat system utilization unit 5 is installed in the same conditioned space as the latent heat system utilization unit 3. That is, the latent heat system utilization unit 2 and the sensible heat system utilization unit 4 are paired to process a latent heat load and a sensible heat load in a certain air-conditioned space. Are paired to process the latent heat load and sensible heat load of another air-conditioned space.

  Next, the structure of the sensible heat system utilization units 4 and 5 will be described. In addition, since the sensible heat system utilization unit 4 and the sensible heat system utilization unit 5 have the same configuration, only the configuration of the sensible heat system utilization unit 4 will be described here. The reference numerals in the 50s are attached instead of the reference numerals in the 40s indicating the respective parts of the sensible heat system utilization unit 4, and the description of each part is omitted.

  The sensible heat system utilization unit 4 mainly constitutes a part of the refrigerant circuit 10, and the sensible heat system utilization side refrigerant circuit 10c capable of dehumidifying or humidifying the air (in the sensible heat system utilization unit 5, the sensible heat system utilization unit 5 A heat system utilization side refrigerant circuit 10d) is provided. The sensible heat system use side refrigerant circuit 10 c mainly includes a sensible heat system use side expansion valve 41 and an air heat exchanger 42. In this embodiment, the sensible heat system use side expansion valve 41 is an electric expansion valve connected to the liquid side of the air heat exchanger 42 in order to adjust the refrigerant flow rate and the like. In the present embodiment, the air heat exchanger 42 is a cross-fin type fin-and-tube heat exchanger composed of heat transfer tubes and a large number of fins, and performs heat exchange between the refrigerant and the indoor air RA. Equipment. In the present embodiment, the sensible heat system utilization unit 4 includes a blower fan (not shown) for supplying indoor air RA as supply air SA after sucking indoor air RA into the unit and exchanging heat. It is possible to exchange heat between the indoor air RA and the refrigerant flowing through the air heat exchanger 322.

  The sensible heat system utilization unit 4 is provided with various sensors. A liquid side temperature sensor 43 that detects the temperature of the liquid refrigerant is provided on the liquid side of the air heat exchanger 42, and a gas side temperature sensor 44 that detects the temperature of the gas refrigerant on the gas side of the air heat exchanger 42. Is provided. Further, the sensible heat system utilization unit 4 is provided with an RA suction temperature sensor 55 for detecting the temperature of the indoor air RA sucked into the unit. In addition, the sensible heat system utilization unit 4 includes a sensible heat system utilization side control unit 48 that controls the operation of each part constituting the sensible heat system utilization unit 4. The sensible heat system use side control unit 48 includes a microcomputer and a memory provided for controlling the sensible heat system use unit 4, and the target temperature and target humidity of the indoor air through the remote controller 11. It is also possible to exchange input signals and the like, and exchange control signals and the like with the heat source unit 6.

<Heat source unit>
The heat source unit 6 is installed on the rooftop of a building or the like, and is connected to the latent heat system use units 2 and 3 and the sensible heat system use units 4 and 5 via the connecting pipes 7, 8, and 9. A refrigerant circuit 10 is configured between the use units 2 and 3 and the sensible heat system use units 4 and 5.

Next, the configuration of the heat source unit 6 will be described. The heat source unit 6 mainly constitutes a part of the refrigerant circuit 10 and includes a heat source side refrigerant circuit 10e. The heat source side refrigerant circuit 10e mainly includes a compression mechanism 61, a three-way switching valve 62, a heat source side heat exchanger 63, a heat source side expansion valve 64, and a receiver 68.
In the present embodiment, the compression mechanism 61 is a positive displacement compressor capable of changing the operation capacity by inverter control. In the present embodiment, the compression mechanism 61 is a single compressor, but is not limited to this, and two or more compressors are connected in parallel according to the number of units used. May be.

  The three-way switching valve 62 connects the discharge side of the compression mechanism 61 and the gas side of the heat source side heat exchanger 63 when the heat source side heat exchanger 63 functions as a condenser (hereinafter referred to as a condensation operation state). When the heat source side heat exchanger 63 functions as an evaporator (hereinafter referred to as an evaporation operation state), the heat source is connected so that the suction side of the compression mechanism 61 and the gas side of the heat source side heat exchanger 63 are connected. This is a valve for switching the flow path of the refrigerant in the side refrigerant circuit 10e. The first port 62a is connected to the discharge side of the compression mechanism 61, and the second port 62b is connected to the suction side of the compression mechanism 61. The third port 62 c is connected to the gas side end of the heat source side heat exchanger 63. As described above, the three-way switching valve 62 connects the first port 62a and the third port 62c (corresponding to the condensation operation state, see the solid line of the three-way switching valve 62 in FIG. 1), It is possible to perform switching to connect the 2-port 62b and the third port 62c (corresponding to the evaporation operation state, see the broken line of the three-way switching valve 62 in FIG. 1). A discharge gas communication pipe 8 is connected between the discharge side of the compression mechanism 61 and the three-way switching valve 62. Accordingly, the high-pressure gas refrigerant compressed and discharged by the compression mechanism 61 can be supplied to the latent heat system use units 2 and 3 and the sensible heat system use units 4 and 5 regardless of the switching operation of the three-way switching valve 62. It has become. The suction side of the compression mechanism 61 is connected to a suction gas communication pipe 9 through which a low-pressure gas refrigerant returning from the latent heat system use units 2 and 3 and the sensible heat system use units 4 and 5 flows.

  In this embodiment, the heat source side heat exchanger 63 is a cross-fin type fin-and-tube heat exchanger constituted by heat transfer tubes and a large number of fins, and exchanges heat with refrigerant using air as a heat source. Equipment. In the present embodiment, the heat source unit 6 includes an outdoor fan (not shown) for taking outdoor air into the unit and sending it out, and heats the outdoor air and the refrigerant flowing through the heat source side heat exchanger 63. It is possible to exchange.

  In the present embodiment, the heat source side expansion valve 64 can adjust the flow rate of the refrigerant flowing between the heat source side heat exchanger 63 and the air heat exchangers 42 and 52 via the liquid communication pipe 7. It is an electric expansion valve. The heat source side expansion valve 64 is used in a substantially fully open state when the heat source side heat exchanger 63 is in the condensing operation state, and the opening degree is adjusted when the heat source side heat exchanger 63 is in the condensing operation state and communicates with the liquid from the air heat exchangers 42 and 52. It is used to decompress the refrigerant flowing into the heat source side heat exchanger 63 via the pipe 7.

The receiver 68 is a container for temporarily storing the refrigerant flowing between the heat source side heat exchanger 63 and the air heat exchangers 42 and 52. In the present embodiment, the receiver 68 is connected between the heat source side expansion valve 64 and the liquid communication pipe 7.
The heat source unit 6 is provided with various sensors. Specifically, the heat source unit 6 performs the operation of the suction pressure sensor 66 that detects the suction pressure of the compression mechanism 61, the discharge pressure sensor 67 that detects the discharge pressure of the compression mechanism 61, and the operation of each part of the heat source unit 6. The heat source side control part 65 to control is provided. The heat source side control unit 65 includes a microcomputer and a memory provided to control the heat source unit 6, and the latent heat system use side control units 28 and 38 of the latent heat system use units 2 and 3 Control signals can be transmitted between the sensible heat system use side control units 48 and 58 of the heat system use units 4 and 5. Further, the heat source side control unit 65 can exchange control signals and the like with the heat source side control unit 65.

  In the air conditioning system 1 of the present embodiment, the high-pressure gas refrigerant compressed and discharged by the compression mechanism 61 of the heat source unit 6 is supplied to the adsorption heat exchangers 22 of the latent heat system utilization units 2 and 3 via the discharge gas communication pipe 8. 23, 32, 33, and return to the suction side of the compression mechanism 61 of the heat source unit 6 from the adsorption heat exchangers 22, 23, 32, 33 of the latent heat system utilization units 2, 3 through the suction gas communication pipe 9. Can be done. For this reason, indoor dehumidification or humidification can be performed regardless of the operation of the sensible heat system utilization units 4 and 5.

  The sensible heat system utilization units 4 and 5 are connected to the gas side of the air heat exchangers 42 and 52 so as to be switchable to the discharge gas communication pipe 8 and the suction gas communication pipe 9 via the connection units 14 and 15. The connection units 14 and 15 mainly include cooling / heating switching valves 71 and 81 and connection unit control units 72 and 82 for controlling the operations of the respective parts constituting the connection units 14 and 15. When the sensible heat system utilization units 4 and 5 perform the cooling operation, the cooling / heating switching valves 71 and 81 are connected to the gas side of the air heat exchangers 42 and 52 of the sensible heat system utilization units 4 and 5 and the intake gas communication pipe 9. When the sensible heat system use units 4 and 5 perform the heating operation, the gas side of the air heat exchangers 42 and 52 of the sensible heat system use units 4 and 5 is connected. Is a valve that functions as a switching mechanism for switching between a state (hereinafter referred to as a heating operation state) for connecting the discharge gas communication pipe 8 and the discharge gas communication pipe 8, and the first ports 71 a and 81 a are connected to the air heat exchangers 42 and 52. The second ports 71 b and 81 b are connected to the intake gas communication pipe 9, and the third ports 71 c and 81 c are connected to the discharge gas communication pipe 8. The cooling / heating switching valves 71, 81 connect the first ports 71a, 81a and the second ports 71b, 81b as described above (corresponding to the cooling operation state, the solid lines of the cooling / heating switching valves 71, 81 in FIG. 1). Or the first port 71a, 81a and the third port 71c, 81c can be connected (corresponding to the heating operation state, see the broken line of the cooling / heating switching valves 71, 81 in FIG. 1). is there. The connection unit control units 72 and 82 include a microcomputer and a memory provided for controlling the connection units 14 and 15, and the sensible heat system use side control unit 48 of the sensible heat system use units 4 and 5. , 58 can transmit control signals. Thereby, the sensible heat system utilization units 4 and 5 can perform a so-called simultaneous cooling and heating operation, for example, the sensible heat system utilization unit 4 is in a cooling operation while the sensible heat system utilization unit 5 is in a heating operation. It has become.

(2) Operation | movement of an air conditioning system Next, operation | movement of the air conditioning system 1 of this embodiment is demonstrated. The air conditioning system 1 can process an indoor latent heat load with a latent heat load processing system, and can process an indoor sensible heat load mainly with a sensible heat load processing system. Prior to the description of the various operation operations, first, operations during the independent operation of the latent heat load processing system of the air conditioning system 1 (that is, when the sensible heat system utilization units 4 and 5 are not operated) will be described.

The air conditioning system 1 can perform various dehumidifying operations and humidifying operations as described below by an independent operation of only the latent heat load processing system.
<All ventilation modes>
First, the dehumidifying operation and the humidifying operation in the full ventilation mode will be described. In the full ventilation mode, when the air supply fan and the exhaust fan of the latent heat system utilization units 2 and 3 are operated, the outdoor air OA is sucked into the unit through the outside air inlet and supplied indoors as the supply air SA through the air inlet. Then, an operation is performed in which the indoor air RA is sucked into the unit through the inside air inlet and discharged to the outside as exhaust air EA through the outlet.

The operation during the dehumidifying operation in the full ventilation mode will be described with reference to FIGS. 2, 3 and 4. Here, FIGS. 2 and 3 are schematic refrigerant circuit diagrams showing the operation during the dehumidifying operation in the full ventilation mode when only the latent heat load processing system of the air conditioning system 1 is operated. FIG. 4 is a control flow diagram when only the latent heat load processing system of the air conditioning system 1 is operated.
2 and 3, during the dehumidifying operation, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated.

In the following description, the operations of the two latent heat system use units 2 and 3 will be described together.
In the first operation, the regeneration operation for the first adsorption heat exchangers 22 and 32 and the adsorption operation for the second adsorption heat exchangers 23 and 33 are performed in parallel. During the first operation, as shown in FIG. 2, the latent heat system use-side four-way switching valves 21 and 31 are in the first state (see the solid line of the latent heat system use-side four-way switching valves 21 and 31 in FIG. 2). Is set. In this state, the high-pressure gas refrigerant discharged from the compression mechanism 61 flows into the first adsorption heat exchangers 22 and 32 through the discharge gas communication pipe 8 and the latent heat system use side four-way switching valves 21 and 31, and the first It condenses while passing through the adsorption heat exchangers 22 and 32. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 24 and 34 and then evaporated while passing through the second adsorption heat exchangers 23 and 33, and the latent heat system use side four-way switching valve 21. , 31 is again sucked into the compression mechanism 61 through the suction gas communication pipe 9 (see the arrow attached to the refrigerant circuit 10 in FIG. 2). At this time, since the sensible heat system utilization side expansion valves 41 and 51 of the sensible heat system utilization units 4 and 5 are closed, the refrigerant does not flow into the sensible heat system utilization units 4 and 5.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is discharged to the outdoors as exhaust air EA through the exhaust port accompanying the indoor air RA. In the second adsorption heat exchangers 23 and 33, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. The outdoor air OA dehumidified by the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 22, 23, 32, and 33 in FIG. 2). (See arrows on both sides of the).

  In the second operation, the adsorption operation for the first adsorption heat exchangers 22 and 32 and the regeneration operation for the second adsorption heat exchangers 23 and 33 are performed in parallel. During the second operation, as shown in FIG. 3, the latent heat system use-side four-way switching valves 21 and 31 are in the second state (refer to the broken lines of the latent heat system use-side four-way switching valves 21 and 31 in FIG. 3). Is set. In this state, the high-pressure gas refrigerant discharged from the compression mechanism 61 flows into the second adsorption heat exchangers 23 and 33 through the discharge gas communication pipe 8 and the latent heat system use-side four-way switching valves 21 and 31, and the second It condenses while passing through the adsorption heat exchangers 23 and 33. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 24 and 34 and then evaporated while passing through the first adsorption heat exchangers 22 and 32, and the latent heat system use side four-way switching valve 21. , 31 is again sucked into the compression mechanism 61 through the suction gas communication pipe 9 (see the arrow attached to the refrigerant circuit 10 in FIG. 3).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is accompanied by the indoor air RA and discharged to the outdoors as exhaust air EA through the exhaust port. In the first adsorption heat exchangers 22 and 32, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant, and the refrigerant evaporates. The outdoor air OA dehumidified by the first adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 22, 23, 32, and 33 in FIG. 3). (See arrows on both sides of the).

Here, the system control performed at the time of the independent operation of only the latent heat load processing system of the air conditioning system 1 will be described.
First, when the indoor air target temperature and target relative humidity are set by the remote controllers 11 and 12, the latent heat system use side control units 28 and 38 of the latent heat system use units 2 and 3 receive these target temperature values and targets. Along with the relative humidity value, the temperature value and relative humidity value of the indoor air sucked into the unit detected by the RA suction temperature / humidity sensors 25, 35, and the unit detected by the OA suction temperature / humidity sensors 26, 36 The temperature value and the relative humidity value of the outdoor air sucked in are input.

  Then, in step S1, the latent heat system use side control units 28 and 38 calculate the target value of enthalpy or the target value of absolute humidity from the target temperature value and target relative humidity value of indoor air, The current value of the enthalpy of air sucked into the unit from the indoor or the current value of absolute humidity is calculated from the temperature value and the relative humidity value detected by the humidity sensors 25 and 35, and the difference between the two values (hereinafter referred to as necessary latent heat capacity). Value Δh). Here, the necessary latent heat capacity value Δh is the difference between the target value of indoor air enthalpy or the target value of absolute humidity and the current enthalpy value or absolute humidity value of indoor air as described above. This corresponds to the latent heat load that must be processed in the system 1. Then, the value of the necessary latent heat capacity value Δh is converted into a capacity UP signal K1 for notifying the heat source side control unit 65 whether or not the processing capacity of the latent heat system use units 2 and 3 needs to be increased. For example, when the absolute value of Δh is smaller than a predetermined value (that is, when the humidity value of indoor air is close to the target humidity value and there is no need to increase or decrease the processing capacity), the capability UP signal K1 is set to “ 0, and when the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the dehumidifying operation, the humidity value of indoor air is higher than the target humidity value and the processing capacity needs to be increased) If the capacity UP signal K1 is “A” and the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be reduced (that is, in the dehumidifying operation, the humidity value of the indoor air is If the humidity is lower than the target humidity value and the processing capacity needs to be lowered, the capacity UP signal K1 is set to “B”.

  Next, in step S2, the heat source side control unit 65 uses the capability UP signal K1 of the latent heat system utilization units 2 and 3 transmitted from the latent heat system utilization side control units 28 and 38, and uses the target condensation temperature value TcS1 and the target condensation temperature value TcS1. The evaporation temperature value TeS1 is calculated. For example, the target condensation temperature value TcS1 is calculated by adding the capability UP signal K1 of the latent heat system use units 2 and 3 to the current target condensation temperature value. Further, the target evaporation temperature value TeS1 is calculated by subtracting the capability UP signal K1 of the latent heat system use units 2 and 3 from the current target evaporation temperature value. As a result, when the value of the capability UP signal K1 is “A”, the target condensation temperature value TcS1 becomes high and the target evaporation temperature value TeS1 becomes low.

  Next, in step S3, a system condensing temperature value Tc1 and a system evaporating temperature value Te1 which are values corresponding to actual measured values of the condensing temperature and the evaporating temperature of the entire air conditioning system 1 are calculated. For example, the system condensing temperature value Tc1 and the system evaporation temperature value Te1 are the suction pressure value of the compression mechanism 61 detected by the suction pressure sensor 66 and the discharge pressure value of the compression mechanism 61 detected by the discharge pressure sensor 67. It is calculated by converting into the refrigerant saturation temperature at the pressure value. Then, the temperature difference ΔTc1 of the target condensation temperature value TcS1 with respect to the system condensation temperature value Tc1 and the temperature difference ΔTe1 of the target evaporation temperature value TeS1 with respect to the system evaporation temperature value Te1 are calculated, and by dividing these temperature differences, the compression mechanism 61 Determine whether the operating capacity needs to be increased or decreased and the range of increase or decrease.

  By controlling the operation capacity of the compression mechanism 61 using the operation capacity of the compression mechanism 61 determined in this way, system control is performed so as to approach the target temperature and target relative humidity of indoor air. For example, when the value obtained by subtracting the temperature difference ΔTe1 from the temperature difference ΔTc1 is a positive value, the operating capacity of the compression mechanism 61 is increased. Conversely, when the value obtained by subtracting the temperature difference ΔTe1 from the temperature difference ΔTc1 is a negative value. Controls to reduce the operating capacity of the compression mechanism 61.

  Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 adsorb moisture in the air and desorb the adsorbed moisture into the air by the adsorption operation and the regeneration operation. In addition to the separation process (hereinafter referred to as latent heat treatment), a process of changing the temperature by cooling or heating the passing air (hereinafter referred to as sensible heat treatment) is also performed. FIG. 5 shows a graph in which the latent heat treatment capability and the sensible heat treatment capability obtained in the adsorption heat exchanger are displayed with the horizontal axis indicating the switching time interval between the first operation and the second operation, that is, the adsorption operation and the regeneration operation. According to this, when the switching time interval is shortened (time C in FIG. 5 is set to the latent heat priority mode), the latent heat treatment, that is, the process of adsorbing or desorbing moisture in the air is preferentially performed. When the switching time interval is increased (time D in FIG. 5, the sensible heat priority mode is selected), it is understood that sensible heat treatment, that is, processing for changing the temperature by cooling or heating the air is preferentially performed. . For example, when air is brought into contact with the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 functioning as an evaporator, moisture is first adsorbed mainly by an adsorbent provided on the surface. This is because the heat of adsorption generated at this time is processed, but if moisture is adsorbed to the vicinity of the moisture adsorption capacity of the adsorbent, air is mainly cooled thereafter. In addition, when air is brought into contact with the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 that function as condensers, the adsorbent is initially treated mainly by heat treatment of the adsorbent provided on the surface. This is because the moisture adsorbed on the air is desorbed in the air, but when the water adsorbed on the adsorbent is almost desorbed, the air is mainly heated thereafter. The ratio of the sensible heat treatment capacity to the latent heat treatment capacity (hereinafter referred to as the sensible heat treatment capacity ratio) can be changed by changing the switching time interval according to a command from the latent heat system utilization side control units 28 and 38. It is like that. As will be described later, the latent heat load processing system of the air conditioning system 1 is operated together with the sensible heat load processing system (that is, when the sensible heat system utilization units 4 and 5 are operated, hereinafter referred to as normal operation). In order to mainly perform the latent heat treatment, the switching time interval is set to the time C, that is, the latent heat priority mode.

Thus, in this air conditioning system 1, in the dehumidifying operation only in the latent heat load processing system, the outdoor air is dehumidified and cooled by the sensible heat treatment capability obtained according to the switching time interval. The cooling operation to supply to can be performed.
The operation during the humidifying operation in the full ventilation mode will be described with reference to FIGS. 6 and 7. Here, FIGS. 6 and 7 are schematic refrigerant circuit diagrams showing the operation during the humidification operation in the full ventilation mode only in the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  6 and 7, during the humidification operation, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through the air supply port along with the outdoor air OA. In the second adsorption heat exchangers 23 and 33, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the second adsorption heat exchangers 23 and 33 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 6). (See arrows on both sides.)

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port along with the outdoor air OA. In the first adsorption heat exchangers 22 and 32, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the first adsorption heat exchangers 22 and 32 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 7). (See arrows on both sides.)

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only the latent heat treatment but also the sensible heat treatment, similarly to the dehumidifying operation in the above-described total ventilation mode.
Thus, in this air conditioning system 1, in the humidification operation of only the latent heat load treatment system in the full ventilation mode, the outdoor air is humidified and heated by the sensible heat treatment ability obtained according to the switching time interval. Humidification operation can be performed.

<Circulation mode>
Next, the dehumidifying operation and the humidifying operation in the circulation mode will be described. In the circulation mode, when the air supply fan and the exhaust fan of the latent heat system utilization units 2 and 3 are operated, the indoor air RA is sucked into the unit through the internal air inlet and supplied indoors as the supply air SA through the air inlet. An operation is performed in which the outdoor air OA is sucked into the unit through the outside air inlet and discharged to the outside as exhaust air EA through the exhaust port.

  The operation during the dehumidifying operation in the circulation mode will be described with reference to FIGS. Here, FIG. 8 and FIG. 9 are schematic refrigerant circuit diagrams showing the operation during the dehumidifying operation in the circulation mode in only the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  During the dehumidifying operation, as shown in FIGS. 8 and 9, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is exhausted to the outdoors as exhaust air EA through the exhaust port accompanying the outdoor air OA. In the second adsorption heat exchangers 23 and 33, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port (the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 8). (See arrows on both sides of the).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is accompanied by the outdoor air OA and discharged to the outdoors as exhaust air EA through the exhaust port. In the first adsorption heat exchangers 22 and 32, the moisture in the indoor air RA is adsorbed by the adsorbent and the indoor air is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. And the indoor air RA dehumidified by the 1st adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through an air supply opening (Adsorption heat exchangers 22, 23, 32, and 33 of FIG. 9). (See arrows on both sides of the).

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only latent heat treatment but also sensible heat treatment.
Thus, in this air conditioning system 1, in the dehumidifying operation in the circulation mode of only the latent heat load processing system, the indoor air is dehumidified and cooled by the sensible heat treatment capability obtained according to the switching time interval. The supplied dehumidifying operation can be performed.

  The operation during the humidification operation in the circulation mode will be described with reference to FIGS. Here, FIG. 10 and FIG. 11 are schematic refrigerant circuit diagrams showing the operation during the dehumidifying operation in the circulation mode only in the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  During the humidification operation, as shown in FIGS. 10 and 11, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is supplied indoors as the supply air SA through the air supply port along with the indoor air RA. In the second adsorption heat exchangers 23 and 33, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the outdoor air OA dehumidified by the second adsorption heat exchangers 23 and 33 is discharged outdoors as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 10). See arrows on both sides).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is supplied indoors as the supply air SA through the air supply port along with the indoor air RA. In the first adsorption heat exchangers 22 and 32, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant, and the refrigerant evaporates. Then, the outdoor air OA dehumidified by the first adsorption heat exchangers 22 and 32 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 11). See arrows on both sides).

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only the latent heat treatment but also the sensible heat treatment, similarly to the dehumidifying operation in the above-described total ventilation mode.
As described above, in the air conditioning system 1, in the humidification operation in the circulation mode of only the latent heat load processing system, the indoor air is humidified and heated by the sensible heat treatment ability obtained according to the switching time interval. The humidification heating operation to supply can be performed.

<Air supply mode>
Next, the dehumidifying operation and the humidifying operation in the air supply mode will be described. In the air supply mode, when the air supply fan and the exhaust fan of the latent heat system utilization units 2 and 3 are operated, the outdoor air OA is sucked into the unit through the outside air inlet and supplied indoors as the supply air SA through the air inlet. Then, an operation is performed in which the outdoor air OA is sucked into the unit through the outside air inlet and is discharged to the outdoors as exhaust air EA through the exhaust port.

  The operation during the dehumidifying operation in the air supply mode will be described with reference to FIGS. Here, FIGS. 12 and 13 are schematic refrigerant circuit diagrams showing the operation during the dehumidifying operation in the air supply mode in only the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  During the dehumidifying operation, as shown in FIGS. 12 and 13, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is exhausted to the outdoors as exhaust air EA through the exhaust port accompanying the outdoor air OA. In the second adsorption heat exchangers 23 and 33, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the outdoor air OA dehumidified by the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 22, 23, 32 and 33 in FIG. 12). (See arrows on both sides of the).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is accompanied by the outdoor air OA and is discharged outdoors as exhaust air EA through the exhaust port. In the first adsorption heat exchangers 22 and 32, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant, and the refrigerant evaporates. The outdoor air OA dehumidified by the first adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 22, 23, 32, and 33 in FIG. 13). (See arrows on both sides of the).

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only latent heat treatment but also sensible heat treatment.
As described above, in the air conditioning system 1, in the dehumidifying operation in the supply air mode of only the latent heat load processing system, the outdoor air is dehumidified and cooled by the sensible heat treatment ability obtained according to the switching time interval. The dehumidifying operation to supply to can be performed.

  The operation during the humidifying operation in the air supply mode will be described with reference to FIGS. 14 and 15. Here, FIG. 14 and FIG. 15 are schematic refrigerant circuit diagrams showing the operation during the humidifying operation in the air supply mode only in the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  During the humidification operation, as shown in FIGS. 14 and 15, for example, in the latent heat system utilization unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through the air supply port along with the outdoor air OA. In the second adsorption heat exchangers 23 and 33, the moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the outdoor air OA dehumidified by the second adsorption heat exchangers 23 and 33 is discharged outdoors as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 14). (See arrows on both sides.)

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port along with the outdoor air OA. In the first adsorption heat exchangers 22 and 32, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant, and the refrigerant evaporates. Then, the outdoor air OA dehumidified by the first adsorption heat exchangers 22 and 32 is discharged to the outdoors as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 15). (See arrows on both sides.)

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only latent heat treatment but also sensible heat treatment.
As described above, in the air conditioning system 1, in the humidification operation in the air supply mode of only the latent heat load processing system, the outdoor air is humidified and heated by the sensible heat treatment ability obtained according to the switching time interval. Humidification operation can be performed.

<Exhaust mode>
Next, the dehumidifying operation and the humidifying operation in the exhaust mode will be described. In the exhaust mode, when the air supply fan and the exhaust fan of the latent heat system utilization units 2 and 3 are operated, the indoor air RA is sucked into the unit through the internal air inlet and supplied indoors as the supply air SA through the air inlet. An operation is performed in which the indoor air RA is sucked into the unit through the inside air inlet and discharged to the outside as exhaust air EA through the outlet.

  The operation during the dehumidifying operation in the exhaust mode will be described with reference to FIGS. 16 and 17. Here, FIGS. 16 and 17 are schematic refrigerant circuit diagrams showing the operation during the dehumidifying operation in the exhaust mode in only the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  During the dehumidifying operation, as shown in FIGS. 16 and 17, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is discharged to the outdoors as exhaust air EA through the exhaust port accompanying the indoor air RA. In the second adsorption heat exchangers 23 and 33, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. The indoor air RA dehumidified by the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 22, 23, 32, and 33 in FIG. 16). (See arrows on both sides of the).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is exhausted to the outdoors as exhaust air EA through the exhaust port accompanying the indoor air RA. In the first adsorption heat exchangers 22 and 32, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. And the indoor air RA dehumidified by the 1st adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through an air supply port (Adsorption heat exchangers 22, 23, 32, and 33 of FIG. 17). (See arrows on both sides of the).

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only latent heat treatment but also sensible heat treatment.
As described above, in the air conditioning system 1, in the exhaust mode dehumidifying operation of only the latent heat load processing system, the indoor air is dehumidified and cooled by the sensible heat treatment ability obtained according to the switching time interval. The supplied dehumidifying operation can be performed.

  The operation during the humidifying operation in the exhaust mode will be described with reference to FIGS. Here, FIG. 18 and FIG. 19 are schematic refrigerant circuit diagrams illustrating the operation during the humidifying operation in the exhaust mode in only the latent heat load processing system of the air conditioning system 1. In addition, about the system control currently performed in the air conditioning system 1, since it is the same as that of the above-mentioned dehumidification operation of all ventilation modes, description is abbreviate | omitted.

  During the humidification operation, as shown in FIGS. 18 and 19, for example, in the latent heat system use unit 2, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes an evaporator. And the second operation in which the second adsorption heat exchanger 23 serves as a condenser and the first adsorption heat exchanger 22 serves as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated. Hereinafter, the flow of the refrigerant in the refrigerant circuit 10 during the first operation and the second operation is the same as the dehumidifying operation in the above-described all-ventilation mode, and thus the description thereof will be omitted, and during the first operation and the second operation. Only the air flow will be described.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is supplied indoors as the supply air SA through the air supply port along with the indoor air RA. In the second adsorption heat exchangers 23 and 33, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the second adsorption heat exchangers 23 and 33 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 18). See arrows on both sides).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is supplied indoors as the supply air SA through the air supply port along with the indoor air SA. In the first adsorption heat exchangers 22 and 32, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. And the indoor air RA dehumidified by the 1st adsorption heat exchangers 22 and 32 is discharged | emitted outdoors as exhaust air EA through an exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 of FIG. 19). See arrows on both sides).

Here, the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 perform not only latent heat treatment but also sensible heat treatment.
As described above, in the air conditioning system 1, in the humidification operation in the exhaust mode of only the latent heat load processing system, the indoor air is humidified and heated by the sensible heat treatment ability obtained according to the switching time interval. The humidification operation to supply can be performed.

  Next, the operation of the air conditioning system 1 when operating the entire air conditioning system 1 including the sensible heat system utilization units 4 and 5 will be described. The air conditioning system 1 processes an indoor latent heat load mainly by a latent heat load processing system (that is, the latent heat system using units 2 and 3), and mainly processes an indoor sensible heat load by a sensible heat load processing system (that is, using a sensible heat system). It can be processed in units 4, 5). Below, various driving | operation operation | movement is demonstrated.

<Dehumidifying and cooling operation>
First, with regard to the operation in the cooling and dehumidifying operation in which the latent heat load processing system of the air conditioning system 1 is dehumidified in the full ventilation mode and the cooling operation is performed in the sensible heat load processing system of the air conditioning system 1, FIGS. This will be described with reference to FIGS. Here, FIG. 20 and FIG. 21 are schematic refrigerant circuit diagrams showing the operation during the dehumidifying and cooling operation in the total ventilation mode in the air conditioning system 1. FIG. 22 is a control flow diagram during normal operation in the air conditioning system 1. FIG. 23 is a control flow diagram during normal operation in the air conditioning system 1 (when changing the switching time intervals of the adsorption heat exchangers 22, 23, 32, and 33). In FIG. 22 and FIG. 23, the latent heat system utilization unit 2 and the sensible heat system utilization unit 4 pair and the latent heat system utilization unit 3 and the sensible heat system utilization unit 5 pair have the same control flow. Illustration of the control flow of the pair of the system utilization unit 3 and the sensible heat system utilization unit 5 is omitted.

First, the operation of the latent heat load processing system of the air conditioning system 1 will be described.
In the latent heat system use unit 2 of the latent heat load processing system, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes the same as in the case of the single operation of the latent heat load processing system. The first operation to be an evaporator and the second operation to have the second adsorption heat exchanger 23 as a condenser and the first adsorption heat exchanger 22 as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated.

In the following description, the operations of the two latent heat system use units 2 and 3 will be described together.
In the first operation, the regeneration operation for the first adsorption heat exchangers 22 and 32 and the adsorption operation for the second adsorption heat exchangers 23 and 33 are performed in parallel. During the first operation, as shown in FIG. 20, the latent heat system use-side four-way switching valves 21, 31 are in the first state (see the solid lines of the latent heat system use-side four-way switching valves 21, 31). Is set. In this state, the high-pressure gas refrigerant discharged from the compression mechanism 61 flows into the first adsorption heat exchangers 22 and 32 through the discharge gas communication pipe 8 and the latent heat system use side four-way switching valves 21 and 31, and the first It condenses while passing through the adsorption heat exchangers 22 and 32. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 24 and 34 and then evaporated while passing through the second adsorption heat exchangers 23 and 33, and the latent heat system use side four-way switching valve 21. , 31 is sucked again into the compression mechanism 61 through the suction gas communication pipe 9 (see the arrow attached to the refrigerant circuit 10 in FIG. 20). Here, the sensible heat system utilization side expansion valves 41 and 51 of the sensible heat system utilization units 4 and 5 are different from the operation of only the latent heat load processing system described above in order to perform the cooling operation, the air heat exchanger 42. , 52 is opened to allow the refrigerant to flow, and the opening degree is adjusted, so that a part of the high-pressure gas refrigerant compressed and discharged by the compression mechanism 61 flows through the latent heat system utilization units 2 and 3. Will be.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is discharged to the outdoors as exhaust air EA through the exhaust port accompanying the indoor air RA. In the second adsorption heat exchangers 23 and 33, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. The outdoor air OA dehumidified by the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 22, 23, 32, and 33 in FIG. 20). (See arrows on both sides of the).

  In the second operation, the adsorption operation for the first adsorption heat exchangers 22 and 32 and the regeneration operation for the second adsorption heat exchangers 23 and 33 are performed in parallel. During the second operation, as shown in FIG. 21, the latent heat system use-side four-way switching valves 21 and 31 are in the second state (see the broken lines of the latent heat system use-side four-way switching valves 21 and 31 in FIG. 21). Is set. In this state, the high-pressure gas refrigerant discharged from the compression mechanism 61 flows into the second adsorption heat exchangers 23 and 33 through the discharge gas communication pipe 8 and the latent heat system use-side four-way switching valves 21 and 31, and the second It condenses while passing through the adsorption heat exchangers 23 and 33. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 24 and 34 and then evaporated while passing through the first adsorption heat exchangers 22 and 32, and the latent heat system use side four-way switching valve 21. , 31 is again sucked into the compression mechanism 61 through the suction gas communication pipe 9 (see the arrow attached to the refrigerant circuit 10 in FIG. 21).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is accompanied by the indoor air RA and discharged to the outdoors as exhaust air EA through the exhaust port. In the first adsorption heat exchangers 22 and 32, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant, and the refrigerant evaporates. And the outdoor air OA dehumidified by the 1st adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through an air supply port (Adsorption heat exchangers 22, 23, 32, and 33 of FIG. 21). (See arrows on both sides of the).

Here, the system control performed in the air conditioning system 1 will be described focusing on the latent heat load processing system.
First, when the target temperature and target relative humidity are set by the remote controllers 11 and 12, the latent heat system use side control units 28 and 38 of the latent heat system use units 2 and 3 together with the target temperature value and the target relative humidity value. The indoor air temperature value and relative humidity value sucked into the unit detected by the RA suction temperature / humidity sensors 225, 235 and the unit detected by the OA suction temperature / humidity sensors 26, 36 are sucked into the unit. The outdoor air temperature value and relative humidity value are input.

  Then, in step S11, the latent heat system use side control units 28 and 38 calculate the target value of enthalpy or the target value of absolute humidity from the target temperature value and target relative humidity value of indoor air, The current value of the enthalpy of the air sucked into the unit from the indoors or the current value of the absolute humidity is calculated from the temperature value and the relative humidity value detected by the humidity sensors 25 and 35, and the necessary latent heat capacity value which is a difference between the two values is calculated. Δh is calculated. Then, the value of Δh is converted into a capability UP signal K1 for notifying the heat source side control unit 65 whether or not the processing capability of the latent heat system use units 2 and 3 needs to be increased. For example, when the absolute value of Δh is smaller than a predetermined value (that is, when the humidity value of indoor air is close to the target humidity value and there is no need to increase or decrease the processing capacity), the capability UP signal K1 is set to “ 0, and when the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the dehumidifying operation, the humidity value of indoor air is higher than the target humidity value and the processing capacity needs to be increased) If the capacity UP signal K1 is “A” and the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be reduced (that is, in the dehumidifying operation, the humidity value of the indoor air is If the humidity is lower than the target humidity value and the processing capacity needs to be lowered, the capacity UP signal K1 is set to “B”. The capacity UP signal K1 is transmitted from the latent heat system use side control units 28 and 38 to the heat source side control unit 65, and is used for calculating the target condensation temperature value TcS and the target evaporation temperature value TeS in step S12. However, this point will be described later.

Next, operation | movement of the sensible heat load processing system of the air conditioning system 1 is demonstrated.
When the cooling operation of the sensible heat system utilization units 4 and 5 is performed, the three-way switching valve 62 of the heat source unit 6 is in a condensing operation state (a state in which the first port 62a and the third port 62c are connected). . The cooling / heating switching valves 71 and 81 of the connection units 14 and 15 are in a cooling operation state (a state where the first ports 71a and 81a and the second ports 71b and 81b are connected). Moreover, the opening degree of the sensible heat system utilization side expansion valves 41 and 51 of the sensible heat system utilization units 4 and 5 is adjusted so as to depressurize the refrigerant. The heat source side expansion valve 64 is open.

  In such a state of the refrigerant circuit 10, the high-pressure gas refrigerant discharged from the compression mechanism 61 passes through the three-way switching valve 62 and flows into the heat source side heat exchanger 63 to be condensed to become liquid refrigerant. The liquid refrigerant is sent to the sensible heat system utilization units 4 and 5 through the heat source side expansion valve 64, the receiver 68 and the liquid communication pipe 7. Then, the liquid refrigerant sent to the sensible heat system use units 4 and 5 is decompressed by the sensible heat system use side expansion valves 41 and 51 and then taken indoors by the air heat exchangers 42 and 52. It evaporates by heat exchange with the air RA and becomes a low-pressure gas refrigerant. The gas refrigerant is again sucked into the compression mechanism 61 of the heat source unit 6 through the cooling / heating switching valves 71 and 81 of the connection units 14 and 15 and the suction gas communication pipe 9. On the other hand, the indoor air RA cooled by heat exchange with the refrigerant in the air heat exchangers 42 and 52 is supplied indoors as supply air SA. As will be described later, the sensible heat system use side expansion valves 41 and 51 have a superheat degree SH in the air heat exchangers 42 and 52, that is, the air heat exchangers 42 and 52 detected by the liquid side temperature sensors 43 and 53, respectively. The opening degree is such that the temperature difference between the liquid side refrigerant temperature value of 52 and the gas side refrigerant temperature value of the air heat exchangers 42 and 52 detected by the gas side temperature sensors 54 and 55 becomes the target superheat degree SHS. Control is being made.

Here, the system control currently performed in the air conditioning system 1 is demonstrated paying attention to a sensible heat load processing system.
First, when the target temperature is set by the remote controllers 11 and 12, the sensible heat system use side control units 48 and 58 of the sensible heat system use units 4 and 5 have the RA intake temperature sensor 45, The temperature value of the indoor air sucked into the unit detected by 55 is input.

  Then, in step S14, the sensible heat system use side control units 48 and 58 determine the temperature difference between the target temperature value of the indoor air and the temperature value detected by the RA suction temperature sensors 45 and 55 (hereinafter referred to as required sensible heat capacity). Value ΔT). Here, since the required sensible heat capacity value ΔT is the difference between the target temperature value of indoor air and the current temperature value of indoor air as described above, the sensible heat that must be processed in the air conditioning system 1. It corresponds to a load. Then, the value of the necessary sensible heat capacity value ΔT is converted into a capacity UP signal K2 for notifying the heat source side control unit 65 whether or not the processing capacity of the sensible heat system utilization units 4 and 5 needs to be increased. For example, when the absolute value of ΔT is smaller than a predetermined value (that is, when the temperature value of indoor air is close to the target temperature value and there is no need to increase or decrease the processing capacity), the capability UP signal K2 is set to “ 0, and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the cooling operation, the temperature value of the indoor air is higher than the target temperature value and the processing capacity needs to be increased). When the capacity UP signal K2 is “a” and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be lowered (that is, in the cooling operation, the temperature value of the indoor air is When the temperature is lower than the target temperature value and the processing capacity needs to be lowered), the capacity UP signal K2 is set to “b”.

  Next, in step S15, the sensible heat system use side control units 48 and 58 change the value of the target superheat degree SHS according to the value of the required sensible heat capacity value ΔT. For example, when it is necessary to reduce the processing capacity of the sensible heat system utilization units 4 and 5 (when the capacity UP signal K2 is “b”), the target superheat degree SHS is increased and the air heat exchangers 42 and 52 are increased. The opening degree of the sensible heat system use side expansion valves 41 and 51 is controlled so as to reduce the amount of heat exchanged between the refrigerant and the air.

  Next, in step S12, the heat source side control unit 65 transmits the capability UP signal K1 of the latent heat system use units 2 and 3 transmitted from the latent heat system use side control units 28 and 38 to the heat source side control unit 65, and the sensible heat system. The target condensation temperature value TcS and the target evaporation temperature value TeS are calculated using the capability UP signal K2 of the sensible heat system utilization units 4, 5 transmitted from the use side control units 48, 58 to the heat source side control unit 65. For example, the target condensation temperature value TcS is calculated by adding the capability UP signal K1 of the latent heat system utilization units 2 and 3 and the capability UP signal K2 of the sensible heat system utilization units 4 and 5 to the current target condensation temperature value. The The target evaporation temperature value TeS is calculated by subtracting the capability UP signal K1 of the latent heat system usage units 2 and 3 and the capability UP signal K2 of the sensible heat system usage units 4 and 5 from the current target evaporation temperature value. . As a result, when the value of the capability UP signal K1 is “A” or when the value of the capability UP signal K2 is “a”, the target condensation temperature value TcS is increased and the target evaporation temperature value TeS is decreased.

  Next, in step S13, a system condensing temperature value Tc and a system evaporating temperature value Te, which are values corresponding to actual measured values of the condensing temperature and evaporating temperature of the entire air conditioning system 1, are calculated. For example, the system condensing temperature value Tc and the system evaporation temperature value Te are the suction pressure value of the compression mechanism 61 detected by the suction pressure sensor 66 and the discharge pressure value of the compression mechanism 61 detected by the discharge pressure sensor 67. It is calculated by converting into the refrigerant saturation temperature at the pressure value. Then, the temperature difference ΔTc of the target condensation temperature value TcS with respect to the system condensation temperature value Tc and the temperature difference ΔTe of the target evaporation temperature value TeS with respect to the system evaporation temperature value Te are calculated, and by dividing these temperature differences, the compression mechanism 61 Determine whether the operating capacity needs to be increased or decreased and the range of increase or decrease.

  By using the operation capacity of the compression mechanism 61 determined in this way, the operation capacity of the compression mechanism 61 is controlled to perform system control to bring the target relative humidity of indoor air closer. For example, when the value obtained by subtracting the temperature difference ΔTe from the temperature difference ΔTc is a positive value, the operating capacity of the compression mechanism 61 is increased. Conversely, when the value obtained by subtracting the temperature difference ΔTe from the temperature difference ΔTc is a negative value. Controls to reduce the operating capacity of the compression mechanism 61.

  Thus, in this air conditioning system 1, the latent heat load (equivalent to the required latent heat treatment capacity, Δh) that must be processed as the entire air conditioning system 1 and the sensible heat load that must be processed as the entire air conditioning system 1 (Necessary sensible heat treatment capacity, corresponding to ΔT) is a latent heat load treatment system (specifically, latent heat system use units 2 and 3) and a sensible heat load treatment system (specifically, sensible heat system use unit 4, 5). Here, the increase / decrease in the processing capacity of the latent heat load processing system and the increase / decrease in the processing capacity of the sensible heat load processing system are calculated by calculating the necessary latent heat treatment capacity value Δh and the necessary sensible heat treatment capacity value ΔT, and based on these values, Since the operation capacity of the compression mechanism 61 is controlled, the latent heat load processing in the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and the sensible heat load processing having the air heat exchangers 42, 52 are performed. The sensible heat load processing in the system can be performed at the same time. Thereby, even when the heat sources of the latent heat load processing system and the sensible heat load processing system are made common as in the air conditioning system 1 of the present embodiment, the operation capacity of the compression mechanism that constitutes the heat source is favorably controlled. Can do.

  By the way, in the system control of the air conditioning system 1 described above, the required sensible heat treatment capability value ΔT is increased (that is, the capability UP signal K2 becomes “a”), and the necessary latent heat treatment capability value Δh is decreased (that is, In the case where the capacity UP signal K1 becomes “B”), basically, the operation capacity of the compression mechanism 61 is increased. Further, even when the necessary latent heat treatment capacity value Δh becomes large (that is, when the capacity UP signal K1 becomes “A”), basically, control for increasing the operation capacity of the compression mechanism 61 is performed.

  On the other hand, in the latent heat load processing by the latent heat load processing system, as described above, the sensible heat treatment is performed together with the latent heat treatment by the adsorption operation or regeneration operation of the adsorption heat exchangers 22, 23, 32, 33. At this time, the ratio of the sensible heat treatment capacity to the latent heat treatment capacity changes as the switching time interval is changed, as shown in FIG. Therefore, in the air conditioning system 1, when the required latent heat treatment capability value Δh is small and the required sensible heat treatment capability value ΔT is large, the sensible heat treatment capability ratio is increased by increasing the switching time interval, and It can cope with an increase in heat load. Here, since the operation for increasing the sensible heat treatment capacity in the latent heat load processing system of the air conditioning system 1 by increasing the switching time interval is not an operation for increasing the operating capacity of the compression mechanism 61, it is wasteful to the entire air conditioning system 1. This makes it possible to perform efficient driving. When the required latent heat treatment capacity value Δh becomes large (that is, the capacity UP signal K1 is “A”), the sensible heat treatment capacity ratio is reduced by shortening the switching time interval to cope with an increase in latent heat load. can do.

  In the air conditioning system 1 of the present embodiment, the above-described system control is performed according to the control flow shown in FIG. Hereinafter, system control of the air conditioning system 1 shown in FIG. 23 will be described. Note that steps S11 to S15 other than steps S16 to S19 in FIG. 23 are the same as steps S11 to S15 shown in FIG.

  In step S16, the latent heat system use side control units 28, 38 determine whether or not the switching time interval of the adsorption heat exchangers 22, 23, 32, 33 is in the sensible heat priority mode (ie, time D), and the capability UP signal. It is determined whether K1 is “A” (that is, the direction in which the latent heat treatment capability is increased). If both of these two conditions are satisfied, the switching time interval is changed to the latent heat priority mode (ie, time C) in step S18. Conversely, if any one of the two conditions is not satisfied, the process proceeds to step S17.

  In step S17, the latent heat system use side control units 28, 38 determine whether the switching time interval of the adsorption heat exchangers 22, 23, 32, 33 is in the latent heat priority mode (ie, time C), and the capability UP signal K1. Is “B” (that is, the direction in which the latent heat treatment capability is lowered), and the capability UP signal K2 transmitted from the sensible heat system use side control units 48 and 58 through the heat source side control unit 65 is “a” (ie, It is determined whether the sensible heat treatment ability is increased). If all three conditions are satisfied, the switching time interval is changed to the sensible heat priority mode (ie, time D) in step S19. Conversely, if any one of the two conditions is not satisfied, the process proceeds to step S12.

  By such system control, as described above, when the necessary latent heat treatment capacity value Δh is small and the necessary sensible heat treatment capacity value ΔT is large, the switching time interval is lengthened (specifically, normal operation) By changing from time C to time D (see FIG. 5), the sensible heat treatment capacity ratio can be increased to cope with an increase in sensible heat load. Moreover, in this system control, when the latent heat load becomes large as in step S16, it is possible to return to the latent heat priority mode. It can cope with an increase in heat load. Here, as an example of the dehumidifying and cooling operation, the case where the cooling operation of the sensible heat load processing system is performed while the latent heat load processing system of the air conditioning system 1 is performing the dehumidifying operation in the full ventilation mode has been described. The present invention is applicable even when the system is dehumidified in other modes such as a circulation mode and an air supply mode.

<Humidification heating operation>
Next, FIG. 22 and FIG. 23 illustrate operations in the humidifying and heating operation in which the heating operation is performed in the sensible heat load processing system of the air conditioning system 1 while performing the humidifying operation of the latent heat load processing system of the air conditioning system 1 in the total ventilation mode. This will be described with reference to FIGS. 24 and 25. FIG. Here, FIG. 24 and FIG. 25 are schematic refrigerant circuit diagrams showing the operation during humidification heating operation in the total ventilation mode in the air conditioning system 1.

First, the operation of the latent heat load processing system of the air conditioning system 1 will be described.
In the latent heat system use unit 2 of the latent heat load processing system, the first adsorption heat exchanger 22 becomes a condenser and the second adsorption heat exchanger 23 becomes the same as in the case of the single operation of the latent heat load processing system. The first operation to be an evaporator and the second operation to have the second adsorption heat exchanger 23 as a condenser and the first adsorption heat exchanger 22 as an evaporator are alternately repeated. Similarly, in the latent heat system utilization unit 3, the first operation in which the first adsorption heat exchanger 32 serves as a condenser and the second adsorption heat exchanger 33 serves as an evaporator, and the second adsorption heat exchanger 33 serves as a condenser. And the second operation in which the first adsorption heat exchanger 32 becomes an evaporator is alternately repeated.

In the following description, the operations of the two latent heat system use units 2 and 3 will be described together.
In the first operation, the regeneration operation for the first adsorption heat exchangers 22 and 32 and the adsorption operation for the second adsorption heat exchangers 23 and 33 are performed in parallel. During the first operation, as shown in FIG. 24, the latent heat system use-side four-way switching valves 21 and 31 are in the first state (see the solid line of the latent heat system use-side four-way switching valves 21 and 31 in FIG. 24). Is set. In this state, the high-pressure gas refrigerant discharged from the compression mechanism 61 flows into the first adsorption heat exchangers 22 and 32 through the discharge gas communication pipe 8 and the latent heat system use side four-way switching valves 21 and 31, and the first It condenses while passing through the adsorption heat exchangers 22 and 32. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 24 and 34 and then evaporated while passing through the second adsorption heat exchangers 23 and 33, and the latent heat system use side four-way switching valve 21. , 31 is again sucked into the compression mechanism 61 through the suction gas communication pipe 9 (see the arrow attached to the refrigerant circuit 10 in FIG. 24). Here, the sensible heat system utilization side expansion valves 41 and 51 of the sensible heat system utilization units 4 and 5 are different from the above-described operation of only the latent heat load processing system in order to perform the heating operation. , 52 is opened to allow the refrigerant to flow, and the opening degree is adjusted, so that a part of the high-pressure gas refrigerant compressed and discharged by the compression mechanism 61 flows through the latent heat system utilization units 2 and 3. Will be.

  During the first operation, in the first adsorption heat exchangers 22 and 32, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the first adsorption heat exchangers 22 and 32 is supplied indoors as supply air SA through the air supply port along with the outdoor air OA. In the second adsorption heat exchangers 23 and 33, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the second adsorption heat exchangers 23 and 33 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 in FIG. 24). See arrows on both sides).

  In the second operation, the adsorption operation for the first adsorption heat exchangers 22 and 32 and the regeneration operation for the second adsorption heat exchangers 23 and 33 are performed in parallel. During the second operation, as shown in FIG. 25, the latent heat system use-side four-way switching valves 21 and 31 are in the second state (see the broken lines of the latent heat system use-side four-way switching valves 21 and 31 in FIG. 25). Is set. In this state, the high-pressure gas refrigerant discharged from the compression mechanism 61 flows into the second adsorption heat exchangers 23 and 33 through the discharge gas communication pipe 8 and the latent heat system use-side four-way switching valves 21 and 31, and the second It condenses while passing through the adsorption heat exchangers 23 and 33. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 24 and 34, and then evaporated while passing through the first adsorption heat exchangers 22 and 32, and the latent heat system use side four-way switching valve 21. , 31 is again sucked into the compression mechanism 61 through the suction gas communication pipe 9 (see the arrow attached to the refrigerant circuit 10 in FIG. 25).

  During the second operation, in the second adsorption heat exchangers 23 and 33, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is supplied indoors as supply air SA through the air supply port along with the outdoor air OA. In the first adsorption heat exchangers 22 and 32, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. And the indoor air RA dehumidified by the 1st adsorption heat exchangers 22 and 32 is discharged | emitted outdoors as exhaust air EA through an exhaust port (of the adsorption heat exchangers 22, 23, 32, and 33 of FIG. 25). (See arrows on both sides.)

Here, the system control performed in the air conditioning system 1 will be described focusing on the latent heat load processing system.
First, when the target temperature and target relative humidity are set by the remote controllers 11 and 12, the latent heat system use side control units 28 and 38 of the latent heat system use units 2 and 3 together with the target temperature value and the target relative humidity value. The temperature value and relative humidity value of the indoor air sucked into the unit detected by the RA suction temperature / humidity sensors 25 and 35, and the air temperature sucked into the unit detected by the OA suction temperature / humidity sensors 26 and 36. The outdoor air temperature value and relative humidity value are input.

  Then, in step S11, the latent heat system use side control units 28 and 38 calculate the target value of enthalpy or the target value of absolute humidity from the target temperature value and target relative humidity value of indoor air, The current value of the enthalpy of the air sucked into the unit from the indoors or the current value of the absolute humidity is calculated from the temperature value and the relative humidity value detected by the humidity sensors 25 and 35, and the necessary latent heat capacity value which is a difference between the two values is calculated. Δh is calculated. Then, the value of Δh is converted into a capability UP signal K1 for notifying the heat source side control unit 65 whether or not the processing capability of the latent heat system use units 2 and 3 needs to be increased. For example, when the absolute value of Δh is smaller than a predetermined value (that is, when the humidity value of indoor air is close to the target humidity value and there is no need to increase or decrease the processing capacity), the capability UP signal K1 is set to “ 0, and when the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the humidification operation, the humidity value of indoor air is lower than the target humidity value and the processing capacity needs to be increased) When the capacity UP signal K1 is “A” and the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be lowered (that is, in the humidification operation, the humidity value of the indoor air is If it is higher than the target humidity value and the processing capacity needs to be lowered), the capacity UP signal K1 is set to “B”. The capacity UP signal K1 is transmitted from the latent heat system use side control units 28 and 38 to the heat source side control unit 65, and is used for calculating the target condensation temperature value TcS and the target evaporation temperature value TeS in step S12. However, this point will be described later.

Next, operation | movement of the sensible heat load processing system of the air conditioning system 1 is demonstrated.
When the heating operation of the sensible heat system utilization units 4 and 5 is performed, the three-way switching valve 62 of the heat source unit 6 is in an evaporation operation state (a state in which the second port 62b and the third port 62c are connected). . Moreover, the cooling / heating switching valves 71 and 81 of the connection units 14 and 15 are in a heating operation state (a state in which the first ports 71a and 81a and the third ports 71c and 81c are connected). Moreover, the opening degree of the sensible heat system utilization side expansion valves 41 and 51 of the sensible heat system utilization units 4 and 5 is adjusted so as to depressurize the refrigerant. The opening degree of the heat source side expansion valve 64 is adjusted so as to reduce the pressure.

  In such a state of the refrigerant circuit 10, the high-pressure gas refrigerant discharged from the compression mechanism 61 is discharged from the discharge side of the compression mechanism 61 and the three-way switching valve 62 to the discharge gas communication pipe 8 and the connection units 14, 15. And sent to the sensible heat system utilization units 4 and 5. The high-pressure gas refrigerant sent to the sensible heat system utilization units 4 and 5 is condensed in the air heat exchangers 42 and 52 by heat exchange with the indoor air RA sucked into the units, and becomes liquid refrigerant. It is sent to the heat source unit 6 through the sensible heat system use side expansion valves 41 and 51 and the liquid communication pipe 7. On the other hand, the indoor air RA heated by the heat exchange with the refrigerant in the air heat exchangers 42 and 52 is supplied indoors as the supply air SA. Then, the liquid refrigerant sent to the heat source unit 6 passes through the receiver 68 and is decompressed by the heat source side expansion valve 64, and then evaporated by the heat source side heat exchanger 63 to become a low pressure gas refrigerant. The air is again sucked into the compression mechanism 61 through 62. As will be described later, the sensible heat system use side expansion valves 41, 51 have a supercooling degree SC of the air heat exchangers 42, 52, that is, the air heat exchanger 42 detected by the liquid side temperature sensors 43, 53. , 52 so that the temperature difference between the refrigerant temperature value on the liquid side and the refrigerant temperature value on the gas side of the air heat exchangers 42, 52 detected by the gas side temperature sensors 44, 54 becomes the target supercooling degree SCS. The opening degree is controlled.

Here, the system control currently performed in the air conditioning system 1 is demonstrated paying attention to a sensible heat load processing system.
First, when the target temperature is set by the remote controllers 11 and 12, the sensible heat system use side control units 48 and 58 of the sensible heat system use units 4 and 5 have the RA intake temperature sensor 45, The temperature value of the indoor air sucked into the unit detected by 55 is input.

  Then, in step S14, the sensible heat system use side control units 48 and 58 determine the temperature difference between the target temperature value of the indoor air and the temperature value detected by the RA suction temperature sensors 45 and 55 (hereinafter referred to as required sensible heat capacity). Value ΔT). Here, since the required sensible heat capacity value ΔT is the difference between the target temperature value of indoor air and the current temperature value of indoor air as described above, the sensible heat that must be processed in the air conditioning system 1. It corresponds to a load. Then, the value of the necessary sensible heat capacity value ΔT is converted into a capacity UP signal K2 for notifying the heat source side control unit 65 whether or not the processing capacity of the sensible heat system utilization units 4 and 5 needs to be increased. For example, when the absolute value of ΔT is smaller than a predetermined value (that is, when the temperature value of indoor air is close to the target temperature value and there is no need to increase or decrease the processing capacity), the capability UP signal K2 is set to “ 0, and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the heating operation, the temperature value of the indoor air is lower than the target temperature value and the processing capacity needs to be increased) When the capacity UP signal K2 is “a” and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be lowered (that is, in the heating operation, the temperature value of indoor air is When the temperature is higher than the target temperature value and the processing capacity needs to be lowered), the capacity UP signal K2 is set to “b”.

  Next, in step S15, the sensible heat system use side control units 48 and 58 change the value of the target supercooling degree SCS according to the value of the required sensible heat capacity value ΔT. For example, when it is necessary to reduce the processing capacity of the sensible heat system utilization units 4 and 5 (when the capacity UP signal K2 is “b”), the target supercooling degree SHS is increased and the air heat exchanger 42, The opening degree of the sensible heat system use side expansion valves 41 and 51 is controlled so as to reduce the amount of heat exchanged between the refrigerant and the air in 52.

  Next, in step S12, the heat source side control unit 65 transmits the capability UP signal K1 of the latent heat system use units 2 and 3 transmitted from the latent heat system use side control units 28 and 38 to the heat source side control unit 65, and the sensible heat system. The target condensation temperature value TcS and the target evaporation temperature value TeS are calculated using the capability UP signal K2 of the sensible heat system utilization units 4, 5 transmitted from the use side control units 48, 58 to the heat source side control unit 65. For example, the target condensation temperature value TcS is calculated by adding the capability UP signal K1 of the latent heat system utilization units 2 and 3 and the capability UP signal K2 of the sensible heat system utilization units 4 and 5 to the current target condensation temperature value. The The target evaporation temperature value TeS is calculated by subtracting the capability UP signal K1 of the latent heat system usage units 2 and 3 and the capability UP signal K2 of the sensible heat system usage units 4 and 5 from the current target evaporation temperature value. . As a result, when the value of the capability UP signal K1 is “A” or when the value of the capability UP signal K2 is “a”, the target condensation temperature value TcS is increased and the target evaporation temperature value TeS is decreased.

  Next, in step S13, a system condensing temperature value Tc and a system evaporating temperature value Te, which are values corresponding to actual measured values of the condensing temperature and evaporating temperature of the entire air conditioning system 1, are calculated. For example, the system condensing temperature value Tc and the system evaporation temperature value Te are the suction pressure value of the compression mechanism 61 detected by the suction pressure sensor 66 and the discharge pressure value of the compression mechanism 61 detected by the discharge pressure sensor 67. It is calculated by converting into the refrigerant saturation temperature at the pressure value. Then, the temperature difference ΔTc of the target condensation temperature value TcS with respect to the system condensation temperature value Tc and the temperature difference ΔTe of the target evaporation temperature value TeS with respect to the system evaporation temperature value Te are calculated, and by dividing these temperature differences, the compression mechanism 61 Determine whether the operating capacity needs to be increased or decreased and the range of increase or decrease.

  By using the operation capacity of the compression mechanism 61 determined in this way, the operation capacity of the compression mechanism 61 is controlled to perform system control to bring the target relative humidity of indoor air closer. For example, when the value obtained by subtracting the temperature difference ΔTe from the temperature difference ΔTc is a positive value, the operating capacity of the compression mechanism 61 is increased. Conversely, when the value obtained by subtracting the temperature difference ΔTe from the temperature difference ΔTc is a negative value. Controls to reduce the operating capacity of the compression mechanism 61.

Thus, in this air conditioning system 1, the same system control as in the dehumidifying and cooling operation can be performed during the humidifying and heating operation.
In addition, in the humidification heating operation, as in the dehumidification heating operation, in the system control of the air conditioning system 1 described above, the required sensible heat treatment capacity value ΔT becomes large (that is, the capacity UP signal K2 is “a”), In addition, when the necessary latent heat treatment capacity value Δh is small (that is, when the capacity UP signal K1 is “B”), control is performed so as to increase the operating capacity of the compression mechanism 61. Even when the necessary latent heat treatment capacity value Δh becomes large (that is, when the capacity UP signal K1 is “A”), control is basically performed so as to increase the operating capacity of the compression mechanism 61. For this reason, in the air conditioning system 1 of the present embodiment, even during the humidifying and heating operation, the system involves changing the switching time intervals of the adsorption heat exchangers 22, 23, 32, and 33 in accordance with the control flow shown in FIG. Control can be performed. That is, as in the dehumidifying and cooling operation, when the necessary latent heat treatment capacity value Δh is small and the necessary sensible heat treatment capacity value ΔT is large, the switching time interval is increased (specifically, during normal operation). By changing from time C to time D (see FIG. 5), the sensible heat treatment capacity ratio can be increased to cope with an increase in sensible heat load. Moreover, in this system control, when the latent heat load becomes large as in step S16, it is possible to return to the latent heat priority mode, so that the sensible heat load is processed while processing the indoor latent heat load. It can cope with the increase of. Here, as an example of the humidification heating operation, the case where the heating operation of the sensible heat load processing system is performed while performing the humidification operation in the full ventilation mode of the latent heat load processing system of the air conditioning system 1 has been described. The present invention is applicable even when the system is dehumidified in other modes such as a circulation mode and an air supply mode.

<Simultaneous operation of dehumidification cooling and humidification heating>
Next, dehumidifying cooling and humidification in which the simultaneous operation of cooling and heating is performed in the sensible heat load treatment system of the air conditioning system 1 while the latent heat load treatment system of the air conditioning system 1 is simultaneously operated in dehumidification and humidification in the full ventilation mode. The operation in the simultaneous operation of heating will be described with reference to FIGS. Here, FIG. 26 and FIG. 27 are schematic refrigerant circuit diagrams showing operations during simultaneous operation of dehumidification cooling and humidification heating in the total ventilation mode in the air conditioning system 1. Here, the pair of latent heat system utilization unit 2 and sensible heat system utilization unit 4 performs dehumidification cooling operation, and the pair of latent heat system utilization unit 3 and sensible heat system utilization unit 5 performs humidification heating operation. The case where the three-way switching valve 62 is in the condensing operation state as the entire unit 6 and the cooling load is large as the entire system will be described. In addition, about system control of the air conditioning system 1, since it is the same as that of the case of the above-mentioned dehumidification cooling operation and humidification heating operation, description is abbreviate | omitted.

First, the operation of the latent heat load processing system of the air conditioning system 1 will be described.
In the latent heat system utilization unit 2, the same operation as the dehumidifying operation in the full ventilation mode at the time of the dehumidifying and cooling operation described above is performed. On the other hand, in the latent heat system utilization unit 3, an operation similar to the humidification operation in the full ventilation mode during the humidification heating operation described above is performed.
Next, operation | movement of the sensible heat load processing system of the air conditioning system 1 is demonstrated. In the sensible heat system utilization unit 4 that is operated in a pair with the latent heat system utilization unit 2, the same operation as the cooling operation during the dehumidifying and cooling operation described above is performed. On the other hand, in the sensible heat system utilization unit 5 operated in a pair with the latent heat system utilization unit 3, an operation similar to the heating operation in the humidification heating operation described above is performed. Here, in the heat source unit 6, since the three-way switching valve 62 is in the condensing operation state, the refrigerant flow in the heat source side refrigerant circuit 10e is the same as in the cooling operation.

Thus, in the air conditioning system 1 of this embodiment, simultaneous operation of dehumidification cooling and humidification heating is also possible.
<System startup>
Next, the operation | movement at the time of starting of the air conditioning system 1 is demonstrated using FIG.5, FIG.20, FIG.21, FIG.28 and FIG. Here, FIG. 28 is a schematic refrigerant circuit diagram showing the operation of the air conditioning system 1 when the first system is started. FIG. 29 is a schematic refrigerant circuit diagram showing an operation at the time of starting the second system in the air conditioning system 1.

  There are three activation methods described below as operations at the time of activation of the air conditioning system 1. The first system activation method is a method of operating in a state where outdoor air does not pass through the adsorption heat exchangers 22, 23, 32, 33 of the latent heat treatment load system of the air conditioning system 1. In the second system activation method, in the state where the switching of the adsorption operation and the regeneration operation of the adsorption heat exchangers 22, 23, 32, and 33 of the latent heat load treatment system of the air conditioning system 1 is stopped, the outdoor air is subjected to the latent heat load treatment. After passing through one of the first adsorption heat exchangers 22 and 32 and the second adsorption heat exchangers 23 and 33 of the system, the air is discharged to the outside, and indoor air is discharged to the first adsorption heat exchangers 22, 32 and 2. In this operation method, the other of the adsorption heat exchangers 23 and 33 is passed through and then supplied indoors. The third system activation method is a method of operating with the switching time interval between the adsorption operation and the regeneration operation of the adsorption heat exchangers 22, 23, 32, and 33 longer than that in the normal operation.

First, the operation at the time of starting the first system will be described with reference to FIG. 28 on the assumption that the sensible heat load processing system of the air conditioning system 1 is in cooling operation.
When an operation command is issued from the remote controllers 11 and 12, the sensible heat load processing system (that is, the sensible heat system utilization units 4 and 5 and the heat source unit 6) of the air conditioning system 1 is activated and the cooling operation is performed. Here, the operation during the cooling operation of the sensible heat load treatment system is the same as that during the dehumidifying and cooling operation described above, and thus the description thereof is omitted.

On the other hand, in the latent heat load processing system of the air conditioning system 1, outdoor air is sucked into the unit by operation of an air supply fan, an exhaust fan, a damper, or the like, and the adsorption heat exchanger 22 of the latent heat system utilization units 2 and 3 is used. , 23, 32, and 33 are not passed and activated.
Then, in the adsorption heat exchangers 22, 23, 32, and 33 of the latent heat system use units 2 and 3, the refrigerant and the air are not in a heat exchange state, so the compression mechanism 61 of the heat source unit 6 is not activated and the latent heat In the load processing system, the latent heat treatment is not performed.

  And the operation | movement at the time of this system starting is cancelled | released after satisfy | filling a predetermined condition, and it transfers to normal dehumidification cooling operation. For example, after a predetermined time (for example, about 30 minutes) has elapsed from the system startup by a timer provided in the heat source side control unit 65, the operation at the time of system startup is canceled or input by the remote controllers 11 and 12 The temperature difference between the target temperature value of the indoor air and the temperature value of the indoor air sucked into the unit detected by the RA intake temperature sensors 45 and 55 has become a predetermined temperature difference (for example, 3 ° C.) or less. Later, this system startup operation is canceled.

  Thus, in the air conditioning system 1, at the time of system start-up, sensible heat treatment is mainly performed by supplying the air heat-exchanged indoors in the air heat exchangers 42 and 52 of the sensible heat system utilization units 4 and 5; In addition, since outdoor air is not allowed to pass by preventing outdoor air from passing through the adsorption heat exchangers 22, 23, 32, 33 of the latent heat system utilization units 2, 3, the latent heat load processing system is activated when the system is activated. It is possible to prevent the introduction of a heat load from outside air in a state where the air conditioning capability is not exhibited, and the target temperature of indoor air can be quickly reached. Accordingly, the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and mainly processing the indoor latent heat load, and the air heat exchangers 42 and 52 mainly processing the indoor sensible heat load. In the air conditioning system 1 including the sensible heat load processing system, cooling can be performed quickly when the system is started. Here, the case where the sensible heat load processing system is air-cooled has been described, but the system activation method can be applied even when the air-warming operation is performed.

Next, the operation at the time of starting the second system will be described with reference to FIGS. 5 and 29 on the assumption that the sensible heat load treatment system of the air conditioning system 1 is in cooling operation.
When an operation command is issued from the remote controllers 11 and 12, the sensible heat load processing system (that is, the sensible heat system utilization units 4 and 5 and the heat source unit 6) of the air conditioning system 1 is activated and the cooling operation is performed. Here, the operation during the cooling operation of the sensible heat load treatment system is the same as described above, and thus the description thereof is omitted.

  On the other hand, in the latent heat load processing system of the air conditioning system 1, the switching operation of the latent heat system use side four-way switching valves 21 and 31 is not performed, and the operation is switched to the same air flow path as in the circulation mode by operation of a damper or the like. When the air supply fan and exhaust fan of the latent heat system utilization units 2 and 3 are operated in this state, the indoor air RA is sucked into the unit through the indoor air inlet and supplied indoors as the supply air SA through the air inlet. An operation is performed in which the air OA is sucked into the unit through the outside air inlet and the exhaust air EA is discharged outside through the exhaust port.

  When such an operation is performed, immediately after the system is started up, the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet and discharged to the outside as exhaust air EA through the outlet, and indoor air The moisture in the RA is adsorbed by the adsorbent, the indoor air RA is dehumidified, and supplied to the indoor as the supply air SA through the air supply port. However, after a certain amount of time has elapsed since the system startup, as shown in FIG. 5, the adsorbent of the adsorption heat exchangers 22, 23, 32, and 33 adsorbs moisture to near the moisture adsorption capacity. As a result, the latent heat load processing system functions as a system for processing the sensible heat load. Thereby, the sensible heat processing capability as the air conditioning system 1 as a whole can be increased, and the sensible heat treatment in the room can be promoted.

  And the operation | movement at the time of this system starting is cancelled | released after satisfy | filling a predetermined condition, and it transfers to normal dehumidification cooling operation. For example, after a predetermined time (for example, about 30 minutes) has elapsed from the system startup by a timer provided in the heat source side control unit 65, the operation at the time of system startup is canceled or input by the remote controllers 11 and 12 The temperature difference between the target temperature value of the indoor air and the temperature value of the indoor air sucked into the unit detected by the RA intake temperature / humidity sensors 25 and 35 is less than a predetermined temperature difference (for example, 3 ° C.). After this, the system startup operation is canceled.

  Thus, in the air conditioning system 1, at the time of system startup, the sensible heat treatment is mainly performed by supplying the air heat-exchanged indoors in the air heat exchangers 42 and 52 of the sensible heat system utilization units 4 and 5, In addition, in a state where the switching of the adsorption operation and the regeneration operation of the adsorption heat exchangers 22, 23, 32, and 33 is stopped, the outdoor heat is passed through the adsorption heat exchangers 22, 23, 32, and 33 and then discharged to the outdoors. Thus, since the sensible heat treatment is performed, the indoor sensible heat treatment can be promoted to quickly reach the target temperature of the indoor air when the system is started. Accordingly, the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and mainly processing the indoor latent heat load, and the air heat exchangers 42 and 52 mainly processing the indoor sensible heat load. In the air conditioning system 1 including the sensible heat load processing system, cooling can be performed quickly when the system is started. Here, the case where the sensible heat load processing system is air-cooled has been described, but the system activation method can be applied even when the air-warming operation is performed.

Next, regarding the operation at the time of starting the third system, the latent heat load processing system of the air conditioning system 1 is dehumidified in the total ventilation mode, and the sensible heat load processing system of the air conditioning system 1 is cooled. This will be described with reference to FIGS. 5, 20, and 21.
When an operation command is issued from the remote controllers 11 and 12, the sensible heat load processing system (that is, the sensible heat system utilization units 4, 5 and the heat source unit 6) is activated to perform the cooling operation. Here, the operation during the cooling operation of the sensible heat load treatment system is the same as described above, and thus the description thereof is omitted.

  On the other hand, the latent heat load processing system of the air conditioning system 1 is similar to the above in that the dehumidifying operation is performed in the full ventilation mode, but the switching time interval between the adsorption operation and the regeneration operation is used in the normal operation. The switching time interval D giving priority to the sensible heat treatment is set longer than the switching time interval C giving priority to the latent heat treatment. For this reason, the switching operation of the latent heat system utilization side four-way switching valves 21 and 31 of the latent heat system utilization units 2 and 3 is performed at a slower cycle than during normal operation only when the system is activated. Then, immediately after the switching of the latent heat system use side four-way switching valves 21 and 31, the adsorption heat exchangers 22, 23, 32, and 33 mainly perform the latent heat treatment, but when the time D elapses, the sensible heat treatment is mainly performed. As a result, the latent heat load processing system mainly functions as a system for processing the sensible heat load. Thereby, the sensible heat processing capability as the air conditioning system 1 as a whole can be increased, and the sensible heat treatment in the room can be promoted.

  And the operation | movement at the time of this system starting is cancelled | released after satisfy | filling a predetermined condition, and it transfers to normal dehumidification cooling operation. For example, after a predetermined time (for example, about 30 minutes) has elapsed from the system startup by a timer provided in the heat source side control unit 65, the operation at the time of system startup is canceled or input by the remote controllers 11 and 12 The temperature difference between the target temperature value of the indoor air and the temperature value of the indoor air sucked into the unit detected by the RA intake temperature / humidity sensors 25 and 35 is less than a predetermined temperature difference (for example, 3 ° C.). After this, the system startup operation is canceled.

  As described above, in the air conditioning system 1, when the system is started, the switching time intervals in the adsorption heat exchangers 22, 23, 32, and 33 of the latent heat system use units 2 and 3 are set longer than those in the normal operation, and thus mainly manifest. By performing the heat treatment, the target temperature of indoor air can be reached quickly. Accordingly, the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and mainly processing the indoor latent heat load, and the air heat exchangers 42 and 52 mainly processing the indoor sensible heat load. In the air conditioning system 1 including the sensible heat load processing system, cooling can be performed quickly when the system is started. Here, the case where the sensible heat load processing system is air-cooled has been described, but the system activation method can be applied even when the air-warming operation is performed. Although the case where the latent heat load processing system is operated in the full ventilation mode has been described here, the system activation method can be applied to other modes such as a circulation mode and an air supply mode.

When starting the air conditioning system 1 that preferentially processes indoor sensible heat loads as described above, for example, the value of the indoor air temperature at the time of starting the system becomes the value of the target temperature of the indoor air. It may be close. In such a case, since it is not necessary to perform the above-described system activation, the operation at the time of system activation may be omitted and the normal operation may be performed.
For this reason, in the air conditioning system 1, before starting the operation | movement which processes the above indoor sensible heat load preferentially at the time of system start-up, the target temperature of indoor air and the temperature of indoor air It is determined whether the temperature difference is equal to or less than a predetermined temperature difference (for example, the same temperature difference as the condition for canceling the operation at system startup), and the temperature difference between the indoor air target temperature and the indoor air temperature is When the temperature difference is equal to or less than the predetermined temperature difference, it is possible to prevent the operation at the time of starting the system.

Thereby, in the air conditioning system 1, at the time of system start-up, without performing the operation | movement which processes an indoor sensible heat load preferentially unnecessarily, it can promptly perform normal operation which processes an indoor latent heat load and a sensible heat load. Can be migrated.
(3) Features of the air conditioning system The air conditioning system 1 of the present embodiment has the following features.

(A)
In the air conditioning system 1 of the present embodiment, at the time of system startup, the sensible heat treatment is mainly performed by supplying the air heat-exchanged indoors in the air heat exchangers 42 and 52 of the sensible heat system utilization units 4 and 5, In addition, since outdoor air is not allowed to pass by preventing outdoor air from passing through the adsorption heat exchangers 22, 23, 32, 33 of the latent heat system utilization units 2, 3, the latent heat load processing system is activated at the time of system startup. It is possible to prevent the introduction of a heat load from outside air in a state where the air conditioning capability is not exhibited, and the target temperature of indoor air can be quickly reached. Accordingly, the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and mainly processing the indoor latent heat load, and the air heat exchangers 42 and 52 mainly processing the indoor sensible heat load. In the air conditioning system 1 including the sensible heat load processing system, cooling and heating can be performed quickly when the system is activated.

(B)
Moreover, in the air conditioning system 1 of this embodiment, the sensible heat treatment is mainly performed by supplying the air heat-exchanged indoors in the air heat exchangers 42 and 52 of the sensible heat system utilization units 4 and 5 when the system is started. In the state where the adsorption heat exchangers 22, 23, 32, 33 are switched between the adsorption operation and the regeneration operation, after the outdoor air is passed through the adsorption heat exchangers 22, 23, 32, 33 Therefore, the sensible heat treatment can be performed so that the indoor sensible heat treatment can be promoted and the target temperature of the indoor air can be quickly reached when the system is activated. Accordingly, the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and mainly processing the indoor latent heat load, and the air heat exchangers 42 and 52 mainly processing the indoor sensible heat load. In the air conditioning system 1 including the sensible heat load processing system, cooling and heating can be performed quickly when the system is activated.

(C)
Moreover, in the air conditioning system 1 of this embodiment, at the time of system start-up, the switching time interval in the adsorption heat exchangers 22, 23, 32, 33 of the latent heat system use units 2, 3 is made longer than that during normal operation, By mainly performing sensible heat treatment, the target temperature of indoor air can be reached quickly. Accordingly, the latent heat load processing system having the adsorption heat exchangers 22, 23, 32, 33 and mainly processing the indoor latent heat load, and the air heat exchangers 42 and 52 mainly processing the indoor sensible heat load. In the air conditioning system 1 including the sensible heat load processing system, cooling and heating can be performed quickly when the system is activated.

(D)
In addition, the operation at the time of starting the system is canceled after a sufficient time has elapsed from the start of the system to the sensible heat treatment, or the difference between the indoor air target temperature and the indoor air temperature value is predetermined. By releasing after the temperature difference is less than or equal to, it is possible to promptly shift to a normal operation for processing the latent heat load and the sensible heat load.

In addition, before starting the operation operation at the time of starting the system, whether or not it is necessary is determined based on the temperature of the indoor air. It is possible to quickly shift to a normal operation for processing indoor latent heat load and sensible heat load without performing preferential processing.
[Second Embodiment]
(1) Configuration of Air Conditioning System FIG. 30 is a schematic refrigerant circuit diagram of an air conditioning system 101 according to a second embodiment of the present invention. The air conditioning system 101 is an air conditioning system that processes a latent heat load and a sensible heat load in a building or the like by performing a vapor compression refrigeration cycle operation. The air conditioning system 101 is a so-called separate type multi-air conditioning system, and mainly includes a latent heat load processing system 201 that mainly processes indoor latent heat loads and a sensible heat load processing system 301 that mainly processes indoor sensible heat loads. I have.

  The latent heat load processing system 201 is a so-called separate type multi-air conditioning system, and mainly includes a plurality of (in this embodiment, two) latent heat system utilization units 202 and 203, a latent heat system heat source unit 206, and latent heat. Latent heat system connection pipes 207 and 208 for connecting the system use units 202 and 203 and the latent heat system heat source unit 206 are provided. In the present embodiment, the latent heat system heat source unit 206 functions as a heat source common to the latent heat system utilization units 202 and 203. Further, in the present embodiment, only one latent heat system heat source unit 206 is provided. However, when there are a large number of latent heat system use units 202 and 203, a plurality of units may be connected in parallel.

<Latent heat system use unit>
The latent heat system utilization units 202 and 203 are installed in an indoor ceiling of a building or the like by being hung or suspended, by wall hanging, or in a space behind the ceiling. The latent heat system use units 202 and 203 are connected to the latent heat system heat source unit 206 via the latent heat system communication pipes 207 and 208, and constitute a latent heat system refrigerant circuit 210 with the latent heat system heat source unit 206. The latent heat system utilization units 202 and 203 can process indoor latent heat load and sensible heat load by circulating a refrigerant in the latent heat system refrigerant circuit 210 and performing a vapor compression refrigeration cycle operation. .

  Next, the configuration of the latent heat system use units 202 and 203 will be described. Since the latent heat system utilization unit 202 and the latent heat system utilization unit 203 have the same configuration, only the configuration of the latent heat system utilization unit 202 will be described here. The reference numerals of the 230 series are attached instead of the reference numerals of the 220 series indicating the respective parts of 202, and the description of each part is omitted.

  The latent heat system utilization unit 202 mainly constitutes a part of the latent heat system refrigerant circuit 210 and includes a latent heat system utilization side refrigerant circuit 210a capable of dehumidifying or humidifying air. This latent heat system utilization side refrigerant circuit 210a mainly includes a latent heat system utilization side four-way switching valve 221, a first adsorption heat exchanger 222, a second adsorption heat exchanger 223, and a latent heat system utilization side expansion valve 224. I have.

  The latent heat system use side four-way switching valve 221 is a valve for switching the flow path of the refrigerant flowing into the latent heat system use side refrigerant circuit 210 a, and the first port 221 a has latent heat via the latent heat system discharge gas communication pipe 207. It is connected to the discharge side of a latent heat system compression mechanism 261 (described later) of the system heat source unit 206, and its second port 221b is connected to the latent heat system compression mechanism 261 of the latent heat system heat source unit 206 via a latent heat system intake gas communication pipe 208. The third port 221 c is connected to the suction side, the third port 221 c is connected to the gas side end of the first adsorption heat exchanger 222, and the fourth port 221 d is connected to the gas side end of the second adsorption heat exchanger 223. It is connected. The latent heat system use side four-way switching valve 221 connects the first port 221a and the third port 221c and connects the second port 221b and the fourth port 221d (first state, use of the latent heat system of FIG. 30). Side four-way switching valve 221), connecting the first port 221a and the fourth port 221d and connecting the second port 221b and the third port 221c (second state, latent heat system of FIG. 30) It is possible to perform switching that refers to the broken line of the use side four-way switching valve 221).

  The first adsorption heat exchanger 222 and the second adsorption heat exchanger 223 are cross fin type fin-and-tube heat exchangers configured by heat transfer tubes and a large number of fins. Specifically, the first adsorption heat exchanger 222 and the second adsorption heat exchanger 223 have a large number of aluminum fins formed in a rectangular plate shape and a copper heat transfer tube penetrating the fins. Yes. The first adsorption heat exchanger 222 and the second adsorption heat exchanger 223 are not limited to cross fin type fin-and-tube type heat exchangers, but other types of heat exchangers, for example, corrugated fin type It may be a heat exchanger or the like.

  In the first adsorption heat exchanger 222 and the second adsorption heat exchanger 223, an adsorbent is supported on the surface of the fin by dip molding (immersion molding). The method for supporting the adsorbent on the surfaces of the fins and the heat transfer tubes is not limited to dip molding, and the adsorbent may be supported on the surface by any method as long as the performance as the adsorbent is not impaired. . As this adsorbent, functionalities such as zeolite, silica gel, activated carbon, organic polymer polymer material having hydrophilicity or water absorption, ion exchange resin material having carboxylic acid group or sulfonic acid group, temperature sensitive polymer, etc. A polymer material or the like can be used.

  The first adsorptive heat exchanger 222 and the second adsorptive heat exchanger 223 function as a refrigerant evaporator while allowing air to pass outside thereof, so that moisture in the air is adsorbed to the adsorbent supported on the surface thereof. Can be made. In addition, the first adsorption heat exchanger 222 and the second adsorption heat exchanger 223 function as a refrigerant condenser while allowing air to pass through the outside of the first adsorption heat exchanger 222 and the second adsorption heat exchanger 223. Can be desorbed.

  The latent heat system use side expansion valve 224 is an electric expansion valve connected between the liquid side end of the first adsorption heat exchanger 222 and the liquid side end of the second adsorption heat exchanger 223, and serves as a condenser. Depressurizing the refrigerant sent from one of the functioning first adsorption heat exchanger 222 and the second adsorption heat exchanger 223 to the other of the first adsorption heat exchanger 222 and the second adsorption heat exchanger 223 functioning as an evaporator. Can do.

  In addition, although not shown in detail, the latent heat system utilization unit 202 is configured to suck outdoor air (hereinafter referred to as outdoor air OA) into the unit and an outside air inlet for discharging the air from the unit to the outside. , An indoor air inlet for sucking indoor air (hereinafter referred to as indoor air RA) into the unit, and an air blown indoors from the unit (hereinafter referred to as supply air SA) The air flow path for switching the air flow path, the exhaust fan disposed in the unit so as to communicate with the exhaust port, the air supply fan disposed in the unit so as to communicate with the air inlet, And a switching mechanism comprising a damper or the like. As a result, the latent heat system utilization unit 202 sucks the outdoor air OA from the outside air inlet into the unit and passes it through the first or second adsorption heat exchangers 222 and 223, and then supplies the air SA supplied indoors from the inlet. Or the outdoor air OA is sucked into the unit from the outside air inlet and passed through the first or second adsorption heat exchangers 222 and 223, and then discharged as exhaust air EA from the outlet to the outside. The air RA is sucked into the unit from the inside air suction port and passed through the first or second adsorption heat exchangers 222 and 223, and then supplied indoors as the supply air SA from the air supply port, or the indoor air RA is sucked into the room air. After being sucked into the unit from the opening and passed through the first or second adsorption heat exchangers 222 and 223, it can be discharged from the exhaust opening to the outside as exhaust air EA.

  Further, the latent heat system utilization unit 202 includes an RA intake temperature / humidity sensor 225 for detecting the temperature and relative humidity of the indoor air RA sucked into the unit, and the temperature and relative humidity of the outdoor air OA sucked into the unit. OA suction temperature / humidity sensor 226 to detect, SA supply temperature sensor 227 to detect the temperature of supply air SA supplied indoors from within the unit, and latent heat system to control the operation of each part constituting latent heat system utilization unit 202 And a use side control unit 228. The latent heat system use side control unit 228 includes a microcomputer and a memory provided for controlling the latent heat system use unit 202, and includes a remote control 111 and a latent heat system heat source unit 206 described later. Through the control unit 265, input signals for the target temperature and target humidity of the indoor air can be exchanged, and control signals can also be exchanged with the latent heat system heat source unit 206.

<Latent heat system heat source unit>
The latent heat system heat source unit 206 is installed on the roof of a building or the like, and is connected to the latent heat system use units 202 and 203 via the latent heat system connection pipes 207 and 208, and is connected to the latent heat system use units 202 and 203. A latent heat system refrigerant circuit 210 is formed between the two.
Next, the configuration of the latent heat system heat source unit 206 will be described. The latent heat system heat source unit 206 mainly constitutes a part of the latent heat system refrigerant circuit 210 and includes a latent heat system heat source side refrigerant circuit 210c. The latent heat system heat source side refrigerant circuit 210c mainly includes a latent heat system compression mechanism 261 and a latent heat system accumulator 262 connected to the suction side of the latent heat system compression mechanism 261.

In this embodiment, the latent heat system compression mechanism 261 is a positive displacement compressor capable of changing the operation capacity by inverter control. In the present embodiment, the latent heat system compression mechanism 261 is a single compressor, but is not limited to this, and two or more compressors connected in parallel according to the number of connected units and the like. It may be.
The latent heat system accumulator 262 is a container for accumulating surplus refrigerant generated by the increase or decrease of the refrigerant circulation amount accompanying the fluctuation of the operation load of the latent heat system use side refrigerant circuits 210a and 210b.

  The latent heat system heat source unit 206 includes a latent heat system suction pressure sensor 263 that detects the suction pressure of the latent heat system compression mechanism 211, a latent heat system discharge pressure sensor 264 that detects the discharge pressure of the latent heat system compression mechanism 211, and a latent heat system heat source. And a latent heat system heat source side control unit 265 that controls the operation of each unit constituting the unit 206. The latent heat system heat source side control unit 265 includes a microcomputer and a memory provided to control the latent heat system use unit 202, and controls the latent heat system use units 202 and 203 described above. Control signals and the like can be exchanged through the units 228 and 238 and the latent heat system heat source side control unit 265.

  The sensible heat load processing system 301 mainly includes a plurality of (in this embodiment, two) sensible heat system use units 302 and 303, a sensible heat system heat source unit 306, a sensible heat system use units 302 and 303, and a sensible heat system use unit 302 and 303. Sensible heat system connection pipes 307 and 308 for connecting the heat system heat source unit 306 are provided. In this embodiment, the sensible heat system heat source unit 306 functions as a heat source common to the sensible heat system utilization units 302 and 303. In the present embodiment, only one sensible heat system heat source unit 306 is provided. However, when the number of sensible heat system use units 302 and 303 is large, a plurality of sensible heat system heat source units 306 may be connected in parallel.

<Sensible heat system use unit>
The sensible heat system utilization units 302 and 303 are installed in a ceiling of a building or the like by being embedded or suspended in a ceiling, by a wall or the like, or in a space behind the ceiling. The sensible heat system utilization units 302 and 303 are connected to the sensible heat system heat source unit 306 via the sensible heat system connection pipes 307 and 308, and the sensible heat system heat source unit 306 is connected to the sensible heat system heat source unit 306. It is composed. The sensible heat system utilization units 302 and 303 can mainly handle indoor sensible heat load by circulating a refrigerant in the sensible heat system refrigerant circuit 310 and performing a vapor compression refrigeration cycle operation. . The sensible heat system utilization unit 302 is installed in the same conditioned space as the latent heat system utilization unit 202, and the sensible heat system utilization unit 303 is installed in the same conditioned space as the latent heat system utilization unit 203. That is, the latent heat system use unit 202 and the sensible heat system use unit 302 are paired to process a latent heat load and a sensible heat load in a certain air-conditioned space. Are paired to process the latent heat load and sensible heat load of another air-conditioned space.

  Next, the configuration of the sensible heat system utilization units 302 and 303 will be described. Since the sensible heat system use unit 302 and the sensible heat system use unit 303 have the same configuration, only the configuration of the sensible heat system use unit 302 will be described here. The reference numerals of the 330 series are assigned instead of the reference numerals of the 320 series indicating the respective parts of the sensible heat system utilization unit 302, and the description of each part is omitted.

  The sensible heat system utilization unit 302 mainly constitutes a part of the sensible heat system refrigerant circuit 310, and includes a sensible heat system utilization side refrigerant circuit 310a capable of cooling or heating air. The sensible heat system use side refrigerant circuit 310 a mainly includes a sensible heat system use side expansion valve 321 and an air heat exchanger 322. In the present embodiment, the sensible heat system utilization side expansion valve 321 is an electric expansion valve connected to the liquid side of the air heat exchanger 322 in order to adjust the refrigerant flow rate or the like. In the present embodiment, the air heat exchanger 322 is a cross-fin type fin-and-tube heat exchanger composed of heat transfer tubes and a large number of fins, and performs heat exchange between the refrigerant and the indoor air RA. Equipment. In this embodiment, the sensible heat system utilization unit 302 includes a blower fan (not shown) for supplying indoor air RA as supply air SA after sucking indoor air RA into the unit and exchanging heat. It is possible to exchange heat between the indoor air RA and the refrigerant flowing through the air heat exchanger 322.

  The sensible heat system utilization unit 302 is provided with various sensors. A liquid side temperature sensor 323 that detects the temperature of the liquid refrigerant is provided on the liquid side of the air heat exchanger 322, and a gas side temperature sensor 324 that detects the temperature of the gas refrigerant on the gas side of the air heat exchanger 322. Is provided. Further, the sensible heat system utilization unit 302 is provided with an RA intake temperature sensor 325 for detecting the temperature of the indoor air RA sucked into the unit. Further, the sensible heat system utilization unit 302 includes a sensible heat system utilization side control unit 328 that controls the operation of each part constituting the sensible heat system utilization unit 302. The sensible heat system use side control unit 328 includes a microcomputer and a memory provided to control the sensible heat system use unit 302, and the indoor air target temperature and target humidity are controlled via the remote controller 111. Exchange of input signals and the like, and exchange of control signals and the like with the sensible heat system heat source unit 306 can also be performed.

<Sensible heat system heat source unit>
The sensible heat system heat source unit 306 is installed on the rooftop of a building or the like, and is connected to the sensible heat system utilization units 302 and 303 via the sensible heat system connection pipes 307 and 308. , 303 constitutes a sensible heat system refrigerant circuit 310.
Next, the configuration of the sensible heat system heat source unit 306 will be described. The sensible heat system heat source unit 306 mainly constitutes a part of the sensible heat system refrigerant circuit 310, and includes a sensible heat system heat source side refrigerant circuit 310c. The sensible heat system heat source side refrigerant circuit 310c mainly includes a sensible heat system compression mechanism 361, a sensible heat system heat source side four-way switching valve 362, a sensible heat system heat source side heat exchanger 363, and a sensible heat system heat source side expansion. A valve 364 and a sensible heat system receiver 368 are provided.

In the present embodiment, the sensible heat system compression mechanism 361 is a positive displacement compressor capable of varying the operation capacity by inverter control. In this embodiment, the sensible heat system compression mechanism 361 is a single compressor, but is not limited to this, and two or more compressors are connected in parallel according to the number of connected sensible heat system utilization units. It may be connected.
The sensible heat system heat source side four-way switching valve 362 is a valve for switching the flow path of the refrigerant in the sensible heat system heat source side refrigerant circuit 310c when switching between the cooling operation and the heating operation, and the first port 362a thereof is The sensible heat system compression mechanism 361 is connected to the discharge side, the second port 362b is connected to the suction side of the sensible heat system compression mechanism 361, and the third port 362c is the sensible heat system heat source side heat exchanger. The third port 362 d is connected to the sensible heat system gas communication pipe 308. The sensible heat system heat source side four-way switching valve 362 connects the first port 362a and the third port 362c and connects the second port 362b and the fourth port 362d (cooling operation state, sensible heat in FIG. 1). 1) (refer to the solid line of the system heat source side four-way switching valve 362), and the first port 362a and the fourth port 362d are connected and the second port 362b and the third port 362c are connected (heating operation state, FIG. It is possible to perform switching that refers to the broken line of the sensible heat system heat source side four-way switching valve 362).

  In the present embodiment, the sensible heat system heat source side heat exchanger 363 is a cross-fin type fin-and-tube heat exchanger composed of heat transfer tubes and a large number of fins. It is equipment for exchange. In the present embodiment, the sensible heat system heat source unit 306 includes an outdoor fan (not shown) for taking in and sending outdoor air into the unit, and the outdoor air and the sensible heat system heat source side heat exchanger 363. It is possible to exchange heat with the refrigerant flowing through

  In this embodiment, the sensible heat system heat source side expansion valve 364 adjusts the flow rate of the refrigerant flowing between the sensible heat system heat source side heat exchanger 363 and the air heat exchangers 322 and 332 via the liquid communication pipe 307. This is an electric expansion valve capable of performing The sensible heat system heat source side expansion valve 364 is used in a substantially fully open state during the cooling operation, and the opening degree is adjusted during the heating operation, and the sensible heat system heat source side heat exchange is performed from the air heat exchangers 322 and 332 via the liquid connection pipe 307. Used to depressurize the refrigerant flowing into the vessel 363.

The sensible heat system receiver 368 is a container for temporarily storing the refrigerant flowing between the sensible heat system heat source side heat exchanger 363 and the air heat exchangers 322 and 332. In the present embodiment, the sensible heat system receiver 368 is connected between the sensible heat system heat source side expansion valve 364 and the liquid communication pipe 307.
The sensible heat system heat source unit 306 is provided with various sensors. Specifically, the sensible heat system heat source unit 306 includes a sensible heat system suction pressure sensor 366 that detects the suction pressure of the sensible heat system compression mechanism 361 and a sensible heat system discharge that detects the discharge pressure of the sensible heat system compression mechanism 361. A pressure sensor 367 and a sensible heat system heat source side control unit 365 that controls the operation of each part constituting the sensible heat system heat source unit 306 are provided. The sensible heat system heat source side control unit 365 includes a microcomputer and a memory provided for controlling the sensible heat system heat source unit 306, and the sensible heat system utilization units 302 and 303 use the sensible heat system. Control signals can be transmitted between the side control units 328 and 338. In addition, the sensible heat system heat source side control unit 365 can exchange control signals and the like with the latent heat system heat source side control unit 265. Further, the sensible heat system heat source side control unit 365 can exchange control signals with the latent heat system use side control units 228 and 238 via the latent heat system heat source side control unit 265.

(2) Operation | movement of an air conditioning system Next, operation | movement of the air conditioning system 101 of this embodiment is demonstrated. The air conditioning system 101 can process an indoor latent heat load with the latent heat load processing system 201 and can mainly process an indoor sensible heat load with the sensible heat load processing system 301. Also in the air conditioning system 101 of this embodiment, the independent operation of the latent heat load processing system 201 is possible similarly to the air conditioning system 1 of 1st Embodiment. In addition, about this operation | movement, in the air conditioning system 1 of 1st Embodiment, while operating independently using the heat source unit 6 common to two systems, in the air conditioning system 101 of this embodiment, Although the point that it operates independently using only the latent heat system heat source unit 206 is different, the operation of the latent heat system use units 202 and 203 is the same as the operation of the latent heat system use units 2 and 3 of the first embodiment. The description in is omitted.

  Next, the operation of the air conditioning system 101 when the latent heat load processing system 201 and the sensible heat load processing system 301 are simultaneously operated will be described. The air conditioning system 101 can process indoor latent heat load mainly by the latent heat load processing system 201 and can process indoor sensible heat load mainly by the sensible heat load processing system 301. Below, various driving | operation operation | movement is demonstrated.

<Dehumidifying and cooling operation>
First, the operation in the cooling / dehumidifying operation in which the latent heat load processing system 201 is dehumidified in the full ventilation mode and the sensible heat load processing system 301 is cooled will be described with reference to FIGS. 31, 32, and 33. Here, FIG.31 and FIG.32 is a schematic refrigerant circuit diagram which shows the operation | movement at the time of the dehumidification air_conditionaing | cooling operation in the total ventilation mode in the air conditioning system 101. FIG. FIG. 33 is a control flow diagram during normal operation in the air conditioning system 101. In FIG. 33, the latent heat system utilization unit 202 and the sensible heat system utilization unit 302 pair and the latent heat system utilization unit 203 and the sensible heat system utilization unit 303 pair have the same control flow. The control flow of a pair of 202 and the sensible heat system utilization unit 303 is not shown.

First, the operation of the latent heat load processing system 201 will be described.
In the latent heat system utilization unit 202 of the latent heat load processing system 201, the first adsorption heat exchanger 222 serves as a condenser as in the case of the single operation of the latent heat load processing system 201 described above. The first operation in which 223 is an evaporator and the second operation in which the second adsorption heat exchanger 223 is a condenser and the first adsorption heat exchanger 222 is an evaporator are alternately repeated. Similarly, in the latent heat system use unit 203, the first operation in which the first adsorption heat exchanger 232 serves as a condenser and the second adsorption heat exchanger 233 serves as an evaporator, and the second adsorption heat exchanger 233 serves as a condenser. Thus, the second operation in which the first adsorption heat exchanger 232 becomes an evaporator is alternately repeated.

In the following description, the operations of the two latent heat system use units 202 and 203 will be described together.
In the first operation, the regeneration operation for the first adsorption heat exchangers 222 and 232 and the adsorption operation for the second adsorption heat exchangers 223 and 233 are performed in parallel. During the first operation, as shown in FIG. 31, the latent heat system use-side four-way switching valves 221, 231 are in the first state (refer to the solid lines of the latent heat system use-side four-way switching valves 221, 231). Is set. In this state, the high-pressure gas refrigerant discharged from the latent heat system compression mechanism 261 flows into the first adsorption heat exchangers 222 and 232 through the latent heat system discharge gas communication pipe 207 and the latent heat system use-side four-way switching valves 221 and 231. And condensed while passing through the first adsorption heat exchangers 222 and 232. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 224 and 234, and then evaporated while passing through the second adsorption heat exchangers 223 and 233, and the latent heat system use side four-way switching valve 221. 231, the latent heat system intake gas communication pipe 208, and the latent heat system accumulator 262 are again sucked into the latent heat system compression mechanism 261 (see the arrow attached to the latent heat system refrigerant circuit 210 in FIG. 31).

  During the first operation, in the first adsorption heat exchangers 222 and 232, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the first adsorption heat exchangers 222 and 232 is discharged to the outside as exhaust air EA through the exhaust port accompanying the indoor air RA. In the second adsorption heat exchangers 223 and 233, the moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. The outdoor air OA dehumidified by the second adsorption heat exchangers 223, 233 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 222, 223, 232, 233 in FIG. 31). (See arrows on both sides of the).

  In the second operation, the adsorption operation for the first adsorption heat exchangers 222 and 232 and the regeneration operation for the second adsorption heat exchangers 223 and 233 are performed in parallel. During the second operation, as shown in FIG. 32, the latent heat system use-side four-way switching valves 221 and 231 are in the second state (refer to the broken lines of the latent heat system use-side four-way switching valves 221 and 231). Is set. In this state, the high-pressure gas refrigerant discharged from the latent heat system compression mechanism 261 flows into the second adsorption heat exchangers 223 and 233 through the latent heat system discharge gas communication pipe 207 and the latent heat system use side four-way switching valves 221 and 231. And condensed while passing through the second adsorption heat exchangers 223 and 233. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 224 and 234 and then evaporated while passing through the first adsorption heat exchangers 222 and 232, and the latent heat system use side four-way switching valve 221. 231, the latent heat system intake gas communication pipe 208, and the latent heat system accumulator 262 are again sucked into the latent heat system compression mechanism 261 (see the arrow attached to the latent heat system refrigerant circuit 210 in FIG. 32).

  During the second operation, in the second adsorption heat exchangers 223 and 233, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the indoor air RA sucked from the inside air intake port. Is done. The moisture desorbed from the second adsorption heat exchangers 23 and 33 is accompanied by the indoor air RA and discharged to the outdoors as exhaust air EA through the exhaust port. In the first adsorption heat exchangers 222 and 232, moisture in the outdoor air OA is adsorbed by the adsorbent and the outdoor air OA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. The outdoor air OA dehumidified by the first adsorption heat exchangers 222 and 232 is supplied indoors as supply air SA through the air supply port (adsorption heat exchangers 222, 223, 232, and 233 in FIG. 32). (See arrows on both sides of the).

Here, the system control performed in the air conditioning system 101 will be described focusing on the latent heat load processing system 201.
First, when the target temperature and the target relative humidity are set by the remote controllers 111 and 112, the latent heat system use side control units 228 and 238 of the latent heat system use units 202 and 203 have the target temperature value and the target relative humidity value. The indoor air temperature value and relative humidity value sucked into the unit detected by the RA suction temperature / humidity sensors 225, 235, and the unit detected by the OA suction temperature / humidity sensors 226, 236 are sucked into the unit. The outdoor air temperature value and relative humidity value are input.

  Then, in step S41, the latent heat system use side control units 228 and 238 calculate the target value of enthalpy or the target value of absolute humidity from the target temperature value and target relative humidity value of indoor air, and the RA intake temperature · Calculate the current value of the enthalpy of air sucked into the unit from the indoors or the current value of absolute humidity from the temperature value and the relative humidity value detected by the humidity sensors 225 and 235, and the necessary latent heat capacity value which is the difference between the two values Δh is calculated. Then, the value of Δh is converted into a capability UP signal K1 for notifying the latent heat system heat source side controller 265 whether or not the processing capability of the latent heat system utilization units 202 and 203 needs to be increased. For example, when the absolute value of Δh is smaller than a predetermined value (that is, when the humidity value of indoor air is close to the target humidity value and there is no need to increase or decrease the processing capacity), the capability UP signal K1 is set to “ 0, and when the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the dehumidifying operation, the humidity value of indoor air is higher than the target humidity value and the processing capacity needs to be increased) If the capacity UP signal K1 is “A” and the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be reduced (that is, in the dehumidifying operation, the humidity value of the indoor air is If the humidity is lower than the target humidity value and the processing capacity needs to be lowered, the capacity UP signal K1 is set to “B”.

  Next, in step S42, the latent heat system heat source side control unit 265 receives the capability UP signal K1 of the latent heat system utilization units 202 and 203 transmitted from the latent heat system utilization side control units 228 and 238 to the latent heat system heat source side control unit 265. The target condensing temperature value TcS1 and the target evaporating temperature value TeS1 are calculated. For example, the target condensation temperature value TcS1 is calculated by adding the capability UP signal K1 of the latent heat system use units 202 and 203 to the current target condensation temperature value. Further, the target evaporation temperature value TeS1 is calculated by subtracting the capability UP signal K1 of the latent heat system utilization units 202 and 203 from the current target evaporation temperature value. As a result, when the value of the capability UP signal K1 is “A”, the target condensation temperature value TcS1 becomes high and the target evaporation temperature value TeS1 becomes low.

  Next, in step S43, a system condensing temperature value Tc1 and a system evaporating temperature value Te1 that are values corresponding to actual measured values of the condensing temperature and the evaporating temperature of the entire latent heat load processing system 201 are calculated. For example, the system condensation temperature value Tc1 and the system evaporation temperature value Te1 are the suction pressure value of the latent heat system compression mechanism 261 detected by the latent heat system suction pressure sensor 263 and the latent heat system compression mechanism 261 detected by the latent heat system discharge pressure sensor 264. Is calculated by converting the discharge pressure value to the saturation temperature of the refrigerant at these pressure values. Then, a temperature difference ΔTc1 of the target condensing temperature value TcS1 with respect to the system condensing temperature value Tc1 and a temperature difference ΔTe1 of the target evaporating temperature value TeS1 with respect to the system evaporating temperature value Te1 are calculated, and the latent heat system compression mechanism is divided by dividing these temperature differences. The necessity / increase / decrease width of the operating capacity of H.261 is determined.

  By using the operation capacity of the latent heat system compression mechanism 261 determined in this way, the operation capacity of the latent heat system compression mechanism 261 is controlled to perform system control to bring it closer to the target relative humidity of indoor air. For example, when the value obtained by subtracting the temperature difference ΔTe1 from the temperature difference ΔTc1 is a positive value, the operating capacity of the latent heat system compression mechanism 261 is increased, and conversely, the value obtained by subtracting the temperature difference ΔTe1 from the temperature difference ΔTc1 is a negative value. In this case, control is performed so as to reduce the operating capacity of the latent heat system compression mechanism 261.

Next, the operation of the sensible heat load processing system 301 will be described.
The sensible heat system heat source side four-way switching valve 362 of the sensible heat system heat source unit 306 of the sensible heat load processing system 301 is in a cooling operation state (the first port 362a and the third port 362c are connected, and the second port 362b The fourth port 362d is connected). Moreover, the opening degree of the sensible heat system utilization side expansion valves 321 and 331 of the sensible heat system utilization units 302 and 303 is adjusted so as to depressurize the refrigerant. The sensible heat system heat source side expansion valve 364 is opened.

  In such a state of the sensible heat system refrigerant circuit 310, when the sensible heat system compression mechanism 361 of the sensible heat system heat source unit 306 is activated, the high-pressure gas refrigerant discharged from the sensible heat system compression mechanism 361 becomes the sensible heat system heat source. It passes through the side four-way switching valve 362, flows into the sensible heat system heat source side heat exchanger 363, and is condensed to become a liquid refrigerant. The liquid refrigerant is sent to the sensible heat system utilization units 302 and 303 through the sensible heat system heat source side expansion valve 364, the sensible heat system receiver 368, and the sensible heat system liquid communication pipe 307. The liquid refrigerant sent to the sensible heat system utilization units 302 and 303 is depressurized by the sensible heat system utilization side expansion valves 321 and 331, and then taken indoors by the air heat exchangers 322 and 332. It evaporates by heat exchange with the air RA and becomes a low-pressure gas refrigerant. This gas refrigerant is again drawn into the sensible heat system compression mechanism 361 of the sensible heat system heat source unit 306 through the sensible heat system gas communication pipe 308. On the other hand, the indoor air RA cooled by the heat exchange with the refrigerant in the air heat exchangers 322 and 332 is supplied indoors as the supply air SA. As will be described later, the sensible heat system use side expansion valves 321 and 331 have superheat degree SH in the air heat exchangers 322 and 332, that is, air heat exchangers 322 detected by the liquid side temperature sensors 323 and 333, The degree of opening is such that the temperature difference between the liquid side refrigerant temperature value 332 and the gas side refrigerant temperature value of the air heat exchangers 322 and 332 detected by the gas side temperature sensors 324 and 334 becomes the target superheat degree SHS. Control is being made.

Here, the system control performed in the air conditioning system 101 will be described by focusing on the sensible heat load processing system 301.
First, when the target temperature is set by the remote controllers 111 and 112, the sensible heat system use side control units 328 and 338 of the sensible heat system use units 302 and 303 have the RA intake temperature sensor 325, The temperature value of indoor air sucked into the unit detected by 335 is input.

  Then, in step S44, the sensible heat system usage side control units 328 and 338 determine the temperature difference between the target temperature value of the indoor air and the temperature value detected by the RA intake temperature / humidity sensors 225 and 235 (hereinafter, the required sensible temperature). Heat capacity value ΔT). Here, since the required sensible heat capacity value ΔT is the difference between the target temperature value of indoor air and the current temperature value of indoor air as described above, the sensible heat that must be processed in the air conditioning system 101. It corresponds to a load. Then, the value of the required sensible heat capacity value ΔT is converted into a capacity UP signal K2 for informing the sensible heat system heat source side control unit 365 whether or not the processing capacity of the sensible heat system utilization units 302 and 303 needs to be increased. To do. For example, when the absolute value of ΔT is smaller than a predetermined value (that is, when the temperature value of indoor air is close to the target temperature value and there is no need to increase or decrease the processing capacity), the capability UP signal K2 is set to “ 0, and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the cooling operation, the temperature value of the indoor air is higher than the target temperature value and the processing capacity needs to be increased). When the capacity UP signal K2 is “a” and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be lowered (that is, in the cooling operation, the temperature value of the indoor air is When the temperature is lower than the target temperature value and the processing capacity needs to be lowered), the capacity UP signal K2 is set to “b”.

  Next, in step S45, the sensible heat system use side control units 328 and 338 change the value of the target superheat degree SHS according to the value of the required sensible heat capacity value ΔT. For example, when it is necessary to reduce the processing capacity of the sensible heat system utilization units 302 and 303 (when the capacity UP signal K2 is “b”), the target superheat degree SHS is increased and the air heat exchangers 322 and 332 are increased. The opening degree of the sensible heat system use side expansion valves 321 and 331 is controlled so as to reduce the amount of heat exchanged between the refrigerant and the air.

  In step S46, the sensible heat system heat source side control unit 365 increases the capacity of the sensible heat system use units 302 and 303 transmitted from the sensible heat system use side control units 328 and 338 to the sensible heat system heat source side control unit 365. A target condensation temperature value TcS2 and a target evaporation temperature value TeS2 are calculated using the signal K2. For example, the target condensation temperature value TcS2 is calculated by adding the capability UP signal K2 of the sensible heat system utilization units 302 and 303 to the current target condensation temperature value. Further, the target evaporation temperature value TeS2 is calculated by subtracting the capability UP signal K2 of the sensible heat system utilization units 302 and 303 from the current target evaporation temperature value. As a result, when the value of the capability UP signal K2 is “a”, the target condensation temperature TcS2 becomes high and the target evaporation temperature value TeS2 becomes low. As described above, in the latent heat load processing system 201, the sensible heat treatment is performed together with the latent heat treatment. Therefore, in calculating the target condensation temperature value TcS2 and the target evaporation temperature value TeS2, the latent heat load processing system 201 determines the latent heat load. A calculation method that takes into account the processing capacity of the sensible heat load (generated sensible heat processing capacity) that is processed together with the processing is employed, but will not be described here and will be described later.

  Next, in step S47, a system condensing temperature value Tc2 and a system evaporating temperature value Te2 that are values corresponding to actual measured values of the condensing temperature and the evaporating temperature of the entire sensible heat load treatment system 301 are calculated. For example, the system condensation temperature value Tc2 and the system evaporation temperature value Te2 are the suction pressure value of the sensible heat system compression mechanism 361 detected by the sensible heat system suction pressure sensor 366 and the sensible heat detected by the sensible heat system discharge pressure sensor 367. Calculation is performed by converting the discharge pressure value of the system compression mechanism 361 into the saturation temperature of the refrigerant at these pressure values. Then, a temperature difference ΔTc2 of the target condensation temperature value TcS2 with respect to the system condensation temperature value Tc2 and a temperature difference ΔTe2 of the target evaporation temperature value TeS2 with respect to the system evaporation temperature value Te2 are calculated. In the case of the cooling operation, necessity / increase / decrease width of the operation capacity of the sensible heat system compression mechanism 361 is determined from the temperature difference ΔTe2.

  By using the operating capacity of the sensible heat system compression mechanism 361 determined in this way, the system control to bring the target temperature of the sensible heat system utilization units 302 and 303 closer to the target temperature by controlling the operation capacity of the sensible heat system compression mechanism 361. It is carried out. For example, when the temperature difference ΔTe2 is a positive value, the operating capacity of the sensible heat system compression mechanism 361 is decreased. Conversely, when the temperature difference ΔTe2 is a negative value, the operating capacity of the sensible heat system compression mechanism 361 is increased. To control.

  Thus, in this air conditioning system 101, the latent heat load (necessary latent heat treatment capability, corresponding to Δh) that must be processed as the entire air conditioning system 101 and the sensible heat load that must be processed as the entire air conditioning system 101. (Necessary sensible heat treatment capacity, corresponding to ΔT) is processed using the latent heat load treatment system 201 and the sensible heat load treatment system 301. Here, the increase or decrease in the processing capacity of the latent heat load processing system 201 is mainly performed by controlling the operation capacity of the latent heat system compression mechanism 261. The increase or decrease in the processing capacity of the sensible heat load processing system 301 is mainly performed by controlling the operation capacity of the sensible heat system compression mechanism 361. That is, increase / decrease in the processing capacity of the latent heat load processing system 201 and increase / decrease in the processing capacity of the sensible heat load processing system 301 are basically performed separately.

  On the other hand, in the latent heat load processing by the latent heat load processing system 201, as described above, the latent heat treatment system 201 and the sensible heat treatment are performed in the latent heat load processing system 201 by the adsorption operation or regeneration operation of the adsorption heat exchangers 222, 223, 232, 233. Is done. That is, if the processing capacity of the sensible heat treatment performed together with the latent heat treatment in the latent heat load processing system 201 is the generated sensible heat processing capacity Δt, the sensible heat load that must be processed by the sensible heat load processing system 301 is the required sensible heat processing capacity value ΔT. Therefore, it is sufficient to subtract the generated sensible heat treatment ability Δt. Nevertheless, since the increase or decrease in the processing capacity of the latent heat load processing system 201 and the increase or decrease in the processing capacity of the sensible heat load processing system 301 are basically performed separately, the processing capacity of the sensible heat load processing system 301 is reduced. Excessive heat treatment capacity Δt will be excessive.

For this reason, in this air conditioning system 101, the following system control is performed in consideration of the above relationship.
First, the latent heat system use side control units 228 and 238 supply the SA with the temperature value and relative humidity value of the indoor air sucked into the unit detected by the RA suction temperature / humidity sensors 225 and 235 described above. Since the temperature value of the air supplied indoors from within the unit detected by the temperature sensors 227 and 237 is input, in step S48, the temperature value detected by the RA suction temperature / humidity sensors 225 and 235, and the SA A generated sensible heat capacity value Δt, which is a temperature difference from the temperature values detected by the supply temperature sensors 227 and 237, is calculated. Then, the value of the generated sensible heat capacity value Δt is converted into a sensible heat treatment signal K3 for informing the sensible heat system heat source side control unit 365 whether or not the processing capacity of the sensible heat system utilization units 302 and 303 needs to be lowered. To do. For example, when the absolute value of Δt is smaller than a predetermined value (that is, the temperature value of the air supplied indoors from the latent heat system use units 202 and 203 is close to the temperature value of the indoor air, and the sensible heat system is used) When it is not necessary to increase or decrease the processing capacity of the units 302 and 303), the sensible heat treatment signal K3 should be set to “0”, and the processing power of the sensible heat system utilization units 302 and 303 must be lowered below the predetermined value of Δt. When the temperature is larger in the direction that must be (that is, in the cooling operation, the temperature value of the air supplied indoors from the latent heat system use units 202 and 203 is lower than the temperature value of the indoor air, and the sensible heat system use unit 302 , 303), the sensible heat treatment signal K3 is set to “a ′”.

  In step S46, the sensible heat system heat source side control unit 365 increases the capacity of the sensible heat system use units 302 and 303 transmitted from the sensible heat system use side control units 328 and 338 to the sensible heat system heat source side control unit 365. When calculating the target condensation temperature value TcS2 and the target evaporation temperature value TeS2 using the signal K2, the latent heat system use side control units 228 and 238 pass through the latent heat system heat source side control unit 265 to the sensible heat system heat source side control unit 365. Calculation is performed in consideration of the transmitted sensible heat treatment signal K3. The target condensation temperature value TcS2 is calculated by adding the capability UP signal K2 of the sensible heat system utilization units 302 and 303 to the current target condensation temperature value and subtracting the sensible heat treatment signal K3. The target evaporation temperature value TeS2 is calculated by subtracting the capability UP signal K2 of the sensible heat system utilization units 302 and 303 from the current target evaporation temperature value and adding the sensible heat treatment signal K3. Thereby, when the value of the sensible heat treatment signal K3 is “a ′”, the target condensation temperature TcS2 becomes low and the target evaporation temperature value TeS2 becomes high. As a result, the sensible heat system utilization units 302 and 303 The target condensing temperature value TcS2 and the target evaporating temperature value TeS2 can be changed in the direction of decreasing the processing capacity.

In step S47, in the case of the cooling operation, the temperature difference ΔTe2 is calculated based on the target evaporation temperature value TeS2 considering the sensible heat treatment signal K3, and whether or not the operation capacity of the sensible heat system compression mechanism 361 needs to be increased or decreased. Determine the range of increase or decrease.
By using the operating capacity of the sensible heat system compression mechanism 361 determined in this way, the system control to bring the target temperature of the sensible heat system utilization units 302 and 303 closer to the target temperature by controlling the operation capacity of the sensible heat system compression mechanism 361. It is carried out. For example, when the temperature difference ΔTe2 is a positive value, the operating capacity of the sensible heat system compression mechanism 361 is decreased. Conversely, when the temperature difference ΔTe2 is a negative value, the operating capacity of the sensible heat system compression mechanism 361 is increased. To control.

  As a result, the air conditioning system 101 calculates the generated sensible heat capacity value Δt corresponding to the generated sensible heat treatment capacity, which is the processing capacity of the sensible heat treatment performed together with the latent heat treatment in the latent heat load processing system 201, and this generated sensible heat treatment capacity Δt. By controlling the operating capacity of the sensible heat system compression mechanism 361 in consideration of the above, it is possible to prevent the sensible heat treatment capacity in the sensible heat load treatment system 301 from becoming excessive. Thereby, the convergence property with respect to the indoor target air temperature can be improved.

Here, as an example of the dehumidifying and cooling operation, the case where the cooling operation of the sensible heat load processing system 301 is performed while the latent heat load processing system 201 is performing the dehumidifying operation in the full ventilation mode has been described. The present invention is applicable even when the dehumidifying operation is performed in other modes such as a circulation mode and an air supply mode.
<Humidification heating operation>
Next, the operation in the humidifying and heating operation in which the latent heat load processing system 201 performs the humidifying operation in the full ventilation mode and the sensible heat load processing system 301 performs the heating operation will be described with reference to FIGS. 33 to 35. Here, FIG. 24 and FIG. 25 are schematic refrigerant circuit diagrams showing an operation during humidification heating operation in the total ventilation mode in the air conditioning system 101.

First, the operation of the latent heat load processing system 201 will be described.
In the latent heat system utilization unit 202 of the latent heat load processing system 201, the first adsorption heat exchanger 222 serves as a condenser as in the case of the single operation of the latent heat load processing system 201 described above. The first operation in which 223 is an evaporator and the second operation in which the second adsorption heat exchanger 223 is a condenser and the first adsorption heat exchanger 222 is an evaporator are alternately repeated. Similarly, in the latent heat system use unit 203, the first operation in which the first adsorption heat exchanger 232 serves as a condenser and the second adsorption heat exchanger 233 serves as an evaporator, and the second adsorption heat exchanger 233 serves as a condenser. Thus, the second operation in which the first adsorption heat exchanger 232 becomes an evaporator is alternately repeated.

In the following description, the operations of the two latent heat system use units 202 and 203 will be described together.
In the first operation, the regeneration operation for the first adsorption heat exchangers 222 and 232 and the adsorption operation for the second adsorption heat exchangers 223 and 233 are performed in parallel. During the first operation, as shown in FIG. 34, the latent heat system use-side four-way switching valves 221 and 231 are in the first state (refer to the solid lines of the latent heat system use-side four-way switching valves 221 and 231). Is set. In this state, the high-pressure gas refrigerant discharged from the latent heat system compression mechanism 261 flows into the first adsorption heat exchangers 222 and 232 through the latent heat system discharge gas communication pipe 207 and the latent heat system use-side four-way switching valves 221 and 231. And condensed while passing through the first adsorption heat exchangers 222 and 232. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 224 and 234, and then evaporated while passing through the second adsorption heat exchangers 223 and 233, and the latent heat system use side four-way switching valve 221. 231, the latent heat system intake gas communication pipe 208 and the latent heat system accumulator 262 are again sucked into the latent heat system compression mechanism 261 (see the arrow attached to the latent heat system refrigerant circuit 210 in FIG. 34).

  During the first operation, in the first adsorption heat exchangers 222 and 232, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the first adsorption heat exchangers 222 and 232 is supplied indoors as the supply air SA through the air supply port along with the outdoor air OA. In the second adsorption heat exchangers 223 and 233, the moisture in the indoor air RA is adsorbed by the adsorbent to dehumidify the indoor air RA, and the heat of adsorption generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the second adsorption heat exchangers 223, 233 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 222, 223, 232, 233 in FIG. 34). See arrows on both sides).

  In the second operation, the adsorption operation for the first adsorption heat exchangers 222 and 232 and the regeneration operation for the second adsorption heat exchangers 223 and 233 are performed in parallel. During the second operation, as shown in FIG. 35, the latent heat system use-side four-way switching valves 221 and 231 are in the second state (see the broken lines of the latent heat system use-side four-way switching valves 221 and 231 in FIG. 35). Is set. In this state, the high-pressure gas refrigerant discharged from the latent heat system compression mechanism 261 flows into the second adsorption heat exchangers 223 and 233 through the latent heat system discharge gas communication pipe 207 and the latent heat system use side four-way switching valves 221 and 231. And condensed while passing through the second adsorption heat exchangers 223 and 233. The condensed refrigerant is depressurized by the latent heat system use side expansion valves 224 and 234, and then evaporated while passing through the first adsorption heat exchangers 222 and 232, and the latent heat system use side four-way switching valve 221. 231, the latent heat system intake gas communication pipe 208 and the latent heat system accumulator 262 are again sucked into the latent heat system compression mechanism 261 (see the arrow attached to the latent heat system refrigerant circuit 210 in FIG. 35).

  During the second operation, in the second adsorption heat exchangers 223 and 233, moisture is desorbed from the adsorbent heated by the condensation of the refrigerant, and the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet. Is done. The moisture desorbed from the second adsorption heat exchangers 223 and 233 is supplied indoors as supply air SA through the air supply port accompanying the outdoor air OA. In the first adsorption heat exchangers 222 and 232, the moisture in the indoor air RA is adsorbed by the adsorbent and the indoor air RA is dehumidified, and the adsorption heat generated at that time is absorbed by the refrigerant and the refrigerant evaporates. Then, the indoor air RA dehumidified by the first adsorption heat exchangers 222 and 232 is discharged to the outside as exhaust air EA through the exhaust port (of the adsorption heat exchangers 222, 223, 232, and 233 in FIG. 35). See arrows on both sides).

Here, the system control performed in the air conditioning system 101 will be described focusing on the latent heat load processing system 201.
First, when the target temperature and the target relative humidity are set by the remote controllers 111 and 112, the latent heat system use side control units 228 and 238 of the latent heat system use units 202 and 203 have the target temperature value and the target relative humidity value. The indoor air temperature value and relative humidity value sucked into the unit detected by the RA suction temperature / humidity sensors 225, 235, and the unit detected by the OA suction temperature / humidity sensors 226, 236 are sucked into the unit. The outdoor air temperature value and relative humidity value are input.

  Then, in step S41, the latent heat system use side control units 228 and 238 calculate the target value of enthalpy or the target value of absolute humidity from the target temperature value and target relative humidity value of indoor air, and the RA intake temperature · Calculate the current value of the enthalpy of air sucked into the unit from the indoors or the current value of absolute humidity from the temperature value and the relative humidity value detected by the humidity sensors 225 and 235, and the necessary latent heat capacity value which is the difference between the two values Δh is calculated. Then, the value of Δh is converted into a capability UP signal K1 for notifying the latent heat system heat source side controller 265 whether or not the processing capability of the latent heat system utilization units 202 and 203 needs to be increased. For example, when the absolute value of Δh is smaller than a predetermined value (that is, when the humidity value of indoor air is close to the target humidity value and there is no need to increase or decrease the processing capacity), the capability UP signal K1 is set to “ 0, and when the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the humidification operation, the humidity value of indoor air is lower than the target humidity value and the processing capacity needs to be increased) When the capacity UP signal K1 is “A” and the absolute value of Δh is larger than the predetermined value in the direction in which the processing capacity must be lowered (that is, in the humidification operation, the humidity value of the indoor air is If it is higher than the target humidity value and the processing capacity needs to be lowered), the capacity UP signal K1 is set to “B”.

  Next, in step S42, the latent heat system heat source side control unit 265 receives the capability UP signal K1 of the latent heat system utilization units 202 and 203 transmitted from the latent heat system utilization side control units 228 and 238 to the latent heat system heat source side control unit 265. The target condensing temperature value TcS1 and the target evaporating temperature value TeS1 are calculated. For example, the target condensation temperature value TcS1 is calculated by adding the capability UP signal K1 of the latent heat system use units 202 and 203 to the current target condensation temperature value. Further, the target evaporation temperature value TeS1 is calculated by subtracting the capability UP signal K1 of the latent heat system utilization units 202 and 203 from the current target evaporation temperature value. As a result, when the value of the capability UP signal K1 is “A”, the target condensation temperature value TcS1 becomes high and the target evaporation temperature value TeS1 becomes low.

  Next, in step S43, a system condensing temperature value Tc1 and a system evaporating temperature value Te1 that are values corresponding to actual measured values of the condensing temperature and the evaporating temperature of the entire latent heat load processing system 201 are calculated. For example, the system condensation temperature value Tc1 and the system evaporation temperature value Te1 are the suction pressure value of the latent heat system compression mechanism 261 detected by the latent heat system suction pressure sensor 263 and the latent heat system compression mechanism 261 detected by the latent heat system discharge pressure sensor 264. Is calculated by converting the discharge pressure value to the saturation temperature of the refrigerant at these pressure values. Then, a temperature difference ΔTc1 of the target condensing temperature value TcS1 with respect to the system condensing temperature value Tc1 and a temperature difference ΔTe1 of the target evaporating temperature value TeS1 with respect to the system evaporating temperature value Te1 are calculated, and the latent heat system compression mechanism is divided by dividing these temperature differences. The necessity / increase / decrease width of the operating capacity of H.261 is determined.

  By using the operation capacity of the latent heat system compression mechanism 261 determined in this way, the operation capacity of the latent heat system compression mechanism 261 is controlled to perform system control to bring it closer to the target relative humidity of indoor air. For example, when the value obtained by subtracting the temperature difference ΔTe1 from the temperature difference ΔTc1 is a positive value, the operating capacity of the latent heat system compression mechanism 261 is increased, and conversely, the value obtained by subtracting the temperature difference ΔTe1 from the temperature difference ΔTc1 is a negative value. In this case, control is performed so as to reduce the operating capacity of the latent heat system compression mechanism 261.

Next, the operation of the sensible heat load processing system 301 will be described.
The sensible heat system heat source side four-way switching valve 362 of the sensible heat system heat source unit 306 of the sensible heat load processing system 301 is in a heating operation state (the first port 362a and the fourth port 362d are connected, and the second port 362b The third port 362c is connected). Moreover, the opening degree of the sensible heat system utilization side expansion valves 321 and 331 of the sensible heat system utilization units 302 and 303 is adjusted according to the heating load of the sensible heat system utilization units 302 and 303. The opening degree of the sensible heat system heat source side expansion valve 364 is adjusted so as to depressurize the refrigerant.

  When the sensible heat system compression mechanism 361 of the sensible heat system heat source unit 306 is activated in such a state of the sensible heat system refrigerant circuit 310, the high-pressure gas refrigerant discharged from the sensible heat system compression mechanism 361 is transferred to the sensible heat system heat source side. It is sent to the sensible heat system utilization units 302 and 303 through the four-way switching valve 362 and the sensible heat system gas communication pipe 308. The high-pressure gas refrigerant sent to the sensible heat system utilization units 302 and 303 is condensed by the heat exchange with the indoor air RA sucked into the units in the air heat exchangers 322 and 332 and becomes liquid refrigerant, It is sent to the sensible heat system heat source unit 306 through the sensible heat system use side expansion valves 321 and 331 and the sensible heat system liquid communication pipe 307. On the other hand, the indoor air RA heated by the heat exchange with the refrigerant in the air heat exchangers 322 and 332 is supplied indoors as the supply air SA. Then, the liquid refrigerant sent to the sensible heat system heat source unit 306 passes through the sensible heat system receiver 368 and is depressurized by the sensible heat system heat source side expansion valve 364, and then evaporated by the sensible heat system heat source side heat exchanger 363. As a result, the refrigerant becomes low-pressure gas refrigerant and is sucked into the sensible heat system compression mechanism 361 again through the sensible heat system heat source side four-way switching valve 362. The sensible heat system use side expansion valves 321 and 331 are, as will be described later, the subcool degree SC of the air heat exchangers 322 and 332, that is, the air heat exchanger 322 detected by the liquid side temperature sensors 323 and 333. 332 so that the temperature difference between the liquid side refrigerant temperature value of 332 and the gas side refrigerant temperature value of the air heat exchangers 322 and 332 detected by the gas side temperature sensors 324 and 334 becomes the target supercooling degree SCS. The opening degree is controlled.

Here, the system control performed in the air conditioning system 101 will be described by focusing on the sensible heat load processing system 301.
First, when the target temperature is set by the remote controllers 111 and 112, the sensible heat system use side control units 328 and 338 of the sensible heat system use units 302 and 303 have the RA intake temperature sensor 325, The temperature value of indoor air sucked into the unit detected by 335 is input.

  Then, in step S44, the sensible heat system usage side control units 328 and 338 determine the temperature difference between the target temperature value of the indoor air and the temperature value detected by the RA intake temperature / humidity sensors 225 and 235 (hereinafter, the required sensible temperature). Heat capacity value ΔT). Here, since the required sensible heat capacity value ΔT is the difference between the target temperature value of indoor air and the current temperature value of indoor air as described above, the sensible heat that must be processed in the air conditioning system 101. It corresponds to a load. Then, the value of the required sensible heat capacity value ΔT is converted into a capacity UP signal K2 for informing the sensible heat system heat source side control unit 365 whether or not the processing capacity of the sensible heat system utilization units 302 and 303 needs to be increased. To do. For example, when the absolute value of ΔT is smaller than a predetermined value (that is, when the temperature value of indoor air is close to the target temperature value and there is no need to increase or decrease the processing capacity), the capability UP signal K2 is set to “ 0, and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be increased (that is, in the heating operation, the temperature value of the indoor air is lower than the target temperature value and the processing capacity needs to be increased) When the capacity UP signal K2 is “a” and the absolute value of ΔT is larger than the predetermined value in the direction in which the processing capacity must be lowered (that is, in the heating operation, the temperature value of indoor air is When the temperature is higher than the target temperature value and the processing capacity needs to be lowered), the capacity UP signal K2 is set to “b”.

  Next, in step S45, the sensible heat system use side control units 328 and 338 change the value of the target supercooling degree SCS according to the value of the required sensible heat capacity value ΔT. For example, when it is necessary to reduce the processing capacity of the sensible heat system utilization units 302 and 303 (when the capacity UP signal K2 is “b”), the target supercooling degree SCS is increased and the air heat exchanger 322, The opening degree of the sensible heat system use side expansion valves 321 and 331 is controlled so as to reduce the amount of heat exchanged between the refrigerant and the air in 332.

  In step S46, the sensible heat system heat source side control unit 365 increases the capacity of the sensible heat system use units 302 and 303 transmitted from the sensible heat system use side control units 328 and 338 to the sensible heat system heat source side control unit 365. A target condensation temperature value TcS2 and a target evaporation temperature value TeS2 are calculated using the signal K2. For example, the target condensation temperature value TcS2 is calculated by adding the capability UP signal K2 of the sensible heat system utilization units 302 and 303 to the current target condensation temperature value. Further, the target evaporation temperature value TeS2 is calculated by subtracting the capability UP signal K2 of the sensible heat system utilization units 302 and 303 from the current target evaporation temperature value. As a result, when the value of the capability UP signal K2 is “a”, the target condensation temperature TcS2 becomes high and the target evaporation temperature value TeS2 becomes low. As described above, in the latent heat load processing system 201, the sensible heat treatment is performed together with the latent heat treatment. Therefore, in calculating the target condensation temperature value TcS2 and the target evaporation temperature value TeS2, the latent heat load processing system 201 determines the latent heat load. A calculation method that takes into account the processing capacity of the sensible heat load (generated sensible heat processing capacity) that is processed together with the processing is employed, but will not be described here and will be described later.

  Next, in step S47, a system condensing temperature value Tc2 and a system evaporating temperature value Te2 that are values corresponding to actual measured values of the condensing temperature and the evaporating temperature of the entire sensible heat load treatment system 301 are calculated. For example, the system condensation temperature value Tc2 and the system evaporation temperature value Te2 are the suction pressure value of the sensible heat system compression mechanism 361 detected by the sensible heat system suction pressure sensor 366 and the sensible heat detected by the sensible heat system discharge pressure sensor 367. Calculation is performed by converting the discharge pressure value of the system compression mechanism 361 into the saturation temperature of the refrigerant at these pressure values. Then, a temperature difference ΔTc2 of the target condensation temperature value TcS2 with respect to the system condensation temperature value Tc2 and a temperature difference ΔTe2 of the target evaporation temperature value TeS2 with respect to the system evaporation temperature value Te2 are calculated. In the case of the heating operation, whether or not the operation capacity of the sensible heat system compression mechanism 361 needs to be increased or decreased is determined from the temperature difference ΔTc2.

  By using the operating capacity of the sensible heat system compression mechanism 361 determined in this way, the system control to bring the target temperature of the sensible heat system utilization units 302 and 303 closer to the target temperature by controlling the operation capacity of the sensible heat system compression mechanism 361. It is carried out. For example, when the temperature difference ΔTc2 is a positive value, the operation capacity of the latent heat system compression mechanism 261 is increased. Conversely, when the temperature difference ΔTc2 is a negative value, the operation capacity of the latent heat system compression mechanism 261 is decreased. Control.

Even in this case, since the sensible heat treatment is performed together with the latent heat treatment in the latent heat load treatment system 201 by the adsorption operation or the regeneration operation of the adsorption heat exchangers 222, 223, 232, 233, the process of the sensible heat load treatment system 301 is performed. A phenomenon occurs in which the capacity becomes excessive by the amount of the generated sensible heat treatment capacity Δt.
For this reason, in this air conditioning system 101, the same system control as in the dehumidifying and cooling operation is performed.

  First, the latent heat system use side control units 228 and 238 supply the SA with the temperature value and relative humidity value of the indoor air sucked into the unit detected by the RA suction temperature / humidity sensors 225 and 235 described above. Since the temperature value of the air supplied indoors from within the unit detected by the temperature sensors 227 and 237 is input, in step S18, the temperature value detected by the RA suction temperature / humidity sensors 225 and 235, and the SA A generated sensible heat capacity value Δt, which is a temperature difference from the temperature values detected by the supply temperature sensors 227 and 237, is calculated. Then, the value of the generated sensible heat capacity value Δt is converted into a sensible heat treatment signal K3 for informing the sensible heat system heat source side control unit 365 whether or not the processing capacity of the sensible heat system utilization units 302 and 303 needs to be lowered. To do. For example, when the absolute value of Δt is smaller than a predetermined value (that is, the temperature value of the air supplied indoors from the latent heat system use units 202 and 203 is close to the temperature value of the indoor air, and the sensible heat system is used) When it is not necessary to increase or decrease the processing capacity of the units 302 and 303), the sensible heat treatment signal K3 should be set to “0”, and the processing power of the sensible heat system utilization units 302 and 303 must be lowered below the predetermined value of Δt. If it is large in the direction that must be (that is, in the heating operation, the temperature value of the air supplied indoors from the latent heat system use units 202 and 203 is higher than the temperature value of the indoor air, and the sensible heat system use unit 302 , 303), the sensible heat treatment signal K3 is set to “a ′”.

  In step S46, the sensible heat system heat source side control unit 365 increases the capacity of the sensible heat system use units 302 and 303 transmitted from the sensible heat system use side control units 328 and 338 to the sensible heat system heat source side control unit 365. When calculating the target condensation temperature value TcS2 and the target evaporation temperature value TeS2 using the signal K2, the latent heat system use side control units 228 and 238 pass through the latent heat system heat source side control unit 265 to the sensible heat system heat source side control unit 365. Calculation is performed in consideration of the transmitted sensible heat treatment signal K3. The target condensation temperature value TcS2 is calculated by adding the capability UP signal K2 of the sensible heat system utilization units 302 and 303 to the current target condensation temperature value and subtracting the sensible heat treatment signal K3. The target evaporation temperature value TeS2 is calculated by subtracting the capability UP signal K2 of the sensible heat system utilization units 302 and 303 from the current target evaporation temperature value and adding the sensible heat treatment signal K3. Thereby, when the value of the sensible heat treatment signal K3 is “a ′”, the target condensation temperature TcS2 becomes low and the target evaporation temperature value TeS2 becomes high. As a result, the sensible heat system utilization units 302 and 303 The target condensing temperature value TcS2 and the target evaporating temperature value TeS2 can be changed in the direction of decreasing the processing capacity.

In step S47, in the case of heating operation, the temperature difference ΔTc2 is calculated based on the target condensation temperature value TcS2 in consideration of the sensible heat treatment signal K3, and whether or not the operation capacity of the sensible heat system compression mechanism 361 needs to be increased or decreased. Determine the range of increase or decrease.
By using the operating capacity of the sensible heat system compression mechanism 361 determined in this way, the system control to bring the target temperature of the sensible heat system utilization units 302 and 303 closer to the target temperature by controlling the operation capacity of the sensible heat system compression mechanism 361. It is carried out. For example, when the temperature difference ΔTc2 is positive, the operating capacity of the sensible heat system compression mechanism 361 is increased, and conversely, when the temperature difference ΔTc2 is negative, the operating capacity of the sensible heat system compression mechanism 361 is decreased. To control.

  As a result, the air conditioning system 101 calculates the generated sensible heat capacity value Δt corresponding to the generated sensible heat treatment capacity, which is the processing capacity of the sensible heat treatment performed together with the latent heat treatment in the latent heat load processing system 201, and this generated sensible heat treatment capacity Δt. By controlling the operating capacity of the sensible heat system compression mechanism 361 in consideration of the above, it is possible to prevent the sensible heat treatment capacity in the sensible heat load treatment system 301 from becoming excessive. Thereby, the convergence property with respect to the indoor target air temperature can be improved.

Here, as an example of the humidification heating operation, the case where the latent heat load processing system 201 performs the heating operation of the sensible heat load processing system 301 while performing the humidification operation in the full ventilation mode has been described. This is applicable even when the humidifying operation is performed in other modes such as a circulation mode and an air supply mode.
<System startup>
Next, the operation | movement at the time of starting of the air conditioning system 101 is demonstrated using FIG.5, FIG.31, FIG.32, FIG.36 and FIG. Here, FIG. 36 is a schematic refrigerant circuit diagram showing the operation of the air conditioning system 101 when the first system is started. FIG. 37 is a schematic refrigerant circuit diagram showing an operation at the time of starting the second system in the air conditioning system 101.

  There are three activation methods described below as operations at the time of activation of the air conditioning system 101. The first system activation method is a method of operating in a state where outdoor air does not pass through the adsorption heat exchangers 222, 223, 232, 233 of the latent heat load processing system 201. In the second system activation method, outdoor air is removed from the latent heat load processing system 201 in a state where switching of the adsorption operation and the regeneration operation of the adsorption heat exchangers 222, 223, 232, 233 of the latent heat load processing system 201 is stopped. After passing through one of the first adsorption heat exchangers 222 and 232 and the second adsorption heat exchangers 223 and 233, it is discharged to the outside, and the indoor air is exchanged with the first adsorption heat exchangers 222 and 232 and the second adsorption heat exchange. This is an operation method of supplying the indoors after passing the other of the containers 223 and 233. The third system activation method is a method of operating with the switching time interval between the adsorption operation and the regeneration operation of the adsorption heat exchangers 222, 223, 232, 233 longer than that in the normal operation.

First, the operation at the time of starting the first system will be described with reference to FIG. 36, assuming that the sensible heat load processing system 301 is in cooling operation.
When an operation command is issued from the remote controllers 111 and 112, the sensible heat load processing system 301 is activated and the cooling operation is performed. Here, the operation during the cooling operation of the sensible heat load treatment system 301 is the same as that during the dehumidifying and cooling operation described above, and thus the description thereof is omitted.

On the other hand, in the latent heat load processing system 201, outdoor air is sucked into the unit by operation of an air supply fan, an exhaust fan, a damper, etc., and the adsorption heat exchangers 222, 223, 232 of the latent heat system utilization units 202, 203 are used. , 234 is started without passing through.
Then, since the refrigerant and air are not in heat exchange in the adsorption heat exchangers 222, 223, 232, 233 of the latent heat system use units 202, 203, the latent heat system compression mechanism 261 of the latent heat system heat source unit 306 is activated. In other words, the latent heat load processing system 201 does not perform the latent heat treatment.

  And the operation | movement at the time of this system starting is cancelled | released after satisfy | filling a predetermined condition, and it transfers to normal dehumidification cooling operation. For example, the timer provided in the latent heat system heat source side control unit 265 cancels the operation at the time of starting the system after a predetermined time (for example, about 30 minutes) has elapsed from the start of the system, or inputs by the remote controllers 111 and 112 The temperature difference between the target temperature value of the indoor air detected and the temperature value of the indoor air sucked into the unit detected by the RA suction temperature sensors 325 and 335 is less than a predetermined temperature difference (for example, 3 ° C.). After this, the system startup operation is canceled.

  As described above, in the air conditioning system 101, at the time of system startup, the sensible heat treatment is mainly performed by supplying the air heat-exchanged indoors in the air heat exchangers 322 and 332 of the sensible heat system utilization units 302 and 303, In addition, since outdoor air is not introduced by preventing outdoor air from passing through the adsorption heat exchangers 222, 223, 232, 233 of the latent heat system utilization units 202, 203, the latent heat load processing system is activated when the system is started. It is possible to prevent the introduction of a heat load from outside air in a state where the air conditioning capability is not exhibited, and the target temperature of indoor air can be quickly reached. Thereby, the latent heat load processing system 201 having the adsorption heat exchangers 222, 223, 232, 233 and mainly processing the indoor latent heat load, and the air heat exchangers 322 and 332 mainly processing the indoor sensible heat load. In the air conditioning system 101 configured with the sensible heat load treatment system 301, the cooling can be performed quickly when the system is activated. Here, the case where the sensible heat load processing system 301 is air-cooled has been described, but this system activation method can be applied even when the air-warming operation is performed.

Next, the operation at the time of starting the second system will be described with reference to FIGS. 5 and 37, assuming that the sensible heat load processing system 301 is in the cooling operation.
When an operation command is issued from the remote controllers 111 and 112, the sensible heat load processing system 301 is activated and the cooling operation is performed. Here, the operation during the cooling operation of the sensible heat load treatment system 301 is the same as described above, and thus the description thereof is omitted.

  On the other hand, in the latent heat load processing system 201, in a state where the switching operation of the latent heat system use side four-way switching valves 221, 231 is not performed, and the state is switched to the same air flow path as the circulation mode by operation of a damper, When the air supply fan and the exhaust fan of the latent heat system utilization units 202 and 203 are operated, the indoor air RA is sucked into the unit through the inside air inlet and supplied indoors as the supply air SA through the air inlet, and the outdoor air OA is outside air. An operation is performed in which the air is sucked into the unit through the suction port and the exhaust air EA is discharged to the outside through the exhaust port.

  When such an operation is performed, immediately after the system is started up, the desorbed moisture is given to the outdoor air OA sucked from the outside air inlet and discharged to the outside as exhaust air EA through the outlet, and indoor air The moisture in the RA is adsorbed by the adsorbent, the indoor air RA is dehumidified, and supplied to the indoor as the supply air SA through the air supply port. However, after a certain period of time has elapsed since the system was started, as shown in FIG. 5, the adsorbents of the adsorption heat exchangers 222, 223, 232, 233 adsorb moisture to the vicinity of the moisture adsorption capacity. As a result, the latent heat load processing system 201 functions as a system for processing the sensible heat load. Thereby, the sensible heat processing capability as the air conditioning system 101 as a whole can be increased, and the sensible heat treatment in the room can be promoted.

  And the operation | movement at the time of this system starting is cancelled | released after satisfy | filling a predetermined condition, and it transfers to normal dehumidification cooling operation. For example, the timer provided in the latent heat system heat source side control unit 265 cancels the operation at the time of starting the system after a predetermined time (for example, about 30 minutes) has elapsed from the start of the system, or inputs by the remote controllers 111 and 112 The temperature difference between the target indoor air temperature value and the indoor air temperature value sucked into the unit detected by the RA intake temperature / humidity sensors 225 and 235 is a predetermined temperature difference (eg, 3 ° C.). After the following condition is reached, this system startup operation is canceled.

  As described above, in the air conditioning system 101, at the time of system startup, the sensible heat treatment is mainly performed by supplying the air heat-exchanged indoors in the air heat exchangers 322 and 332 of the sensible heat system utilization units 302 and 303, In addition, in the state where the switching of the adsorption operation and the regeneration operation of the adsorption heat exchangers 222, 223, 232, 233 is stopped, the outdoor heat is passed through the adsorption heat exchangers 222, 223, 232, 233 and then discharged to the outdoors. Thus, since the sensible heat treatment is performed, the indoor sensible heat treatment can be promoted and the target temperature of the indoor air can be quickly reached when the system is activated. Thereby, the latent heat load processing system 201 having the adsorption heat exchangers 222, 223, 232, 233 and mainly processing the indoor latent heat load, and the air heat exchangers 322 and 332 mainly processing the indoor sensible heat load. In the air conditioning system 101 configured with the sensible heat load treatment system 301, the cooling can be performed quickly when the system is activated. Here, the case where the sensible heat load processing system 301 is air-cooled has been described, but this system activation method can be applied even when the air-warming operation is performed.

Next, regarding the operation at the time of starting the third system, it is assumed that the latent heat load processing system 201 is dehumidified in the total ventilation mode and the sensible heat load processing system 301 is cooled. 32.
When an operation command is issued from the remote controllers 111 and 112, the sensible heat load processing system 301 is activated and the cooling operation is performed. Here, the operation during the cooling operation of the sensible heat load treatment system 301 is the same as described above, and thus the description thereof is omitted.

  On the other hand, the latent heat load processing system 201 is similar to the above in that the dehumidifying operation is performed in the full ventilation mode, but the switching time interval between the adsorption operation and the regeneration operation has priority over the latent heat treatment used in the normal operation. The switching time interval D that prioritizes the sensible heat treatment is set to be longer than the switching time interval C to be performed. Therefore, the switching operation of the latent heat system use side four-way switching valves 221 and 231 of the latent heat system use units 202 and 203 is performed at a slower cycle than during normal operation only when the system is activated. Then, immediately after the switching of the latent heat system use side four-way switching valves 221, 231, the adsorption heat exchangers 222, 223, 232, 233 mainly perform the latent heat treatment, but when the time D elapses, the sensible heat treatment is mainly performed. As a result, the latent heat load processing system 201 functions as a system mainly for processing the sensible heat load. Thereby, the sensible heat processing capability as the air conditioning system 101 as a whole can be increased, and the sensible heat treatment in the room can be promoted.

  And the operation | movement at the time of this system starting is cancelled | released after satisfy | filling a predetermined condition, and it transfers to normal dehumidification cooling operation. For example, the timer provided in the latent heat system heat source side control unit 265 cancels the operation at the time of starting the system after a predetermined time (for example, about 30 minutes) has elapsed from the start of the system, or inputs by the remote controllers 111 and 112 The temperature difference between the target indoor air temperature value and the indoor air temperature value sucked into the unit detected by the RA intake temperature / humidity sensors 225 and 235 is a predetermined temperature difference (eg, 3 ° C.). After the following condition is reached, this system startup operation is canceled.

  As described above, in the air conditioning system 101, at the time of system startup, the switching time intervals in the adsorption heat exchangers 222, 223, 232, 233 of the latent heat system use units 202, 203 are set longer than those during normal operation to mainly perform sensible heat treatment. By performing the above, it is possible to quickly reach the indoor air target temperature. Thereby, the latent heat load processing system 201 having the adsorption heat exchangers 222, 223, 232, 233 and mainly processing the indoor latent heat load, and the air heat exchangers 322 and 332 mainly processing the indoor sensible heat load. In the air conditioning system 101 configured with the sensible heat load treatment system 301, the cooling can be performed quickly when the system is activated. Here, the case where the sensible heat load processing system 301 is air-cooled has been described, but this system activation method can be applied even when the air-warming operation is performed. Although the case where the latent heat load processing system 201 is operated in the full ventilation mode has been described here, the system activation method can be applied in other modes such as a circulation mode and an air supply mode.

  In starting the air conditioning system 101 that preferentially processes indoor sensible heat load as described above, for example, the value of the indoor air temperature at the time of starting the system becomes the target temperature value of the indoor air. It may be close. In such a case, since it is not necessary to perform the above-described system activation, the operation at the time of system activation may be omitted and the normal operation may be performed.

  For this reason, in the air conditioning system 101, before starting the operation | movement which processes the indoor sensible heat load as mentioned above preferentially at the time of system starting, it is the target temperature of indoor air, and the temperature of indoor air. It is determined whether the temperature difference is equal to or less than a predetermined temperature difference (for example, the same temperature difference as the condition for canceling the operation at system startup), and the temperature difference between the indoor air target temperature and the indoor air temperature is When the temperature difference is equal to or less than the predetermined temperature difference, it is possible to prevent the operation at the time of starting the system.

Thereby, in the air conditioning system 101, at the time of system start-up, the indoor latent heat load and the sensible heat load are promptly performed in the normal operation without performing the operation of preferentially processing the indoor sensible heat load unnecessarily. Can be migrated.
(3) Features of the Air Conditioning System In the air conditioning system 101 of the present embodiment as well, as with the air conditioning system 101 of the first embodiment, the outdoor air is used as the adsorption heat of the latent heat system utilization units 202 and 203 when the system is activated. By operating in a state where the exchangers 222, 223, 232, and 233 are not passed, cooling and heating can be performed quickly.

  In addition, when the system is started, outdoor air is first adsorbed by the latent heat load processing system 201 in a state where switching of the adsorption operation and the regeneration operation of the adsorption heat exchangers 222, 223, 232, 233 of the latent heat load processing system 201 is stopped. After passing one of the heat exchangers 222 and 232 and the second adsorption heat exchangers 223 and 233, the air is discharged to the outside, and the indoor air is discharged to the first adsorption heat exchangers 222 and 232 and the second adsorption heat exchanger 223. By passing the other of 233 and supplying it indoors, it is possible to perform cooling and heating quickly.

In addition, when the system is started, cooling and heating can be performed quickly by operating the adsorption heat exchangers 222, 223, 232, and 233 with longer switching time intervals between the adsorption operation and the regeneration operation than in the normal operation. .
In addition, the operation at the time of starting the system is canceled after a sufficient time has elapsed from the start of the system to the sensible heat treatment, or the difference between the indoor air target temperature and the indoor air temperature value is predetermined. By releasing after the temperature difference is less than or equal to, it is possible to promptly shift to a normal operation for processing the latent heat load and the sensible heat load.

  In addition, before starting the operation operation at the time of starting the system, whether or not it is necessary is determined based on the temperature of the indoor air. It is possible to quickly shift to a normal operation for processing indoor latent heat load and sensible heat load without performing preferential processing.

  If the present invention is used, a latent heat load processing system that has an adsorption heat exchanger and mainly processes indoor latent heat loads, and a sensible heat load processing system that has an air heat exchanger and mainly processes indoor sensible heat loads, and In the air conditioning system constructed from the above, cooling or heating can be performed quickly when the system is started.

1 is a schematic refrigerant circuit diagram of an air conditioning system according to a first embodiment of the present invention. It is a schematic refrigerant circuit diagram showing the operation at the time of dehumidifying operation in the full ventilation mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram showing the operation at the time of dehumidifying operation in the full ventilation mode when only the latent heat load processing system is operated. It is a control flow figure at the time of operating only a latent heat load processing system. It is the graph which displayed the latent heat processing capability and the sensible heat processing capability in an adsorption heat exchanger on the horizontal axis for the switching time interval of adsorption operation and regeneration operation. It is a schematic refrigerant circuit diagram showing the operation at the time of humidification operation in the full ventilation mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram showing the operation at the time of humidification operation in the full ventilation mode when only the latent heat load processing system is operated. FIG. 5 is a schematic refrigerant circuit diagram showing an operation during a dehumidifying operation in a circulation mode when only the latent heat load processing system is operated. FIG. 5 is a schematic refrigerant circuit diagram showing an operation during a dehumidifying operation in a circulation mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram showing the operation at the time of humidification operation in the circulation mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram showing the operation at the time of humidification operation in the circulation mode when only the latent heat load processing system is operated. FIG. 6 is a schematic refrigerant circuit diagram illustrating an operation during a dehumidifying operation in an air supply mode when only the latent heat load processing system is operated. FIG. 6 is a schematic refrigerant circuit diagram illustrating an operation during a dehumidifying operation in an air supply mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram showing the operation at the time of humidification operation in the air supply mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram showing the operation at the time of humidification operation in the air supply mode when only the latent heat load processing system is operated. FIG. 6 is a schematic refrigerant circuit diagram illustrating an operation during a dehumidifying operation in an exhaust mode when only the latent heat load processing system is operated. FIG. 6 is a schematic refrigerant circuit diagram illustrating an operation during a dehumidifying operation in an exhaust mode when only the latent heat load processing system is operated. FIG. 3 is a schematic refrigerant circuit diagram showing an operation during a humidifying operation in an exhaust mode when only the latent heat load processing system is operated. FIG. 3 is a schematic refrigerant circuit diagram showing an operation during a humidifying operation in an exhaust mode when only the latent heat load processing system is operated. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of the dehumidification air_conditionaing | cooling operation of the whole ventilation mode in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of the dehumidification air_conditionaing | cooling operation of the whole ventilation mode in the air conditioning system of 1st Embodiment. It is a control flow figure at the time of normal operation in the air harmony system of a 1st embodiment. It is a control flow figure at the time of normal operation in the air harmony system of a 1st embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of humidification heating operation of the whole ventilation mode in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of humidification heating operation of the whole ventilation mode in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of simultaneous operation | movement of the dehumidification cooling of all ventilation mode and humidification heating in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of simultaneous operation | movement of the dehumidification cooling of all ventilation mode and humidification heating in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of system starting in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of system starting in the air conditioning system of 1st Embodiment. It is a schematic refrigerant circuit figure of the air conditioning system of 2nd Embodiment concerning this invention. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of the dehumidification air_conditionaing | cooling operation of the whole ventilation mode in the air conditioning system of 2nd Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of the dehumidification air_conditionaing | cooling operation of the whole ventilation mode in the air conditioning system of 2nd Embodiment. It is a control flow figure at the time of normal operation in the air harmony system of a 2nd embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of humidification heating operation of the whole ventilation mode in the air conditioning system of 2nd Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of humidification heating operation of the whole ventilation mode in the air conditioning system of 2nd Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of system starting in the air conditioning system of 2nd Embodiment. It is a schematic refrigerant circuit diagram which shows the operation | movement at the time of system starting in the air conditioning system of 2nd Embodiment.

Explanation of symbols

1, 101 Air conditioning system 10a, 10b, 210a, 210b Latent heat system use side refrigerant circuit (first use side refrigerant circuit)
22, 23, 32, 33, 222, 223, 232, 233 Adsorption heat exchanger 42, 52, 322, 332 Air heat exchanger 10c, 10d, 310a, 310b Sensible heat system utilization side refrigerant circuit (second utilization side refrigerant) circuit)

Claims (6)

An air conditioning system that processes indoor latent heat load and sensible heat load by performing a vapor compression refrigeration cycle operation,
It has an adsorption heat exchanger (22, 23, 32, 33) (222, 223, 232, 233) provided with an adsorbent on its surface, and functions as a refrigerant evaporator to remove moisture in the air. It is possible to dehumidify or humidify the air by alternately switching between an adsorption operation for adsorbing the adsorbent and a regeneration operation for functioning as a refrigerant condenser to desorb moisture in the air from the adsorbent. Possible first usage-side refrigerant circuits (10a, 10b) (210a, 210b);
A second use side refrigerant circuit (10c, 10d) (310a, 310b) having air heat exchangers (42, 52) (322, 332) and capable of exchanging heat between the refrigerant and air; With
It is possible to supply indoors the air that has passed through the adsorption heat exchanger,
It is possible to supply the air that has passed through the air heat exchanger indoors,
When the system is started, the air that has passed through the air heat exchanger is supplied indoors, and outdoor air is prevented from passing through the adsorption heat exchanger.
Air conditioning system (1) (101). An air conditioning system that processes indoor latent heat load and sensible heat load by performing a vapor compression refrigeration cycle operation,
It has a plurality of adsorption heat exchangers (22, 23, 32, 33) (222, 223, 232, 233) provided with an adsorbent on the surface, and functions as a refrigerant evaporator to allow moisture in the air. The air is dehumidified or humidified by alternately switching between an adsorption operation for adsorbing the adsorbent on the adsorbent and a regeneration operation for functioning as a refrigerant condenser to desorb moisture in the air from the adsorbent. A first usage-side refrigerant circuit (10a, 10b) (210a, 210b) capable of
A second use side refrigerant circuit (10c, 10d) (310a, 310b) having air heat exchangers (42, 52) (322, 332) and capable of exchanging heat between the refrigerant and air; With
It is possible to supply indoors the air that has passed through the adsorption heat exchanger,
It is possible to supply the air that has passed through the air heat exchanger indoors,
At the time of system startup, in a state where switching between the adsorption operation and the regeneration operation of the plurality of adsorption heat exchangers is stopped, outdoor air is exhausted outdoors after passing through one of the plurality of adsorption heat exchangers, The indoor air is again supplied indoors after passing through an adsorption heat exchanger different from the adsorption heat exchanger that allows the outdoor air to pass among the plurality of adsorption heat exchangers.
Air conditioning system (1) (101). An air conditioning system that processes indoor latent heat load and sensible heat load by performing a vapor compression refrigeration cycle operation,
It has a plurality of adsorption heat exchangers (22, 23, 32, 33) (222, 223, 232, 233) provided with an adsorbent on the surface, and functions as a refrigerant evaporator to allow moisture in the air. The air is dehumidified or humidified by alternately switching between an adsorption operation for adsorbing the adsorbent on the adsorbent and a regeneration operation for functioning as a refrigerant condenser to desorb moisture in the air from the adsorbent. A first usage-side refrigerant circuit (10a, 10b) (210a, 210b) capable of
A second use side refrigerant circuit (10c, 10d) (310a, 310b) having air heat exchangers (42, 52) (322, 332) and capable of exchanging heat between the refrigerant and air; With
When the system is started, the switching time interval between the adsorption operation and the regeneration operation of the adsorption heat exchanger is made longer than that during normal operation.
Air conditioning system (1) (101).   The air conditioning system (1) (101) according to any one of claims 1 to 3, wherein the operation at the time of system startup is canceled after a predetermined time has elapsed since system startup.   The air according to any one of claims 1 to 3, wherein the operation at the time of starting the system is canceled after a temperature difference between a target temperature of indoor air and a temperature of indoor air becomes equal to or less than a predetermined temperature difference. Harmony system (1) (101). Before starting the operation at the time of starting the system, determine whether the temperature difference between the indoor air target temperature and the indoor air temperature is equal to or less than a predetermined temperature difference,
When the temperature difference between the target temperature of indoor air and the temperature of indoor air is equal to or lower than a predetermined temperature difference, the operation at the time of starting the system is not performed.
The air conditioning system (1) (101) according to any one of claims 1 to 5.

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