JP7328487B2 - air conditioning system - Google Patents

Description

The present invention relates to air conditioning systems.

The device described in Patent Literature 1 includes a plurality of air conditioners. Paragraphs 0055 and 0056 of the document describe that an operation is performed to lower the evaporation temperature of a certain indoor unit among the plurality of indoor units to lower the sensible heat ratio (sensible heat capacity/total capacity).

Japanese Patent Application Laid-Open No. 2010-121798

Patent Literature 1 does not specifically disclose which of the plurality of air conditioners is to be the latent heat treatment machine.

An object of the present disclosure is to propose an air conditioning system that can appropriately select a latent heat processor from a plurality of air conditioners.

A first aspect includes a plurality of air conditioners (10), each of which individually performs a refrigerating cycle and targets the same indoor space (5), and at least one of the plurality of air conditioners (10). becomes a latent heat treatment machine (10-L) and at least one becomes a sensible heat treatment machine (10-S).
The control device (40)
When performing a selection process for selecting the latent heat treatment device (10-L) from among the plurality of air conditioners (10), the index indicating the air volume of indoor air is small among the plurality of air conditioners (10). The air conditioning system is characterized in that the air conditioner (10) is preferentially selected as the latent heat processor (10-L). Here, the "latent heat treatment machine" means an air conditioner that dehumidifies the air by cooling the indoor air to a temperature below the dew point temperature. A “sensible heat processor” means an air conditioner that cools indoor air at a temperature higher than the dew point temperature without dehumidifying the air.

In the selection process, the control device (40) of the first aspect gives priority to the air conditioner (10) having a small air volume index. This is because an air conditioner (10) with a small index indicating air volume has a small SHF (sensible heat ratio) and a high latent heat treatment capacity.

A second aspect is the first aspect,
When the control device (40) performs the selection process, if at least two air conditioners (10) have the same air volume index, the control device (40) determines that the temperature of the intake air in these air conditioners (10) is The air conditioning system is characterized in that an expensive air conditioner (10) is preferentially selected as the latent heat processor (10-L).

In the second aspect, in the selection process, if there are at least two air conditioners (10) having the same air volume index, the air conditioner (10) with the higher intake air temperature is prioritized. If an air conditioner (10) with a low suction temperature is used as a latent heat treatment machine (10-L), the suction temperature will become excessively low and the comfort in the room will be impaired, or the latent heat treatment machine (10-L) will be This is because the thermostat is turned off.

A third aspect is the first or second aspect,
During the operation, the control device (40)
This air conditioning system is characterized by performing the selection process when selecting the latent heat treatment machine (10-L) from at least two sensible heat treatment machines (10-S).

In the third aspect, when the latent heat treatment machine (10-L) is selected from two or more sensible heat treatment machines (10-S), the one with the smaller air volume index is preferentially selected.

A fourth aspect is any one of the first to third aspects,
The control device (40)
In the operation, the air conditioner (10) is configured to be switchable to the blower (10-F),
In the air conditioning system, the selection process is performed when selecting the latent heat processor (10-L) from at least two fans (10-F) during the operation. Here, the "blower" means an air conditioner intended to actively circulate the indoor air in the indoor space (5) by blowing the indoor air without cooling/dehumidifying the indoor air.

In the fourth aspect, when the latent heat processor (10-L) is selected from two or more fans (10-F), the one with the smaller index indicating the air volume is preferentially selected.

A fifth aspect, in any one of the first to fourth,
The air conditioning system, wherein the index indicating the air volume is the horsepower of the air conditioner (10).

In the fifth aspect, the air conditioner (10) with low horsepower is preferentially selected in the process of selecting the latent heat processor (10-L).

FIG. 1 is a schematic configuration diagram of an air conditioning system according to an embodiment. FIG. 2 is a schematic configuration diagram of a refrigerant circuit of an air conditioner. FIG. 3 is a schematic configuration diagram showing the communication relationship of the air conditioning system. FIG. 4 is a psychrometric chart conceptually showing changes in the air state from preliminary operation, determination processing, and latent/visual separation operation. FIG. 5 is a schematic flow chart from preliminary operation to latent-visual separation operation. FIG. 6 is an explanatory diagram conceptually showing how the latent heat load and the sensible heat load are distributed to each air conditioner in preliminary operation. FIG. 7 is a psychrometric diagram for explaining the bypass factor. FIG. 8 is a flow chart showing the process of determining the number of latent heat processors, target evaporating temperature, and air volume in preliminary operation. FIG. 9 is a flow chart showing the process of determining the number of sensible heat processors, the target evaporation temperature, and the air volume in preliminary operation. FIG. 10 is a flow chart showing the air volume control of the latent heat processor in the latent-visual separation operation. FIG. 11 is an explanatory diagram schematically showing changes in the latent heat treatment capability and the sensible heat treatment capability when the air volume is reduced in the air volume control of the latent heat treatment machine. FIG. 12 is an explanatory diagram schematically showing changes in the latent heat treatment capability and the sensible heat treatment capability when the air volume is increased in the air volume control of the latent heat treatment machine. FIG. 13 is a flow chart showing the evaporation temperature control of the latent heat processor in the latent-visual separation operation. FIG. 14 is a flow chart showing air volume control of the sensible heat processor in the latent-visual separation operation. FIG. 15 is a flow chart showing evaporation temperature control of the sensible heat processor in the latent-visual separation operation. FIG. 16 is a flow chart showing the number change control in the latent/visual separation operation. FIG. 17 is an explanatory diagram of the latent heat treatment machine selection process (horsepower priority).

Hereinafter, this embodiment will be described in detail based on the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its applications, or its uses.

<Overall configuration of air conditioning system>
The air conditioning system (1) of this embodiment air-conditions the same indoor space (5). The air conditioning system (1) switches between cooling operation, heating operation, and latent/visual separation operation. An air conditioning system (1) includes a plurality of air conditioners (10). Although FIG. 1 shows four air conditioners (10) in the air conditioning system (1), the number may be two or more. These air conditioners (10) have the same basic configuration.

The air conditioning system (1) of this example is configured by adding additional units to existing equipment (existing units). Each air conditioner (10) of the existing unit is configured to be able to perform cooling operation, heating operation, and air blowing operation. By adding an additional unit to the existing unit, the latent/visual separation operation can be further executed. The existing unit includes a plurality of air conditioners (10) and a local controller (41) corresponding to each air conditioner (10).

<Basic configuration of air conditioner>
Each air conditioner (10) in the example of FIG. 1 is a so-called paired air conditioner. That is, the air conditioner (10) of this example includes one outdoor unit (11), one indoor unit (12), and two wires connecting the outdoor unit (11) and the indoor unit (12). connecting pipes (13, 14); The outdoor unit (11) is installed outdoors. The indoor unit (12) of this example is installed so as to face the indoor space (5). The indoor unit (12) is configured as a ceiling-mounted type (strictly, a ceiling-suspended type or a ceiling-embedded type). Each air conditioner (10) is provided with a remote controller (15). By operating the remote controller (15), the user can switch the indoor set temperature and the operation mode.

<Configuration of refrigerant circuit and each device>
As shown in FIG. 2, each air conditioner (10) has a refrigerant circuit (20). In the refrigerant circuit (20), a vapor compression refrigeration cycle is performed by circulating the filled refrigerant. A compressor (21), an outdoor heat exchanger (22), an expansion valve (23), a four-way switching valve (24), and an indoor heat exchanger (25) are connected to the refrigerant circuit (20). A compressor (21), an outdoor heat exchanger (22), an expansion valve (23), and a four-way switching valve (24) are provided in the outdoor unit (11). The indoor heat exchanger (25) is provided in the indoor unit (12).

The compressor (21) is a variable capacity inverter type compressor. That is, the compressor (21) is configured such that the number of rotations (operating frequency) of the electric motor is adjustable by controlling the output of the inverter device. The outdoor heat exchanger (22) is, for example, a fin-and-tube heat exchanger. An outdoor fan (26) is installed near the outdoor heat exchanger (22). In the outdoor heat exchanger (22), heat is exchanged between the outdoor air blown by the outdoor fan (26) and the refrigerant. The expansion valve (23) is an electronic expansion valve with a variable opening. An expansion valve (23) may be provided in the indoor unit (12).

The four-way switching valve (24) has first to fourth ports (P1, P2, P3, P4). The first port (P1) communicates with the discharge side of the compressor (21), the second port (P2) communicates with the suction side of the compressor (21), and the third port (P3) communicates with the outdoor heat exchanger ( 22), and the fourth port (P4) communicates with the gas side end of the indoor heat exchanger (25). The four-way switching valve (24) is in a first state (see FIG. 2) in which the first port (P1) communicates with the third port (P3) and the second port (P2) communicates with the fourth port (P4). a state indicated by solid lines), and a second state (dashed lines in FIG. 2) in which the first port (P1) communicates with the fourth port (P4) and the second port (P2) communicates with the third port (P3). state shown by ).

The indoor heat exchanger (25) is arranged in the internal passage of the indoor unit (12). An indoor fan (27) is provided near the indoor heat exchanger (25). When the indoor fan (27) is operated, the indoor air in the indoor space (5) flows into the internal passage of the indoor unit (12) as intake air. In the indoor heat exchanger (25), heat is exchanged between the air flowing through the internal passage and the refrigerant. The air that has passed through the indoor heat exchanger (25) is supplied to the indoor space (5) as blown air.

The indoor fan (27) is configured such that the air volume (rotational speed of the motor) is variable. The air volume of the indoor fan (27) of the present embodiment is configured to be switchable in three stages. Specifically, the so-called fan taps of the indoor fan (27) are switched among LL tap (light air volume), L tap (small air volume), M tap (medium air volume), and H tap (large air volume).

A suction temperature sensor (28) is provided near the indoor unit (12). The intake temperature sensor (28) detects the temperature of the intake air of the corresponding indoor unit (12) as the intake temperature (Th1). The suction temperature sensor (28) may be provided, for example, at the suction port of the indoor unit (12), or may be provided in the indoor space (5).

A suction humidity sensor (29) is provided near the indoor unit (12). The suction humidity sensor (29) detects the humidity (strictly speaking, the relative humidity) of the suction air of the corresponding indoor unit (12) as the suction humidity (Rh1). The suction humidity sensor (29) may be provided, for example, at the suction port of the indoor unit (12), or may be provided in the indoor space (5).

The indoor heat exchanger (25) described above is provided with a refrigerant temperature sensor (30). The refrigerant temperature sensor (30) detects the evaporation temperature (Te) of refrigerant flowing through the indoor heat exchanger (25) in the cooling cycle. The refrigerant temperature sensor (30) detects the condensation temperature (Tc) of refrigerant flowing through the indoor heat exchanger (25) in the heating cycle.

<Control device>
As shown in FIG. 3, the air conditioning system (1) includes a control device (40) for controlling each air conditioner (10). The control device (40) includes a plurality of local controllers (41), a plurality of wireless LAN adapters (42), a router (43), a communication terminal (44), and a main controller (45). A local controller (41) is included in the existing unit. A wireless LAN adapter (42), a router (43), and a main controller (45) are included in the additional unit.

A plurality of local controllers (41) are provided so as to correspond to each air conditioner (10). The local controller (41) has a processor (eg, microcontroller) and a memory device (eg, semiconductor memory) that stores software for operating the processor. The local controller (41) of this example is provided in the corresponding indoor unit (12). The local controller (41) is configured to be communicable with the outdoor unit (11) wirelessly or by wire. A local controller (41) controls components such as a compressor (21), a four-way switching valve (24), an expansion valve (23), an outdoor fan (26) and an indoor fan (27).

A plurality of wireless LAN adapters (42) are provided so as to correspond to each local controller (41) one by one. Each wireless LAN adapter (42) is connected to the Internet (I) via a router (43).

A communication terminal (44) is a communication device for a user or the like to send a command regarding the latent/visual separation operation. The communication terminal (44) is composed of, for example, a smart phone or a tablet PC. The communication terminal (44) has, for example, a touch panel that serves both as a display section and an operation section, and a communication interface for communicating with the main control section via the Internet (I).

The communication terminal (44) has a processor (eg, microcontroller) and a memory device (eg, semiconductor memory) that stores software for operating the processor. The communication terminal (44) stores an application for executing the latent/visual separation operation. By operating the communication terminal (44), the user can switch ON/OFF of the latent-visual separation operation and set the set temperature (RTh) and set humidity (Rh) during the latent-visual separation operation.

The main control unit (45) is provided, for example, in a cloud server (C) on the Internet (I). The main control section (45) is connected to the communication terminal (44) via the Internet (I). Command values (target temperature (RTh), target humidity (Rh), etc.) output from the communication terminal (44) are appropriately input to the main control section (45). The main controller (45) is connected to each local controller (41) via the Internet (I). The main control unit (45) stores the operating information of each air conditioner (10) (suction temperature (Th1), suction humidity (Rh1), evaporation temperature (Te), condensation temperature (Tc), indoor fan (27) The air volume (Q) (fan tap) is appropriately input, etc. Based on these signals, the main control section (45) calculates parameters for controlling each air conditioner (10).Main control section (45) (45) transmits the parameters (update parameters) thus obtained to each local controller (41) at predetermined update intervals (communication intervals) Δt (for example, several tens of seconds). ) is rewritten to update parameters at each update interval ΔT.

-Basic driving behavior-
The basic operation of the air conditioning system (1) will be explained. Each air conditioner (10) is configured to be capable of performing a cooling operation, a heating operation, and a blowing operation. These operations can be performed only by existing units.

<Cooling operation>
In the cooling operation, the indoor air in the indoor space (5) is cooled. In cooling operation, the four-way switching valve (24) of the air conditioner (10) is in the first state, and the compressor (21), indoor fan (27), and outdoor fan (26) are operated. In cooling operation, a first refrigerating cycle (cooling cycle) is performed in which the outdoor heat exchanger (22) functions as a condenser or radiator, and the indoor heat exchanger (25) functions as an evaporator. That is, the refrigerant compressed by the compressor (21) releases heat and condenses in the outdoor heat exchanger (22), and is decompressed by the expansion valve (23). The depressurized refrigerant evaporates in the indoor heat exchanger (25) to cool the indoor air. The evaporated refrigerant is sucked into the compressor (21) and compressed again. In cooling operation, the evaporation temperature (Te) of the indoor heat exchanger (25) is controlled so that the suction temperature (Th1) approaches the target temperature (RTh). Specifically, the control target value (target evaporation temperature (TeS)) of the evaporation temperature (Te) is adjusted based on the suction temperature (Th1) and the target temperature (RTh).

<Thermo-off control/thermo-on control during cooling operation>
During the cooling operation, the air conditioner (10) is appropriately controlled to turn off the thermostat and to turn on the thermostat. These controls are performed based on the suction temperature (Th1) and the target temperature (RTh).

Specifically, when the intake temperature (Th1) of the air conditioner (10) during cooling operation becomes equal to or lower than a predetermined thermo-off temperature (Thoff), the air conditioner (10) enters a resting state (thermo-off control). Here, the thermo-off temperature (Thoff) is set to a value lower than the target temperature (RTh) by a predetermined temperature (for example, 1° C.). When the air conditioner (10) is in a rest state (thermo-off state), refrigerant does not flow through the indoor heat exchanger (25), and air is not cooled. Specifically, in the air conditioner (10) in the thermo-off state, the compressor (21) is stopped and the refrigeration cycle is not performed. In the air conditioner (10) in the thermo-off state, the air volume of the indoor fan (27) is smaller than the air volume of the indoor fan (27) in cooling operation (thermo-on state). Specifically, the air volume of the indoor fan (27) is, for example, LL tap (small air volume) or L tap (small air volume). The indoor fan (27) may be stopped in the air conditioner (10) in the thermo-off state.

When the air conditioner (10) is in the thermo-off state and the suction temperature (Th1) reaches or exceeds a predetermined thermo-on temperature (Thon), the air conditioner (10) is put into operation again (thermo-on control). Here, the thermo-on temperature (Thon) is set to a value higher than the target temperature (RTh) by a predetermined temperature (for example, 1° C.). When the air conditioner (10) enters an operating state (thermo-on state), the cooling operation described above is resumed.

<Heating operation>
In the heating operation, the indoor air in the indoor space (5) is heated. In heating operation, the four-way switching valve (24) of the air conditioner (10) is in the second state, and the compressor (21), indoor fan (27), and outdoor fan (26) are operated. In the heating operation, the indoor heat exchanger (25) functions as a condenser or radiator, and the outdoor heat exchanger (22) functions as an evaporator in a second freezing cycle (heating cycle). That is, the refrigerant compressed by the compressor (21) releases heat and condenses in the indoor heat exchanger (25) to heat the indoor air. The refrigerant that has released heat is decompressed by the expansion valve (23). The decompressed refrigerant evaporates in the outdoor heat exchanger (22), then is sucked into the compressor (21) and compressed again. In heating operation, the condensation temperature (Tc) of the indoor heat exchanger (25) is controlled so that the intake temperature (Th1) approaches the target temperature (RTh). Specifically, the control target value (target condensation temperature (TcS)) of the condensation temperature (Tc) is adjusted based on the intake temperature (Th1) and the target temperature (RTh).

<Thermo-off control/thermo-on control during heating operation>
During the heating operation, the air conditioner (10) is appropriately controlled to turn off the thermostat and to turn on the thermostat. These controls are performed based on the suction temperature (Th1) and the target temperature (RTh). When the intake temperature (Th1) of the air conditioner (10) during heating operation reaches or exceeds a predetermined thermo-off temperature (Thoff), the air conditioner (10) enters a resting state (thermo-off state) as in the cooling operation described above. Become. Further, when the air conditioner (10) is in the thermo-off state and the suction temperature (Th1) becomes equal to or lower than a predetermined thermo-off temperature (Thoff), the heating operation of the air conditioner (10) is resumed.

<Blower operation>
In the fan operation, the indoor air in the indoor space (5) is not cooled or heated, but is circulated. In the air-blowing operation, the compressor (21) is stopped and the refrigerant circuit (20) does not operate in the refrigeration cycle. Meanwhile, the indoor fan (27) is operated. Indoor air flows through the internal passage of the indoor unit (12) and is supplied to the indoor space (5) again. That is, air that is neither cooled nor heated is blown from the indoor unit (12). The fan tap of the indoor fan (27) is set, for example, to H tap (large air volume) or M tap (medium air volume). The air volume of the indoor fan (27) of the air conditioner (10) in air blowing operation is greater than the air volume of the indoor fan (27) of the air conditioner (10) in the thermo-off state.

<Overview of latent/microscopic separation operation>
The air conditioning system (1) is configured to be capable of executing a latent/visual separation operation for simultaneously processing the latent heat load and the sensible heat load of the indoor space (5). The latent/visual separation operation includes a state in which at least one of the plurality of air conditioners (10) becomes a latent heat treatment machine (10-L) and at least one becomes a sensible heat treatment machine (10-S). is driving. Further, in the latent-visual separation operation of the present embodiment, the air conditioner (10) may also serve as the blower (10-F) (the air conditioner that performs the blowing operation described above).

In the latent heat processor (10-L), the evaporation temperature (Te) of the indoor heat exchanger (25) is controlled so as to cool the air below the dew point temperature. Therefore, the latent heat processor (10-L) dehumidifies the indoor air and treats the latent heat load of the indoor space (5). In principle, the sensible heat processor (10-S) controls the evaporation temperature (Te) so as to cool the air to a temperature higher than the dew point temperature. Therefore, the sensible heat processor (10-S) cools the indoor air without dehumidifying it, and processes the sensible heat load of the indoor space (5). The blower (10-F) performs the blowing operation described above. That is, the fan (10-F) blows/circulates the room air without handling the latent or sensible heat load of the room air. The air volume of the indoor fan (27) of the blower (10-F) is greater than the air volume of the indoor fan (27) of the above-described air conditioner (10) in the thermo-off state.

<Preliminary operation>
As shown in FIGS. 4 and 5, a preliminary operation is performed before the latent/visual separation operation is performed. In the preliminary operation, the latent heat processor (10-L), the sensible heat processor (10-S), and the fan (10-F) are used at the start of the subsequent latent-visual separation operation (first operation). A determination process for determining the air conditioner (10) is performed.

When the user operates the communication terminal (44) to turn on the latent/visual separation operation, an operation command for executing the latent/visual separation operation is input to the local controller (41). Then, the preliminary operation is started (step ST1). In preliminary operation, all the air conditioners (10) become coolers (air conditioners that perform the above-described cooling operation). That is, in each air conditioner (10), the cooling cycle is performed, and the indoor fan (27) operates with M tap or H tap. Therefore, the indoor air in the indoor space (5) is rapidly cooled.

In step ST2, a predetermined time A has passed since the operation command was input, and the difference (Th1-RTh) between the intake temperature (Th1) and the target temperature (RTh) of at least one air conditioner (10) is When the temperature drops below a predetermined value (for example, 2° C.), the process proceeds to step ST4. Further, in step ST3, when a predetermined time B (B>A) elapses after the operation command is input, the process proceeds to step ST4. In other words, when the condition that the indoor air in the indoor space (5) approaches the target temperature (RTh) is established by performing the preliminary operation, the process proceeds to the determination processing of steps ST4 and ST5.

In step ST4, a process of calculating the latent heat load (HL-L) and sensible heat load (HL-S) of the indoor space (5) is performed. In step ST5, the number of latent heat processors (10-L) and sensible heat processors (10-S) for processing the calculated latent heat load (HL-L) and sensible heat load (HL-S) is determined. . At this time, the air volume (Q) of the indoor fan (27) of the latent heat processor (10-L), the target evaporation temperature (TeS), and the air volume (Q ), and the target evaporation temperature (TeS) and the number of fans (10-F) are also determined.

An outline of step ST5 will be described with reference to FIG. In step ST5, first, the number of latent heat processors (10-L) capable of processing the calculated latent heat load (HL-L), air volume, and target evaporation temperature (TeS) are determined. Then, from the calculated sensible heat load (HL-S), subtract the determined total sensible heat processing capacity of the latent heat processor (10-L) to calculate the remaining sensible heat load (HL-S). Next, the number of sensible heat processors (10-S), air volume (Q), and target evaporation temperature (TeS) required to process the remaining sensible heat load are determined. In step ST5, among the plurality of air conditioners (10), the air conditioner (10) that was not selected as either the latent heat treatment machine (10-L) or the sensible heat treatment machine (10-S) is the blower (10). -F).

<How to calculate the latent heat load>
A method of calculating the latent heat load (HL-L) in step ST4 will be described in detail.

The latent heat load (HL-L) is currently insufficient for the latent heat treatment capacity (CL) output by the air conditioner (10), which is a cooler in standby operation, and the target temperature (RTh) and target humidity (Rh). It is obtained by the sum of the latent heat treatment capacity (deficit latent heat treatment capacity (ΔCL)). In the preliminary operation of this example, all the air conditioners (10) are in operation. Therefore, the latent heat treatment capacity (CL) is the sum of the latent heat treatment capacities of all the air conditioners (10).

The latent heat treatment capacity (CL) of each air conditioner (10) can be obtained by the following formula (1).

Latent heat treatment capacity (CL) = air volume of air conditioner [m3/min] x (1/60) x air density [kg/m3] x latent heat of vaporization [kJ/kg] x (absolute humidity of indoor air Rz1 [kg/ kg] - absolute humidity of blown air Rz2 [kg/kg]) (1) formula

Here, the air volume is the air volume (Q) of the indoor fan (27) of the air conditioner (10) in preliminary operation. The absolute humidity Rz1 of indoor air is obtained from the intake temperature (Th1) and the intake humidity (Rh1) of the air conditioner (10). The absolute humidity Rz2 of the blown air can be obtained by the following formula (2).

Absolute humidity of blown air Rz2 = Rze [kg/kg] + bypass factor BF x (Rz1 [kg/kg] - Rze [kg/kg]) (2) formula

Here, Rze is the absolute humidity of the blowing air, assuming that the air is cooled to the same temperature as the evaporation temperature (Te) of the indoor heat exchanger (25) and the relative humidity is 100%. The bypass factor BF is the ratio (=a/b) of the length of line segment a to the length of line segment b in the psychrometric diagram shown in FIG. That is, when the air is cooled at the evaporation temperature (Te) in the indoor heat exchanger (25), the air in the state of point P1 (state of suction temperature Th1 and suction humidity Rh1) should ideally be in the state of point P3. It will be cooled to (air temperature same as evaporation temperature (Te), relative humidity = 100%). On the other hand, in reality, the air at the point P1 is only cooled down to the state of the point P2 (blowing temperature Th2, blowing humidity Rh2) due to the performance of the indoor heat exchanger (25). The performance of such an indoor heat exchanger (25) can be obtained in advance as a bypass factor BF. Conversely, by using this bypass factor BF, the blowing air Absolute humidity Rz1 can be obtained. A bypass factor BF corresponding to the air volume of the indoor fan (27) is preliminarily stored in a memory or the like of the controller (40).

The insufficient latent heat treatment capacity (ΔCL) can be obtained by the following formula (3).

Insufficient latent heat treatment capacity (ΔCL) = Indoor space volume V [m3] x Air density [kg/m3] x Evaporation latent heat [kJ/kg] x (Target absolute humidity Rzt [kg/kg] - Suction absolute humidity Rz1 [kg /kg]) × [1/sec] (3) formula

Here, the volume V [m3] may be set in advance according to the indoor space (5) targeted by the air conditioning system (1). Further, the volume V may be simply obtained from, for example, the rated capacity (horsepower) of the air conditioner (10) of the air conditioning system (1), the rated air volume of the indoor fan (27), and the like. In addition, in the example of formula (3), [1/sec] is multiplied assuming that the latent heat load of the remaining indoor space (5) is processed in one second.

At step ST4 in FIG. 5, the latent heat load (HL-L) of the indoor space (5) is calculated as described above. Note that this method of calculating the latent heat load (HL-L) does not take into consideration changes in the temperature and humidity of the indoor space (5). This is because, at the start of the determination process, the temperature and humidity of the indoor air are close to the target values due to the preliminary operation described above, so that the change in the temperature and humidity of the indoor space (5) slows down.

<Calculation method of sensible heat load in preliminary operation determination processing>
A method of calculating the sensible heat load (HL-S) of the indoor space (5) in the preliminary operation determination process will be described in detail.

The sensible heat load (HL-S) is the sensible heat treatment capacity (CS) output by the air conditioner (10), which is a cooler in preliminary operation, and the target temperature (RTh) and target humidity (Rh). It is obtained by the sum of the insufficient sensible heat treatment capacity (shortage sensible heat treatment capacity (ΔCS)). In the preliminary operation of this example, all the air conditioners (10) are in operation. Therefore, the sensible heat processing capacity (CS) is the sum of the sensible heat processing capacities of all the air conditioners (10).

The sensible heat treatment capacity (CS) of each air conditioner (10) can be obtained by the following formula (4).

Sensible heat treatment capacity (CS) = air volume of air conditioner [m3/min] x (1/60) x air density [kg/m3] x specific heat at constant pressure [kJ/kg K] x (intake air temperature Th1 [°C ] - Blowing air temperature Th2 [°C]) (4) Equation

Here, the air volume is the air volume (Q) of the indoor fan (27) of the air conditioner (10) in preliminary operation. The temperature Th2 of the blown air can be obtained from the following equation (5) using the bypass factor BF described above. Here, the bypass factor BF corresponds to a/b in FIG.

Blowing temperature Th2 = Evaporation temperature (Te) + Bypass factor BF x (Th1 - Te) (5)

The insufficient sensible heat treatment capability (ΔCS) can be obtained by the following equation (6).

Insufficient sensible heat treatment capacity (ΔCS) = Volume of indoor space V [m3] x Air density [kg/m3] x Specific heat at constant pressure [kJ/kg K] x (Target temperature (RTh) - Suction temperature (Th1)) x [ 1/sec] (6) formula

Here, the volume V [m3] of the indoor space (5) may be set in advance according to the target space of the air conditioning system (1). Further, the volume V may be simply obtained from, for example, the rated capacity (horsepower) of the air conditioning system (1), the rated air volume of the indoor fan (27), and the like. In addition, in the example of formula (6), [1/sec] is multiplied assuming that the sensible heat load of the remaining indoor space (5) is processed in one second.

At step ST4 in FIG. 5, the sensible heat load (HL-S) of the indoor space (5) is calculated as described above. In calculating the sensible heat load (HL-S) below, changes in indoor air temperature are not considered. This is because, at the start of the determination process, the temperature of the room air approaches the target value due to the above-described preliminary operation, so the change in the temperature of the room air becomes moderate.

<Determination flow of the latent heat treatment machine in the preliminary operation determination process>
In step ST4, when the latent heat load (HL-L) and sensible heat load (HL-S) of the indoor space (5) are calculated, as shown in FIG. A process of determining the target evaporation temperature and air volume is performed. This processing is performed immediately before the actual latent/visual separation operation is started.

In step ST11, a process of determining the order of priority of which air conditioner (10) among the plurality of air conditioners (10) is preferentially used as the latent heat processor (10-L) is performed. In the present embodiment, among the plurality of air conditioners (10), the one with the smaller horsepower (rated capacity) is preferentially selected as the latent heat treatment machine (10-L). The details of this priority determination will be described later.

Next, in step ST12, it is tentatively decided which air conditioners (10), how many of them, the latent heat processors (10-L) and the sensible heat processors (10-S). First, when the total number N of the air conditioners (10) is an even number, the number of the latent heat processors (10-L) and the sensible heat processors (10-S) is the same (N/2 units). When the total number N of air conditioners (10) is an odd number, the number of latent heat treatment machines (10-L) is increased by one. In other words, the number of latent heat treatment machines (10-L) is (N-1)/2+1, and the number of sensible heat treatment machines (10-S) is (N-1)/2.

When determining the latent heat processor (10-L) from among the plurality of air conditioners (10), the order of priority determined in step ST11 is followed. Therefore, for example, when provisionally determining two latent heat processors (10-L) out of four air conditioners (10), two of these air conditioners (10) with lower horsepower are selected.

Next, in step ST13, the calculated latent heat load (HL-L) is distributed to the determined latent heat processors (10-L). At this time, the calculated latent heat load (HL-L) is proportionally distributed according to the horsepower (rated stress) of the air conditioner (10), which is the latent heat treatment machine. For example, as shown in FIG. 6, when the latent heat load is equivalent to 6 kW, the first latent heat treatment machine (10-L) is 2 horsepower, and the second latent heat treatment machine (10-L) is 1 horsepower. , 4 kW of the 6 kW latent heat load is processed by the first latent heat processor (10-L), and the remaining 2 kW is processed by the second latent heat processor (10-L).

Next, in step ST14, the target evaporation temperature (TeS) and air volume (Q) are provisionally determined for the provisionally determined latent heat treatment machine (10-L). Here, the capacity for processing the distributed latent heat load (latent heat processing capacity (CL)) is the air volume (Q ), bypass factor BF, intake air absolute humidity (Rz1), and evaporation temperature (Te). Therefore, by setting the air volume (Q) of the indoor fan (27) to, for example, M tap or H tap, and using the current absolute humidity (Rz1) of the intake air, the evaporation temperature (Te ) can be obtained. At this time, if the calculated evaporation temperature (Te) is above the upper limit or below the lower limit of the control range, adjust the air volume (Q) (fan tap) so that the evaporation temperature (Te) falls within the control range. and recalculate accordingly.

Next, in step ST15, the tentatively determined sensible heat processing capability of the latent heat processor (10-L) is calculated. If there are two or more tentatively determined latent heat treatment machines (10-L), this sensible heat treatment capacity will be the sum of these sensible heat treatment capacities (CS).

In step ST16, the sensible heat capacity calculated in step ST15 is compared with the sensible heat load (HL-S) of the indoor space (5) calculated in step ST4. If the sensible heat treatment capacity of the latent heat processor (10-L) is smaller than the sensible heat load (HL-S), move to step ST19 and proceed to the determination flow of the sensible heat processor (10-S) (details will be described later) do).

On the other hand, when the sensible heat processing capacity of the latent heat processor (10-L) is greater than the sensible heat load (HL-S), the process proceeds to step ST17. In step ST17, when the number of latent heat treatment machines (10-L) is one, the process proceeds to step ST19. That is, in the determination flow of the latent heat treatment machine (10-L), at least one machine is always determined as the latent heat treatment machine (10-L).

In step ST17, if there are two or more latent heat processors (10-L), the process proceeds to step ST18. In this case, one of the tentatively determined latent heat processors (10-L) will be replaced with a fan (10-F). In step ST18, the air conditioner (10) having the lowest priority (having the highest horsepower) among the plurality of air conditioners (10) determined in step ST11 becomes the fan (10-F). In step ST18, when the tentatively determined latent heat processor (10-L) is reduced by one, the processing of steps ST13 to ST16 is performed again in this state. In other words, with one latent heat treatment machine (10-L) reduced, the total of the target evaporation temperature (TeS), air volume (Q), and sensible heat treatment capacity (CS) of the remaining latent heat treatment machine (10-L) is asked again.

As described above, when finally moving to step ST19, at the start of the latent-visual separation operation, the number/type of the air conditioners (10) to be the latent heat treatment machines (10-L), the latent heat treatment machine (10 -L) target evaporation temperature (TeS) and latent heat treatment machine (10-L) air volume (Q) are determined (confirmed).

<Determination flow of sensible heat treatment machine in preliminary operation determination process>
After the number of latent heat processors (10-L), the target evaporation temperature, and the air volume are determined, the process proceeds to the flow for determining the sensible heat processors (10-S) shown in FIG. In this flow, processing for determining the number of sensible heat processors (10-S), target evaporation temperature, and air volume is performed. This processing is performed immediately before the actual latent/visual separation operation is started.

In step ST21, the sensible heat load (HL-S) of the indoor space (5) calculated in step ST4 minus the sensible heat capacity of the latent heat processor (10-L) obtained in step ST15 is subtracted. A heat load (HL-S') is obtained. As illustrated in FIG. 6, the sensible heat load (HL-S) is equivalent to 8 kW, and the sensible heat treatment capacity of the first latent heat treatment machine (10-L) and the second latent heat treatment machine (10-L) is Assume that the total is 5 kW. In this case, the remaining sensible heat load (HL-S') that cannot be processed by these latent heat processors (10-L) is 3 kW (=8 kW - 5 kW).

Next, in step ST22, the remaining sensible heat load (HL-S) is applied to the remaining air conditioners (10) other than the latent heat treatment machine (10-L) and the fan (10-F) (i.e., the sensible heat treatment machine ( 10-S)) to distribute. At this time, the remaining sensible heat load (HL-S') is proportionally distributed according to the horsepower (rated capacity) of the air conditioner (10), which is the sensible heat treatment machine.

Next, in step ST23, the target evaporation temperature (TeS) and air volume (Q) are provisionally determined for the provisionally determined sensible heat processor (10-S). Here, the ability to process the distributed sensible heat load (sensible heat treatment ability) is expressed by the above-described equations (4) and (5), the air volume (Q) of the indoor fan (27), It is a function of bypass factor BF, suction temperature (Th1) and evaporation temperature (Te). Therefore, by setting the air volume (Q) of the indoor fan (27) to, for example, M tap or H tap, and using the current suction temperature (Th1), the evaporation temperature (Te) for processing the distributed sensible heat load can be calculated as can ask. At this time, if the evaporating temperature (Te) falls above the upper limit value or below the lower limit value of the control range, change the air flow (Q) appropriately so that the evaporating temperature (Te) falls within the control range. to recalculate.

Next, in step ST24, if the target evaporation temperature (TeS) of all the sensible heat processors (10-S) does not fall below the upper limit of the evaporation temperature control range, the process proceeds to step ST25, and one sensible heat processor (10-S) to blower (10-F). Next, in step ST26, if the number of sensible heat treatment machines (10-S) is 0, the process proceeds to step ST27; otherwise, the process proceeds to step ST22. In step ST26, when the provisionally determined number of sensible heat processors (10-S) is reduced by one, the processing of steps ST22 to ST24 is performed again in this state. That is, with the number of sensible heat processors (10-S) reduced by one, the target evaporation temperatures (TeS) and air volumes (Q) of the remaining sensible heat processors (10-S) are obtained again.

As described above, when the process is finally shifted to step ST27, at the start of the latent-visual separation operation, the number/type of the air conditioners (10) to be the sensible heat treatment machines (10-S), -S) target evaporation temperature (TeS) and the air volume (Q) of the sensible heat processor (10-S) are determined (confirmed).

<Control at the start of the latent/visual separation operation>
When the latent-visual separation operation is started, the plurality of air conditioners (10) are controlled to reflect the details determined in the preliminary operation. In other words, each air conditioner (10) operates with the type determined in preliminary operation (one of the latent heat processor (10-L), sensible heat processor (10-S), and fan (10-F)). be done. The latent heat treatment machine (10-L) is controlled with the air volume (Q) and target evaporation temperature (TeS) determined in preliminary operation as target values. The sensible heat processor (10-S) is controlled using the air volume (Q) and target evaporation temperature (TeS) determined in the preliminary operation as target values. That is, at the start of the latent-visual separation operation, each air conditioner (10) is operated at a capacity corresponding to the current latent heat load and sensible heat load, so that the latent heat load and sensible heat load can be processed just enough.

<Updating operating parameters during latent/visual separation operation>
Strictly speaking, the latent heat processor (10-L) and sensible heat processor (10-S) during the latent/visual separation operation are controlled by the local controller (41) of the existing unit. )). That is, the latent heat processor (10-L) and the sensible heat processor (10-S) basically try to perform the same cooling cycle as the cooling operation. On the other hand, as described above, the main control section (45) replaces the control parameters of the local controller (41) every update time ΔT. Specifically, the target evaporation temperature (TeS) corresponding to the latent heat processor (10-L) is updated within a predetermined control range so that the latent heat processor (10-L) can cool the air below the dew point temperature. be. The target evaporation temperature (TeS) corresponding to the sensible heat processor (10-S) is updated within a predetermined control range so that the sensible heat processor (10-S) can cool the air above the dew point temperature. The target evaporation temperature (TeS) control range of the latent heat processor (10-L) is smaller than the target evaporation temperature (TeS) control range of the sensible heat processor (10-S).

In this way, for the latent heat processor (10-L) and the sensible heat processor (10-S), which are coolers, their target evaporation temperatures (TeS) are forcibly rewritten by signals from the main controller (45). This makes it possible to provide the air conditioning system (1) with the function of latent/visual separation operation. The main control section (45) of the additional unit also updates the air volume (Q) of the latent heat processor (10-L) and the sensible heat processor (10-S) in the arithmetic processing of the local controller (41).

The latent heat processor (10-L) and sensible heat processor (10-S) are basically controlled in the same way as the air conditioner. In -S), thermo-off/thermo-on control is performed in the same manner as the cooling operation described above.

<Overview of control during latent/microscopic separation operation>
After the latent-visual separation operation is started, control is performed to change the air volume (Q), the target evaporation temperature (TeS), and the number of each air conditioner (10) at predetermined update intervals ΔT (for example, 20 seconds). conduct. Such control includes air volume control of the latent heat treatment machine (10-L), evaporation temperature control of the latent heat treatment machine (10-L), air volume control of the sensible heat treatment machine (10-S), and sensible heat treatment machine (10-S ) can be broadly classified into evaporation temperature control and number change control.

<Air volume control of latent heat treatment machine>
In the latent heat treatment machine (10-L) during the latent/visual separation operation, the air volume control shown in FIG. 10 is first prioritized. In the air volume control, control is performed to change the indoor air volume (Q) and the target evaporation temperature (TeS) of the air conditioner (10) while maintaining the latent heat treatment capacity of the latent heat processor (10-L).

Specifically, in step ST31, the suction temperature (Th1) of the latent heat processor (10-L) is lower than a predetermined value (for example, the target temperature (RTh)) and the indoor temperature of the latent heat processor (10-L) When the fan tap of the fan (27) is M or H tap, the process proceeds to steps ST32 to ST35. In other words, when the condition of step ST31 is satisfied, there is a possibility that the suction temperature (Th1) reaches the thermo-off temperature (Thoff) or lower and the latent heat processor (10-L) is thermo-off. Therefore, when the condition of step ST31 is established, the process proceeds to steps ST32 to ST35, and control is performed to decrease the air volume of the latent heat treatment machine (10-L).

In step ST32, the latent heat processing capacity (CL) of the target latent heat processing machine (10-L) is calculated. This latent heat treatment capability (CL) is determined by the above equations (1) and (2). Next, in step ST33, the evaporation temperature (target evaporation temperature (TeS)) is calculated. Specifically, the target evaporating temperature (TeS) is determined by the latent heat treatment capacity (CL) of the latent heat treatment machine (10-L), the suction temperature (Th1), the suction humidity (Rh1 ), the changed air volume (Q′), and the bypass factor BF corresponding to the changed air volume (Q′). The target evaporation temperature (TeS) calculated here is lower than the current target evaporation temperature (TeS).

Next, in step ST34, the air volume of the latent heat processor (10-L) is reduced to the air volume (Q'). Specifically, the fan tap of the indoor fan (27) is decreased by one tap. Next, in step ST35, the target evaporation temperature (TeS) of the latent heat processor (10-L) is changed to the value calculated in step ST33. That is, in step ST35, the target evaporation temperature (TeS) of the latent heat processor (10-L) is lowered.

As described above, when the air volume of the latent heat processor (10-L) is decreased and the target evaporation temperature (TeS) is lowered, the latent heat treatment capacity ( The sensible heat treatment capacity (CS) of this latent heat processor (10-L) can be suppressed while maintaining CL). When the air volume of the latent heat processor (10-L) is reduced, the proportion of air bypassing the indoor heat exchanger (25) is reduced and the contact time between the air and the indoor heat exchanger (25) is lengthened. As a result, the amount of water condensed on the surface of the indoor heat exchanger (25) increases, and the SHF (sensible heat ratio) of the latent heat processor (10-L) decreases. Therefore, the latent heat load can be reliably processed while avoiding the latent heat processor (10-L) from reaching the thermo-off state.

If the condition of step ST31 is not satisfied, the process proceeds to step ST36. In step ST36, the suction temperature (Th1) of the latent heat treatment machine (10-L) is higher than a predetermined value (value obtained by adding Δt1 (for example, 1°C) to the target temperature (RTh)), and the latent heat treatment machine (10 -L) is equal to or less than the L tap and the target evaporation temperature (TeS) is equal to or less than the lower limit of the control range, the process proceeds to steps ST37 to ST40. In other words, when the condition of step ST36 is satisfied, there is a possibility that the temperature in the room is too high and comfort is impaired. Therefore, when this condition is satisfied, the process proceeds to steps ST37 to ST40, and control is performed to increase the air volume of the latent heat treatment machine (10-L).

At step ST37, the latent heat treatment capacity (CL) of the target latent heat treatment machine (10-L) is obtained from the above equations (1) and (2). Next, in step ST38, the evaporation temperature (target evaporation temperature (TeS)) is calculated. Specifically, the target evaporation temperature (TeS) is the latent heat treatment capacity (CL) of the latent heat treatment machine (10-L), the suction temperature (Th1), and the suction humidity (Rh1) in the above equations (1) and (2). , the changed air volume (Q′), and the bypass factor BF corresponding to the changed air volume (Q′). The target evaporation temperature (TeS) calculated here is higher than the current target evaporation temperature (TeS).

Next, in step ST39, the air volume (Q) of the latent heat processor (10-L) is increased to the air volume (Q'). Specifically, the fan tap of the indoor fan (27) is increased by one tap. Next, in step ST40, the target evaporation temperature (TeS) of the latent heat processor (10-L) is changed to the value calculated in step ST38. That is, in step ST38, the target evaporation temperature (TeS) of the latent heat processor (10-L) is raised.

By increasing the air volume (Q) of the latent heat processor (10-L) and raising the target evaporation temperature (TeS) as described above, the latent heat It is possible to increase the sensible heat processing capacity (CS) while maintaining the processing capacity (CL). Increasing the air volume (Q) of the latent heat processor (10-L) increases the SHF (sensible heat ratio) of the latent heat processor (10-L). Therefore, the indoor temperature can be quickly brought close to the target temperature (RTh), and the dehumidification can be continued to improve indoor comfort. In addition, by increasing the target evaporation temperature (TeS) of the latent heat processor (10-L), the power consumption of the air conditioner (10) (strictly speaking, the compressor (21)) can be suppressed.

In this way, the air volume control of the latent heat treatment machine (10-L) maintains the latent heat treatment capacity of the latent heat treatment machine (10-L). No effect. Therefore, the other air conditioner (10) may turn off the thermostat or the type of the other air conditioner (10) may be switched due to a change in the latent heat treatment capacity of the latent heat treatment device (10-L). can be suppressed.

<Evaporation temperature control of latent heat treatment machine>
After the air volume control of the latent heat processor (10-L) is performed, the evaporation temperature control shown in FIG. 13 is performed. In this evaporation temperature control, basically, the target evaporation temperature is controlled so that the absolute humidity of the intake air of the latent heat treatment machine (10-L) (intake absolute humidity (Rz1)) approaches the target value (target absolute humidity (Rzt)). The temperature (TeS) is controlled, where the suction absolute humidity (Rz1) is determined from the suction temperature (Th1) and the suction humidity (Rh1), the target absolute humidity (Rzt) is the target suction temperature (Th1) and the target suction humidity (Rh1).

FIG. 13 shows an example of evaporation temperature control of the latent heat treatment machine (10-L). In step ST41, if the condition indicating that the evaporation temperature (Te) of the latent heat treatment machine (10-L) has not converged is established, the process proceeds to step ST45, and the target evaporation temperature (TeS) is maintained. . In step ST42, if the suction temperature (Th1) of the latent heat treatment machine (10-L) is lower than a predetermined value (a value obtained by subtracting a predetermined temperature Δt2 (for example, 0.5°C) from the target temperature (RTh)), step ST46 Move to That is, when the suction temperature (Th1) is close to the thermo-off temperature (Thoff), the process proceeds to step ST46 to increase the target evaporation temperature (TeS). In step ST43, when the suction absolute humidity (Rz1) of the latent heat processor (10-L) has converged to the target value, the target evaporation temperature (TeS) is maintained. If none of the conditions of steps ST41 to ST43 are satisfied, the process proceeds to step ST44, and the target evaporation temperature (TeS) is adjusted so that the suction absolute humidity (Rz1) approaches the target value.

<Air volume control of sensible heat treatment machine>
In the sensible heat processor (10-S) during the latent-visual separation operation, the air volume control shown in FIG. 14 is first prioritized. In the air volume control, control is performed to change the indoor air volume (Q) and the target evaporation temperature (TeS) of the air conditioner (10) while maintaining the sensible heat treatment capacity of the sensible heat treatment machine (10-S).

Specifically, in step ST51, the suction temperature (Th1) of the sensible heat treatment machine (10-S) is lower than a predetermined value (for example, the target temperature (RTh), and the fan tap of the sensible heat treatment machine (10-S) is the H tap, the process moves to steps ST52 to ST55.In other words, if the conditions of step ST51 are satisfied, the suction temperature (Th1) reaches the thermo-off temperature (Thoff) or lower and the sensible heat treatment machine (10-S) is thermo-off. Therefore, when this condition is established, the process proceeds to steps ST52 to ST55, and control is performed to reduce the air volume of the sensible heat treatment machine (10-S).

Specifically, in step ST52, the sensible heat treatment capacity (CS) of the target sensible heat treatment machine (10-S) is calculated. This sensible heat treatment capability (CS) is obtained by the above equations (4) and (5). Next, in step ST53, even if the air volume of the current sensible heat treatment machine (10-S) is reduced to a predetermined air volume (Q'), the evaporation temperature (target evaporation temperature (TeS )) is calculated. Specifically, the target evaporation temperature (TeS) is the sensible heat treatment capacity (CS) of the sensible heat treatment machine (10-S), the suction temperature (Th1), and the suction humidity (Rh1) in the above equations (4) and (5). , the changed air volume (Q′), and the bypass factor BF corresponding to the changed air volume (Q′). The target evaporation temperature (TeS) calculated here is lower than the current target evaporation temperature (TeS).

Next, in step ST54, the air volume (Q) of the sensible heat processor (10-S) is reduced to the air volume (Q'). Specifically, the fan tap of the indoor fan (27) is decreased by one tap. Next, in step ST55, the target evaporation temperature (TeS) of the sensible heat processor (10-S) is changed to the value calculated in step ST53. That is, in step ST55, the target evaporation temperature (TeS) of the sensible heat processor (10-S) is lowered.

Here, if the air volume of the sensible heat processor (10-S) is simply decreased and the target evaporation temperature (TeS) is maintained, the intake temperature (Th1) of the sensible heat processor (10-S) will increase as the air volume decreases. It may rise sharply. In this case, there is a possibility that the target evaporation temperature (TeS) is controlled to drop sharply by evaporation temperature control, which will be detailed later. In this case, a so-called undershoot may cause the suction temperature (Th1) to reach the thermo-off temperature (Thoff). On the other hand, when the air volume of the sensible heat processor (10-S) is decreased and the target evaporation temperature (TeS) is lowered as described above, the suction temperature (Th1) of the sensible heat processor (10-S) sharply increases. You can prevent it from rising. Therefore, it is possible to prevent the sensible heat processor (10-S) from reaching the thermo-off state due to the undershoot as described above.

If the target evaporation temperature (TeS) is lowered by this control, the suction temperature (Th1) tends to be lowered. Also, a sufficient control allowance is ensured between the actual evaporation temperature (Te) and the upper limit of the control range of the target evaporation temperature (TeS). Therefore, in subsequent evaporation temperature control, the target evaporation temperature (TeS) gradually increases.

If the condition of step ST51 is not satisfied, the process proceeds to step ST56. In step ST56, the suction temperature (Th1) of the sensible heat treatment machine (10-S) is higher than a predetermined value (a value obtained by adding a predetermined value Δt3 (for example, 1°C) to the target temperature (RTh)), and If the (10-S) fan tap is equal to or less than the M tap and the target evaporation temperature (TeS) is equal to or less than the lower limit value of the control range, the process proceeds to steps ST57 to ST60. In other words, when the condition of step ST56 is satisfied, there is a possibility that the temperature in the room is too high and comfort is impaired. Therefore, when this condition is satisfied, the process proceeds to steps ST57 to ST60, and control is performed to increase the air volume of the sensible heat treatment machine (10-S).

Specifically, in step ST57, the sensible heat treatment capacity (CS) of the target sensible heat treatment machine (10-S) is obtained by the above equations (4) and (5). Next, in step ST58, even if the air volume (Q) of the current sensible heat treatment machine (10-S) is increased to a predetermined air volume (Q') based on the above equations (4) and (5), the calculated sensible heat treatment The evaporation temperature (Te) (target evaporation temperature (TeS)) that can maintain the capacity (CS) is calculated. Specifically, the target evaporation temperature (TeS) is the sensible heat treatment capacity (CS) of the sensible heat treatment machine (10-S), the suction temperature (Th1), and the suction humidity (Rh1) in the above equations (4) and (5). , the changed air volume (Q′), and the bypass factor BF corresponding to the changed air volume (Q′). The target evaporation temperature (TeS) calculated here is higher than the current target evaporation temperature (TeS).

Next, in step ST59, the air volume (Q) of the sensible heat processor (10-S) is increased to the air volume (Q'). Specifically, the fan tap of the indoor fan (27) is increased by one tap. Next, in step ST60, the target evaporation temperature (TeS) of the sensible heat processor (10-S) is changed to the value calculated in step ST58. That is, in step ST60, the target evaporation temperature (TeS) of the sensible heat processor (10-S) is raised.

As described above, when the air volume of the sensible heat processor (10-S) is increased and the target evaporation temperature (TeS) is increased, the sensible heat treatment capacity (CS) of the sensible heat processor (10-S) is maintained. Target evaporation temperature (TeS) can be increased.

Here, if the air volume of the sensible heat processor (10-S) is simply increased and the target evaporation temperature (TeS) is maintained, the suction temperature (Th1) of the sensible heat processor (10-S) increases as the air volume increases. is greatly reduced, and the suction temperature (Th1) may reach the thermo-off temperature (Thoff). On the other hand, if the air volume of the sensible heat processor (10-S) is increased and the target evaporation temperature (TeS) is increased as described above, the suction temperature (Th1) of the sensible heat processor (10-S) will drop significantly. You can prevent it from happening. This can prevent the sensible heat processor (10-S) from reaching the thermo-off state. In addition, since the target evaporation temperature (TeS) of the sensible heat processor (10-S) is increased, the power consumption of the air conditioner (10) can be suppressed.

When the target evaporation temperature (TeS) is increased by this control, the suction temperature (Th1) tends to increase. Also, a sufficient control allowance is ensured between the actual evaporation temperature (Te) and the lower limit of the control range of the target evaporation temperature (TeS). Therefore, in subsequent evaporation temperature control, the target evaporation temperature (TeS) gradually decreases.

As described above, the air volume control of the sensible heat processor (10-S) maintains the sensible heat treatment capacity (CS) of the sensible heat processor (10-S), so it is possible to process with another air conditioner (10). should have no effect on the sensible heat load. Therefore, due to the change in the sensible heat treatment capacity (CS) of the sensible heat treatment machine (10-S), the other air conditioner (10) may turn off the thermostat or switch the type of the other air conditioner (10). can be suppressed.

<Evaporation temperature control of sensible heat treatment machine>
After air volume control of the sensible heat processor (10-S) is performed, evaporation temperature control of the sensible heat processor (10-S) shown in FIG. 15 is performed. In this evaporation temperature control, basically, the target evaporation temperature (TeS) is controlled so that the suction temperature (Th1) of the sensible heat processor (10-S) approaches the target temperature (RTh).

FIG. 15 shows an example of evaporation temperature control of the sensible heat processor (10-S). In step ST61, if the condition that the evaporation temperature (Te) of the latent heat treatment machine (10-L) has not converged or the condition that the suction temperature (Th1) has converged is established, proceed to step ST63, A target evaporation temperature (TeS) is maintained. If the condition of step ST61 is not satisfied, the process proceeds to step ST62, and the target evaporation temperature (TeS) is adjusted so that the suction temperature (Th1) approaches the target temperature (RTh).

<Number change control>
After the air volume control and evaporation temperature control in the latent heat treatment machine (10-L) and the air volume control and evaporation temperature control in the sensible heat treatment machine (10-S) are completed, the type and number of each air conditioner (10) is controlled to change the number of units.

In other words, in the latent-visual separation operation, the evaporation temperature and air volume control of the latent heat treatment machine (10-L) and sensible heat treatment machine (10-S) are prioritized, and even if these controls are performed, the situation does not improve. number change control is performed.

As shown in FIG. 16, in the number change control, the sensible heat treatment machine (10-S) is changed to the latent heat treatment machine (10-L) (step ST82), the sensible heat treatment machine (10-S) is changed to the blower (10 -F) (step ST83), control to change the blower (10-F) to the latent heat treatment machine (10-L) (step ST84), change the latent heat treatment machine (10-L) to the sensible heat treatment machine (10 -S) (step ST85), and control (step ST86) to change the blower (10-F) to the sensible heat treatment machine (10-S).

In the number change control, control for changing the latent heat processor (10-L) to the blower (10-F) is not performed. Condensed moisture easily adheres to the surface of the indoor heat exchanger (25) of the latent heat treatment machine (10-L). Therefore, when the latent heat treatment machine (10-L) is changed to the blower (10-F), the moisture adhering to the surface of the indoor heat exchanger (25) of the blower (10-F) evaporates, This is because there is a risk that it will be released to (5).

As shown in FIG. 16, the number of air conditioners (10) is changed one by one, and the types of two or more air conditioners (10) are not changed at the same time. As a result, it is possible to suppress rapid changes in indoor temperature and humidity.

When changing one of multiple sensible heat processors (10-S) to latent heat processors (10-L), or when multiple fans (10-F) are changed to latent heat processors (10-L) In that case, the above priority order (step ST11 in FIG. 8) is followed. That is, in the present embodiment, among the plurality of air conditioners (10), the one with the smaller horsepower (rated capacity) is preferentially selected as the latent heat treatment machine (10-L). The details of this priority determination will be described later.

The determination in step ST72 shown in FIG. 16 is based on the condition a1 indicating that the indoor humidity is higher than a predetermined value, and the evaporation temperature (Te) of the latent heat processor (10-L) is below a predetermined value (lower limit) of the control range. condition a2 indicating that there is one, condition a3 indicating that the suction temperature (Th1) is lower than a predetermined value (close to the thermo-off temperature (Thoff)), and condition a4 indicating that there is one or more sensible heat processors (10-S) based on

More strictly, the condition a1 is that the difference ΔRz (Rh1−Rh) between the suction humidity (Rh1) of the latent heat processor (10-L) and the target humidity (Rh) is greater than a predetermined value. Condition a2 is that the target evaporation temperature (TeS) of the latent heat processor (10-L) is equal to or lower than a predetermined value (lower limit). Condition a3 is that the difference ΔTh1 (Th1-RTh) between the suction temperature (Th1) of the latent heat processor (10-L) and the target temperature (RTh) is smaller than a predetermined value Δt3.

Here, ΔRz of the condition a1 may be the difference between the suction humidity (Rh1) of the air conditioner (10) in operation and the target humidity (Rh), not necessarily the suction humidity of the latent heat treatment machine (10-L) It does not have to be the difference between (Rh1) and the target humidity (Rh). Specifically, for example, the difference ΔRz between the suction humidity (Rh1) of the sensible heat treatment machine (10-S) and the target humidity (Rh) may be used, or the suction humidity (Rh1) of the blower (10-F) and A difference ΔRz from the target humidity (Rh) may be used. When there are two or more latent heat processors (10-L), the largest or specific ΔRz of these latent heat processors (10-L) can be used for the determination of condition a1. When there are two or more air conditioners (10) in operation, the largest ΔRz of these air conditioners (10) or a specific one may be used to determine condition a1.

The predetermined value of the condition a2 does not necessarily have to be the lower limit of the control range of the evaporation temperature (Te).

Δt3 of condition a3 is set to -0.5° C., for example. Δt3 is a value smaller than 0 and larger than the difference (Thoff-RTh=-1.0° C.) between the thermo-off temperature (Thoff) and the target temperature (RTh).

In this example, when the condition a1 is satisfied, at least one of the conditions a2 and a3 is satisfied, and the condition a4 is satisfied, the process proceeds to step ST82, and one sensible heat treatment machine (10-S) is latent heat Changed to processor (10-L).

In step ST72, at least conditions a1 and a2 are satisfied when the latent heat load in the room is high, but the evaporation temperature (Te) of the latent heat processor (10-L) cannot be lowered any further. Therefore, under such circumstances, one sensible heat processor (10-S) is switched to a latent heat processor (10-L). As a result, the latent heat treatment capacity of the air conditioning system (1) as a whole can be increased, and the suction absolute humidity (Rz1) can quickly converge to the target absolute humidity (Rzt).

In step ST72, for example, at least a1 and a3 are satisfied because the latent heat load in the room is high, but if the evaporation temperature (Te) of the latent heat treatment machine (10-L) is lowered too much, the latent heat treatment machine (10-L ) is at risk of turning off the thermostat. Therefore, under such circumstances, one sensible heat processor (10-S) is switched to a latent heat processor (10-L). As a result, the latent heat treatment capacity of the air conditioning system (1) as a whole can be increased while avoiding the latent heat treatment machine (10-L) from turning off the thermostat.

The condition a3 is also established when the suction temperature (Th1) of the latent heat processor (10-L) is equal to or lower than the thermo-off temperature (Thoff). In this case, the latent heat processor (10-L) turns off the thermostat, but even in this case, if conditions a1 and a4 are satisfied, the process proceeds to step ST82, and the sensible heat processor (10-S) turns off the latent heat processor. (10-L).

The determination in step ST73 is made based on the condition b1 indicating that the suction temperature (Th1) of the sensible heat processor (10-S) is lower than a predetermined value (close to the thermo-off temperature (Thoff)).

More strictly, the condition b1 is that the difference ΔTh1 (Th1-RTh) between the intake temperature (Th1) of the sensible heat processor (10-S) and the target temperature (RTh) is smaller than a predetermined value Δt4.

Δt4 of condition b1 is set to -0.5° C., for example. Δt4 is a value smaller than 0 and larger than the difference (Thoff-RTh=-1.0° C.) between the thermo-off temperature (Thoff) and the target temperature (RTh).

In this example, when the condition b1 is satisfied, the process proceeds to step ST83, and one sensible heat treatment machine (10-S) is changed to the blower (10-F).

At step ST73, the condition b1 is established when there is a risk that the sensible heat processor (10-S) will turn off the thermostat. Therefore, under such circumstances, one sensible heat processor (10-S) is switched to a fan (10-F). The air volume (Q) of the fan (10-F) is greater than the air volume of the cooler in the thermo-off state. Therefore, the air in the indoor space (5) can be sufficiently agitated, and uneven temperature and humidity in the indoor space (5) can be suppressed.

The condition b1 is also satisfied when the suction temperature (Th1) of the sensible heat processor (10-S) is equal to or lower than the thermo-off temperature (Thoff). In this case, the sensible heat processor (10-S) turns off the thermostat, but in this case also, the process proceeds to step T83 and is changed to the fan (10-F).

In step ST73, the condition b2 that the number of sensible heat processors (10-S) is one or more may be added.

The judgment in step ST74 is condition c1 indicating that the indoor humidity is higher than a predetermined value, and indicating that the evaporation temperature (Te) of the latent heat treatment machine (10-L) is below a predetermined value (lower limit) of the control range. This is done based on condition c2 and condition c3 indicating that the suction temperature (Th1) of the blower (10-F) is higher than a predetermined value.

More strictly, the condition c1 is that the difference ΔRz (Rh1−Rh) between the suction humidity (Rh1) of the latent heat processor (10-L) and the target humidity (Rh) is greater than a predetermined value. Condition c2 is that the target evaporation temperature (TeS) of the latent heat processor (10-L) is equal to or less than a predetermined value (lower limit). Condition c3 is that the difference ΔTh1 (Th1-RTh) between the intake temperature (Th1) of the fan (10-F) and the target temperature (RTh) is greater than a predetermined value Δt5.

Here, ΔRz of the condition c1 may be the difference between the suction humidity (Rh1) of the air conditioner (10) in operation and the target humidity (Rh), not necessarily the suction humidity of the latent heat treatment machine (10-L) It does not have to be the difference between (Rh1) and the target humidity (Rh). Specifically, for example, the difference ΔRz between the suction humidity (Rh1) of the sensible heat treatment machine (10-S) and the target humidity (Rh) may be used, or the suction humidity (Rh1) of the blower (10-F) and A difference ΔRz from the target humidity (Rh) may be used. If there are two or more latent heat processors (10-L), the largest or specific ΔRz of these latent heat processors (10-L) can be used for the determination of condition c1. When there are two or more air conditioners (10) in operation, the largest ΔRz of these air conditioners (10) or a specific one can be used for the determination of condition c1.

The predetermined value of condition c2 does not necessarily have to be the lower limit of the control range of the evaporation temperature (Te).

Δt5 of condition c3 is set to -0.5° C., for example. Δt5 is a value smaller than 0 and larger than the difference (Thoff-RTh=-1.0° C.) between the thermo-off temperature (Thoff) and the target temperature (RTh).

In this example, when conditions c1, c2, and c3 are all satisfied, the process proceeds to step ST84, and one fan (10-F) is changed to a latent heat processor (10-L).

In step ST74, all of the conditions c1, c2, and c3 are satisfied because the latent heat load in the room is high, but the evaporation temperature (Te) of the latent heat processor (10-L) cannot be lowered any further, In addition, the suction temperature (Th1) of the fan (10-F) is high. Therefore, under such circumstances, one fan (10-F) is replaced with a latent heat processor (10-L). As a result, the latent heat treatment capacity of the entire air conditioning system (1) can be increased, and the suction absolute humidity (Rz1) can quickly converge to the target absolute humidity (Rzt).

In step ST74, the determination of condition c4 that the number of blowers (10-F) is one or more may be added.

The determination in step ST75 is based on condition d1 indicating that the indoor humidity is lower than a predetermined value, condition d2 indicating that the suction temperature (Th1) of the latent heat treatment machine (10-L) is higher than a predetermined value, and condition d2 indicating that the latent heat treatment machine ( 10-L) is equal to or higher than a predetermined value (upper limit) of the control range, and condition d4 indicates that the number of latent heat treatment machines (10-L) is two or more. based on

More strictly, the condition d1 is that the difference ΔRz (Rh1−Rh) between the suction humidity (Rh1) of the latent heat processor (10-L) and the target humidity (Rh) is smaller than a predetermined value. Condition d2 is that the difference ΔTh1 (Th1-RTh) between the suction temperature (Th1) of the latent heat processor (10-L) and the target temperature (RTh) is greater than a predetermined value Δt6. Condition d3 is that the target evaporation temperature (TeS) is equal to or higher than a predetermined value (upper limit).

ΔRz of the condition d1 may be the difference between the suction humidity (Rh1) of the air conditioner (10) in operation and the target humidity (Rh), not necessarily the suction humidity (Rh1) of the latent heat treatment machine (10-L). and the target humidity (Rh). Specifically, for example, the difference ΔRz between the suction humidity (Rh1) of the sensible heat treatment machine (10-S) and the target humidity (Rh) may be used, or the suction humidity (Rh1) of the blower (10-F) and A difference ΔRz from the target humidity (Rh) may be used. When there are two or more latent heat processors (10-L), the largest or specific ΔRz of these latent heat processors (10-L) can be used to determine condition d1. When there are two or more air conditioners (10) in operation, the largest ΔRz of these air conditioners (10) or a specific one can be used to determine condition d1.

Δt6 of condition d2 is set to -0.5° C., for example. Δt6 is a value smaller than 0 and larger than the difference W (Thoff−RTh=−1.0° C.) between the thermooff temperature (Thoff) and the target temperature (RTh).

The predetermined value of the condition d3 does not necessarily have to be the upper limit of the control range of the evaporation temperature (Te).

In this example, when all of the conditions d1, d2, d3, and d4 are satisfied, the process proceeds to step ST85, and one latent heat treatment machine (10-L) becomes the sensible heat treatment machine (10-S). is changed to

In step ST75, at least the conditions d1, d2, and d3 are satisfied when the latent heat load in the room is low, the suction temperature (Th1) of the latent heat treatment machine (10-L) is slightly high, and the latent heat treatment machine (10-L) It is a situation where the evaporation temperature (Te) cannot be increased any further. Therefore, under such circumstances, one latent heat processor (10-L) is replaced with a sensible heat processor (10-S). As a result, the SHF of the entire air conditioning system (1) is increased, and the sensible heat load can be treated preferentially.

The determination in step ST76 is made based on condition e1 indicating that the intake temperature (Th1) of the blower (10-F) is higher than a predetermined value.

More strictly, the condition e1 is that the difference ΔTh1 (Th1-RTh) between the intake temperature (Th1) of the fan (10-F) and the target temperature (RTh) is greater than a predetermined value Δt7.

Δt7 of condition e1 is set to +0.5° C., for example. Δt7 is a value greater than zero. In this example, when the condition e1 is satisfied, the process proceeds to step ST86, and one blower (10-F) is changed to the sensible heat treatment machine (10-S).

In step ST76, the condition e1 is satisfied when the suction temperature (Th1) of the blower (10-F) is high. Therefore, under such circumstances, one fan (10-F) is replaced with a sensible heat processor (10-S). As a result, the sensible heat treatment capacity of the entire air conditioning system (1) can be increased.

In step ST76, the condition e2 that the number of blowers (10-F) is one or more may be added.

In the number change control, after the number of air conditioners (10) is changed in steps ST81 to ST86, the next number (type) is prohibited from being changed until a predetermined time C elapses (step ST71). This predetermined time C is set to the update interval ΔT×n (n is the number of updates, eg, n≧2). That is, when the number of times of communication/control for updating the control parameter is less than n times after the number of air conditioners (10) is changed, the process proceeds to step ST81. In this case, changing the number of air conditioners (10) is prohibited. On the other hand, after the number of air conditioners (10) is changed, when the number of times of communication/control for updating the control parameters reaches n times, the process proceeds to steps ST72 to ST76. In this case, a change in the number of air conditioners (10) is allowed again. By restricting changes in the number and types of air conditioners (10) in this way, it is possible to suppress rapid changes in indoor temperature and humidity.

<Priority determination of latent heat treatment machines>
In the preliminary operation determination process and the number change control described above, the latent heat treatment machine (10-L) is selected according to the determined priority. This priority determination method (selection process) will be described in detail with reference to FIG.

In the selection process, an air conditioner (10) having a small index indicating the air volume of indoor air among the plurality of air conditioners (10) is selected as the latent heat treatment machine (10-L). In this example, the horsepower (rated capacity) of the air conditioner (10) is used as an index indicating the air volume of the indoor air. Generally, there is a correlation between the air volume of the indoor fan (27) and the horsepower of the air conditioner (10), and the horsepower increases as the air volume increases. Therefore, the horsepower of the air conditioner (10) is an index indicating the volume of indoor air. The rated air volume, minimum air volume, maximum air volume, etc. of the indoor fan (27) may be used as an index indicating the air volume of the indoor air.

In the air conditioning system (1) of the example shown in FIG. 17, there are five air conditioners (10) from NO.1 to NO.5. The horsepower of No.1 air conditioner (10) is 2.0, the horsepower of No.2 and No.3 air conditioners (10) is 2.5, and the horsepower of No.4 and No.5 is 3.0. In the selection process of this example, among these air conditioners (10), the No. 1 air conditioner (10) with the lowest horsepower (index indicating air volume) has the highest priority (first place). ).

In the example of FIG. 17, the No. 2 and No. 3 air conditioners (10) have the second highest horsepower after the No. 1 air conditioner (10). The horsepower of the air conditioners (10) of NO.2 and NO.3 is 2.5, which are equal to each other. In the priority selection process, if at least two air conditioners (10) have the same horsepower (indicator indicating air volume), the temperature of the intake air (intake temperature (Th1) ) is selected preferentially. In this example, the intake temperature (Th1) of the NO.2 air conditioner (10) is 28°C, and the intake temperature (Th1) of the NO.3 air conditioner (10) is 27.5°C. Therefore, in this example, the priority of the No. 2 air conditioner (10), which has a higher intake temperature, is higher and comes second. The No. 3 air conditioner (10) has the 3rd priority.

In this example, the remaining No. 4 and No. 5 air conditioners (10) have the same horsepower (an index indicating the air volume), and their suction temperatures (Th1) are also the same. In this case, these priorities are determined based on, for example, a preset identification number of the air conditioner (10).

As described above, in the selection process of the present embodiment, priority is given to the latent heat treatment machine (10-L) that has a small index indicating the air volume. In the latent heat processor (10-L) with a small air volume, the flow rate bypassing the indoor heat exchanger (25) is small, and the contact time between the indoor air and the indoor heat exchanger (25) is long. As a result, the amount of water condensed on the surface of the indoor heat exchanger (25) increases, and the SHF (sensible heat ratio) of the latent heat processor (10-L) decreases. Therefore, the latent heat treatment capacity of the air conditioning system (1) can be sufficiently exhibited by preferentially setting the latent heat treatment machine (10-L) to the one with the smaller index indicating the air volume.

In this example, when the plurality of air conditioners (10) have the same horsepower, the one with the higher suction temperature (Th1) is preferentially used as the latent heat processor (10-L). If the latent heat treatment machine (10-L) is used as the air conditioner (10) with a relatively low suction temperature (Th1), the suction temperature (Th1) of the latent heat treatment machine (10-L) becomes excessively low, and the thermo-off temperature ( Thoff). On the other hand, by preferentially setting the air conditioner (10) having a high suction temperature (Th1) as the latent heat processor (10-L), it is possible to suppress the thermo-off of the latent heat processor (10-L).

- Effects of the embodiment -
In the above embodiment, during the preliminary operation or during the latent/visual separation operation, when performing the selection process for selecting the latent heat treatment machine (10-L), the air volume of the indoor air among the plurality of air conditioners (10) is indicated. The air conditioner (10) with a small index is preferentially selected as the latent heat treatment machine (10-L). Specifically, in the example of FIG. 17, the air conditioner (10) with the lowest horsepower is given the highest priority as the latent heat processor (10-L).

An air conditioner (10) with a small air volume index has a high SHF and a high latent heat treatment capacity compared to a sensible heat treatment capacity. If the air conditioner (10) with low latent heat treatment capacity is changed to the latent heat treatment machine (10-L), the target evaporating temperature (TeS) will be excessively low, and the target evaporating temperature (TeS) will reach the lower limit. , the thermostat may be turned off. On the other hand, by selecting an air conditioner (10) with a high latent heat treatment capacity as the latent heat treatment machine (10-L), it is possible to suppress the target evaporation temperature (TeS) from becoming excessively low, thereby preventing such problems. can be avoided.

In the above embodiment, in the selection process, if the indices indicating the air volumes of the plurality of air conditioners (10) are equal, the air conditioner (10) having the higher intake air temperature among these air conditioners (10) is selected. Prioritize selection.

An air conditioner (10) with a high suction temperature (Th1) is less likely to turn off the thermostat than an air conditioner (10) with a low suction temperature (Th1). Therefore, by setting the air conditioner (10) having a high intake temperature (Th1) as the latent heat treatment machine (10-L), it is possible to prevent the latent heat treatment machine (10-L) from turning off the thermostat thereafter. .

In the above embodiment, in the latent-visual separation operation, when switching one of the plurality of sensible heat treatment machines (10-S) to the latent heat treatment machine (10-L) (step ST82 in FIG. 16), shown in FIG. Perform selection processing. Therefore, the air conditioner (10) having excellent latent heat processing capability can be switched to the latent heat processing device (10-L), and the latent heat load of the indoor space (5) can be quickly processed.

In the above embodiment, in the latent-visual separation operation, when switching one of the plurality of blowers (10-F) to the latent heat treatment machine (10-L) (step ST84 in FIG. 16), the selection process shown in FIG. I do. Therefore, the air conditioner (10) having excellent latent heat processing capability can be switched to the latent heat processing device (10-L), and the latent heat load of the indoor space (5) can be quickly processed.

<<Other embodiments>>
The above-described embodiment (including other modifications, etc.) may have the following configuration.

The air conditioner (10) does not have to be a pair type. For example, a so-called multi system in which two or more indoor units (12) are connected to one outdoor unit (11) may be used.

In the above embodiment, the control device (40) is configured by connecting the additional unit to the existing unit, but the control device (40) may be configured without the additional unit. For example, by providing the main control section (45) in the local controller (41), the control device (40) can be configured without using a communication line such as the Internet (I).

Although the embodiments have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the claims. Moreover, the above-described embodiments and modifications may be appropriately combined or replaced as long as the functions of the object of the present disclosure are not impaired. The descriptions of "first", "second", "third", etc. described above are used to distinguish the words and phrases to which these descriptions are given, and even the quantity and order of the words and phrases are limited. not something to do.

INDUSTRIAL APPLICABILITY As described above, the present invention is useful for air conditioning systems.

1 air conditioning system
5 Interior space
10 Air conditioner
10-L latent heat treatment machine
10-S Sensible Heater
10-F blower
40 control unit

Claims (4)

a plurality of air conditioners (10) each having an indoor heat exchanger (25) and an indoor fan (27), performing a refrigerating cycle individually and targeting the same indoor space (5);
A control device (40) for executing an operation including a state in which at least one of the plurality of air conditioners (10) is a latent heat treatment machine (10-L) and at least one is a sensible heat treatment machine (10-S). and
The control device (40)
When performing a selection process for selecting the latent heat treatment machine (10-L) from among the plurality of air conditioners (10),
An air conditioner (10) having a small minimum air volume of the indoor fan (27) among the plurality of air conditioners (10) is preferentially selected as the latent heat treatment device (10-L). system. In claim 1,
When performing the selection process, the control device (40) selects at least two air conditioners (10), if the indoor fans (27) have the same minimum air volume, among these air conditioners (10) An air conditioning system characterized by preferentially selecting an air conditioner (10) having a high intake air temperature as the latent heat processor (10-L). In claim 1 or 2,
During the operation, the control device (40)
An air conditioning system characterized by performing the selection process when selecting the latent heat treatment machine (10-L) from at least two sensible heat treatment machines (10-S). In any one of claims 1 to 3,
The control device (40)
In the operation, the air conditioner (10) is configured to be switchable to the blower (10-F),
An air conditioning system characterized by performing the selection process when selecting the latent heat processor (10-L) from at least two fans (10-F) during the operation.

Images